TD 756 .5 .C665 Tt w ° ; •’bs? ° r\ o ^%y||fvo$ C aV -/V ^ ^p£|lir o o r *K°ygWs & % +*0KSr+ & 4 °3W* n r f*0* * JlfjSj * gV ° g^lgjg; a '/* 0 ' * * u> ~ *va » ^ % United States Environmental Protection Agency Manual Office of Research and EPA/625/R-99/010 Development September 2000 Cincinnati, Ohio 45268 http://www.epa.gov/ORD/NRMRL Constructed Wetlands Treatment of Municipal Wastewaters EPA/625/R-99/010 Manual Constructed Wetlands Treatment of Municipal Wastewaters National Risk Management Research Laboratory Office of Research and Development U.S. Environmental Protection Agency Cincinnati, Ohio 45268 Printed on Recycled Paper Notice This document has been reviewed in accordance with the U.S. Environmental Protection Agency’s peer and administrative review policies and approved for publication. Mention of trade names or commercial products does not constitute endorsement or recommendation for use. , C 1 n I h LC Control Number 00 329464 Foreword The U.S. Environmental Protection Agency is charged by Congress with protecting the Nation’s land, air, and water resources. Under a mandate of national environmental laws, the Agency strives to formulate and implement actions leading to a compatible balance between human activities and the ability of natural systems to support and nurture life. To meet this mandate, EPA’s research program is providing data and technical support for solving environ¬ mental prob-lems today and building a science knowledge base necessary to manage our eco¬ logical re-sources wisely, understand how pollutants affect our health, and prevent or reduce environmen-tal risks in the future. The National Risk Management Research Laboratory is the Agency’s center for investiga¬ tion of technicological and management approaches for reducing risks from threats to human health and the environment. The focus of the Laboratory’s research program is on methods for the prevention and control of pollution to air, land, water and subsurface resources; protection of water quality in public water systems; remediation of contaminated sites and ground water; and prevention and control of indoor air pollution. The goal of this research effort is to catalyze development and implementation of innovative, cost-effective environmental technologies; de¬ velop scientific and engineering information needed by EPA to support regulatory and policy decisions; and provide technical support and information transfer to ensure effective implemen¬ tation of environmental regulations and strategies. This publication has been produced as part of the Laboratory’s strategic long-term research plan. It is published and made available by EPA’s Office of Research and Development to assist the user community and to link researchers with their clients. E. Timothy Oppelt, Director National Risk Management Research Laboratory Abstract This manual discusses the capabilities of constructed wetlands, a functional design ap¬ proach, and the management requirements to achieve the designed purpose. The manual also attempts to put the proper perspective on the appropriate use, design and performance of con¬ structed wetlands. For some applications, they are an excellent option because they are low in cost and in maintenance requirements, offer good performance, and provide a natural appear¬ ance, if not more beneficial ecological benefits. In other applications, such as large urban areas with large wastewater flows, they may not be at all appropriate owing to their land requirements. Constructed wetlands are especially well suited for wastewater treatment in small communities where inexpensive land is available and skilled operators hard to find and keep. Primary customers will be engineers who service small communities, state regulators, and planning professionals. Secondary users will be environmental groups and the academics. IV Contents Chapter 1 Introduction.1 1.1. Scope.1 1.2. Terminology.1 1.3. Relationship to Previous EPA Documents.2 1.4. Wetlands Treatment Database.2 1.5. History.4 1.6. Common Misperceptions.4 1.7. When to Use Constructed Wetlands.5 1.8 Use of This Manual.8 1.9 References.8 Chapter 2 Introduction to Constructed Wetlands.10 2.1 Understanding Constructed Wetlands.10 2.2 Ecology of Constructed Wetlands.12 2.3 Botany of Constructed Wetlands.12 2.4 Fauna of Constructed Wetlands.16 2.5 Ecological Concerns for Constructed Wetland Designers.16 2.6 Human Health Concerns.18 2.7 Onsite System Applications.19 2.8 Related Aquatic Treatment Systems.19 2.9 Frequently Asked Questions.20 2.10 Glossary.23 2.11 References.27 Chapter 3 Removal Mechanisms and Modeling Performance of Constructed Wetlands.30 3.1 Introduction.30 3.2 Mechanisms of Suspended Solids Separations and Transformations.30 3.3 Mechanisms for Organic Matter Separations and Transformations. 35 3.4 Mechanisms of Nitrogen Separations and Transformations.42 3.5 Mechanisms of Phosphorus Separations and Transformations.46 3.6 Mechanisms of Pathogen Separations and Transformations.48 3.7 Mechanisms of Other Contaminant Separations and Transformations.49 3.8 Constructed Wetland Modeling.50 3.9 References.52 Chapter 4 Free Water Surface Wetlands.55 4.1 Performance Expectations.55 4.2 Wetland Hydrology.64 4.3 Wetland Hydraulics.65 4.4 Wetland System Design and Sizing Rationale.68 4.5 Design.69 4.6 Design Issues.78 4.7 Construction/Civil Engineering Issues.81 4.8 Summary of Design Recommendations.83 4.9 References.83 v Contents (cont.) Chapter 5 Vegetated Submerged Beds.86 5.1 Introduction.86 5.2 Theoretical Considerations.86 5.3 Hydrology.91 5.4 Basis of Design.93 5.5 Design Considerations.101 5.6 Design Example for a VSB Treating Septic Tank or Primary Effluent.103 5.7 On-site Applications.106 5.8 Alternative VSB Systems.106 5.9 References.107 Chapter 6 Construction, Start-Up, Operation, and Maintenance.Ill 6.1 Introduction.Ill 6.2 Construction.Ill 6.3 Start-Up.117 6.4 Operation and Maintenance.118 6.5 Monitoring.119 6.6 References.119 Chapter 7 Capital and Recurring Costs of Constructed Wetlands.120 7.1 Introduction.120 7.2 Construction Costs.120 7.3 Operation and Maintenance Costs.125 7.4 References.127 Chapter 8 Case Studies.128 8.1 Free Water Surface (FWS) Constructed Wetlands.128 8.2 Vegetated Submerged Bed (VSB) Systems.141 8.3 Lessons Learned.152 VI List of Figures 2-1 Constructed wetlands in wastewater treatment train.11 2-2 Elements of a free water surface (FWS) constructed wetland.11 2-3 Elements of a vegetated submerged bed (VSB) system.11 2- 4 Profile of a 3-zone FWS constructed wetland cell.18 3- 1 Mechanisms which dominate FWS systems.32 3-2 Weekly transect TSS concentration for Areata cell 8 pilot receiving oxidation pond effluent.34 3-3 Variation in effluent BOD at the Areata enhancement marsh.36 3-4 Carbon transformations in an FWS wetland.37 3-5 Dissolved oxygen distribution in emergent and submergent zones of a tertiary FWS.40 3-6 Nitrogen transformations in FWS wetlands.43 3-7 Phosphorus cycling in an FWS wetland.47 3-8 Phosphorus pulsing in pilot cells in Areata.48 3-9 Influent versus effluent FC for the TADB systems.49 3- 10 Adaptive model building.51 4- 1 Effluent BOD vs areal loading.57 4-2 Internal release of soluble BOD during treatment.57 4-3 Annual detritus BOD load from Scirpus & Typha.58 4-4 TSS loading vs TSS in effluent.58 4-5 Effluent TKN vs TKN loading.59 4-6 Effluent TP vs TP areal loading.61 4-7 Total phosphorus loading versus effluent concentration for TADB systems.61 4-8 Hydraulic retention time vs orthophosphate removal.62 4-9 Influent versus effluent FC concentration for TADB systems.63 4-10 TSS, BOD and FC removals for Areata Pilot Cell 8.63 4-11 Tracer response curve for Sacramento Regional Wastewater Treatment Plant Demonstration Wetlands Project Cell 7.67 4-12 Transect BOD data for Areata Pilot Cell 8.71 4-13 Elements of a free water surface (FWS) constructed wetland.71 4- 14 Generic removal of pollutants in a 3-zone FWS system.72 5- 1 Seasonal cycle in a VSB.90 5-2 Preferential flow in a VSB.93 5-3 Lithium chloride tracer studies in a VSB system.94 5-4 Effluent TSS vs areal loading rate.95 5-5 Effluent TSS vs volumetric loading rate.95 5-6 Effluent BOD vs areal loading rate.96 5-7 Effluent BOD vs volumetric loading rate.96 5-8 Effluent TKN vs areal loading rate.98 5-9 Effluent TP vs areal loading rate.99 5-10 NADB VSBs treating pond effluent.100 5- 11 Proposed Zones in a VSB.102 6- 1 Examples of constructed wetland berm construction.112 6-2 Examples of constructed wetland inlet designs.114 VII List of Figures (cont.) 6-3 Outlet devices.115 8-1 Schematic diagram of wetland system at Areata, CA.129 8-2 Schematic diagram of Phase 1 &2 wetland systems at West Jackson County, MS.132 8-3 Schematic diagram of Phase 3 wetland expansion at West Jackson County, MS.132 8-4 Schematic diagrams of the wetland system at Gustine, CA.136 8-5 Schematic diagram of the wetland system at Ouray, CO.140 8-6 Schematic of Minoa, NY, VSB system.142 8-7 Schematic diagram of typical VSB (one of three) at Mesquite, NV.145 8-8 Schematic of VSB system at Mandeville, LA.147 8-9 Schematic of VSB system at Sorrento, LA.151 VIII List of Tables 1-1. Types of Wetlands in the NADB.3 1-2. Types of Wastewater Treated and Level of Pretreatment for NADB Wetlands.3 1-3. Size Distribution of Wetlands in the NADB.4 1-4. Distribution of Wetlands in the NADB by State/Province.4 1- 5. Start Date of Treatment Wetlands in the NADB.4 2- 1 Characteristics of Plants for Constructed Wetlands.14 2-2 Factors to Consider in Plant Selection.15 2- 3 Characteristics of Animals Found in Constructed Wetlands.16 3- 1 Typical Constructed Wetland Influent Wastewater.30 3-2 Size Distributions for Solids in Municipal Wastewater.31 3-3 Size Distribution for Organic and Phosphorus Solids in Municipal Wastewater.31 3-4 Fractional Distribution of BOD, COD, Turbidity and TSS in the Oxidation Pond Effluent and Effluent from Marsh Cell 5.34 3-5 Background Concentrations of Contaminants of Concern in FWS Wetland Treatment System Effluents.35 3- 6 Wetland Oxygen Sources and Sinks.41 4- 1 Loading and Performance Data for Systems Analyzed in This Document.56 4-2 Trace Metal Concentrations and Removal Rates, Sacramento Regional Wastewater Treatment Plant.63 4-3 Fractional Distribution of BOD, COD and TSS in the Oxidation Pond Effluent and Effluent from Marsh Cell 5.64 4-4 Background Concentrations of Water Quality Constituents of Concern in FWS Constructed Wetlands.70 4-5 Examples of Change in Wetland Volume Due to Deposition of Non-Degradable TSS (V ss ) and Plant Detritus (V d ) Based on 100 Percent Emergent Plant Coverage.74 4-6 Lagoon Influent and Effluent Quality Assumptions.77 4- 7 Recommended Design Criteria for FWS Constructed Wetlands.83 5- 1 Hydraulic Conductivity Values Reported in the Literature.92 5-2 Comparison of VSB Areas Required for BOD Removal Using Common Design Approaches.97 5-3 Data from Las Animas, CO VSB Treating Pond Effluent.100 5-4 Summary of VSB Design Guidance.106 7-1 Cost Comparison of 4,645m 2 Free Water Surface Constructed Wetland and Vegetated Submerged Bed.121 7-2 Technical and Cost Data for Wetland Systems Included in 1997 Case Study Visitations.121 7-3 Clearing and Grubbing Costs for EPA Survey Sites.122 7-4 Excavation and Earthwork Costs for EPA Survey Sites.122 7-5 Liner Costs for EPA Survey Sites.123 7-6 Typical Installed Liner Costs for 9,300m 2 Minimum Area.123 7-7 Media Costs for VSBs from EPA Survey Sites.124 7-8 Costs for Wetland Vegetation and Planting from EPA Survey Sites.124 7-9 Costs for Inlet and Outlet Structures from EPA Sites.124 7-10 Range of Capital Costs for a 0.4 ha Membrane-Lined VSB and FWS Wetland.126 7-11 Annual O&M Costs at Carville, LA (570m 3 /d) Vegetated Submerged Bed.127 7-12 Annual O&M Costs for Constructed Wetlands, Including All Treatment Costs.127 IX List of Tables (cont.) 8-1 Summary of Results, Phase 1 Pilot Testing, Areata, CA.130 8-2 Long-Term Average Performance, Areata WWTP.131 8-3 Wetland Water Quality, West Jackson County, MS.134 8-4 Performance Results in Mature Vegetated vs Immature Vegetated FWS Cells, Gustine, CA.138 8-5 Wetland Effluent Characteristics, Gustine, CA.139 8-6 BOD & TSS Removal for Ouray, CO.141 8-7 Village of Minoa VSB Construction Costs.143 8-8 Summary Performance, Mesquite, NV, VSB Component.146 8-9 Monthly Effluent Characteristics, Mesquite, NV, VSB Component.146 8-10 Water Quality Performance, Mandeville, LA, Treatment System (June - Sept., 1991).149 8-11 Water Quality Performance, Mandeville, LA, Treatment System (Jan. 1996 - July 1997). 150 8-12 VSB Effluent Water Quality, Sorrento, LA.152 x Acknowledgements Many people participated in the creation of this manual. Technical direction throughout the multi-year production process was provided by USEPA’s National Risk Management Research Laboratory (NRMRL). Technical writing was carried out in several stages, but culminated into a final product as a cooperative effort between the NRMRL and the contractors named below. Significant technical reviews and contributions based on extensive experience with constructed wetlands were made by a number of prominent practitioners. Technical review was provided by a group of professionals with extensive experience with the problems specific to small commu¬ nity wastewater treatment systems. The production of the document was also a joint effort by NRMRL and contractual personnel. All of these people are listed below: Primary Authors and Oversight Committee Donald S. Brown, Water Supply and Water Resources Division, NRMRL, Cincinnati, OH James F. Kreissl, Technology Transfer and Support Division, NRMRL, Cincinnati, OH Robert A. Gearheart, Humboldt University, Areata, CA Andrew P. Kruzic, University of Texas at Arlington, Arlington, TX William C. Boyle, University of Wisconsin, Madison, Wl Richard J. Otis, Ayres Associates, Madison, Wl Major Contributors/Authors Sherwood C. Reed, Environmental Engineering Consultants, Norwich, VT Richard Moen, Ayres Associates, Madison, Wl Robert Knight, Consultant, Gainesville, FL Dennis George, Tennessee Technological University, Cookeville, TN Michael Ogden, Southwest Wetlands Group, Inc., Santa Fe, NM Ronald Crites, Brown and Caldwell, Sacramento, CA George Tchobanoglons, Consultant, Davis, CA Contributing Writers/Production Specialists Ian Clavey, CEP Inc., Cincinnati, OH Vince lacobucci, CEP Inc., Cincinnati, OH Julie Hotchkiss, CEP Inc., Cincinnati, OH Peggy Heimbrock, TTSD - NRMRL, Cincinnati, OH Stephen E. Wilson, TTSD - NRMRL, Cincinnati, OH Denise Ratliff, TTSD - NRMRL, Cincinnati, OH Betty Kampsen, STD - NRMRL, Cincinnati, OH Technical Reviewers Arthur H. Benedict, EES Consulting, Inc., Bellevue, WA Pio Lombardo, Lombardo Associates, Inc., Newton, MA Rao Surampalli, USEPA- Region VII, Kansas City, KS Robert K. Bastian, USEPA - Office of Wastewater Management, Washington, DC XI Chapter 1 Introduction to the Manual 1.1. Scope Constructed wetlands are artificial wastewater treatment systems consisting of shallow (usually less than 1 m deep) ponds or channels which have been planted with aquatic plants, and which rely upon natural microbial, biological, physical and chemical processes to treat wastewater. They typically have impervious clay or synthetic liners, and en¬ gineered structures to control the flow direction, liquid de¬ tention time and water level. Depending on the type of sys¬ tem, they may or may not contain an inert porous media such as rock, gravel or sand. Constructed wetlands have been used to treat a variety of wastewaters including urban runoff, municipal, indus¬ trial, agricultural and acid mine drainage. However, the scope of this manual is limited to constructed wetlands that are the major unit process in a system to treat munici¬ pal wastewater. While some degree of pre- or post- treat¬ ment will be required in conjunction with the wetland to treat wastewater to meet stream discharge or reuse re¬ quirements, the wetland will be the central treatment com¬ ponent. This manual discusses the capabilities of constructed wetlands, a functional design approach, and the manage¬ ment requirements to achieve the designed purpose. This manual also attempts to put the proper perspective on the appropriate use of constructed wetlands. For some appli¬ cations, they are an excellent option because they are low in cost and in maintenance requirements, offer good per¬ formance, and provide a natural appearance, if not more beneficial ecological benefits. However, because they re¬ quire large land areas, 4 to 25 acres per million gallons of flow per day, they are not appropriate for some applica¬ tions. Constructed wetlands are especially well suited for wastewater treatment in small communities where inex¬ pensive land is available and skilled operators are hard to find. 1.2 Terminology A brief discussion of terminology will help the reader dif¬ ferentiate between the constructed wetlands discussed in this manual and other types of wetlands. Wetlands are defined in Federal regulations as “those areas that are in¬ undated or saturated by surface or ground water at a fre¬ quency and duration sufficient to support, and that under normal circumstances do support, a prevalence of veg¬ etation typically adapted for life in saturated soil condi¬ tions. Wetlands generally include swamps, marshes, bogs and similar areas.” (40 CFR 230.3(t)) Artificial wetlands are wetlands that have been built or extensively modified by humans, as opposed to natural wetlands which are existing wetlands that have had little or no modification by humans, such as filling, draining, or altering the flow pat¬ terns or physical properties of the wetland. The modifica¬ tion or direct use of natural wetlands for wastewater treat¬ ment is discouraged and natural wetlands are not dis¬ cussed in this manual (see discussion of policy issues in Section 1.7.2). As previously defined, constructed wetlands are artifi¬ cial wetlands built to provide wastewater treatment. They are typically constructed with uniform depths and regular shapes near the source of the wastewater and often in upland areas where no wetlands have historically existed. Constructed wetlands are almost always regulated as wastewater treatment facilities and cannot be used for compensatory mitigation (see Section 1.7.2). Some EPA documents refer to constructed wetlands as constructed treatment wetlands to avoid any confusion about their pri¬ mary use as a wastewater treatment facility (USEPA, 1999). Constructed wetlands which provide advanced treatment to wastewater that has been pretreated to sec¬ ondary levels, and also provide other benefits such as wildlife habitat, research laboratories, or recreational uses are sometimes called enhancement wetlands. Constructed wetlands have been classified by the lit¬ erature and practitioners into two types. Free water sur¬ face (FWS) wetlands (also known as surface flow wet¬ lands) closely resemble natural wetlands in appearance because they contain aquatic plants that are rooted in a soil layer on the bottom of the wetland and water flows through the leaves and stems of plants. Vegetated sub¬ merged bed (VSB) systems (also known as subsurface flow wetlands) do not resemble natural wetlands because they have no standing water. They contain a bed of media (such as crushed rock, small stones, gravel, sand or soil) which has been planted with aquatic plants. When prop¬ erly designed and operated, wastewater stays beneath the surface of the media, flows in contact with the roots and rhizomes of the plants, and is not visible or available to wildlife. 1 The term “vegetated submerged bed” is used in this manual instead of subsurface flow wetland because it is a more ac¬ curate and descriptive term. The term has been used previ¬ ously to describe these units (WPCF, 1990; USEPA, 1994). Some VSBs may meet the strict definition of a wetland, but a VSB does not support aquatic wildlife because the water level stays below the surface of the media, and is not condu¬ cive to many of the biological and chemical interactions that occur in the water and sediments of a wetland with an open water column. VSBs have historically been characterized as constructed wetlands in the literature, and so they are in¬ cluded in this manual. Constructed wetlands should not be confused with cre¬ ated or restored wetlands, which have the primary function of wildlife habitat. In an effort to mimic natural wetlands, the latter often have a combination of features such as varying water depths, open water and dense vegetation zones, veg¬ etation types ranging from submerged aquatic plants to shrubs and trees, nesting islands, and irregular shorelines. They are frequently built in or near places that have histori¬ cally had wetlands, and are often built as compensatory miti¬ gation. Created and restored wetlands for habitat or com¬ pensatory mitigation are not discussed in this manual. Finally, the term vertical flow wetland is used to describe a typical vertical flow sand or gravel filter which has been planted with aquatic plants. Because successful operation of this type of system depends on its operation as a filter (i.e. frequent dosing and draining cycles), this manual does not discuss this type of system. 1.3 Relationship to Previous EPA Documents Several Offices or Programs within USEPA have published documents in recent years on the subject of constructed wetlands. Some examples of publications and their USEPA sponsors are: • Design Manual: Constructed Wetlands and Aquatic Plant Systems for Municipal Wastewater Treatment (1988) (Office of Research and Development, Cincinnati, OH, EPA 625-1 -88-022) • Subsurface Flow Constructed Wetlands for Wastewa¬ ter Treatment: A Technology Assessment (1993) (Office of Wastewater Management, Washington, DC, EPA 832- R-93-008) • Habitat Quality Assessment of Wetland Treatment Sys¬ tems (3 studies in 1992 and 1993) (Environmental Re¬ search Lab, Corvallis, OR, EPA600-R-92-229, EPA600- R-93-117, EPA 600-R-93-222) • Constructed Wetlands for Wastewater Treatment and Wildlife Habitat: 17 Case Studies (1993) (Office of Waste- water Management, Washington, DC, EPA 832-R-93- 005) • Guidance for Design and Construction of a Subsur¬ face Flow Constructed Wetland (August 1993) (USEPA Region VI, Municipal Facilities Branch) • A Handbook of Constructed Wetlands (5 volumes, 1995) (USEPA Region III with USDA, NRCS, ISBN 0- 16-052999-9) • Constructed Wetlands for Animal Waste Treatment: A Manual on Performance, Design, and Operation With Cases Histories (1997) (USEPA Gulf of Mexico Pro¬ gram) • Free Water Surface Wetlands for Wastewater Treat¬ ment: A Technology Assessment (1999) (Office of Wastewater Management, Washington, DC, EPA/832/ R-99/002) Some information presented in this manual may contra¬ dict information presented in these other documents. Some contradictions are the result of new information and un¬ derstanding developed since the publication of earlier docu¬ ments; some contradictions are the result of earlier mis¬ conceptions about the mechanisms at work within con¬ structed wetlands; and some contradictions are the result of differing opinions among experts when insufficient in¬ formation exists to present a clear answer to issues sur¬ rounded by disagreement. As stated previously, this manual attempts to put an environmental engineering perspective on the use, design and performance of constructed wet¬ lands as reflected by the highest quality data available at this time. In areas where there is some disagreement among experts, this manual assumes a conservative ap¬ proach based on known treatment mechanisms which fit existing valid data. 1.4 Wetlands Treatment Database Through a series of efforts funded by the USEPA, a Wetlands Treatment Database, “North American Wetlands for Water Quality Treatment Database or NADB” (USEPA, 1994) has been compiled which provides information about natural and constructed wetlands used for wastewater treatment in North America. Version 1 of the NADB was released in 1994 and contains information for treatment wetlands at 174 locations in over 30 US states and Cana¬ dian provinces. Information includes general site informa¬ tion, system specific information (e.g., flow, dimensions, plant species), contact people with addresses and phone numbers, literature references, and permit information. It also contains some water quality data (BOD, TSS, N-se- ries, P, DO, and fecal conforms), but the data is not of uni¬ form quantity and quality, which makes it inappropriate for design or modeling purposes. Version 2 of the NADB is currently undergoing Agency review and contains information on treatment wetlands at 245 locations in the US and Canada. Because each loca¬ tion may have multiple wetland cells, there are over 800 individual wetland cells identified in Version 2. Besides expanding the number of wetland locations from Version 1, Version 2 also contains information regarding vegeta¬ tion, wildlife, human use, biomonitoring and additional water quality data. As with Version 1, the data is not adequate for design or modeling. 2 Data did not exist or were incomplete for many of the wetlands included in the NADB. Only existing informa¬ tion was collected for the NADB; no new measurements were made. Therefore, the NADB is very useful for ob¬ taining general information about the status of con¬ structed wetlands usage, as well as the locations of operating systems and people to contact. However, it is not useful as a source of water quality data for wetland design or prediction of treatment performance. Tables 1.1 through 1.4 give an overview of Version 2 of the NADB. The size range and median size are shown in several tables to give the reader a feel for the size of each type of wetland. The median size is shown because there are a few very large wetlands in some of the groups, which makes the median size more characteristic of the group than the mean size. Tables 1.1 and 1.2 group the wetlands by type of wet¬ land and type of wastewater being treated, respectively. In general FWSs are larger than VSBs, with the median size of FWS wetlands being twice that of VSBs. The summary statistics for “other water” wetlands in Table 1.2 are some¬ what misleading because they are influenced by the large Everglades Nutrient Removal project in Florida. Table 1-1. Types of Wetlands in the NADB Type of Wetland Qty. Min. Size (hectares) Median Max. Constructed Wetlands 205 0.0004 0.8 1406 Free Water Surface 138 0.0004 1 1406 Marsh* 125 0.0004 1 1406 Other 13 0.08 3 188 Vegetated Submerged Bed (all Marsh) 49 0.004 0.5 498 Combined FWS & VSB (all Marsh) 8 0.1 0.4 17 Other or Not Classified 10 0.01 1 14 Natural Wetlands (all Free Water Surface) 38 0.2 40 1093 Forest 18 1 40 204 Marsh 16 0.2 33 1093 Other or Not Classified 4 6 64 494 Not Classified 2 'Marshes are characterized by soft-stemmed herbaceous plants, including emergent species, such as cattails, floating species, such as water lilies, and submerged species, such as pondweeds. (Niering, 1985) Table 1-2. Types of Wastewater Treated and Level of Pretreatment for NADB Wetlands Size (hectares) Wastewater Type Pretreatment Qty. Min. Median Max. Agricultural 58 0.0004 0.1 47 None 8 Primary 35 Facultative 14 Not classified 1 Industrial 13 0.03 10 1093 Primary 1 Facultative 2 Secondary 6 Advanced Secondary 1 Not classified 3 Municipal 159 0.004 2 500 Primary 9 Facultative 78 Secondary 49 Advanced Secondary 9 Tertiary 4 Other 4 Not classified 6 Stormwater 6 0.2 8 42 None 4 Secondary 1 Other 1 Other Water 7 3 376 1406 None 4 Primary 1 Facultative 1 Secondary 1 Not classified 2 3 Table 1.3 groups all the wetlands, regardless of type of wetland or wastewater being treated, by size. In terms of area, the majority of the wetlands are less than 10 hect¬ ares (25 acres), and almost 90% are less than 100 hect¬ ares (250 acres). In terms of design flow rate, the majority are less than 1000 m3/d (about 0.25 mgd), and 82% are less than 4060 m3/d (1 mgd). Table 1.4 groups all the wetlands, regardless of type of wetland or wastewater being treated, by location. Treat¬ ment wetlands are located in 34 US states and 6 Cana¬ dian provinces. The number of wetlands per state is prob¬ ably more a function of having an advocate for treatment wetlands in the state than climate or some other favorable condition. Table 1-3. Size Distribution of Wetlands in the NADB Area (hectares) Design Flow (m3/d) Size Range Cumulative Percentage Size Range Cumulative Percentage less than 1 46 less than 10 19 less than 10 75 less than 100 31 less than 100 93 less than 1000 62 less than 1000 99 less than 10,000 93 Table 1-4. Distribution of Wetlands in the NADB by State/Province State or Province* Number of Wetlands Min. Size (hectares) Median Max. SD 42 0.3 2 134 FL 24 0.2 44.5 1406 AR 21 0.3 0.8 4 KY 19 0.01 0.1 5 LA 15 0.02 0.3 17 MS 11 0.02 0.9 101 CA 9 0.1 14 59 AL 8 0.04 0.2 6 ONT 8 0.02 0.09 0.4 MD 5 0.1 0.2 2 OR 5 0.1 4 36 SC 5 20 36 185 IN 4 0.002 0.12 1 Ml 4 5 56.5 110 MO 4 0.04 0.25 37 NY 4 0.03 0.25 2 PA 4 0.01 0.055 0.2 TX 4 0.1 0.2 0.5 AZ 3 2 38 54 GA 3 0.01 0.3 0.4 ND 3 14 17 33 NVS 3 0.1 0.1 0.4 TN 3 0.1 0.2 0.3 Wl 3 0.01 6 156 ALB, IA, ME, MN, NC, NM, NV, QUE 2 CT, IL, MA, NJ, NWT, PEI, VA, WA 1 *Two-letter abbreviations are states; three-letter abbreviations are provinces. 1.5 History Kadlec and Knight (1996) give a good historical account of the use of natural and constructed wetlands for waste- water treatment and disposal. As they point out, natural wetlands have probably been used for wastewater disposal for as long as wastewater has been collected, with docu¬ mented discharges dating back to 1912. Some early con¬ structed wetlands researchers probably began their efforts based on observations of the apparent treatment capacity of natural wetlands. Others saw wastewater as a source of water and nutrients for wetland restoration or creation. Research studies on the use of constructed wetlands for wastewater treatment began in Europe in the 1950's, and in the US in the late 1960's. Research efforts in the US increased throughout the 1970's and 1980's, with signifi¬ cant Federal involvement by the Tennessee Valley Authority (TVA) and the U.S. Department of Agriculture in the late 1980's and early 1990's. USEPA has had a limited role in constructed wetlands research which might explain the dearth of useful, quality-assured data. Start dates for constructed wetlands in the NADB are shown in Table 1.5, with the start dates for natural wet¬ lands used for treatment included for comparison. The table shows that the use of FWS wetlands and VSBs in North America really began in the early and latel980's, respec¬ tively, and the number continues to increase. No new natu¬ ral wetland treatment systems have begun since 1990, and at least one-third of the natural wetland treatment systems included in the NADB are no longer operating. 1.6 Common Misconceptions Many texts and design guidelines for constructed wet¬ lands, in addition to those listed above sponsored by the various offices of USEPA, have been published since USEPA’s 1988 design manual (EC/EWPCA (1990); WPCF (1990); Tennessee Valley Authority (1993); USDA (1993); Reed, et al (1995); Kadlec and Knight (1996); Campbell and Ogden (1999)). Also, a number of international con¬ ferences have been convened to present the findings of constructed wetlands research from almost every conti¬ nent (Hammer (1989); Cooper and Findlater (1990); Moshiri Table 1-5. Start Date of Treatment Wetlands in the NADB Type before 1950 1950's & 60's 1970's ‘80-‘84 ‘85-‘89 1990's (latest*) Constructed, FWS 1 0 3 8 33 85 (‘96) Constructed, VSB 0 0 0 0 21 31 (‘94) Constructed, hybrid 0 0 0 1 4 6 (‘94) Natural, FWS 4 3 9 5 8 1 (‘90) 'Year of last wetland included in database for this type of wetland - other wetlands may have started after this date, but are not in the database. 4 (1993); IAWQ (1994)(1995) (1997)). However, in spite of the great amount of resources devoted to constructed wet¬ lands, questions and misconceptions remain about their ap¬ plication, design, and performance. This section briefly de¬ scribes four common misconceptions; further discussion of these items is found in other chapters. Misconception #1: Wetland design has been well-charac¬ terized by published design equations. Constructed wetlands are complex systems in terms of biology, hydraulics and water chemistry. Furthermore, there is a lack of quality data of suf¬ ficient detail, both temporally and spatially, on full-scale con¬ structed wetlands. Due to the lack of data, designers have been forced to derive design parameters by aggregating per¬ formance data from a variety of wetlands, which leads to uncertainties about the validity of the parameters. Data from wetlands with detailed research studies with rigorous quality control (QC) might be combined with data from wetlands with randomly collected data with little QC. Data from small wetlands with minimal pretreatment might be combined with data from large wetlands used for polishing secondary efflu¬ ent. Additional problems with constructed wetlands data in¬ clude: lack of paired influent-effluent samples; grab samples instead of composited samples; lack of reliable flow or de¬ tention time information; and lack of important incidental in¬ formation such as temperature and precipitation. The result¬ ing data combinations, completed to obtain larger data sets, have sometimes been used to create regression equations of questionable value for use in design. Finally, data from constructed wetlands treating relatively high quality (but in¬ adequately characterized) wastewater has sometimes been used to derive design parameters for more concentrated municipal treatment applications, which is less than assur¬ ing for any designer. Misconception #2: Constructed wetlands have aerobic as well as anaerobic treatment zones. Probably the most com¬ mon misconception concerns the ability of emergent wet¬ land plants to transfer oxygen to their roots. Emergent aquatic plants are uniquely suited to the anaerobic environment of wetlands because they can move oxygen from the atmo¬ sphere to their roots. Research has shown that some oxy¬ gen “leaks” from the roots into the surrounding soils (Brix, 1997). This phenomenon, and early work with natural and constructed wetlands that treated wastewater with a low oxygen demand, has led to the assumption that significant aerobic micro-sites exist in all wetland systems. Some con¬ structed wetlands literature states or implies that aerobic bio¬ degradation is a significant treatment mechanism in fully vegetated systems, which has led some practitioners to be¬ lieve that wetlands with dense vegetation, or many sources of “leaking” oxygen, are in fact aerobic systems. However, the early work with tertiary or polishing wetlands is not di¬ rectly applicable to wetlands treating higher strength waste- water because it fails to account for the impacts of the waste- water on the characteristics of the wetland. Treatment mecha¬ nisms that function under light loads are impaired or over¬ whelmed due to changes imparted by the large oxygen de¬ mand of more contaminated municipal wastewater. Field experience and research have shown that the small amount of oxygen leaked from plant roots is insignificant compared to the oxygen demand of municipal wastewater applied at practical loading rates. Misconception #3: Constructed wetlands can remove sig¬ nificant amounts of nitrogen. Related to the misconception about the availability of oxygen in constructed wetlands is the misconception about the ability of constructed wetlands to remove significant amounts of nitrogen. Harvesting re¬ moves less than 20% of influent nitrogen (Reed, et al,1995) at conventional loading rates. This leaves nitrification and denitrification as the primary removal mechanisms. If it is assumed that wetlands have aerobic zones, it then follows that nitrification of ammonia to nitrate should occur. Further¬ more, if the aerobic zone surrounds only the roots of the plants, it then follows that anaerobic zones dominate, and denitrification of nitrate to nitrogen gas should also occur. Unfortunately, the nitrogen-related misconceptions have been responsible for the failure of several constructed wetlands that were built to remove or oxidize nitrogen. Because anaero¬ bic processes dominate in both VSBs and fully vegetated FWS wetlands, nitrification of ammonia is unlikely to occur in the former and will occur only if open water zones are introduced to the latter. Constructed wetlands can be de¬ signed to remove nitrogen, if sufficient aerobic (open water) and anaerobic (vegetated) zones are provided. Otherwise, constructed wetlands should be used in conjunction with other aerobic treatment processes that can nitrify to remove nitro¬ gen. Misconception #4: Constructed wetlands can remove sig¬ nificant amounts of phosphorus. Phosphorus removal in con¬ structed wetlands is limited to seasonal uptake by the plants, which is not only minor compared to the phosphorus load in municipal wastewater, but is negated during the plants’ se¬ nescence, and to sorption to influent solids which are cap¬ tured, soils or plant detritus, all of which have a limited ca¬ pacity. Two problems have been associated with phospho¬ rus data in the literature. First, some phosphorus removal data has been reported in terms of percent removal. How¬ ever, many of the early phosphorus studies were for natural wetlands or constructed wetlands that received wastewater with a low phosphorus concentration. Because of low influ¬ ent concentrations, removal of only a single mg/L of phos¬ phorus was reported as a large percent removal. Second, for studies evaluating the performance of newly constructed wetlands, phosphorus removal data will be uncharacteristic of long-term performance. New plants growing in a freshly planted wetland will uptake more phosphorus than a mature wetland, which will have phosphorus leaching from dying (senescent) plants as well as uptake by growing plants. Also, newly placed soils or media will have a greater phosphorus sorption capacity than a mature system which will have most sorption sites already saturated. 1.7 When to Use Constructed Wetlands 1.7.1 Appropriate Technology for Small Communities Appropriate technology is defined as a treatment sys¬ tem which meets the following key criteria: 5 Affordable - Total annual costs, including capital, op¬ eration, maintenance and depreciation are within the user’s ability to pay. Operable - Operation of the system is possible with locally available labor and support. Reliable - Effluent quality requirements can be con¬ sistently meet. Unfortunately, many rural areas of the U.S. with small treatment plants (usually defined as treating less than 3,800 m3/d (1 mgd)) have failed to consider this appropriate tech¬ nology definition, and have often adopted inappropriate technologies such as activated sludge. In 1980, small, activated sludge systems constituted 39% of the small publicly owned treatment facilities (GAO, 1980). Recent information from one state showed that 73% of all treat¬ ment plants of less than 3,800m3/d capacity used some form of the activated sludge process. Unfortunately, the activated sludge process is considered by almost all U.S. and international experts to be the most difficult to operate and maintain of the various wastewater treatment concepts. Presently, small treatment plants constitute more than 90% of the violations of U.S. discharge standards. At least one U.S. state, Tennessee, has required justification for the use of activated sludge package plants for very small treat¬ ment plant applications (Tennessee Department of Public Health, 1977). Small community budgets become severely strained by the costs of their wastewater collection and treatment fa¬ cilities. Inadequate budgets and poor access to equipment, supplies and repair facilities preclude proper operation and maintenance (O&M). Unaffordable capital costs and the inability to reliably meet effluent quality requirements add up to a prime example of violating the prior criteria for ap¬ propriate technology. Unfortunately, no consideration for reuse, groundwater recharge, or other alternatives to stream discharge has heretofore been common, except in a few states where water shortages exist. Presently there are a limited number of appropriate tech¬ nologies for small communities which should be immedi¬ ately considered by a community and their designer. These include stabilization ponds or lagoons, slow sand filters, land treatment systems, and constructed wetlands. All of these technologies fit the operability criterion, and to vary¬ ing degrees, are affordable to build and reliable in their treatment performance. Because each of these technolo¬ gies has certain characteristics dNd requirements for pre- and post- treatment to meet a certain effluent quality, they may be used alone or in series with others depending on the treatment goals. For example, the designer may wish to supplement sta¬ bilization ponds with a tertiary system to meet reuse or discharge criteria consistently. Appropriate stabilization pond upgrading methods to meet effluent standards in¬ clude FWS wetlands, which can provide the conditions for enhanced settling to attain further reduction of fecal coliforms and removal of the excess algal growth which characterizes pond system effluents. FWS wetlands are normally used after ponds because of their ability to handle the excess algal solids generated in the ponds. Although VSBs have been employed after ponds, excess algal sol¬ ids have caused problems at some locations, thus defeat¬ ing the operability factor in the appropriate technology defi¬ nition. VSBs are more appropriately applied behind a pro¬ cess designed to minimize suspended and settleable sol¬ ids, such as a septic or Imhoff tank or anaerobic lagoon. Constructed wetlands may also require post-treatment processes, depending on the ultimate goals of the treat¬ ment system. More demanding effluent requirements may require additional processes in the treatment train or may dictate the use of other processes altogether. For example, the ability of constructed wetlands to remove nitrogen and phosphorus has frequently been overestimated. Two ap¬ propriate technologies that readily accomplish ammonium oxidation are intermittent and recirculating sand filters. There is at least one case study of the successful use of a recirculating gravel filter in conjunction with a VSB (Reed, et al, 1995 ). FWS systems can both nitrify and denitrify, thus removing significant portions of nitrogen from the wastewater, by alternating fully vegetated and open water zones in proper proportions. If the municipal facility is re¬ quired to have significant phosphorus removal (e.g., to at¬ tain 1 mg/L from a typical influent value of 6 to 7 mg/L), constructed wetlands will need to be accompanied by some process or processes that can remove the phosphorus. In conclusion, constructed wetlands are an appropriate technology for areas where inexpensive land is generally available and skilled labor is less available. Whether they can be used essentially alone or in series with other ap¬ propriate technologies depends on the required treatment goals. Additionally, they can be appropriate for onsite sys¬ tems where local regulators call for and allow systems other than conventional septic tank - soil absorption systems. 1.7.2 Policy and Permitting Issues An interagency workgroup, including representatives from several Federal agencies, is presently developing Guiding Principles for Constructed Treatment Wetlands: Providing Water Quality and Wildlife Habitat (USEPA, 1999). The essence of the current draft of the guidelines is that constructed treatment wetlands will: — receive no credit as mitigation wetlands; — be subject to the same rules as treatment lagoons regarding liner requirements; — be subject to the same monitoring requirements as treatment lagoons; — should not be constructed in the waters of the United States, including existing natural wetlands; and — will not be considered Waters of the United States upon abandonment if the first and the fourth condi¬ tions are met. 6 The guidance encourages use of local plant species and expresses concern about permit compliance during lengthy startup periods and vector attraction and control issues. To avoid additional permitting and regulatory require¬ ments, constructed wetlands should be designed as a treat¬ ment process and built in uplands as opposed to wetlands or flood plains, i.e., outside of waters of the U.S.. Consider the following from the draft guidelines. If your constructed treatment wetland is constructed in an existing water of the U.S., it will remain a water of the U.S. unless an individual CWA section 404 per¬ mit is issued which explicitly authorizes it as an ex¬ cluded waste treatment system designed to meet the requirements of the CWA.... Once constructed, if your treatment wetland is a water of the U.S., you will need a NPDES permit for the discharge of pollutants... into the wetland.... [Additionally,] if you wish to use a de¬ graded wetland for wastewater treatment and plan to construct water control structures, such as berms or levees, this construction will... require a Section 404 permit. Subsequent maintenance may also require a permit. As stated in the guidelines: If the constructed wetland is abandoned or is no longer being used as a treatment system, it may revert to a water of the U.S. if... the following conditions exist: the system has wetland characteristics (i.e., hydrol¬ ogy, soils, vegetation) and it is either (1) an interstate wetland, (2) is adjacent to another water of the U.S. (other than waters which are themselves wetlands), or (3) if it is an isolated intrastate water which has a nexus to interstate commerce (e.g., it provides habitat for migratory birds). None of preceding discussion precludes designing and building a wetland which provides water reuse, habitat or public use benefits in addition to wastewater treatment. Constructed wetlands built primarily for treatment will gen¬ erally not be given credit as compensatory mitigation to replace wetland losses. However, in limited cases, some parts of a constructed wetland system may be given credit, especially if additional wetland area is created beyond that needed for treatment purposes. Also, current policy en¬ courages the use of properly treated wastewater to restore degraded wetlands. For example, restoration might be possible if: 1 the source water meets all applicable water qual ity standards and criteria, (2) its use would result in a net environmental benefit to the aquatic system’s natural functions and values, and if applicable, (3) it would help restore the aquatic system to its historical condition. Prime candidates for restoration may include wetlands that were degraded or destroyed through the diversion of water supplies,... For example, in the arid west, there are often historic wetlands that no longer have a reliable water source due to upstream water allocations or sink¬ ing groundwater tables. Pre-treated effluent may be the only source of water available for these areas and their dependent ecosystems.... EPA has developed regional guidance to assist dischargers and regulators in dem¬ onstrating a net ecological benefit from maintenance of a wastewater discharge to a waterbody. This discussion of policy and permitting issues is very general and regulatory decisions regarding these issues are made on a case-by-case basis. Planners and design¬ ers should seek guidance from State and Regional regu¬ lators about site specific constructed wetland criteria in¬ cluding location, discharge requirements, and possible long-term monitoring requirements. 1.7.3 Other Factors Probably the most important factor which impacts all aspects of constructed wetlands is their inherent aesthetic appeal to the general public. The desire of people to have such an attractive landscape enhancement treat their wastewater and become a valuable addition to the com¬ munity is a powerful argument when the need for waste- water treatment upgrading becomes a matter of public debate. The appeal of constructed wetlands makes the need to accurately assess the capability of the technology so important and so difficult. The engineering community often fails to appreciate this inherent appeal, while the environmental community often lacks the understanding of treatment mechanisms to appreciate the limitations of the technology. The natural attraction of constructed wet¬ lands and the potential for other aesthetic benefits may sometimes offset the treatment or cost advantages of other treatment options, and public opinion may dictate that a constructed wetland is the preferred option. In other situa¬ tions, constructed wetlands will be too costly or unable to produce the required effluent water quality, and the de¬ signer will have to convince the public that wetlands are not a viable option, in spite of their inherent appeal. The use of constructed wetlands as a treatment tech¬ nology carries some degree of risk for several reasons. First, as noted in a review of constructed wetlands for wastewater treatment by Cole (1998), constructed wetlands are not uniformly accepted by all state regulators or EPA regions. Some authorities encourage the use of constructed wetlands as a proven treatment technology, due in part to the misconceptions noted in Section 1.6. Others still con¬ sider them to be an emerging technology. As with any new treatment technology, uniform acceptance of constructed wetlands will take some time. Other natural treatment pro¬ cesses which are now generally accepted, such as slow rate or overland flow land treatment systems, went through a similar course of variable acceptance. Second, although there is no evidence of harm to wild¬ life using constructed wetlands, some regulators have ex¬ pressed concern about constructing a system which will treat wastewater while it attracts wildlife. Unfortunately, there has not been any significant research conducted on the risks to wildlife using constructed wetlands. Although 7 they are a distinctly different type of habitat, the lack of evidence of risks to wildlife using treatment lagoon sys¬ tems for many years suggests that there may not be a serious risk for wetlands treating municipal wastewater. Of course, if a wetland is going to treat wastewater with high concentrations of known toxic compounds, the de¬ signer will need to use a VSB system or incorporate fea¬ tures in a FWS wetland which restrict access by wildlife. Finally, as noted earlier, due to the lack of a large body of scientifically valid data, the design process is still em¬ pirical, that is, based upon observational data rather than scientific theories. Due to the variability of many factors at constructed wetlands being observed by researchers (e.g., climatic effects, influent wastewater characteristics, design configurations, construction techniques, and O&M prac¬ tices), there will continue to be disagreement about some design and performance issues for some period of time. 1.8 Use of This Manual Chapters 1,2,7 and 8 provide information for non-tech- nical readers, such as decision-makers and stakeholders, to understand the capabilities and limitations of constructed wetlands. These chapters provide the type of information required to question designers and regulators in the pro¬ cess of determining how constructed wetlands may be used to expand, upgrade or develop wastewater treatment in¬ frastructure. Chapters 3 through 6 provide information for technical readers, such as design engineers, regulators and plan¬ ners, to plan, design, build and manage constructed wet¬ lands as part of a comprehensive plan for local and re¬ gional management of municipal wastewater collection, treatment, and reuse. Chapter 2 describes constructed wetland treatment sys¬ tems and their identifiable features. It answers the most frequently asked questions about these systems and in¬ cludes a glossary of terms which are used in this manual and generally in discussion of constructed wetland sys¬ tems. There are brief discussions of other aquatic treat¬ ment systems that are in use or are commercially avail¬ able and an annotated introduction to specific uses for constructed wetlands outside the purview of this manual. Chapter 3 discusses the treatment mechanisms occur¬ ring in a constructed wetland to help the reader under¬ stand the most important processes and what climatic con¬ ditions and other physical phenomena most affect these processes. A basic understanding of the mechanisms in¬ volved will allow the reader to more intelligently interpret information from other literature sources as well as infor¬ mation in chapters 4 and 5 of this manual. Chapters 4, 5, and 6 describe the design, construction, startup and operational issues of constructed wetlands in some detail. It will be apparent to the reader that there are presently insufficient data to create treatment models in which there can be great confidence. Most data in the lit¬ erature has been generated with inadequate quality as¬ surance and control (Qa/Qc), and most research studies have not measured or focused on documentation of key variables which could explain certain performance char¬ acteristics. Chapters 4 and 5 use the existing data of suffi¬ cient quality to create a viable approach to applicability and design of both FWS and VSB systems and sets prac¬ tical limits on their performance capabilities. Chapter 6 deals with the practical issues of construction and start-up of these systems which have been experienced to date. Chapter 7 contains cost information for constructed wet¬ lands. Subsequent to standardizing the costs to a specific time, it becomes clear that local conditions and require¬ ments can dominate the costs. However, the chapter does provide a reasonable range of expected costs which can be used to evaluate constructed wetlands against other alternatives in the facility planning stage. Also, there is sufficient information presented to provide the user with a range of unit costs for certain components and to indicate those components that dominate system costs and those that are relatively inconsequential. Chapter 8 presents eight case studies to allow readers to become familiar with sites that have used constructed wetlands and their experiences. The systems in this chap¬ ter are not ones which are superior to other existing facili¬ ties, but they are those which have been observed and from which lessons can be learned by the reader about either successful or unsuccessful design practices. 1.9 References Brix, H. 1997. Do Macrophytes Play a Role in Constructed Treatment Wetlands?. Water Science & Technology, Vol 35, No. 5, pp.11-17. Campbell, C.S. and M.H. Ogden. 1999. Constructed Wet¬ lands in the Sustainable Landscape. John Wiley and Sons, New York, New York. Cole, Stephen. 1998. The Emergence of Treatment Wet¬ lands. Environmental Science & Technology, Vol. 3, No.5, pp 218A-223A. Cooper, P.F., and B.C. Findlater, eds. 1990. Constructed Wetlands in Water Pollution Control. Pergamon Press, New York, New York. EC/EWPCA. 1990. European Design and Operations Guidelines for Reed Bed Treatment Systems. Prepared for the EC/EWPCA Expert Contact Group on Emer¬ gent Hydrophyte Treatment Systems. P.F. Cooper, ed., European Community/European Water Pollution Con¬ trol Association. Government Accounting Office. 1980. Costly wastewater treatment plants fail to perform as expected. CED-81- 9. Washington, D.C. Hammer, D.A., ed. 1989. Constructed Wetlands for Waste- water Treatment. Lewis Publishers, Inc. Chelsea, Michigan. 8 IAWQ. 1992. Proceedings of international conference on treatment wetlands, Sydney, Australia. Water Science & Technology. Vol. 29, No. 4. IAWQ. 1995. Proceedings of international conference on treatment wetlands, Guangzhou, China. Water Science & Technology. Vol. 32, No. 3. IAWQ. 1997. Proceedings of international conference on treatment wetlands, Vienna, Austria. Water Science & Technology. Vol. 35, No. 5. Kadlec, R.H. and R.L. Knight. 1996. Treatment Wetlands. CRC Press LLC. Boca Raton, FL. Moshiri, L., ed. 1993. Constructed Wetlands for Water Qual¬ ity Improvement. Lewis Publishers, Inc., Chelsea, Ml. Niering, W.A. 1985. Wetlands. Alfred A. Knopf, Inc., New York, NY. Reed, S.C., R.W. Crites, and J.E. Middlebrooks. 1995. Natural Systems for Waste Management and Treat¬ ment. Second edition. McGraw-Hill, Inc., New York, NY. Tennessee Department of Public Health. 1977. Regula¬ tions for plans, submittal, and approval; Control of con¬ struction; Control of operation. Chapter 1200-4-2, State of Tennessee Administrative Rules. Knoxville, TN. Tennessee Valley Authority. 1993. General Design, Con¬ struction, and Operation Guidelines: Constructed Wet¬ lands Wastewater Treatment Systems for Small Us¬ ers Including Individual Residences. G.R. Steiner and J.T. Watson, eds. 2nd edition. TVA Water Management Resources Group. TVA/WM--93/10. Chattanooga, TN. U.S. Department of Agriculture. 1995. Handbook of Con¬ structed Wetlands. Svolumes. USDA-Natural Re¬ sources Conservation Service/US EPA-Region III/ Pennsylvania Department of Natural Resources. Washington, D.C. U.S. Environmental Protection Agency. 1988. Design Manual: Constructed Wetlands and Aquatic Plant Sys¬ tems for Municipal Wastewater Treatment. EPA/625/ 1-88/022. US EPA Office of Research and Develop¬ ment, Cincinnati, OH. U.S. Environmental Protection Agency. 1993. Subsurface Flow Constructed Wetlands for Wastewater Treatment: A Technology Assessment. S.C. Reed, ed., EPA/ 832/ R-93/008. US EPA Office of Water, Washington, D.C. U.S. Environmental Protection Agency. 1994. Wetlands Treatment Database (North American Wetlands for Water Quality Treatment Database). R.H. Kadlec, R.L. Knight, S.C. Reed, and R.W. Ruble eds., EPA/600/C- 94/002. US EPA Office of Research and Development, Cincinnati, OH. U.S. Environmental Protection Agency. 1999. Final Draft - Guiding Principles for Constructed Treatment Wetlands: Providing Water Quality and Wildlife Habitat. Developed by the Interagency Workgroup on Constructed Wetlands (U.S. Environmental Protection Agency, Army Corps of Engineers, Fish and Wildlife Sen/ice, Natural Resources Conservation Services, National Marine Fisheries Ser¬ vice, and Bureau of Reclamation). Final Draft 6/8/1999. http://www.epa.gov/owow/wetlands/constructed/ guide.html Water Pollution Control Federation. 1990. Natural Systems for Wastewater Treatment. Manual of Practice FD-16, S.C. Reed, ed., Water Pollution Control Federation, Alexandria, VA. 9 Chapter 2 Introduction to Constructed Wetlands 2.1 Understanding Constructed Wetlands Constructed wetlands are wastewater treatment systems composed of one or more treatment cells in a built and partially controlled environment designed and constructed to provide wastewater treatment. While constructed wet¬ lands have been used to treat many types of wastewater at various levels of treatment, the constructed wetlands described in this manual provide secondary treatment to municipal wastewater. These are treatment systems that receive primary effluent and treat it to secondary effluent standards and better, in contrast to enhancement systems or polishing wetlands, which receive secondary effluent and treat it further prior to discharge to the environment. This distinction emphasizes the degree of treatment more than the means of treatment, because the constructed wetlands described in this manual receive higher-strength wastewater than the polishing wetlands that have been widely used as wastewater treatment systems for the last 20 years. While constructed wetlands discussed in this manual provide secondary treatment in a community’s wastewa¬ ter treatment system, this technology also can be used in combination with other secondary treatment technologies. For example, a constructed wetland could be placed up¬ stream in the treatment train from an infiltration system to optimize the cost of secondary treatment. In other uses, constructed wetlands could discharge secondary effluent to enhancement wetlands for polishing. Constructed wet¬ lands are not recommended for treatment of raw waste- water. Figure 2-1 portrays a hypothetical wastewater treat¬ ment train utilizing constructed wetlands in series. The distinction between constructed wetlands for sec¬ ondary treatment and enhancement systems for tertiary treatment is critical in understanding the limitations of ear¬ lier accounts of wetland-based treatment systems and databases of system performance. Most of the commonly available information on constructed wetland treatment systems is derived from data gathered at many larger pol¬ ishing wetlands and a relatively few smaller constructed wetlands for secondary treatment. In the past, largely un¬ verified data from these disparate sources has been ag¬ gregated, statistically rendered, and then applied as guid¬ ance for constructed wetland systems, with predictably inconsistent results. In contrast, guidance offered in this manual is drawn from reliable research data and practical application in constructed wetlands for secondary treat¬ ment of higher-strength municipal wastewater. Constructed wetlands comprise two types of systems that share many characteristics but are distinguished by the location of the hydraulic grade line. Design variations for both types principally affect shapes and sizes to fit site- specific characteristics and optimize construction, opera¬ tion, and performance. Both types of constructed wetlands typically may be fitted with liners to prevent infiltration, depending on local soil conditions and regulatory require¬ ments. Free water surface (FWS) constructed wetlands closely resemble natural wetlands in appearance and function, with a combination of open-water areas, emergent vegetation, varying water depths, and other typical wetland features. Figure 2-2 illustrates the main components of a FWS con¬ structed wetland. Atypical FWS constructed wetland con¬ sists of several components that may be modified among various applications but retain essentially the same fea¬ tures. These components include berms to enclose the treatment cells, inlet structures that regulate and distribute influent wastewater evenly for optimum treatment, various combinations of open-water areas and fully vegetated sur¬ face areas, and outlet structures that complement the even distribution provided by inlet structures and allow adjust¬ ment of water levels within the treatment cell. Shape, size, and complexity of design often are functions of site char¬ acteristics rather than preconceived design criteria. Vegetated submerged bed (VSB) wetlands consist of gravel beds that may be planted with wetland vegetation. Figure 2-3 provides a schematic drawing of a VSB sys¬ tem. Atypical VSB system, like the FWS systems described above, contains berms and inlet and outlet structures for regulation and distribution of wastewater flow. In addition to shape and size, other variable factors are choice of treat¬ ment media (gravel shape and size, for example) as an economic factor, and selection of vegetation as an optional feature that affects wetland aesthetics more than perfor¬ mance. The apparent simplicity and natural function of con¬ structed wetlands may obscure the complexity of interac- 10 Figure 2-1. Constructed wetlands in wastewater treatment train Floating and Submerged Floating and Emergent Inlet Settling Zone Emergent Plants Growth Plants Plants Zone 1 Fully Vegetated D O. (-) H < 0.75 m Zone 2 Open-Water Surface D O. B H > 1.2 m Zone 3 Fully Vegetated D.O. B H < 0.75 m Figure 2-2. Elements of a free water surface (FWS) constructed wetland Pretreated (Settled) Influent Figure 2-3. Elements of a vegetated submerged bed (VSB) system 11 tions required for effective wastewater treatment. Unlike natural wetlands, constructed wetlands are designed and operated to meet certain performance standards. Once a constructed wetland is designed and becomes operational, the system requires regular monitoring to ensure proper operation. Based on monitoring results, these systems may need minor modifications, in addition to routine manage¬ ment, to maintain optimum performance. In this chapter, a basic understanding of constructed wetland ecology is presented for planners, policy makers, local government officials, and others involved in the ap¬ plication of constructed wetlands for wastewater treatment. Basic ecological components and functions of wetlands are briefly described to bring readers to a common level of understanding, but detailed descriptions are purposely omitted for the sake of focus and relative correlation to treatment performance. To enhance one’s knowledge of wetland ecology, many publications are commonly avail¬ able. For designers and operators, general knowledge of wetland ecology is assumed, and detailed information on constructed wetlands is offered in succeeding chapters. While municipal wastewater treatment systems utilizing constructed wetlands modeled on the functions of natural wetlands systems are the focus of this manual, related systems utilizing components of natural wetland systems also are briefly described. In addition, constructed wetlands for on-site domestic wastewater systems and non-munici¬ pal wastewater treatment are introduced. Because VSB wetlands are not dependent on wetland vegetation for treatment performance and do not require open-water areas, portions of this chapter describe de¬ sign and management considerations that pertain only to FWS wetlands. For reference purposes, important terms are highlighted in bold type and are explained in a glos¬ sary at the end of the chapter. 2.2 Ecology of Constructed Wetlands Constructed wetlands are ecological systems that com¬ bine physical, chemical, and biological processes in an engineered and managed system. Successful construc¬ tion and operation of an ecological system for wastewater treatment requires a basic knowledge and understanding of the components and the interrelationships that compose the system. The treatment systems of constructed wetlands are based on ecological systems found in natural wetlands. A main distinction between constructed wetlands and natu¬ ral wetlands is the degree of control over natural processes. For example, a constructed wetland operates with a rela¬ tively stable flow of water through the system, in contrast to the highly variable water balance of natural wetlands, mostly due to the effects of variable precipitation. As a re¬ sult, wetland ecology in constructed wetlands is affected by continuous flooding and concentrations of total sus¬ pended solids (TSS), biochemical oxygen demand (BOD), and other wastewater constituents at consistently higher levels than would otherwise occur in nature. In a constructed wetland, most of the inflow is a predict¬ able volume of wastewater discharged through sewers. Lesser volumes of precipitation and surface runoff are sub¬ ject to seasonal and annual variations. Losses from these systems can be calculated by measuring outflow and esti¬ mating evapotranspiration as well as by accounting for seepage in unlined systems. Even with predictable inflow rates, however, modeling the water balance of constructed wetlands must comprehend weekly and monthly variations in precipitation and runoff and the effects of these vari¬ ables on wetland hydraulics, especially detention time re¬ quired for treatment. See Chapter 3 for a more thorough discussion of modeling concerns. Temperature variations also affect the treatment perfor¬ mance of constructed wetlands, although not consistently for all wastewater constituents. Treatment performance for some constituents tends to decrease with colder tempera¬ tures, but BOD and TSS removal through flocculation, sedi¬ mentation, and other physical mechanisms is less affected. In colder months, the absence of plant cover would allow atmospheric reaeration and solar insolation to occur with¬ out the shading and surface covering that plant cover pro¬ vides during the growing season. Ice cover is another sea¬ sonal variable that affects constructed wetlands by alter¬ ing wetland hydraulics and restricting solar insolation, at¬ mospheric reaeration, and biological activity; however, the insulating layer provided by ice cover would slow down the rate and degree of cooling in the water column but would not affect physical processes such as settling, filtra¬ tion, and flocculation. Plant senescence and decay also decreases under ice cover, with a corresponding decrease in effluent BOD. 2.3 Botany of Constructed Wetlands Successful performance of constructed wetlands de¬ pends on ecological functions that are similar to those of natural wetlands, which are based largely on interactions within plant communities. Research has confirmed that treatment of typical wastewater pollutants (TSS and BOD) in FWS constructed wetlands generally is better in cells with plants than in adjoining cells without plants (Bavor et al., 1989; Burgoon et al., 1989; Gearheart et al., 1989; Thut, 1989). However, the mechanisms by which plant populations enhance treatment performance have yet to be determined fully. Some authors have hypothesized a relationship between plant surface area and the density and functional performance of attached microbial popula¬ tions (EPA, 1988; Reed et al., 1995), but demonstrations of this relationship have yet to be proven. Plant communities in constructed wetlands undergo sig¬ nificant changes following initial planting. Very few con¬ structed wetlands maintain the species composition and density distributions envisioned by their designers. Many of these changes are foreseeable, and many have little apparent effect on treatment performance. Other changes, however, may result in poor performance and the conse¬ quent need for increased management. The following sec¬ tions summarize basic principles of plant ecology that may aid in understanding of constructed wetlands. 12 2.3.1 Wetland Microbial Ecology In any wetland, the ecological food web requires micro¬ scopic bacteria, or microbes, to function in all of its com¬ plex transformations of energy. In a constructed wetland, the food web is fueled by influent wastewater, which pro¬ vides energy stored in organic molecules. Microbial activ¬ ity is particularly important in the transformations of nitro¬ gen into varying biologically useful forms. In the various phases of the nitrogen cycle, for example, different forms of nitrogen are made available for plant metabolism, and oxygen may be either released or consumed. Phosphorus uptake by plants also is dependent in part on microbial activity, which converts insoluble forms of phosphorus into soluble forms that are available to plants. Microbes also process the organic (carbon) compounds, and release carbon dioxide in the aerobic areas of a constructed wet¬ land and a variety of gases (carbon dioxide, hydrogen sul¬ fide, and methane) in the anaerobic areas. Plants, plant litter, and sediments provide solid surfaces where micro¬ bial activity may be concentrated. Microbial activity varies seasonally in cold regions, with lesser activity in colder months, although the performance differential in warm versus cold climates is less in full-scale constructed wetlands than in small-scale, controlled ex¬ periments (Wittgren and Maehlum, 1996), apparently be¬ cause of the multiplicity of physical, chemical, and biologi¬ cal transformations taking place simultaneously over a larger contiguous area. 2.3.2 Algae Algae are ubiquitous in wet habitats, and they inevitably become components of FWS systems. While algae are a major component in certain treatment systems (for ex¬ ample, lagoons), algae can affect treatment performance of FWS constructed wetlands significantly. As a result, the presence of algae must be anticipated in the design stage. Algae in open areas, especially in areas of submergent vegetation, can form a living canopy that blocks sunlight from penetrating the water column to that vegetation, which results in reduced dissolved oxygen (DO) levels. The pres¬ ence of open, unshaded water near the outlet of a con¬ structed wetland typically promotes seasonal blooms of phytoplanktonic algal species, which results in elevated concentrations of suspended solids and particulate nutri¬ ent forms in the effluent. Several floating aquatic plant species, especially duck¬ weed, have very high rates of primary production, which result in large quantities of biomass and trapped nonliving elements accumulating within the fully vegetated portion of the FWS wetland and pond systems (Table 2-1). Water hyacinth can also perform well in pond systems in tropical climates to enhance TSS and algal removal. However, both species block sunlight and lower DO levels by eliminating atmospheric re aeration at the water/air interface. High growth rates of these plants have led to special¬ ized wastewater treatment systems that use these plants for harvesting nutrients from wastewater. The disadvan¬ tages of harvesting these plants arise from their low % solids (typically less than 5% on a wet-weight basis) and the consequent need for drying prior to disposal, which simultaneously creates secondary odor and water-quality problems. For disposal, harvested duckweed, which has a high protein content, typically has been incorporated into agricultural soils as green manure, and water hyacinths have been partially dried and landfilled or allowed to de¬ compose in a controlled environment to produce methane as a useful by-product. However, numerous attempts to demonstrate beneficial and cost-effective by-product re¬ covery have been mostly unsuccessful under North Ameri¬ can social and economic conditions. 2.3.3 Emergent Herbaceous Plants Emergent herbaceous wetland plants are very impor¬ tant structural components of wetlands. Their various ad¬ aptations allow competitive growth in saturated or flooded soils. These adaptations include one or more of the fol¬ lowing traits: lenticels (small openings through leaves and stems) that allow air to flow into the plants; aerenchymous tissues that allow gaseous convection throughout the length of the plant, which provides air to plant roots; special mor¬ phological growth structures, such as buttresses, knees, or pneumatophores, that provide additional root aeration; adventitious roots for absorption of gases and plant nutri¬ ents directly from the water column; and extra physiologi¬ cal tolerance to chemical by-products resulting from growth in anaerobic soil conditions. The primary role of emergent vegetation in FWS sys¬ tems is providing structure for enhancing flocculation, sedi¬ mentation, and filtration of suspended solids through ide¬ alized hydrodynamic conditions. Emergent wetland plant species also play a role in winter performance of FWS constructed wetlands by insulating the water surface from cold temperatures, trapping falling and drifting snow, and reducing the heat-loss effects of wind (Wittgren and Maehlum, 1996). Limited information is available to demonstrate signifi¬ cant or consistent effects of plant species selection on constructed wetland performance. For example, in two simi¬ lar FWS treatment cells at the Iron Bridge Wetland in Florida, the major difference between the cells was the dominant plant species. Bulrush appeared to perform nearly the same as cattail in treatment of BOD, TSS, total nitrogen (TN), and total phosphorus (TP). As research and application of constructed wetlands have expanded, docu¬ mentation of actual performance differences between emergent marsh plant species in constructed wetlands has become increasingly less valuable to constructed wetland designers. The wetland designer is strongly encouraged to seek information from experienced local wetland practitioners when selecting emergent herbaceous species to ensure selection of locally successful species. Table 2-2 provides guidelines for initial selection and establishment of plant species adapted to wetland environments. 13 Table 2.1 Characteristics of plants for constructed wetlands General Types of Plants General Characteristics and Common Examples Function or Importance to Treatment Process Function or Importance for Habitat Design & Operational Considerations Free-Floating Aquatic Roots or root-like structures suspended from floating leaves. Will move about with water currents. Will not stand erect out of the water. Common duckweed (Lemna), Big duckweed (Spirodela). Primary purposes are nutrient uptake and shading to retard algal growth. Dense floating mats limit oxygen diffusion from the atmosphere. Duckweed will be present as an invasive species. Dense floating mats limit oxygen diffusion from the atmosphere and block sunlight from submerged plants. Plants provide shelter and food for animals. Duckwood is a natural invasive species in North America. No specific design is required. Rooted Floating Aquatic Usually with floating leaves, but may have submerged leaves. Rooted to bottom. Will not stand erect out of the water. Water lily (Nymphea), Pennywort (Hydrocotyle). Primary purposes are providing structure for microbial attachment and releasing oxygen to the water column during daylight hours. Dense floating mats limit oxygen diffusion from the atmosphere. Dense floating mats limit oxygen diffusion from the atmosphere and block sunlight from submerged plants. Plants provide shelter and food for animals. Water depth must be designed to promote the type of plant (i.e. floating, submerged, emergent) desired while hindering other types of plants. Submerged Aquatic Usually totally submerged; may have floating leaves. Rooted to bottom. Will not stand erect in air. Pondweed (Potamogeton), Water weed (Elodea). Primary purposes are provioing structure for microbial attachment, and providing oxygen to the water column during daylight hours. Plants provide shelter and food for animals (especially fish). Retention time in open water zone should be less than necessary to promote algal growth which can destroy these plants through sunlight blockage. Emergent Aquatic Herbaceous (i.e. non-woody). Rooted to the bottom. Stand erect out of the water. Tolerate flooded or saturated conditions. Cattail (Typha), Bulrush (Scirpus), Common Reed (Phragmites). Primary purpose is providing structure to induce enhanced flocculation and sedimentation. Secondary purposes are shading to retard algal growth, windbreak to promote quiescent conditions for settling, and insulation during winter months. Plants provide shelter and food for animals. Plants provide aesthetic beauty for humans. Water depths must be in the range that is optimum for the specific species chosen (planted). Shrubs Woody, less than 6 m tall. Tolerate flooded or saturated soil conditions. Dogwood (Cornus), Holly (Ilex). Treatment function is not defined: it is not known if treatment data from unsaturated or occasionally saturated phytoremediation sites in upland areas is applicable to continuously saturated wetland sites. Plants provide shelter and food for animals (especially birds). Plants provide aesthetic beauty for humans. Possible perforation of liners by roots. Trees Woody, greater than 6 m tall. (same as for shrubs) (same as for shrubs) (same as for shrubs) Tolerate flooded or saturated soil conditions. Maple (Acer). Willow (Salix). 2.3.4 Plant Nutrition and Growth Cycles Wetland plants require optimum environmental condi¬ tions in each phase of their life cycles, including germina¬ tion and initial plant growth, adequate nutrition, normal seasonal growth patterns, and rates of plant senescence and decay. For more detailed information on wetland plant ecology, the nonbiologist is referred to the wetland ecol¬ ogy text by Mitsch and Gosselink (1993) and portions of the constructed wetland text by Kadlec and Knight (1996). A wide variety of references describe growth cycles, tim¬ ing of seed release, overwintering ability, energy cycling, and other characteristics and processes that provide wet¬ land plant species with a competitive advantage in their natural habitats; the reader is referred to other sources for detailed information. An overview of important character¬ istics follows. Emergent herbaceous wetland species planted early in the growing season in temperate climates generally multi¬ ply by vegetative reproduction to a maximum total stand¬ ing biomass in late summer or early fall within a single growing season. This biomass may represent multiple growth and death periods for individual plants during the course of the growing season, or it may represent a single emergence of plant structures, depending on the species. For many species, seeds are produced along with maxi¬ mum standing crop and released with maturation in the fall for early germination in the spring. 14 Table 2.2 Factors to Consider in Plant Selection (adapted from Thunhorst, 1993) Factors Consult local experts Native species Invasive or aggressive species Tolerant of high nutrient load Comments The number of professional wetland scientists, practitioners, and plant nurseries has increased dramatically in the past 10 years. Help from an experienced, local person should be available from a variety of sources, including government agencies and private companies. Using plants that grow locally increases the likelihood of plant survival and acceptance by local officials. Plants that have extremely rapid growth, lack natural competitors, or are allelopathic* can crowd out all other spe¬ cies and destroy species diversity. State or local agencies may ban the use of some species. Unlike natural wetlands, constructed wetlands will receive a continuous inflow of wastewater with high nutrient concentrations. Plants that can not tolerate this condition will not survive. Tolerant of continuous Unlike natural wetlands, which may experience periodic or occasional dry periods, constructed wetlands will flooding receive a continuous inflow of wastewater. Plants that require periodic or occasional drying as part of their reproductive cycle will not survive. Growth characteristics Perennial plants are generally preferred over annual plants because plants will continue growing in the same area and there is no concern about seeds being washed or carried away. For emergent species, persistent plants are generally preferred over semi- or non-persistent plants because the standing plant material provides added shelter and insulation during the winter season.f Available form for planting Costs of obtaining and planting the plants will vary depending on the form of planting material, which may be available in a variety of forms depending on the plant species. Entire plant forms (e.g. bare root plants or plugs) will usually cost more than partial plant material (e.g. seeds or rootstock), but the plant supplier may guarantee a higher survival rate.T Rate of growth Slower growing plants will require a greater number of plants, planted closer together, at start-up to obtain the same density of plant coverage in the initial growing season. Wildlife benefits If the wetland is to be used for habitat, plants that provide food, shelter/cover and nesting/nursery for the desired animals should be chosen. Plant diversity Mono-cultures of plants are more susceptible to decimation by insect or disease infestations; catastrophic infestations will temporarily affect treatment performance. Greater plant diversity will also tend to encourage a greater diversity of animals. * Allelopathic - plants that have harmful effects on other plants by secreting toxic chemicals t Perennial - aboveground portion dies, but below-ground portion remains dormant and sprouts in the next growing season. Annual - entire plant dies and reproduction is only by seed produced before the plant dies. Persistent - aboveground dead portions remain upright through the dormant season. Semi-persistent - aboveground dead portions may remain standing for some part of the dormant season before falling into clumps. Non-persistent - aboveground dead portions decay and wash away at the end of the growing season. t Bare root plant - seedling with soil washed from roots. Plug - seedling with soil still on roots. Rootstock - piece of underground stem (rhizome). For some species with high lignin content, particularly cattail, bulrush, and common reed, much of the plant re¬ mains standing as dead biomass that slowly decays dur¬ ing the winter season. In FWS systems, this standing dead biomass provides additional structure for enhanced floc¬ culation and sedimentation that is important in wetland treatment performance throughout the annual cycle. Dead biomass, both standing and fallen, also is important to root viability under flooded, winter conditions because of the insulating layer it provides, in addition to its contribution to the internal load on the system. Like all plants, wetland plants require many macro- and micronutrients in proper proportions for healthy growth. While municipal wastewater can supply adequate quanti¬ ties of these limiting nutrients, other types of wastewater, including industrial wastewater, acid mine drainage, and stormwater, may not. Nitrogen and phosphorus are key nutrients in the life cycles of wetland plants. However, plant uptake of nitro¬ gen and phosphorus is not a significant mechanism for removal of these elements in most wetlands receiving par¬ tially treated municipal wastewater because nitrogen and phosphorus are taken up and released in the cycle of plant growth and death. Nonetheless, undecomposed litter from dead biomass provides storage for phosphorus, metals, and other relatively conservative elements (Kadlec and Knight, 1996). While uptake rates of nitrogen and phosphorus are po¬ tentially high, harvesting plant biomass to remove these nutrients has been limited to floating aquatic plant com¬ munities, in which the plants can be harvested with only brief altering of system performance. Although common reed is harvested annually from certain European con¬ structed wetlands as a by-product (and not for nutrient re¬ duction), full-scale constructed wetlands where plants are 15 routinely harvested have not been documented in the United States. 2.4 Fauna of Constructed Wetlands The role that animal species may play in constructed wetlands is a consideration for management of FWS wet¬ lands. Animals typically compose less biomass than do wetland plants, but animals are able to alter energy and mass flows disproportionately to their biomass contribu¬ tion. During outbreaks of insect pests in constructed wet¬ lands, for example, entire marshes and floating aquatic plant systems can be defoliated, which interrupts mineral cycles and upsets water-quality treatment performance. In another example, the rooting action of bottom-feeding fish (primarily carp) causes sediment resuspension, which affects performance of constructed wetlands in removing suspended solids and associated pollutants. The presence of large seasonal waterfowl populations has had similar results in constructed wetlands at Columbia, Missouri, and elsewhere. In VSB wetlands, only avian species play a significant role. While wildlife species play generally positive, second¬ ary roles in constructed wetlands, their presence also may generate unintended consequences. Bird species common to wetland environments, for example, typically attract birdwatchers, who may provide public support for munici¬ palities and industries employing this treatment technol¬ ogy. The presence of the public at constructed wetlands for secondary treatment, however, necessitates manage¬ ment efforts to ensure adequate protection from human health and safety risks presented by exposure to primary effluent (see also section 2.6). Conversely, regulatory con¬ cern for potentially vulnerable wildlife species has impeded plans for constructed wetlands at certain sites and for cer¬ tain wastewaters with toxic constituents. Free water surface wetlands closely resemble the ecol¬ ogy of natural wetlands and aquatic habitats, and they in¬ evitably attract animal species that rely on wet environ¬ ments during some or all of their life history. All animal groups are represented in constructed wetlands: protozo¬ ans, insects, mollusks, fish, amphibians, reptiles, birds, and mammals. Table 2-3 summarizes animal species that may be found in constructed wetlands. 2.5 Ecological Concerns for Constructed Wetland Designers Wetland ecology is integral to the success of constructed wetlands because of their complexity and their accessibil¬ ity to wildlife. While the ecology of VSB systems relates more to its subsurface than its surface environment, wet¬ land plants and other surface features that are character¬ istic of VSB wetlands also require consideration. Table 2.3 Characteristics of Animals Found in Constructed Wetlands Members of Group Commonly Found in Function or Importance to Treatment Animal Group Treatment Wetlands Process Design & Operational Considerations Invertebrates, including protozoa, insects, spiders, and crustaceans A wide variety will be present, but diversity and populations will vary seasonally and spatially. Undoubtedly play a role in chemical and biological cycling and transformations and in supporting food web for higher organisms, but exact functions have not been defined Mosquito control must be considered; mono-cultures of plants are more susceptible to decimation by insect infestations. Fish Species adapted to living at or near the surface (mosquitofish, mudminnow); species adapted to living in polluted waters (bowfin, catfish, killifish, carp). Consumers of insects and decaying material (e.g. mosquitofish eat mosquito larvae). Anaerobic conditions will limit populations; nesting areas required; bottom-feeders can uproot plants and resuspend sediments. Amphibians and Reptiles Frogs, alligators, snakes, turtles Consumers of lower organisms Turtles have an uncanny ability to fall into water control structures and to get caught in pipes, so turtle exclusion devices are needed; monitoring of control structures and levees for damage or obstruction is needed. Birds A wide variety (35-63 species') are present, including forest and prairie species as well as waterfowl, but diversity and populations vary seasonally and spatially. Consumers of lower organisms Heavy use, especially by migratory waterfowl, can contribute to pollutant load on a seasonal basis. Mammals Small rodents (shrews, mice, voles); large rodents (rabbits, nutria, muskrats, beaver); large grazers (deer); large carnivores (opossums, raccoons, foxes). Consumers of plants and lower organisms Nutria and muskrat populations can reach nuisance levels, removing vegetation and destroying levees; structural controls and animal removal may be required. * McAllister, 1992, 1993a, 1993b 16 Constructed wetlands invariably attract wildlife, a factor that must be considered in the design and management of constructed wetlands. As components of an ecological community, animals in general perform vital ecological func¬ tions in constructed wetlands. Specific roles of animals in the development and operation of constructed wetlands, however, are not well researched. Experience has shown that many animals are beneficial elements in constructed wetlands, but many other are nuisance species. Proper attention to desirable and undesirable wildlife species, as well as primary and ancillary functions of constructed wet¬ lands, will aid the success of a constructed wetland. 2.5.1 Primary and Ancillary Functions of Constructed Wetlands Primary functions of most constructed wetlands include water storage and water-quality improvement. Some of these constructed wetlands are designed intentionally for ground water recharge. Numerous other functions attrib¬ uted to natural wetlands are important in constructed wet¬ lands and are described in succeeding chapters. Ancillary functions include primary production of organic carbon by plants; oxygen production through photosyn¬ thesis; production of wetland herbivores, as well as preda¬ tor species that range beyond the wetland boundaries; reduction of export of organic matter and nutrients to down¬ stream ecosystems; and creation of cultural values in terms of educational and recreational resources. One or more of these ancillary functions may be an important goal in some constructed wetland projects. For detailed descriptions of ancillary functions, the reader is referred to information presented elsewhere (Feierabend, 1989; Sather, 1989; Knight, 1992). 2.5.2 Wildlife Access Controls Successful wildlife management in FWS wetlands re¬ quires maintaining a balance between attracting benefi¬ cial species and controlling pest species (EPA, 1993a). While most wildlife species in wetlands are attractive but often unnoticed, many species are attractive for aesthetic reasons but are impediments to the success of constructed wetlands. Nuisance species in constructed wetlands in¬ clude burrowing rodents, especially beavers, nutria, and muskrats, which burrow through berms and levees and consume beneficial emergent vegetation; mosquitoes, which cause annoyance and health concerns; and certain bottom-feeding fish, such as carp, which uproot aquatic vegetation and cause increases in effluent TSS and asso¬ ciated pollutants by stirring up sediments and resuspend¬ ing them in the water column. Waterfowl in large numbers also may be undesirable because they cause similar prob¬ lems, and their nutrient-rich droppings place additional demands on the water-quality performance of constructed wetlands. Control of wildlife access in constructed wetlands is highly site-specific; as a result, control measures must be based on geographic location, nuisance species, wetland design, and preferred levels of management. Control methods are applied throughout the planning, construction, and opera¬ tion of constructed wetland projects. Control of carp, for example, can be anticipated during design and managed with winter drawdown of water levels and subsequent in- depth freezing in northern climates. Also effective is draw¬ down and physical removal of stranded individuals, but this method is more labor intensive and less effective in eradicating carp populations. Large rodents can be screened out of culverts to limit access and prevent dam¬ ming; however, trapping and physical removal may be needed to prevent burrowing and subsequent undermin¬ ing of banks and other damage. For waterfowl control, lim¬ ited open-water areas will discourage many species, but treatment requirements will dictate the size and use of these zones. Netting suspended over unavoidable open-water areas can prevent their use for feeding, but this method deviates from the intent to incorporate natural methods of wildlife control. Wetland wildlife species frequently have home ranges well outside the borders of an individual constructed wet¬ land cell; consequently, they can become a public resource that may need to be protected and promoted for reasons unrelated to their perceived value to constructed wetlands. Although the values of constructed wetlands for wildlife habitat may be subject to public and scientific debate, this topic nonetheless must be considered in all project phases to determine optimum design and management features to promote or discourage the presence of wildlife (Knight, 1997; Worrall et al., 1996). 2.5.3 Mosquito Habitat Controls Mosquitoes may be integral components of the ecologi¬ cal food web, but mosquitoes generally are considered a pest species. While a constructed wetland’s attractiveness to wildlife may be regarded as a benefit to the human com¬ munity, the potential for breeding mosquitoes can be an obstacle to permitting, funding, and other steps essential to the siting of a constructed wetland. Several methods of mosquito control can be employed in the planning, construction, and operation of constructed wetlands. Predation is one means. Mosquito fish have been found to be effective in reducing mosquito populations when habitat conditions are optimized by manipulating water lev¬ els and when channels are kept free of dead vegetation. Drawdown of water levels aids mosquito fish spawning in spring and provides the fish with better access to mos¬ quito larvae during mosquito breeding season (Dill, 1989). In warm climates, mosquito fish habitat must be monitored for excessive water temperatures and fluctuations in efflu¬ ent strength and content. Bats and several avian species also are effective predators, but planning and managing optimum conditions have yet to be standardized. In the planning and construction stages, management of mosquito habitat can be enabled with steep slopes on water channels that reduce standing water area in shallow areas. In contrast to this design is the use of more natural, undulating banks that have been popular in polishing wet- 17 lands. This natural appearance is more visually appealing but is ineffective for mosquito-control purposes. A channel profile that has been effective in mosquito control is a steep¬ sided channel flanked by relatively flat aprons leading out¬ ward to steep-sided banks (Dill, 1989). This profile allows the facility operator to draw down water levels to the lower channel during the mosquito-breeding season. Figure 2-4 illustrates this design. With standing water eliminated from emergent vegetation in the shallow flanks of the channel, deeper water in the lower channel provides an environ¬ ment more conducive to mosquito predation by fish spe¬ cies. Flexible drainage capability is essential to this means of control. Water spray systems also have been used for mosquito control, but such mechanical systems are inconsistent with the passive nature of constructed wetlands, which utilize natural systems to accomplish wastewater treatment and manage ancillary concerns. Vegetation management is another approach to mos¬ quito control, especially in the absence of water-level con¬ trol features (Dill, 1989). Taller vegetation especially needs management. Cattails and bulrushes, for example, tend to fall over late in the growing season, which creates condi¬ tions favorable for mosquito reproduction in the following growing season, as well as unfavorable conditions for pre¬ dation by mosquito fish (Martin and Eldridge, 1989). Chan¬ nels planted with lower-growing vegetation and cleared annually of dead standing stock can reduce mosquito popu¬ lations and optimize predation, providing that this vegeta¬ tion imparts the same structural role beneath the water surface. Larvicide is a proven means of active mosquito control when employed in conjunction with other management techniques. A bacterium (Bacillus sphaericus) has been found effective in reducing culex mosquitoes, one of the most common species in the United States. Tests have indicated that a commercial larvicide containing the bacte¬ ria may be capable of eliminating most of the populations of culex in treatment lagoons (WaterWorld, 1996). The concentrated bacteria in powdered form is applied to stand¬ ing water as a coating on granulated corncobs, which quickly releases protein crystals and bacteria spores to the water surface. Upon ingestion, the bacteria enter mos¬ quito larvae tissues through pores in the gut wall and mul¬ tiply rapidly, and the infected larvae typically die within two days. However, fully vegetated zones are more difficult to treat than open water zones or lagoons. 2.6 Human Health Concerns Many studies of constructed wetlands’ biological effec¬ tiveness and attractiveness to humans for aesthetic and cultural reasons have focused on polishing wetlands that receive secondary effluent, which are outside the focus of this manual. At many of these successful polishing wet¬ lands for tertiary treatment, interpretive centers and signage invite visitors, and boardwalks and naturalists guide them through the outdoor experience. Constructed wetlands that receive primary effluent for secondary treatment, on the other hand, may not be visitor-friendly places, and human visitors may best enjoy them from the periphery for sev¬ eral reasons. Partially treated wastewater in a constructed wetland for secondary treatment, despite the proven effectiveness of this ecological approach to treatment, presents essentially the same risks to human health as wastewater in primary treatment and lagoons. Risk of dermal contact and pos¬ sible transmission of disease is equally unappealing in FWS wetlands for secondary treatment as it is in open lagoons. This concern is distinguished from human interaction with Figure 2-4. Profile of a three-zone FWS constructed wetland cell 18 polishing systems, where influent wastewater has already met effluent quality requirements which are set by regula¬ tory authorities. In constructed wetlands receiving primary effluent, hu¬ man exposure to wastewater is a greater concern at the inlet end of the system, where influent has achieved pri¬ mary treatment only. Lesser concern for human exposure is warranted at the outlet end, where wastewater has been treated to the quality of secondary treatment or better, which is the quality of wastewater entering the polishing wetlands that have been popular for environmental awareness and education activities. As a result, humans must be considered an unwanted species in most areas of FWS wetlands treating municipal wastewater to meet secondary treatment (defined as 30 mg/L of BOD and TSS). Nonetheless, constructed wet¬ lands can serve as recreational areas and outdoor labora¬ tories, especially at the outlet end where wastewater has been treated to secondary effluent standards. Management considerations may include the public’s access, percep¬ tions, and exposure to health threats (Knight, 1997). To effectively address these concerns, fencing, signage, and other controls must be considered in the proposal stage as well as in design and operation of the system. Mosquito populations may represent merely an annoy¬ ance factor to be managed, as described above, but some species of mosquitoes also carry a health risk that must be addressed. In warmer climates, including the southern United States, the encephalitis mosquito (Culex tarsalis) thrives in the extended breeding season provided by con¬ structed wetlands, but water-level manipulation and mos¬ quito fish predation in the two-tiered pond design described previously have been effective in controlling these mos¬ quito populations (Dill, 1989). The two-tiered design allows water levels to be drawn down to concentrate prey spe¬ cies (mosquitoes) in smaller areas for more efficient con¬ sumption by predators (mosquito fish). Most of the health concerns described above do not apply to VSB systems, in which wastewater typically is not ex¬ posed at the land surface. 2.7 On-site System Applications On-site constructed wetland systems may also be ap¬ plied to wastewater treatment and disposal at individual properties. On-site constructed wetlands generally utilize the same technologies as the municipal VSB systems de¬ scribed in this manual, and they share with municipal sys¬ tems the advantages of cost-effectiveness and low-main¬ tenance requirements. However, on-site constructed wet¬ lands are distinguished typically by final effluent discharge to soils instead of surface water. For purposes of this dis¬ cussion, on-site constructed wetland systems treat septic tank effluent, or primary effluent, in small-scale VSB sys¬ tems for subsurface disposal to soils. On-site constructed wetlands also differ from municipal systems in scale. On-site constructed wetlands typically occupy only a few hundred square feet. Municipal VSB systems may serve hundreds of residential, commercial, and industrial properties, while on-site systems would serve a single home or several residences in a cluster. An on-site VSB system typically consists of a lined VSB that receives primary effluent from a septic tank, and in some designs, a second VSB that receives effluent from the upstream VSB system. The second VSB can be un¬ lined to allow treated wastewater to infiltrate to soil for dis¬ posal. Variations of this treatment train include use of supplemental absorption trenches to facilitate soil absorp¬ tion and direct surface discharge with or without subse¬ quent disinfection. Each VSB typically is planted with wet¬ land vegetation. Applied studies and research experiments of on-site constructed wetland systems have shown adequate treat¬ ment performance for most wastewater constituents, in¬ cluding BOD, TSS, and fecal coliforms, with variations in performance for removal of ammonia nitrogen (Burgan and Sievers, 1994; Huang et al., 1994; Johns et al., 1998; Mankin and Powell, 1998; Neralla et al., 1998; White and Shirk, 1998). 2.8 Related Aquatic Treatment Systems Several types of aquatic treatment systems have been constructed to treat municipal and other wastewaters, and most of these systems fall outside the definition of con¬ structed wetlands discussed in this manual. These other types of systems are briefly described to provide the reader with additional background and references to source ma¬ terial. Polishing wetlands have been used also to remove trace metals, including cadmium, chromium, iron, lead, manga¬ nese, selenium, and zinc in a variety of situations. The primary removal mechanism for metals in wastewater ap¬ pears to be sedimentation. Plant uptake results in deposi¬ tion of metals to soil via plant roots and requires harvest of plants to partially remove metals from the system. In some cases, however, effluent concentrations of metals have exceeded influent levels, apparently due to evaporation of wastewater. One proprietary treatment system, which among its many manifestations has used both FWS-like and VSB-like treat¬ ment units as part of its treatment train, is known as the Advanced Ecologically Engineered System (AEES), or “Living Machine.” This system incorporates conventional treatment system components, including sedimentation/ anaerobic bioreactors, extended aeration, clarifiers, fixed- film reactors, and a final clarifier, sometimes with a VSB for polishing, in a greenhouse setting. The AEES was ap¬ plied to four demonstration projects funded with federal grants. The four projects underwent evaluation of treat¬ ment performance for various wastewater types and set¬ tings (e.g., raw wastewater in a moderate climate, raw wastewater at higher flow rates in a colder climate, in situ water-quality improvements to pond water, and polishing 19 of secondary effluent). One of the demonstration projects also was evaluated by an independent firm under contract to the U.S. EPA (EPA, 1997b). Results of performance evaluations indicated that wastewater treatment met per¬ formance goals for certain wastewater constituents; other goals were unmet. Although this technology is presented by its developers as a type of natural system, the use of wetland plants appears to influence aesthetics more than treatment performance. The reader is directed to other sources for further information (EPA, 1993b; EPA, 1997b; Living Technologies, 1996; Reed et al., 1995; Todd and Josephson, 1994). Floating macrophyte systems rely only partially on treat¬ ment processes provided by wetlands and require mecha¬ nized components to achieve the intended treatment per¬ formance. Larger duckweed systems and water hyacinth systems utilize mechanical systems to remove floating macrophytes. Both have been employed to treat waste- water by removing some of the wastewater constituents, primarily BOD and TSS. In both systems, removal of plants usually requires additional mechanical systems for drying, disposal, and other residuals handling (Zirschky and Reed, 1988). 2.9 Frequently Asked Questions 1. What are constructed wetlands? The term “constructed wetlands” refers to a technol¬ ogy designed to employ ecological processes found in natural wetland ecosystems. These systems uti¬ lize wetland plants, soils, and associated microorgan¬ isms to remove contaminants from wastewater. As with other natural biological treatment technologies, wetland treatment systems are capable of providing additional benefits. They are generally reliable sys¬ tems with no anthropogenic energy sources or chemi¬ cal requirements, a minimum of operational require¬ ments, and large land requirements. The treatment of wastewater using constructed wetland technology also provides an opportunity to create or restore wet¬ lands for environmental enhancement, such as wild¬ life habitat, greenbelts, passive recreation associated with ponds, and other environmental amenities. 2. What are wetland treatment systems? The term “wetland treatment system” generally re¬ fers to two types of passive treatment systems. One type of system is a free water surface (FWS) con¬ structed wetland, which is a shallow wetland with a combination of emergent aquatic plants (cattail, bul¬ rush, reeds, and others), floating plants (duckweed, water hyacinth, and others), and submergent aquatic plants (sago pondweed, widgeon grass, and others). A FWS wetland may have open-water areas domi¬ nated by submergent and floating plants, or it may contain islands for habitat purposes. It may be lined or unlined, depending on regulatory and/or perfor¬ mance requirements. These systems exhibit com¬ plex aquatic ecology, including habitat for aquatic and wetland birds. A second type of system is termed “vegetated sub¬ merged bed (VSB)” and is known to many as a sub¬ surface flow wetland. A VSB is not an actual wet¬ land because it does not have hydric soils. Emer¬ gent wetland plants are rooted in gravel, but waste- water flows through the gravel and not over the surface. This system is also shallow and contains sufficiently large gravel to permit long-term subsur¬ face flow without clogging. Roots and tubers (rhi¬ zomes) of the plants grow into pore spaces in the gravel. Most current data indicate that these sys¬ tems perform as well without plants as with plants; as a result, wetland ecology is not a critical factor in VSB systems. 3. Are constructed wetlands reliable? What do they treat? Constructed wetlands are an effective and reliable water reclamation technology if they are properly designed, constructed, operated, and maintained. They can remove most pollutants associated with municipal and industrial wastewater and stormwater and are usually designed to remove contaminants such as biochemical oxygen demand (BOD) and suspended solids. Constructed wetlands also have been used to remove metals, including cadmium, chromium, iron, lead, manganese, selenium, zinc, and toxic organics from wastewater. 4. How does a constructed wetland treat wastewa¬ ter? A natural wetland acts as a watershed filter, a sink for sediments and precipitates, and a biogeochemi¬ cal engine that recycles and transforms some of the nutrients. A constructed wetland performs the same functions for wastewater, and a constructed wetland can perform many of the functions of con¬ ventional wastewater treatment trains (sedimenta¬ tion, filtration, digestion, oxidation, reduction, ad¬ sorption, and precipitation). These processes oc¬ cur sequentially as wastewater moves through the wetland, with wastewater constituents becoming comingled with detritus of marsh plants. 5. What is the difference between treatment and en¬ hancement wetlands? Constructed wetlands generally are designed to treat municipal or industrial effluents as well as stormwater runoff. Enhancement marshes, or pol¬ ishing wetlands, are designed to benefit the com¬ munity with multiple uses, such as water reclama¬ tion, wildlife habitat, water storage, mitigation banks, and opportunities for passive recreation and envi¬ ronmental education. Both types of wetland sys¬ tems can be designed as separate systems, or 20 important attributes of each can be integrated into a single design with multiple treatment and en¬ hancement objectives. 6. Can a constructed wetland be used to meet a sec¬ ondary effluent standard? Both FWS and VSB constructed wetlands can be used to meet a 30/30 mg/L BOD and TSS discharge standard. It is not advisable to put raw wastewater into a constructed wetland. 7. Can a constructed wetland be used to meet an advanced secondary/tertiary discharge standard? With sufficient pretreatment and wetland area, FWS constructed wetlands can meet discharge standards of less than 10 mg/L BOD, TSS, and TN on a monthly average basis. Many examples of FWS wetland systems meeting these standards on a monthly average basis can be found in the United States (EPA, 1999). VSB systems have been used extensively in England for polishing secondary ef¬ fluents and treating effluent from combined sani¬ tary and storm sewers. In the U.S., they have gen¬ erally not performed well in consistently reaching advanced treatment goals with primary treatment influent. 8. How much area is required for constructed wet¬ lands? As a general rule, a constructed wetland receiving wastewater with greater degrees of pretreatment (for example, primary clarification, oxidation pond, trickling filter, etc.) requires less area than a con¬ structed wetland receiving higher-strength waste- water. Historically, constructed wetlands designers have employed from <2 to over 200 acres/MGD (4 to 530 L/m 2 -d). However, there is no generic an¬ swer to the question since it depends on the efflu¬ ent criteria to be met and buffer areas required. 9. Do these systems have to be lined? The requirement for liners in constructed wetlands depends on each state’s regulatory requirements and/or the characteristics of surface and subsur¬ face soils. In a general sense, if soils are porous (e.g., sands), well-drained, and contain small amounts of loams, clays, and silts, lining is likely to be a requirement for constructed wetlands. On the other hand, if soils are poorly drained and composed mostly of clays, then lining might not be required. These systems would tend to produce a layer of peat on the bottom that would reduce infiltration with time. The concept of a “leaky wetland,” which may take advantage of natural processes to purify waste- water as it moves downward through soil to re¬ charge the ground water, may be considered a po¬ tential benefit in certain areas. 10. What is the role of the plants in constructed wet¬ lands? In FWS constructed wetlands, plants play several essential roles. The most important function of emergent and floating aquatic plants is providing a canopy over the water column, which limits produc¬ tion of phytoplankton and increases the potential for accumulation of free-floating aquatic plants (e.g., duckweed) that restrict atmospheric reaeration. These conditions also enhance reduction of sus¬ pended solids within the FWS constructed wetland. Emergent plants play a minor role in taking up ni¬ trogen and phosphorus. The effect of litter fall from previous growing seasons as it moves through the water column and eventually decomposes into hu¬ mic soil and lignin particles may be significant in terms of effluent quality. The role of plants in VSB systems is not clear. Ini¬ tially it was believed that translocation of oxygen by plants was a major source of oxygen to microbes growing in the VSB media, and therefore plants were critical components in the process. However, side-by-side comparisons of planted and unplanted systems have not confirmed this belief. Neverthe¬ less, planted VSB systems are more desirable aes¬ thetically than unplanted horizontal rock-filter sys¬ tems, and plants do not appear to hinder perfor¬ mance of VSB systems. 11. How much time is needed for a constructed wet¬ land to become fully operational and meet discharge requirements? For FWS wetland systems, several growing sea¬ sons may be needed to obtain the optimum veg¬ etative density necessary for treatment processes. The length of this period is somewhat dependent on the original planting density and the season of the initial planting. Effluent quality has been ob¬ served to improve with time, suggesting that veg¬ etation density and accumulated plant litter play an important role in treatment effectiveness. VSB systems also require more than one growing season to achieve normal wetland plant densities. However, the time required for VSB systems to become fully operational is considerably less than FWS systems because of the minor role of plants in the treatment process. Development of the mi¬ crobial biomass in the media of a VSB system typi¬ cally requires from three to six months. 12. How long can a FWS wetland operate before ac¬ cumulated plant material and settled solids need to be removed? FWS wetland systems receiving oxidation pond effluent may operate for 10 to 15 years without the need to remove accumulated litter and settled 21 nondegradable influent solids. Treatment capaci¬ ties of these wetlands have not shown a decrease in treatment effectiveness with time. However, it is assumed that further experience will reveal that there is a finite period of accumulation that will re¬ sult in the need to remove solids. In both types of systems, the bulk of the solids accumulation oc¬ curs at the influent end of the system. As a result, solids may need to be removed from only a portion of the system that may be as small as 10 to 25% of the surface area. 13. How much effort is required to operate and main¬ tain a constructed wetland? These systems require a minimum of operational control. Monthly or weekly inspection of weirs and weekly sampling typically are required at the efflu¬ ent end, and periodic sampling between multiple cells is recommended. Maintenance of constructed wetlands generally is limited to the control of unwanted aquatic plants and control of disease vectors, especially mosqui¬ toes. Harvesting of plants generally is not required, but annual removal or thinning of vegetation or re¬ planting of vegetation may be needed to maintain flow patterns and treatment functions. Effective vector control can be achieved by appro¬ priately applying integrated pest management prac¬ tices, such as introducing mosquito fish or provid¬ ing habitat for mosquito-eating birds and bats. Bi¬ monthly monitoring of mosquito larvae and pupae and applications of larvacides may be required on an as-needed basis. Sediment accumulation typically is not a problem in a well-designed and properly operated con¬ structed wetland, thus partial dredging is required only rarely. These tasks would require approximately one day per week of labor for a wetland system treating a flow of one million gallons per day (MGD) (3,880 m 3 /d) or less, and monitoring may be the most de¬ manding task. 14. Do constructed wetlands produce odors? Conventional wastewater treatment processes pro¬ duce odors mostly associated with anaerobic de¬ composition of human waste and food waste found in sewage. These odors usually are concentrated in areas of small confinement and point discharges, like influent pump stations, anaerobic digesters, and sludge-handling processes. Wetlands, in contrast, incorporate normal processes of decomposition over a relatively large area, potentially diluting odors associated with the natural decomposition of plant material, algae, and other biological solids. How¬ ever, wetland treatment systems receiving septic tank and primary effluents can release anaerobic odors around the inlet piping, and both types are generally anaerobic, which makes odor generation a major operational concern. 15. Are mosquitoes a potential problem with con¬ structed wetlands? If so, how are they managed? Mosquitoes generally are not a problem in properly designed and operated VSB systems. However, mosquitoes can be a problem in FWS constructed wetlands. If a FWS wetland is designed with suffi¬ cient open water (40 to 60% of the surface area) to permit effective control with mosquito fish, and in¬ let and outlet weirs are placed to allow level control and drainage of wetland cells, the potential for mosquito populations to thrive is reduced. This lat¬ ter concept provides for isolation of various wet¬ land cells to allow them to be drained and/or to al¬ low predators and mosquitoes to become concen¬ trated in pools and channels. Along with these physical factors, the development of a balanced ecosystem that includes other aquatic invertebrates (beetles), aquatic insects (dragon flies and damsel flies), fish (top-feeding minnows, stick¬ lebacks, gobis, and others), birds (swallows, ducks, and others), and mammals (bats) will help main¬ tain acceptable levels of mosquitoes. Under these conditions, the mosquito is simply a component in a balanced food web. If an imbalance develops, then intervention with certain biological and chemi¬ cal agents may be required. A successful intervention method has been the use of Bti, a bacterium spore that interferes with devel¬ opment of the adult. In essence, Bti kills the larva via physical actions. Several applications over the mosquito season are needed to interfere with the mosquito’s natural growth cycle, which may be three to four months in length. Other larvacides, such as methoprene, are chemicals that are not selective for certain stages of mosquitoes’ life cycle. Adulticides also are not selective for life cycles but could be used at critical times. In general, proper design that supports a healthy wetland ecosystem produces conditions that main¬ tain sufficiently low mosquito populations. 16. What is the present level of application of this tech¬ nology? As of late 1999, more than 200 communities in the United States were reported to be utilizing con¬ structed wetlands for wastewater treatment. Most of these communities use wetlands for polishing lagoon effluent. In addition, communities in a wide range of sizes use this technology, including large cities such as Phoenix, Arizona, and Orange 22 County, Florida. For the most part, however, FWS technology has been utilized by small- to medium¬ sized communities ranging from 5,000 to 50,000 in population. Even though constructed wetlands for municipal wastewater treatment have been around for as long as 40 years, there have been widespread problems in their performance with respect to nitrogen trans¬ formations and removal as well as phosphorus re¬ moval (WRC, 2000). This manual has been cre¬ ated to help future owners and designers avoid unrealistic expectations from these systems. 17. Can these systems operate at elevations other than sea level? FWS and VSB systems are found in a wide range of elevations extending, for example, from the desert Southwest to New England, and from the southeast United States to the Rocky Mountains and Pacific coast regions. The common wetland plants used in these systems are found in all areas of the United States and Canada. There is no in¬ herent biological or ecological basis for these types of systems to not work in the normal range of physi¬ ographic conditions in the United States, Canada, and Mexico. 18. Can constructed wetlands work in cold tempera¬ tures? Constructed wetlands are found in a wide range of climatological settings, including cold climates where ice forms on the surface for four to six months of the year. For example, these systems are found in Canada, North Dakota, Montana, Vermont, Colo¬ rado, and other cold-climate areas. Special con¬ siderations must be included in the design of these systems for the formation of an ice layer and the effect of cold temperatures on mechanical systems, such as the influent and effluent works. The ab¬ sence of living plants that have died back for the winter and the presence of a layer of ice approxi¬ mately 0.5 to 1.0 ft. thick have not been shown to severely affect the secondary treatment capabili¬ ties of these systems. Nitrogen transformation and removal is, however, impaired during very cold pe¬ riods. 19. Can you receive full treatment benefits from a con¬ structed wetland that also provides ancillary ben¬ efits such as wildlife habitat? Multiple benefits can accrue from a FWS con¬ structed wetland if it is properly sited and designed. For example, FWS wetlands that have a significant portion of surface area occupied by submergent aquatic plants and deeper water have been found to produce higher-quality effluent and provide greater habitat value than other configurations. This open space is used by aquatic fowl for feeding, access to refugia, and as a source of fresh water. The same submerged aquatic plants that provide wastewater treatment also serve as a food source for aquatic birds and mammals. Because reduced human health risk is associated with tertiary treatment or “polishing” wetlands, they have commonly enjoyed full recreational access to the FWS systems, but they provide minimal removal of several key pollutants in comparison to the treat¬ ment wetlands that are the focus of this manual. Therefore, human access to these systems entails greater health risks because the wastewater is ac¬ tively being treated. The wildlife and other natural ecological populations may be equally abundant in these systems as in the polishing systems, but hu¬ man access may be restricted, at least in the inlet environs. The potential for ancillary benefits is reduced with VSB systems. Depending on its size and degree of vegetation, a VSB system could provide wildlife habitat. VSB wetlands also can be used for envi¬ ronmental education and awareness activities. 2.10 Glossary Abiotic Nonbiological processes or treatment mechanisms in a constructed wetland. Adsorption Adherence by chemical or physical bonding of a pollutant to a solid surface. Adventitious roots provide a competitive advantage to a plant by growing from stems into the surrounding air (around terrestrial plants) or water (around aquatic plants) before entering the soil substrate to provide additional up¬ take or absorption directly from the surrounding medium. Aerenchymous tissues in aquatic plants provide for trans¬ fer of gases within a plant. In wastewater treatment sys¬ tems, emergent aquatic plants rely on aerenchymous tis¬ sues for transfer of oxygen to their roots. Aerobic processes in wastewater treatment systems take place in the presence of dissolved oxygen. Algae are single-celled to multicelled organisms that rely on photosynthesis for growth. Most algae are classified as plants. Anaerobic processes in wastewater treatment systems take place in the absence of dissolved oxygen and instead rely on molecular oxygen available in decomposing com¬ pounds. Aspect ratio The length of a constructed wetland divided by its width (LVW). Atmospheric reaeration introduces atmospheric oxygen into the water at the water’s surface, which provides dis¬ solved oxygen to the aquatic environment. 23 Autotrophic Types of reactions that generally require only inorganic reactants; for example, nitrification. Biochemical oxygen demand (BOD) is the demand for dissolved oxygen that decomposition of organic matter places on a wastewater treatment process. BOD as ex¬ pressed in milligrams per liter (mg/L) is used as a mea¬ sure of wastewater organic strength and as a measure of treatment performance. This constituent is represented throughout the text of this manual as “BOD,” which stands for the U.S. standard 5-day BOD test result. Biomass is the total amount of living material, including plants and animals, in a unit volume. Biotic is a term which implies microbiological or biological mechanisms of treatment. BOD removal is the lowering of demand for dissolved oxy¬ gen required for biological decomposition processes in the water column; hence, BOD removal can be accomplished by biological decomposition in open-water zones and by flocculation and sedimentation in fully vegetated zones and in VSBs. Bulrush is the common name for a number of plants of the genus Scirpus found in wetlands. Several species of bulrush commonly used in constructed wetlands thrive in the wide range of environmental conditions in constructed wetlands, including varying levels of water depth and qual¬ ity. The large, terete bulrush species include S. validus, S. californicus, and S. acutus, all of which form dense stands with large numbers of round-sectioned stems that main¬ tain an upright posture for one or more years. Other spe¬ cies of Scirpus include the three-square varieties, such as S. americanus (olynei), S. fluviatilis, and S. robustus, which offer tolerance to salinity, a variety of color shades, and attractiveness to various animal species. Canopy Uppermost or tallest vegetation in a plant com¬ munity. Cattail is the common name for a number of plants of the genus Typha that are common in constructed wetlands in the United States, with at least three species predominant: T. latifolia, T. domingensis, and T. angustifolia. Along with their hybridized forms, these species occupy numerous water-depth and water-quality niches within constructed wetlands. The wetland designer is advised to consult local botanists and geographic references to determine which local cattail species or hybrid is best adapted to the spe¬ cific water quality, water depth, and substrate planned for a constructed wetland. Common reed (Phragmites) probably is the most widely used plant in constructed wetlands on a worldwide basis, but it typically is not used in the United States. Although this plant has excellent growth characteristics in very shal¬ low constructed wetlands, it is an invasive species in some natural wetlands, and its transport and intentional intro¬ duction to some localities are discouraged. Common reed is considered to offer little value as food or habitat for wet¬ land wildlife species (Thunhorst, 1993). Constructed wetlands are wastewater treatment systems that rely on physical, chemical, and biological processes typically found in natural wetlands to treat a relatively con¬ stant flow of pretreated wastewater. Deciduous Woody plants that shed their leaves in cold seasons. Dentrification Biotic conversion of nitrate-nitrogen to ni¬ trogen gases. Detritus Loose, dead leaves and stems from dead veg¬ etation. Dike A wall of mounded soil that contains or separates constructed wetlands from surrounding areas. Dissolved oxygen (DO) is required in the water column of a waste- water treatment system for aerobic biochemical processes that take place in constructed wetlands. Dominant plant species The plant species that exerts a controlling influence on the function of the entire plant com¬ munity. Duckweed Duckweed naturally moves on a large water surface by movement induced by wind action unless it is protected from the wind and held in place by dense stands of emergent plants (e.g., macrophytes) or artificial barri¬ ers. In FWS systems, this results in dense growths of duck¬ weed within the fully vegetated zones. Duckweed effec¬ tively seals the water surface and prevents atmospheric reaeration. This action combined with the inherent oxygen demand of the incompletely treated municipal wastewater results in anaerobic conditions in these fully vegetated zones. Emergent herbaceous wetland plants grow rooted in the soil, with plant structures extending above the surface of the water. These plants are herbaceous by virtue of their relatively decomposable (leafy) plant structures, but they also have sufficient internal structure to maintain their up¬ right growth, even without the support of surrounding wa¬ ters. Most emergent wetland plants grow with or without the presence of surface water; however, they generally grow in shallow water near the banks of a water body. Emergent vegetation (see macrophytes). Evapotranspiration Loss of water to the atmosphere through water surface and vegetation. Exotic species A plant not indigenous to the region. Fecal coliform A common measure for pathogenicity of wastewater. This analytical test reveals the number of these types of organisms in counts/100 milliliters (#/100mL) Filtration is the process of filtering influent solids from the wastewater and typically is provided by plant stems and leaves and other vegetation in the water column. 24 Floating aquatic plants are commonly found in FWS sys¬ tems, including water hyacinth ( Eichhornia crassipes), duckweed ( Lemna spp., Spirodela spp., and Wolffia spp.), water fern ( Azolla carotiniana and Salvinia rotundifolia), and water lettuce ( Pistia stratiotes). Also common are rooted plants growing in a floating form, including penny¬ wort ( Hydrocotlyle spp.), water lily ( Nymphaea spp.), frog's bit (Limnobium spongia), spatterdock (Nuphar spp.), and pondweed ( Potemogeton spp.). Floating aquatic systems are in essence shallow basins covered with floating aquatic plants. One type of plant that can remain in place is the water hyacinth, but it is very sensitive to other than tropical temperatures and is con¬ sidered to be an invasive species. Duckweed has been held in place with artificial barriers in these types of sys¬ tems. Flocculation is the process of very small particles of mat¬ ter clumping together to reach a collectively larger size. In wastewater treatment processes, flocculation typically ag¬ glomerates colloidal particulates into larger, settleable sol¬ ids that are then removed by sedimentation processes. Free water surface (FWS) wetlands are constructed wet¬ lands that provide wastewater treatment through floccula¬ tion and sedimentation during the flow of wastewater through stands of aquatic plants growing in shallow water. In some FWS wetlands, there are also open areas where aerobic bio-oxidation complements the physical removal processes. FWS systems resemble natural wetlands in function and appearance. FWS systems have also been termed “surface flow systems.” Function refers to the purpose, role, or actions expected of constructed wetlands in the process of wastewater treat¬ ment. Function is expressed in terms of expected results, such as nutrient uptake, removal of TSS and BOD, main¬ tenance of dissolved oxygen in open water zones, and reduction of wastewater constituents to acceptable levels, waterfowl habitat, and water storage. Habitat value The suitability of an area to support a given species. Herbaceous Plant material that has no woody parts. Herbivores are members of the animal kingdom that con¬ sume plant matter. Hydric soils, or wetland soils, exhibit distinct chemical and physical changes that result from periodic inundation and saturation. Flooding and subsequent decomposition and oxidation of soil chemicals typically result in anaerobic soil conditions. Hydrophyte Any plant growing in a soil that is deficient in oxygen. Indigenous species Species of plants that are native to an area. Inorganics Compounds that do not contain organic car¬ bon. Lagoons are also called stabilization ponds, oxidation ponds, etc. In conventional wastewater treatment systems, they typically are used to provide intermediate treatment of wastewater through a variety of physical, chemical, and biological processes. Limiting nutrient is the nutrient that controls a particular plant’s growth. When present in insufficient amounts rela¬ tive to a given plant’s needs, a limiting nutrient limits that plant’s growth. Limnetic The open water zone of a FWS system where light can penetrate to induce photosynthesis. Macrophytes are plants that are readily visible to the un¬ aided eye and include vascular or higher plants. Vascular plants include mosses, ferns, conifers, monocots, and di¬ cots. Macrophytes also may be categorized by a variety of ecological growth forms. Marsh A common term applied to treeless wetlands. Microbes or microorganisms are microscopic organisms (only viewed with a microscope), such as bacteria, proto¬ zoans, and certain species of algae, which are respon¬ sible for many of the biochemical transformations neces¬ sary in wastewater treatment processes. Nitrification Biotic conversion of ammonium nitrogen to nitrite and nitrate-nitrogen. Nuisance species Plants that detract from or interfere with the designated purpose(s) of constructed wetlands. On-site constructed wetland systems are wastewater systems for treatment and disposal at the site where waste- water is generated. For example, a residential septic sys¬ tem is an on-site system. Organics Compounds that contain organic carbon (also volatile solids). Oxygen demand Generally expressed through relatively high BOD concentrations, the property of municipal waste- water that removes dissolved oxygen from the water col¬ umn. Photosynthesis is the conversion of sunlight into organic matter by plants through a process of combining carbon dioxide and water in the presence of chlorophyll and light, which releases oxygen as a by-product. Phytoplankton are algae that are microscopic in size which float or drift in the upper layer of the water column and depend on photosynthesis and the presence of phos¬ phorus and nitrogen in the water. Pneumatophores are structures that provide air channels for emergent plants growing in water environments. Polishing wetlands are designed to provide tertiary treat¬ ment to secondary effluent to meet performance standards 25 required by National Pollutant Discharge Elimination Sys¬ tem (NPDES) permits. Design considerations for polish¬ ing wetlands are outside the scope of this manual. Primary effluent is the product of primary treatment of wastewater that typically involves settling of solids in a containment structure, such as a septic tank, settling pond, or lagoon. Primary production is the production of biomass (organic carbon) by plants and microscopic algae, typically through photosynthesis, as the first link in the food chain. Primary treatment of wastewater is a settling process for removal of settleable solids from wastewaters. Rhizome Root-like stem that produces roots and stems to propogate itself in a surrounding zone. Secondary effluent is wastewater that has undergone sec¬ ondary treatment and is discharged to the environment or receives further treatment in tertiary treatment processes. Secondary treatment continues the process begun in pri¬ mary treatment by removing certain constituents, such as biochemical oxygen demand (BOD) and total suspended solids (TSS) from primary effluent to prescribed treatment levels; typically, 30 mg/L in the United States. Sediment Organic and mineral particulates that have settled from the overlying water column (also sludge). Seepage Loss of water from a constructed wetland to the soil through infiltration below the system. Senescence is the phase at the end of a plant’s life that leads to death and, finally, decay. Solar insolation refers to the amount of solar radiation that reaches the constructed wetland. Solar radiation in the summer months may play an important role in photo¬ synthesis in open-water zones of a FWS system. Standing biomass in a constructed wetland is the total amount of plant material that stands erect. This term typi¬ cally is used as “dead standing biomass” to refer to dead, standing plants, in contrast to green plants and plant litter composed of broken and fallen dead plant parts. Structure refers to the form and amount of living and nonliving components of an ecosystem. For example, emergent vegetation provides the structure to perform wetland functions. Wetland structure is expressed in qualitative terms such as species of flora and fauna, or type of wetland such as marsh, bog, or bottomland for¬ est. Submerged aquatic plants or submergent vegetation are rooted plants that grow in open water zones within the water column of an aquatic environment (compare to emergent aquatic plants) and provide dissolved oxygen for aerobic biochemical reactions. They lie below the wa¬ ter surface, except for flowering parts in some species. Subsurface flow (SF) wetlands (see vegetated sub¬ merged bed (VSB) systems). Tertiary treatment (see polishing wetlands). Total nitrogen (TN) is the sum of all the forms of nitrogen, including nitrate, nitrite, ammonia, and organic nitrogen in wastewater, and is typically expressed in milligrams per liter (mg/L). Total phosphorus (TP) is a measure of all forms of phos¬ phorus in wastewater, typically expressed in milligrams per liter (mg/L). Total suspended solids (TSS) are particulate matter in wastewater consisting of organic and inorganic matter that is suspended in the water column. The numeric value is provided by specific analytical test. Typically, municipal wastewaters include the settleable solids and some por¬ tion of the colloidal fraction. Vascular plant Plant that readily conducts water, miner¬ als and foods throughout its boundaries. Vegetated submerged bed (VSB) systems provide waste- water treatment in filter media that is not directly exposed to the atmosphere but may be slightly influenced by the roots of surface vegetation. VSB systems also have been termed subsurface flow (SF) wetlands, rock reed filters, submerged filters, root zone method, reed bed treatment systems, and microbial rock plant filters. In this manual, the term “vegetated submerged bed systems” is used be¬ cause gravel beds rather than hydric soils are the support media for wetland plants; as a result, the systems are not truly wetlands. Vegetative reproduction is the process of asexual repro¬ duction, in which new plants develop from roots, stems, and leaves of the parent plant. Wastewater treatment is the process of improving the quality of wastewater. The term can refer to any parts or all parts of the process by which raw wastewater is transformed through biological, biochemical, and physi¬ cal means to reduce contaminant concentrations to pre¬ scribed levels prior to release to the environment. A wastewater treatment process typically consists of pri¬ mary, secondary, and tertiary treatment. Wetland hydraulics refers to movement of water through constructed wetlands, including volumes, forces, velocities, rates, flow patterns, and other char¬ acteristics. Woody plants are plants that produce bark and vascu¬ lar structures that are not leafy in nature. Woody plants have trunks, stems, branches, and twigs that allow them to occupy a greater variety of available niches than her¬ baceous plants can occupy. General terms that describe categories of woody plants found in wetlands are shrubs, trees (canopy or subcanopy), and woody vines. 26 Wrack Plant debris carried by water. Zooplankton Microscopic and small animals that live in the water column. 2.11 References Arizona Department of Environmental Quality (ADEQ). 1995. Arizona guidance manual for constructed wet¬ lands for water quality improvement. Prepared by R. L. Knight, R. Randall, M. Girts, J.A. Tress, M. Wilhelm, and R.H. Kadlec. ADEQ TM 95-1. Armstrong, W. 1978. Root aeration in the wetland envi¬ ronment. In: D.D. Hook and R.M.M. Crawford (eds.) Plant life in anaerobic environments. Ann Arbor, Ml: Ann Arbor Science, Chapter 9, pp. 269-297. Bavor, H.J., D.J. Roser, P.J. Fisher, and I.C. Smalls. 1989. Performance of solid-matrix wetland systems viewed as fixed-film bioreactors. In: D.A. Hammer (ed.) Constructed wetlands for wastewater treat¬ ment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 39k, pp. 646-656. Burgan, M.A. and D.M. Sievers. 1994. On-site treatment of household sewage via septic tank and two- stage submerged bed wetland. In: Proceedings of the Sev¬ enth International Symposium on Individual and Small Community Sewage Systems. American So¬ ciety of Agricultural Engineers, Atlanta, GA: pp. 77- 84. Burgoon, P.S., K.R. Reddy, and T.A. DeBusk. 1989. Do¬ mestic wastewater treatment using emergent plants cultured in gravel and plastic substrates. In: D.A. Hammer (ed.) Constructed wetlands for wastewa¬ ter treatment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 38f, pp. 536-541. Dennison, M.S. and J.F. Berry. 1993. Wetlands: guide to science, law, and technology. Park Ridge, NJ: Noyes Publications, 439 pp. Dill, C.H. 1989. Wastewater wetlands: user friendly mos¬ quito habitats. In: D.A. Hammer (ed.) Constructed wetlands for wastewater treatment, municipal, in¬ dustrial, and agricultural. Chelsea, Ml: Lewis Pub¬ lishers, Chapter 39m, pp. 664-667. Feierabend, J.S. 1989. Wetlands: the lifeblood of wild¬ life. In: D.A. Hammer (ed.) Constructed wetlands for wastewater treatment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chap¬ ter 7, pp. 107-118. Friend, M. 1985. Wildlife health implications of sewage disposal in wetlands. In: P.J. Godfrey, E.R. Kaynor, S. Pelczarski, and J. Benforado (eds.) Ecological considerations in wetlands treatment of municipal wastewaters. New York, NY: Van Nostrand Reinhold, Chapter 17, pp. 262-269. Gearheart, R.A., F. Klopp, and G. Allen. 1989. Con¬ structed free surface wetlands to treat and receive wastewater: pilot project to full scale. In: D.A. Ham¬ mer (ed.) Constructed wetlands for wastewater treat¬ ment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 8, pp. 121 — 137. Hammer, D.A. 1992. Creating freshwater wetlands. Boca Raton, FL: Lewis Publishers, 298 pp. Huang, J., R.B. Renau, Jr., and C. Hagedorn. 1994. Con¬ structed wetlands for domestic wastewater treat¬ ment. In: Proceedings of the Seventh International Symposium on Individual and Small Community Sewage Systems. American Society of Agricultural Engineers, Atlanta, GA, pp. 66-76. Johns, M.J., B.J. Lisidar, A.L. Kenimer, and R.W. Weaver. 1998. Nitrogen fate in a subsurface flow constructed wetland for on-site wastewater treatment. In: Proceed¬ ings of the Eighth National Symposium on Individual and Small Community Sewage Systems. American Society for Agricultural Engineers, Orlando, FL, pp. 237-246. Kadlec, R.H. and R.L. Knight. 1996. Constructed wetlands. Boca Raton, FL: Lewis Publishers, 893 pp. Kadlec, R.H., D.A. Hammer, and M.A. Girts. 1990. A total evaporative constructed wetland treatment system. In: P.F. Cooper and B.C. Findlater (eds.) Constructed wet¬ lands in water pollution control. Oxford, UK: Pergamon Press, pp. 127-138. Kent, D.M. 1994. Applied wetlands science and technol¬ ogy. Boca Raton, FL: Lewis Publishers, 436 pp. Knight, R.L. 1992. Ancillary benefits and potential prob¬ lems with the use of wetlands for nonpoint source pol¬ lution control. Ecological Engineering, 1:97-113. Knight, R.L. 1997. Wildlife habitat and public use benefits of constructed wetlands. In: R. Haberl, R. Perfler, J. Laber, and P. Cooper (eds.) Wetland systems for wa¬ ter pollution control 1996. Water Science & Technol¬ ogy 35(5). Oxford, UK: Elsevier Science Ltd., pp. 35- 43. Kroodsma, D.E. 1978. Habitat values for nongame wet¬ land birds. In: P.E. Greeson, J.R. Clark, and J.E. Clark (eds.) Wetland functions and values: The state of our understanding. Minneapolis, MN: American Water Resources Association, pp. 320-326. Living Technologies, Inc. 1996. Interim performance re¬ port for the South Burlington, Vermont “Living Ma¬ chine,” January-August 1996. Burlington, VT: Living Technologies, Inc., September 1996. 27 Majumdar, S.K., R.P. Brooks, F.J. Brenner, and R.W. Tiner (eds.) 1989. Wetlands ecology and conserva¬ tion: Emphasis in Pennsylvania. Easton, PA: The Pennsylvania Academy of Science, 394 pp. Mankin, K.R. and G. M. Powell. 1998. Onsite rock-plant filter monitoring and evaluation in Kansas. In: Pro¬ ceedings of the Eighth National Symposium on In¬ dividual and Small Community Sewage Systems. American Society for Agricultural Engineers, Or¬ lando, FL, pp. 228-236. Marble, A.D. 1992. A guide to wetland functional de¬ sign. Boca Raton, FL: Lewis Publishers, 222 pp. Martin, C.V. and B.F. Eldridge. 1989. California’s expe¬ rience with mosquitoes in aquatic wastewater treat¬ ment systems. In: D.A. Hammer (ed.) Constructed wetlands for wastewater treatment, municipal, in¬ dustrial, and agricultural. Chelsea, Ml: Lewis Pub¬ lishers, pp. 393-398. McAllister, L.S. 1992. Habitat quality assessment of two wetland treatment systems in Mississippi—A pilot study. EPA/600/R-92/229. U.S. Environmental Pro¬ tection Agency, Environmental Research Laboratory, Corvallis, OR. November 1992. McAllister, L.S. 1993a. Habitat quality assessment of two wetland treatment systems in the arid west—A pilot study. EPA/600/R-93/117. U.S. Environmental Protection Agency, Environmental Research Labo¬ ratory, Corvallis, OR. July 1993. McAllister, L.S. 1993b. Habitat quality assessment of two wetland treatment systems in Florida—A pilot study. EPA/600/R-93/222. U.S. Environmental Pro¬ tection Agency, Environmental Research Laboratory, Corvallis, OR. November 1993. Merritt, A. 1994. Wetlands, industry & wildlife: A manual of principles and practices. Gloucester, UK: The Wildfowl Trust, 182 pp. Mitsch, W.J. and J.G. Gosselink. 1993. Wetlands. 2d ed. New York, NY: Van Nostrand Reinhold, 722 pp. Neralla, S., R.W. Weaver, and B.J. Lesikar. 1998. Plant selection for treatment of septic effluent in subsur¬ face wetlands. In: Proceedings of the Eighth Na¬ tional Symposium on Individual and Small Commu¬ nity Sewage Systems. American Society for Agri¬ cultural Engineers, Orlando, FL, pp. 247-253. Niering, W.A. 1985. Wetlands. New York, NY: Alfred A. Knopf, 638 pp. Payne, N.F. 1992. Techniques for wildlife habitat man¬ agement of wetlands. New York, NY: McGraw-Hill. Post, Buckley, Schuh & Jernigan, Inc. 1993. Compli¬ ance and performance review for the City of Orlando’s easterly wetland treatment system. Pre¬ pared for the City of Orlando, FL. Reed, S.C., R.W. Crites, and E.J. Middlebrooks. 1995. Natural systems for waste management and treat¬ ment. 2d ed. New York, NY: McGraw-Hill, 433 pp. Reed, S.C., J. Salisbury, L. Fillmore, and R. Bastian. 1996. An evaluation of the “Living Machine” waste- water treatment concept. In: Proceedings, WEFTEC *96, 69th Annual Conference and Exhibition, Dal¬ las, TX. Water Environment Federation, Alexandria, VA, October 1996. Sather, J.H. 1989. Ancillary benefits of wetlands con¬ structed primarily for wastewater treatment. In: D.A. Hammer (ed.) Constructed wetlands for wastewa¬ ter treatment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 28a, pp. 353-358. Schueler, T.R. 1992. Design of stormwater wetland sys¬ tems: Guidelines for creating diverse and effective stormwater systems in the mid-Atlantic region. Anacostia Restoration Team, Metropolitan Washing¬ ton Council of Governments, Washington, DC. 133 pp. Snoddy, E.L., G.A. Brodie, D.A. Hammer, and D.A. Tomljanovich. 1989. Control of the armyworm, Simyra henrici (Lepidoptera: Noctuidae), on cattail plantings in acid drainage constructed wetlands at Widows Creek Steam-Electric Plant. In: D.A. Ham¬ mer (ed.) Constructed wetlands for wastewater treat¬ ment, municipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 421, pp. 808-811. Stowell, R., S. Weber, G. Tchobanoglous, B.A. Wilson, and K.R. Townzen. 1985. Mosquito considerations in the design of wetland systems for the treatment of wastewater. In: P.J. Godfrey, E.R. Kaynor, S. Pelczarski, and J. Benforado (eds.) Ecological con¬ siderations in wetlands treatment of municipal wastewaters. New York, NY: Van Nostrand Reinhold, Chapter 3, pp. 38-47. Thunhorst, G.A. 1993. Wetland planting guide for the northeastern United States: Plants for wetland cre¬ ation, restoration, and enhancement. St. Michaels, MD: Environmental Concern, Inc., 179 pp. Thut, R.N. 1989. Utilization of artificial marshes for treat¬ ment of pulp mill effluents. In: D.A. Hammer (ed.) Constructed wetlands for wastewater treatment, mu¬ nicipal, industrial, and agricultural. Chelsea, Ml: Lewis Publishers, Chapter 19, pp. 239-244. Todd, J. and B. Josephson. 1994. Living machines: Theoretical foundations and design precepts. Falmouth, MA: Ocean Arks International. 28 U.S. Environmental Protection Agency (EPA). 1988. Design manual: Constructed wetlands and aquatic plant sys¬ tems for municipal wastewater treatment. Center for Environmental Research Information, Cincinnati, OH. U.S. Environmental Protection Agency (EPA). 1993a. Con¬ structed wetlands for wastewater treatment and wildlife habitat. EPA 832-R-005. Office of Water, Washington, DC. U.S. Environmental Protection Agency (EPA). 1993b. Sub¬ surface flow constructed wetlands for wastewater treat¬ ment: A technology assessment. EPA 832-R-93-008. Office of Water, Washington, DC. U.S. Environmental Protection Agency (EPA). 1997a. Re¬ sponse to Congress on use of decentralized wastewa¬ ter treatment systems. EPA 832-R-97-001 b. Office of Water, Washington, DC. U.S. Environmental Protection Agency (EPA). 1997b. Re¬ sponse to Congress on the AEES “Living Machine” Wastewater Treatment Technology. EPA 832-R-97-002. Office of Water, Washington, DC. U.S. Environmental Protection Agency (EPA). 1999. Free water surface wetlands for wastewater treatment: A tech¬ nology assessment. EPA 832/R-99/002. Office of Wa¬ ter, Washington, DC. Visher, S.S. 1954. Climatic atlas of the United States. Cam¬ bridge, MA: Harvard University Press. Vymazal, J. 1995. Algae and element cycling in wetlands. Boca Raton, FL: Lewis Publishers, 689 pp. Water Research Commission (South Africa). 2000. Con¬ structed wetlands: The answer to small scale wastewa¬ ter treatment in South Africa. WaterWorld. 1996. Product focus, June. Weller, M.W. 1978. Management of freshwater marshes for wildlife. In: R.E. Good, D.F. Whigham, and R.L. Simpson (eds.) Freshwater wetlands: Ecological processes and management potential. New York, NY: Academic Press, pp. 267-284. White, K.D. and C.M. Shirk. 1998. Performance and design recommendations for on-site wastewater treatment us¬ ing constructed wetlands. In: Proceedings of the Eighth National Symposium on Individual and Small Commu¬ nity Sewage Systems. American Society for Agricultural Engineers, Orlando, FL, pp. 195-201. Williams, C.R., R.D. Jones, and S.A. Wright. 1996. Mosquito control in a constructed wetland. In: Proceedings, WEFTEC ‘96, 69th Annual Conference and Exposition, Dallas, TX. Water Environment Federation, Alexandria, VA, October 1996, pp. 333-344. Wittgren, H.B. and T. Maehlum. 1996. Wastewater con¬ structed wetlands in cold climates. In: R. Haberl, R. Perfler, J. Laber, and P. Cooper (eds.) Water Science & Technology 35(5), Wetland systems for water pollution control 1996. Oxford, UK: Elsevier Science Ltd., pp. 45- 53. Wolverton, B.C. 1987. Aquatic plants for wastewater treat¬ ment: An overview. In: K.R. Reddy and W.H. Smith (eds.) Aquatic plants for water treatment and resource recov¬ ery. Orlando, FL: Magnolia Publishing, pp. 3-15. Worrall, P, K.J. Peberdy, and M.C. Millett. 1996. Constructed wetlands and nature conservation. In: R. Haberl, R. Perfler, J. Laber, and P. Cooper (eds.) Water Science & Technology 35(5), Wetland systems for water pollution control 1996. Oxford, UK: Elsevier Science Ltd., pp. 205- 213. Zirschky, J. and S.C. Reed. 1988. The use of duckweed for wastewater treatment. Journal of the Water Pollution Control Foundation, 60:1253-1258. 29 Chapter 3 Removal Mechanisms and Modeling Performance of Constructed Wetlands 3.1 Introduction Constructed wetlands are highly complex systems that separate and transform contaminants by physical, chemi¬ cal, and biological mechanisms that may occur simulta¬ neously or sequentially as the wastewater flows through the system. In a qualitative sense, the processes that oc¬ cur are known, but in only a few cases have they been adequately measured to provide a more quantitative as¬ sessment. The predominant mechanisms and their se¬ quence of reaction are dependent on the external input parameters to the system, the internal interactions, and the characteristics of the wetland. The external input pa¬ rameters most often of concern include the wastewater quality and quantity and the system hydrological cycle. Typical characteristics of municipal wastewaters most often treated in constructed wetlands are described in Table 3-1. The emphasis of this manual is on the treatment of municipal wastewater with the objectives of achieving tar¬ get levels of suspended solids, organic matter, pathogens, and in some instances, nutrients (specifically total nitro¬ gen) and heavy metals. Wastewaters that will be consid¬ ered include septic tank effluent, primary effluent, pond effluents, and some secondary effluents from overloaded or poorly controlled systems. Table 3-1 shows that the char¬ acter of the wastewater is dependent on pretreatment and Table 3-1. Typical Constructed Wetland Influents Constituent (mg/L) Septic Tank Effluent 1 Primary Effluent 2 Pond Effluent 3 BOD 129-147 40-200 11-35 Sol. BOD 100-118 35-160 7-17 COD 310-344 90-400 60-100 TSS 44-54 55-230 20-80 VSS 32-39 45-180 25-65 TN 41-49 20-85 8-22 nh 3 28-34 15-40 0.6-16 no 3 0-0.9 0 0.1-0.8 TP 12-14 4-15 3-4 OrthoP 10-12 3-10 2-3 Fecal coli (log/100ml) 5.4-6.0 5.0-7.0 0.8-5.6 'EPA (1978), 95% confidence interval. Prior to major detergent reformulations which reduce P species by -50%. 2 Adapted from Metcalf and Eddy, (1991) assuming typical removal by primary sedimentation-soluble BOD = 35 to 45% total. 3 EPA (1980). may contain both soluble and particulate fractions of or¬ ganic and inorganic constituents in reduced or oxidized forms. As will be seen later, these characteristics play an important role in the major mechanisms of removal. The two major mechanisms at work in most treatment systems are liquid/solid separations and constituent trans¬ formations. Separations typically include gravity separa¬ tion, filtration, absorption, adsorption, ion exchange, strip¬ ping, and leaching. Transformations may be chemical, in¬ cluding oxidation/reduction reactions, flocculation, acid/ base reactions, precipitation, or a host of biochemical re¬ actions occurring under aerobic, anoxic, or anaerobic con¬ ditions. Both separations and transformations may lead to contaminant removal in wetlands but often only result in the detention of the contaminant in the wetland for a pe¬ riod of time. There may be changes in the contaminant composition that will effectively achieve treatment objec¬ tives, such as the biochemical transformation of organic compounds to gases such as C0 2 or CH 4 . A biochemical transformation, however, may produce biomass or organic acids that may not achieve the treatment objective if these materials escape in the effluent. In the case of biomass, it may escape as volatile suspended solids, or it may un¬ dergo further bacterial reaction, which may result in the leaching of a soluble carbon compound back into the wa¬ ter column. The remainder of this chapter will review potential mecha¬ nisms that may be at work in constructed wetlands. These reactions may occur in the water column, on the surfaces of plants, within the litter and detritus accumulating at the wetland surface or on the bottom, or within the root zone of the system. The reactions unique to the wetland type will also be delineated. 3.2 Mechanisms of Suspended Solids Separations and Transformations 3.2.1 Description and Measurement Suspended solids in waters are defined by the method of analysis. Standard Methods (1998) defines total sus¬ pended solids as those solids retained on a standard glass fiber filter that typically has a nominal pore size of 1.2pm. The type of filter holder, the pore size, porosity, area and thickness of the filter, and the amount of material depos- 30 ited on the filter are the principal factors affecting the sepa¬ ration of suspended from dissolved solids. As a result, the measurement reported for total suspended solids may in¬ clude particle sizes ranging from greater than 100|im to about 1 pm. Soluble (dissolved) solids would therefore include col¬ loidal solids smaller than 1 pm and molecules in true solu¬ tion. A classical method of solids classification by size would include the following: Settleable Solids >100pm Supracolloidal Solids 1 -100pm Colloidal Solids 10-3-1 pm Soluble Solids <10-3pm Solids are also classified as volatile or fixed, again based on the method of analysis. Standard Methods (1998) de¬ fines a volatile solid as one that ignites at 550°C. Although the method is intended to distinguish between organic sol¬ ids and inorganic solids, it is not precise since volatile solids will include losses due to the decomposition or volatilization of some mineral salts depending on the time of exposure to the ignition temperature. Wastewater influents to wetlands may contain significant quantities of suspended solids (Table 3-1). The composition of these solids is quite different, however. Septic tank and primary effluents will normally contain neutral density colloi¬ dal and supracolloidal solids emanating from food wastes, fecal materials, and paper products. Pond effluent suspended solids are likely to be predominantly algal cells. All three will be high in organic content. Size distribution is also different among the waste streams. Tables 3-2 and 3-3 present infor¬ mation on size distributions of suspended solids, organic matter, and phosphorus in domestic wastewaters with vari¬ ous levels of pretreatment. It should be noted that methods differed between investigators on estimating size ranges. High settleable fractions are not surprising for raw wastewa¬ ter samples or for the pond effluent containing algal cells. It is important to note the association of organic matter and phosphorus with the various solid fractions. Table 3-2. Size Distributions for Solids in Municipal Wastewater Type of Sample (% by Weight) Size Range (fxm) Primary Eff. 1 Primary Eft. 2 Primary Eff. 3 Raw Sewage 4 Raw Sewage 5 <10 3 _ _ _ 31 48 10 3 -1.0 20 22(10-30) - 14 9 1.0-12 54 35(24-51) - - - >12 26 43(30-60) - - - 1.0-100 - - 81 24 18 >100 - - 19 31 23 ' Levine et al. (1984). 2 Tchobanoglous et al. (1983). 3 Gearheart, etal. (1993). 4 Heukelekian and Balmat (1959). 5 Rickert and Hunter ((1972). Table 3-3. Size Distribution for Organic and Phosphorus Solids in Municipal Wastewater Type of Solids (% by Weight) Size Range (nm) Organic Solids' (primary effluent) Organic Solids 2 (primary effluent) Organic Solids 2 (primary effluent) Organic Solids 2 (primary effluent) Organic Solids 2 (primary effluent) Organic Solids 3 (raw sewage) Total Phos. 4 (primary effluent) Total Phos. 4 (primary effluent) <10 3 9 _ _ _ _ 42 _ _ <0.1 - 51 50 25 35 - 17.2 15.7 10-M.0 ? - - - - 11 - - 0.1-1.0 - 8 19 2 1 - 54.6 67.0 1.0-12 - 34 26 13 13 - 7.1 5 6 T >12 - 7 5 60 41 - 21.0® 8.5" 1.0-100 15 - - - - 20 - - >100 28 - - - - 27 - - ' Munch et al. (1980). 2 Levine et al. (1991). 3 Rickert and Hunter (1972). “Levine et al. (1984). 5 Range: 1-5 /urn 6 Range: >5 //m 31 3.2.2 Suspended Solids in Free Water Surface Wetlands Total suspended solids are both removed and produced by natural wetland processes. The predominant physical mechanisms for suspended solids removal are flocculation/ sedimentation and filtration/interception, whereas suspended solids production within the wetland may occur due to death of invertebrates, fragmentation of detritus from plants, pro¬ duction of plankton and microbes within the water column or attached to plant surfaces, and formation of chemical pre¬ cipitates such as iron sulfide. Figure 3-1 illustrates the most important of these processes as they occur in a FWS sys¬ tem. Resuspension of solids may occur due primarily to tur¬ bulence created by animals, high inflows, or winds. A brief discussion of some of these processes and how they may affect free water surface systems follows. 3.2.2.1 Discrete and Flocculant Settling Typically, particulate settling produced by gravity may be categorized as discrete or flocculant settling. Both sepa¬ ration processes exploit the properties of particle size, spe¬ cific gravity, shape, and fluid specific gravity and viscosity. Discrete settling implies that the particle settles indepen¬ dently and is not influenced by other particles or changes in particle size or density. A mathematical expression for the terminal settling velocity of the discrete particle may be derived from Newton’s Law. Under laminar flow condi¬ tions, which exist in fully vegetated zones of a FWS and in VSBs, the velocity of a spherical particle can be estimated by Stokes’ Law, which states that the settling velocity is directly proportional to the square of the nominal diameter and the difference in particle and fluid densities and is in¬ versely proportional to fluid viscosity. Drag on the particle that influences settling velocity is affected by particle shape, fluid/particle turbulence, and fluid viscosity. Whereas discrete settling can be estimated given the independent variables discussed previously, flocculant settling cannot be so easily determined, requiring experi¬ mental measurement. It occurs as the result of particle growth and, perhaps, change in characteristics overtime. As a result, particle settling velocity typically increases with time. Flocculent settling is promoted by the relative move¬ ment of target particles in such a fashion as to cause an effective collision. This relative velocity (velocity gradient) is often calculated as G, the mean velocity gradient, which is a function of power input, dynamic viscosity, and system volume (Camp and Stein, 1943). Effective velocity gradi- Duckweed, Floating Litter & Detritus Settled TSS & Detritus from Plants Dissolved Oxygen «0 (Anoxic) Fully Vegetated Zone Removals due to Flocculation, Sedimentation, Adsorption and Anaerobic Reactions, Primarily Atmospheric Reaeration -WAr BOD Oxidation NH 4 -N-^N0 3 -N Solar Radiation Submerged Vegetation Dissolved Oxygen +++(Aerobic) Open Water Zone Transformations by Aerobic Biological Treatment, Primarily Pathogen Kill by Sunlight & Time Figure 3-1. Mechanisms that dominate FWS systems 32 ents for flocculation range from 10 to 75 sec- 1 . Floccula¬ tion may occur naturally, as when fresh water flows into saline water forming a delta, or it may require chemical (coagulant) addition. It may affect large particles (100pm to 1000pm) of low to moderate specific gravity (1.001 to 1.01) and small particles (1.0pm to 10pm) with high spe¬ cific gravity (1.5 to 2.5). The formation of larger flocculant particles is dependent on the electric charge on the par¬ ticle surface. Like electrical charges on the double layer surrounding particles may produce particle stability that hinders attachment even if collisions take place. This charge is sensitive to the composition of the fluid. Adsorp¬ tion of solutes to the surface occurs as a result of a variety of binding mechanisms, which may eventually result in the destabilization of the particles and result in particle adhe¬ sion. There has been little work done on the evaluation of natural flocculation phenomena with primary effluent or algal cells. The existence of emergent plant stems in FWS wetlands will promote effective velocity gradients for par¬ ticle collisions, but the adhesion of these particles would be dependent on surface properties that would be influ¬ enced by water column quality. In wetland systems treating primary or septic tank efflu¬ ents (or secondary effluents), particle sizes are mostly in the colloidal to low supracolloidal range (Table 3-2). Typi¬ cally sedimentation processes will remove material larger than about 50pm with specific gravity of about 1.20. The remaining particles are normally the lower density materi¬ als. Using Stokes’ Law to approximate discrete settling velocity, particles ranging from 1.0pm to 10pm with a spe¬ cific gravity ranging from 1.01 to 1.10 will settle at a rate of from 0.3 to 4 x 10~ 4 m/d. Typical hydraulic loads to FWS wetlands are in the range of 0.01 to 0.5 m/d (note that the hydraulic load is equivalent to the mean settling velocity of a particle that will be removed exactly at that loading). As¬ suming the higher settling velocity of 0.3 m/d and a typical FWS system velocity of 50 m/d and depth of 0.8m, the larger particles would settle by gravity in approximately 2.7 days, or 133 m along the wetland longitudinal axis. The smaller, less dense particles would require over 200 days and a length of over 11,000 m. Therefore it can be concluded that the larger, denser particles could be re¬ moved in the primary zone of a wetland based on simple discrete settling theory (see Chapter 4 for more details on design). The smaller, neutral-density particles, which make up a significant fraction of septic tank and primary effluent, are not likely removed in this primary zone by simple dis¬ crete sedimentation, but may be flocculated due to the velocity gradients imposed by emergent plant stems in the water column. It is also possible that some particles may be intercepted by angular emergent plant tissue as would occur in settling basins equipped with plate or tube set¬ tlers. Clearly, removal of TSS by a FWS wetland is more complex than predicted by discrete settling theory. There is currently insufficient transect data available on waste- water influents of interest to develop a rational separation model, either qualitatively or quantitatively, for TSS removal from primary or septic tank effluents in FWS systems. For wetland systems receiving pond effluents, the pri¬ mary source of suspended solids for much of the season is algal cells. These cells include green algae, pigmented flagellates, blue-greens, and diatoms. Sizes range from Ip to lOOiim, and shapes may range from coccoid to fila¬ mentous. Specific gravity of actively growing algal cells may be close to that of water insofar as they must remain suspended high up within the water column in order to survive. Flotation may be accomplished by gas vacuoles (blue-green algae), gelatinous sheathes, or shapes that increase particle drag. It is believed that wind-induced tur¬ bulence and vertical water motion greatly influence algae distribution in ponds (Bella, 1970). Motile algae are not typically predominant in wastewater pond systems. Once algal cells die for lack of nutrients and/or sunlight, they lose this flotation characteristic and will settle. Settling ve¬ locities range from 0.0 to 1.0 m/s (typically, 0.1 to 0.3 m/s) depending on species and physiological condition (Hutchinson, 1967). It is likely that many of these cells will be removed by sedimentation in wetlands covered by emergent vegetation providing shading and reducing wind action. Flocculation of the cells within the wetland is also possible although little experimental evidence has been presented to date. Table 3-4 was generated by Gearheart and Finney (1996), and it represents the only known appli¬ cation of the particle-size theory to show that colloidal frac¬ tions are flocculated in FWS systems (see Chapter 4 for further explanation). Figure 3-2 illustrates the removal of TSS observed for a fully vegetated FWS wetland treating pond effluent. Attempts to settle algae from ponds in open settling basins have not been successful, however, likely due to the presence of light and wind action. 3.2.2.2 Filtration/Interception Filtration, in the usual sense of this unit process, is not likely to be significant in surface wetlands. Stems from emergent plants are too far apart to effect significant en¬ trapment of the particle sizes found in influent to these wetlands. Furthermore, plant litter and detritus at the sur¬ face and bottom of the wetland are high in void fraction such that filtration is not likely an important mechanism. On the other hand, interception and adhesion of particles on plant surfaces could be significant mechanisms for re¬ moval. The efficiency of particle collection would be de¬ pendent on particle size, velocity, and characteristics of the particle and the plant surfaces that are impacted. In wetlands, plant surfaces in the water column are coated with an active biofilm of periphyton. This biofilm can ad¬ sorb colloidal and supracolloidal particles as well as ab¬ sorb soluble molecules. Depending on the nature of the suspended solids, they may be metabolized and converted to soluble compounds, gases, and biomass or may physi¬ cally adhere to the biofilm surfaces to eventually be sloughed off into the surrounding water column. Similar reactions may occur in the surface detritus or at the surficial bottom sediment. To date, there have been no definitive studies reported on the importance of this mechanism in suspended solids removal in free surface wetlands. 3.2.2.3 Resuspension In FWS wetlands, velocity induced resuspension is mini¬ mal. Water velocities are too low to resuspend settled par- 33 Table 3-4. Fractional Distribution of Bod, COD, Turbidity, and SS in the Oxidation Pond Effluent and Effluent from Marsh Cell 5 (Gearheart and Finney, 1996) BOD COD Turbidity SS mg/I % mg/I % NTU % MG/L % Oxidation Pond Fraction Total 27.5 100 80 100 11.0 100 31.0 100 Settleable 3.7 13 5 6 2.5 23 5.8 19 Supracolloidal 13.7 50 23 29 5.3 48 25.2 81 Colloidal, soluble 10.1 37 52 65 3.2 29 “ “ Marsh Fraction Total 4.8 100 50 100 3.9 100 2.3 100 Settleable 0 0 0 0 0.6 15 0.3 13 Supracolloidal 1.2 24 4 8 1.6 42 2.0 87 Colloidal, soluble 3.6 76 46 92 1.7 43 - “ Figure 3-2. Weekly transect TSS concentration for Areata cell 8 pilot receiving oxidation pond effluent (EPA, 1999) tides from bottom sediments or from plant surfaces. Fur¬ thermore, fully vegetated wetlands provide excellent sta¬ bilization of sediments by virtue of sediment detritus and root mats. The reintroduction of settled solids in wetlands is most likely due to gas-lift in vegetated areas or bioturbation or wind-induced turbulence in open water ar¬ eas. Wetland sediments and microdetritus are typically near neutral buoyancy, flocculant, and easily disturbed. Bioturbation by fish, mammals, and birds can resuspend these materials and lead to increases in wetland suspended solids. The oxygen generated by algae and submerged plants, nitrogen oxides and nitrogen gas from denitrifica¬ tion, or methane formed in anaerobic process may cause flotation of particulates (Kadlec and Knight, 1996). As discussed previously, the generation of new biom¬ ass by primary production or through the metabolism of influent wastewater constituents will eventually result in the return of some suspended materials back into the wa¬ ter column. The magnitude of wetland particulate cycling is large, with high internal levels of gross sedimentation and resuspension, and almost always overshadows influ¬ ent TSS loading in natural or tertiary treatment wetlands. The effluent TSS from a wetland rarely results directly from nonremovable TSS in the influent wastewater and is often dictated by the wetland processes that generate TSS in the wetland. Typical background TSS concentrations ex¬ pected in FWS wetlands appear in Table 3-5. It should be noted that large expanses of open wetland prior to dis- 34 charge structures could result in unusually high effluent TSS concentrations due to the production of excessive amounts of algae and induced high levels of wildlife activi¬ ties that could produce effluent variations as typified in Fig¬ ure 3-3. High incoming TSS or organic loading will result in a measurable increase in bottom sediments near the inlet structure (Van Oostrom and Cooper, 1990; EPA, 1999). However, no FWS treatment wetland has yet required maintenance because of sediment accumulation, includ¬ ing some that have been in service for over 20 years. 3.2.3 Suspended Solids in Vegetated Submerged Beds One of the primary intermediate mechanisms in the re¬ moval of suspended solids by VSB systems is the floccu¬ lation and settling of colloidal and supracolloidal particu¬ lates. These systems are relatively effective in TSS removal because of the relatively low velocity and high surface area in the VSB media. VSBs act like horizontal gravel filters and thereby provide opportunities for TSS separations by gravity sedimentation (discrete and flocculant), straining and physical capture, and adsorption on biomass film at¬ tached to gravel and root systems. Clogging of the filter media has been of some concern especially with high TSS loading, but documentation of this phenomenon has not been forthcoming. The accumulation of recalcitrant or slowly degradable solids may eventually lead to increased headlosses near the influent end of the system. Design features to overcome this are described in Chapter 5. The importance of vegetation in VSB systems has been debated for some time. Several recent studies have com¬ pared pollutant removal performance of planted and unplanted VSB systems and have shown no significant dif¬ ference in performance (Liehr, 2000; Young et al., 2000). The importance of plant type has also been evaluated (Gersberg et al., 1986; Young et al., 2000). Maximum root length and growth rates have been reported. Although some investigators claimed that certain treatment goals are likely to benefit from certain plants, these claims have not been sustained by others (Young et al., 2000). The extension of root system within the gravel bed is dependent on system loading, plant type, climate, and wastewater characteristics, among other variables. It appears that a dominant fraction of the flow passes below the root system in VSB facilities. The role of root surfaces in TSS removal has not been proven experimentally. The contributions of internal biological processes to ef¬ fluent TSS is likely similar to that found in FWS systems, although algal contributions should be negligible. Resuspension of separated solids is not likely since sys¬ tem velocities are low and scouring should not be signifi¬ cant. Furthermore, bioturbation in these systems should be minimal. Background concentrations for VSB systems have not yet been definitively documented with reliable information. 3.3 Mechanisms for Organic Matter Separations and Transformations 3.3.1 Description and Measurement Organic matter in wastewater has been measured in a number of ways over the years. Because the organic frac¬ tion in wastewater is often complex and the concentra¬ tions of the individual components relatively low, analyses Table 3-5. Background Concentrations of Contaminants of Concern in FWS Wetland Treatment System Effluents Constituent Range (mg/L) Typical (mg/L) Factors Governing Value Reference TSS 2-5 3 Plant types, coverage, Climate, wildlife Reed et al.,1995; Kadlec and Knight, 1996 BOD 5 ’ 2-8 5 Plant types, coverage, Climate, plant density Reed et al., 1995 Gearheart, 1992 BOD 5 2 5-12 10 Plant types, coverage, Climate, plant density Kadlec and Knight, 1996 TN 1-3 2 Plant types, coverage, Climate, oxic/anoxic Kadlec and Knight, 1996; Reed et al., 1995 NH -N 4 0.2-1.5 1.0 Plant types, coverage, Climate, oxic/anoxic Kadlec and Knight, 1996; Reed et al., 1995 TP 0.1-0.5 0.3 Plant types, coverage, Climate, soil type Kadlec and Knight, 1996; Reed et al., 1995 Fecal Coli CFU/100 ml 50-5,000 200 Plant types, coverage, Climate, wildlife Watson et al, 1987; Gearheart et al., 1989 'Wetland system with significant open water and submergent vegetation 2 Wetland system fully covered by emergent vegetation 35 O) E o o CD ** c 3 Q. o Date Figure 3-8. Phosphorus pulsing in pilot cells in Areata; Marsh 1 received tap water until June 1982 (no phosphorus load), while Marsh 3 received oxidation pond effluent (Gearheart, 1993) 48 It is significant to note that indicator organisms and per¬ haps pathogens may be generated within the wetland. Thus background levels of indicators will be found even in natu¬ ral wetland systems (see Table 3-5). These background levels are variable, influenced by season and other opera¬ tional parameters of the system (Figure 3-9). It should be noted that in general these indicator organisms are not from human sources. However, constructed wetlands are unlikely to consistently meet stringent effluent fecal coliform permit levels. Therefore, regulators may require disinfec¬ tion of treatment wetland effluents prior to discharge. Gearheart (1998) consistently attained an FC count of less than 2/100 mL with UV disinfection of FWS effluent. 3.7 Mechanisms of Other Contaminant Separations and Transformations 3.7.1 Metals While some metals are required for plant and animal growth in trace quantities (barium, beryllium, boron, chro¬ mium, cobalt, copper, iodine, iron, magnesium, manga¬ nese, molybdenum, nickel, selenium, sulfur, and zinc), these same metals may be toxic at higher concentrations. Other metals have no known biological role and may be toxic at even very low concentrations (e.g., arsenic, cad¬ mium, lead, mercury, and silver) (Gersberg et al., 1984; Crites et al., 1997). Influent wastewater to wetlands may carry metals as soluble or insoluble species. Metals entering wetlands as insoluble suspended solids are separated from the water column in a manner similar to TSS. Depending on pH and redox potential, these in¬ soluble species may be resolubilized and returned to the liquid phase. Important removal mechanisms for metals include cation exchange and chelation with wetland soils and sediments, binding with humic materials, precipitation as insoluble salts of sulfides, carbonates, and oxyhydroxides, and uptake by plants, algae, and bacteria. The chemically bound metals may eventually become bur¬ ied in the anoxic sediments where sulfides occur. These bound metals are often not bio-available and remain re¬ moved from the system. If sediments are disturbed or re¬ suspended and moved to oxic regions of the wetland, se¬ questered metals may resolubilize. Metals may be incorporated into the wetland biomass by way of the primary production process. For macro¬ phytes, metals are taken up through the root system and distributed through the plant. The extent of uptake is de¬ pendent on the metal species and plant type. Gersberg et al. (1984), found only minor uptake by plants in VSB sys¬ tems, while others claim that metals can be found on root surfaces due to precipitation and adsorption. The accu¬ mulation of heavy metals was found to be variable in a marsh in New Jersey receiving wastewater (Simpson et al., 1981; 1983). Cadmium, copper, lead, nickel, and zinc had accumulated in the litter at the end of the growing sea¬ son in much higher concentrations than in the live vegeta¬ tion. Other studies have shown that metals like cadmium, chromium, copper, lead, mercury, nickel, and zinc can be sequestered by wetland soils and biota or both (Mitsch and Gosselink, 1993). The high uptake of selenium by biota in a wetland marsh receiving irrigation waters was dis¬ cussed in Hammer (1992), but some could have been vola¬ tilized. Studies have shown that some algae will seques¬ ter selected metals (Kadlec and Knight, 1996). Floating plants such as duckweed have been shown to be excel¬ lent accumulators of cadmium, copper, and selenium, but only moderate accumulators for chromium and poor accu¬ mulators for nickel and lead (Zayed et al., 1998). A review of metal removal in wetlands is found in Kadlec and Knight (1996). ^ 10,000 o o 3 30 - £ 20 10 - ♦ V V ♦ o ❖ o oo V ♦ V 0 V o V o O V T 50 o V o V o V = Fully Vegetated O = Significant Open Area - 1 - 1 — 100 150 TSS Load (kg/ha-day) Figure 4-4. TSS loading vs. TSS in effluent (DMDB) 200 58 Subsequently, the removal essentially ceases without sub¬ sequent open zones which can provide conditioning and transformation processes which may improve overall re¬ moval of TSS attainable by the system. A closer analysis of the DMDB again shows that TSS loadings can be higher for FWS systems with open-water zones. Only one very small site with such zones exceeded secondary effluent TSS standards (30 mg/L), and it was loaded at more than 90 kg/ha-d. Below a loading of 30 kg/ ha-d an effluent of 20 mg/L of TSS was consistently achiev¬ able. It is therefore recommended that in addition to that areal loading limitation a maximum loading of 50 kg/ha-d be employed to attain an effluent of 30 mg/L of TSS until more performance data can be obtained. 4.1.5 Nitrogen Performance Any discussion of nitrogen species in FWS constructed wetlands must be predicated by a return to first principles, as described in Chapter 3. Given the numerous transfor¬ mation possibilities and the dearth of removal mechanisms, there are only a few meaningful explanations. Influent ni¬ trogen for the typical applications of this manual will be primarily in the form of ammonia-nitrogen (NFI4-N) with a significant organic nitrogen (ON) contribution. Approxi¬ mately 10 to 15% of the oxidation pond effluent TSS due to algae is organic nitrogen (Balmer and Vik, 1978). Since both are measured by the total Kjeldahl nitrogen (TKN) test, it becomes the likely standard of areal loading analy¬ sis. Any discussion of just one species (typically, NH4-N) is of little value and often misleading to readers. Another key discussion point is the inherent inability of fully vegetated FWS systems to nitrify a typical FWS influ¬ ent, as described in the preceding paragraph, within a prac¬ tical number of days of HRT. During periods of senescence when fully vegetated zones become partially open-water zones, different mechanisms of treatment can replace these which dominate during the normal growing season, if the climate can sustain them. This is further reinforce¬ ment for the fact that there are few absolutes in natural systems. Sadly, these conditions are rarely recognized or adequately described and measured, making use of most existing data sets open to some question. However, in this analysis the fact that a system is classified as either fully vegetated or as having significent open-water zones aids in explaining many anomolies. 4.1.5.1 TKN Performance Figure 4-5 illustrates that for a fully vegetated FWS which receives 30 to 50 mg/L of TKN the effluent exceeds 24 mg/L since the only removal mechanism is sedimentation 35 CT> E z * c 4 ) 3 LU 30 - 25 - 20 - 15 10 - 5 - ♦ V ♦ v ♦ v « v ♦ v ❖ V ❖ V ♦ ♦♦ ooo T 5 T 10 T 15 V = Fully Vegetated O = Significant Open Area 20 25 TKN Load (kg/ha-day) Figure 4-5. Effluent TKN vs. TKN loading 59 of organic nitrogen (ON). One more lightly loaded (3.3 kg/ ha-d) fully vegetated system did produce an effluent TKN of about 9 mg/L. The three open-water zone systems were all lightly loaded (< 2.8 kg/ha-d) and produced effluent TKN of about 4 mg/L. Since these latter designs offer a mecha¬ nism to transform the TKN to nitrate-nitrogen (N03 -N), which could subsequently be removed through denitrifica¬ tion, they could conceivably be loaded more heavily and still meet a stringent total nitrogen standard (e.g., 10 mg/ L). No more heavily loaded systems were indicated in the DMDB. The TADB analysis (EPA, 1999) did indicate that any FWS system which received a TKN loading of less than 3.3 kg/ha-d could meet an effluent TKN of less than 10 mg/L, but does not subdivide results into the two subcatagories used herein. Arcata’s open-water-zone sys¬ tems have been able to maintain effluent total nitrogen (TN) below 5 mg/L at loadings of up to 3 kg TN/ha-d (Gearheart, 1995) through the denitrification provided near the FWS system outlet which is fully vegetated. Maximum TKN load¬ ings to sustain an effluent TKN of less than 10 mg/L can conservatively be set at 5 kg/ha-d until more data are made available. This only applies to open water FWS systems, while fully vegetated systems are limited to only a small percentage of TKN removal due to the settling of organic nitrogen particulate matter. 4.1.5.2 Denitrification The extent of nitrate removal via denitrification is de¬ pendent on the extent of the prior conversion of TKN to N03-N, a labile carbon or other energy source and anaero¬ bic/anoxic conditions in the water column. Therefore, deni¬ trification, which converts N03-N to gaseous end prod¬ ucts which can leave the constructed wetland, is best suited to a fully vegetated condition. Further, any N03-N which enters a FWS wetland is likely to be quickly removed, while any nitrate formation (nitrification), which occurs in the open-water zones of the FWS can be removed near the fully vegetated outlet zone if the conditions noted above are met. The DMDB offers no assistance in that all the systems which had nitrate-nitrogen in their influent had it at very low concentrations (average = 2.47 mg/L), even though effluent concentrations were lower (average = 2.22 mg/L). Gearheart (1995) reports that the carbon produced from decaying macrophytes is sufficient to denitrify 100 mg N03- N/L in an FWS and that the reaction rate is temperature dependent, signifying its biological nature. Reed, et al (1995) and Crites and Tchobanoglous (1998) also indicate that FWS systems have the capablility to denitrify, but they offer no specific examples. Therefore, denitrification should be feasible in FWS systems as long as there is sufficient detention time in fully vegetated zones with anaerobic/an¬ oxic conditions. 4.1.5.3 Ammonia Nitrogen Performance Also, as noted previously, ammonia-nitrogen (NH4-N) limits are often specified for treatment facilities in their NPDES permit. However, the level of effluent ammonia in an FWS constructed wetland effluent bears only a tenu¬ ous relationship to its influent NH4-N concentration. The normal case will find that all influent nitrogen is measured as TKN, and that this total will be divided between organic nitrogen and NH4-N. It is likely that this total nitrogen will be reduced in any FWS owing to the loss of organic nitro¬ gen due to enhanced settling. In the DMDB the average TKN removal was 32%, while the fully vegetated systems reported 28%. This difference is not larger because the open-water FWS systems were few in number and were all loaded more lightly. Although one can plot the effluent NH4-N vs NH4-N loading from the DMDB, the data dem¬ onstrate no useful relationship. Therefore, unless a FWS is designed for very low TKN loadings with an ample open- water zone to nitrify the influent, there is no meaningful chance to meet any NH4-N effluent standard which is sig¬ nificantly lower (>30%) than the influent concentration. 4.1.5.4 Other Nitrogen Performance Since total nitrogen is the sum of all forms of nitrogen, it will be reduced through nitrification/denitrification, the loss of organic nitrogen due to flocculation and sedimentation and plant uptake of NH4-N. Since some of this settled frac¬ tion will return to the mainstream as the settled organics partially digest and the plant uptake will return due to se¬ nescence, the total nitrogen budget should be evaluated on an annual basis. The returned nitrogen will likely be in the same two forms (organic and ammonia-nitrogen) as the normal influent TN load, making this internal load very compatible with the external load. Given the transformability of individual nitrogen components between each other based on the conditions existing at different locations in the FWS wetland, the designer needs to provide passive controls(e.g..depth and vegetation patterns) if he or she wishes to remove a substantial portion of the incoming ni¬ trogen load. 4.1.6 Total Phosphorus Performance Only 4 of the DMDB systems measured TP loadings and effluent quality, as shown in Figure 4-6. While some ap¬ proximate comparisons can be made, the need to sepa¬ rate the inorganic phosphorus performance from the or¬ ganic particulate phosphorus performance makes the lack of DM data impossible to utilize effectively, therefore, the TA database (EPA.1999) is used for an approximate analy¬ sis. Figure 4-7 shows that over a range of loading up to 4.5 kg/ha-day at the TADB sites, total phosphorus effluent con¬ centration generally increased with loading (USEPA, 1999). At the lower loading rates (<0.55 kg/ha-d), however, the effluent phosphorus concentration was less than 1.5 mg/ L. The fractional distribution of TP in municipal wastewa¬ ter previously treated by lagoons is variable and has not been well documented. Balmer and Vik (1978) found fil¬ tered P/total P to be 20-25%, but the flocculation and sedi¬ mentation superiority of the initial FWS fully vegetated zone will remove a significant % of those forms which enter as supracolloidal and settleable solids. Gearheart (1993) has performed extensive studies on the Areata FWS systems and found a relationship between areal loading and phos- 60 Effluent TP (mg/L) 4 3.5 - ❖ 2.5 - ♦ 2 - 1.5 - 1 - 0 0.5 1 1.5 2 2.5 3 TP Load (kg/ha*day) Figure 4-6. Effluent TP vs. TP areal loading Figure 4-7. Average total phosphorus loading rate vs. total phosphorus effluent concentration for TADB wetland systems 61 phorus removal. An upper limit of 1.5 mg/L removal of or¬ thophosphates was found at loadings of less than 1.5 kg/ ha-d and a hydraulic retention time (HRT) of at least 15 days. HRTs of less than 7 days yielded a maximum re¬ moval of 0.7 mg/L of orthophosphate, as shown in Figure 4-8. The phosphorus cycle of uptake during the growing sea¬ son and release during senescence and the initial sub¬ stantial uptake of phosphorous by the soil of the FWS fur¬ ther confounds short-time studies of phosphorus transfor¬ mations and removal. As a final issue in this conundrum, the particulate fractionation and chemical speciation of the influent phosphorus will also have some impact on trans¬ formations and fate of P. Therefore, long-term studies which differentiate between P forms and document vegetation condition, climate, temperature and other pertinent water quality parameters are necessary to provide meaningful information for future FWS system designers, but the an¬ nual P removal by these systems is quite limited based on mechanistic evaluations and controlled studies. 4.1.7 Fecal Coliform Performance Only four systems in the DMDB reported fecal coliform (FC) data, and three of those were fully vegetated sys¬ tems. The average removal was just over 2 logs, from 72,700/1 OOmL to 400/100ml. The TADB (EPA, 1999) re¬ sults are shown in Figure 4-9 which offers no obvious rela¬ tionship between inlet and outlet concentrations. Figure 4- 10 (Gearheart, 1989) shows results from the Areata pilot study which demonstrate that flocculation/sedimentation is the primary FC removal mechanism for fully vegetated cells or zones. This figure is especially valuable in light of the world literature on FC dieoff in lagoons which identify solar radiation as the primary disinfection mechanism (Mara, 1975). Such a mechanism can be effective in open- water zones of the FWS, but the same mechanisms which remove settleable and colloidal solids in fully vegetated zones are responsible for FC removal in those zones. Figure 4-8. Retention Time vs. Orthophosphate Removal (mg/I) Estimates of the internal addition of background fecal coliform by wildlife in treatment wetlands are provided by those systems that receive disinfected influent. For ex¬ ample, the Areata Enhancement Wetland received chlori¬ nated effluent, and during the period 1990-1997 (Gearheart,et al,1998), the effluent FC was less than 500 MPN/1 OOmL about 80% of the time. This is a system with large open-water zones that supports a wide variety and high population of aquatic birds and mammals. Higher lev¬ els of background FC levels are found during the fall and winter bird migration period. A similar study on the same system during 1995-1996 showed that the effluent mean was 40 CFU/IOOmL, was less than 300 CFU/IOOmL over 90 percent of the time, and on no occasion exceeded 500 CFU/1 OOmL. Studies of MS-2 coliphage showed similar (2 logs) removal to that which was obtained with FC (Gearheart, 1995). The considerable temporal variability in the effluent mi¬ croorganism counts produced by treatment wetlands and conventional treatment technologies suggests the use of geometric averaging to determine monthly mean values from daily or weekly measurements. Even with geometric means, individual monthly values are frequently 10 times larger or smaller than the long-term mean for many treat¬ ment wetlands, possibly due to wildlife habitat features. This implies that at sites which have strict FC restrictions, the ability to disinfect the FWS effluent is required. 4.1.8 Metals & Other Particulate-Oriented Pollutants While some metals are required for plant and animal growth in trace quantities (barium, boron, chromium, co¬ balt, copper, iodine, iron, magnesium, manganese, mo¬ lybdenum, nickel, selenium, sulfur, and zinc), these same metals may be toxic at higher concentrations. Other met¬ als may be toxic at even very low concentrations (e.g. ar¬ senic, cadmium, lead, mercury, and silver) (Gearheart, 1993). Information from FWS treatment wetlands indicates that a fraction of the incoming metal load will be trapped and effectively removed through sequestration with settleable suspended solids and soils. For many metals, the limited data indicate that concentration reduction efficiency and mass reduction efficiency correlate with TSS reduction. Wetland background metal concentrations and internal profiles are not well known. It has been shown that chro¬ mium levels higher than 0.1 mg/L and copper levels higher than 1.0 mg/L have detrimental effects on a floating duck¬ weed species (Lemna gibba). Table 4-2 shows metal con¬ centration data obtained from a constructed wetland dem¬ onstration project in Sacramento, where disinfected acti¬ vated sludge effluent was applied to parallel 1.44 acre cells, each with a hydraulic loading of 65 m3/ha-d and similar plant density. The valence and form of each metal was not determined, but nickel and arsenic appeared to be the most resistent to removal (SCRSD, 1998). Several researchers have stud- 62 ~ 10,000 1 o o 0) n E 3 C, o c 0 _3 5= LU 1,000 100 -= 1 10 100 1,000 10,000 100,000 1 , 000,000 Influent FC (number/100 mL) Figure 4-9. Average influent FC concentration vs. FC effluent concentration for TADB wetland systems 10 5 10 4 1,000 100 Figure 4-10. Areata pilot Cell 8, TSS, BOD, FC Table 4-2. Trace Metal Concentrations and Removal Rates, Sacramento Regional Wastewater Treatment Plant (SCRSD, 1998). Removal (%) Metal Influent (mg/L) Effluent (mg/L) Rate Min Mean Max Min Mean Max Silver 0.25 0.29 0.32 0.02 0.03 0.03 90 Arsenic 2.00 2.23 2.60 1.50 2.20 3.10 1.3 Cadmium 0.040 0.077 0.140 0.005 0.009 0.019 88 Chromium 0.50 1.05 1.40 0.50 0.77 3.10 27 Copper 4.60 8.62 17.00 1.60 4.04 7.00 19 Mercury 0.0084 0.0105 0.0144 0.0021 0.0031 0.0041 71 Nickel 4.30 8.23 23.00 4.10 8.96 20.00 — Lead 0.25 0.58 1.20 0.05 0.14 0.26 55 Antimony 0.40 0.41 0.42 0.12 0.15 0.20 63 Selenium 0.50 0.50 0.50 0.50 0.50 0.50 — Zinc 6.4 26.2 34.0 1.30 3.53 8.70 70 63 ied particle sizes vs removal rates. Most have concentrated on urban mechanical wastewater treatment systems. Odegaard (1987) noted that except for nickel 50 to 75% of the incoming metals (zinc, copper, chromium, lead, and cadmium) in the wastewater were associated with the TSS. Hannah, et al, (1986) showed that facultative lagoons re¬ moved 40 to 80% of metals, including nickel. The sum¬ mary of these and other studies is that most metals, with the exception of nickel, boron, selenium, and arsenic, tend to associate with removable solids fractions. Gearheart and Finney (1996) evaluated particle size removals of oxida¬ tion pond effluent in a FWS wetland (see Table 4-3). Their results show that the settleable solids (> 100 &m) portion of BOD, COD and TSS are essentially completely removed, the supracolloidal 1 to 100 &m) fraction is 80 to 90% re¬ moved, while the remaining (<1&m) fractions are less im¬ pacted. 4.1.9 Stochastic Variability Free water surface (FWS) treatment wetlands demon¬ strate the same type of water quality variability typical of other complex biological treatment processes. While inlet concentration pulses are frequently dampened through the long hydraulic and solids retention times of the treatment wetland, there is always significant spatial and temporal variability in wetland water pollutant concentrations. The stochastic character of rainfall and the periodicity and sea¬ sonal fluctuation in ET contribute to much of this variability in the concentrations in wetland effluents. Better design and operational factors could reduce some of the variation seen in systems to date. Each site and its unique climatol¬ ogy require the designer to consider the effect these vari¬ ables will have on the sizing, depth, and configuration of the system. 4.2 Wetland Hydrology The hydrology of FWS wetlands is considered by many to be the most important factor in maintaining wetland struc¬ ture and function, determining species composition, and Table 4-3. Fractional Distribution of BOD, COD and TSS in the Oxidation Pond Effluent and Effluent from Marsh Cell 5 (Gearheart and Finney, 1996) BOD COD TSS mg/L % mg/L % mg/L % Oxidation Pond Fraction Total 27.5 100 80 100 31.0 100 Settleable 3.7 13 5 6 5.8 19 Supracolloidal 13.7 50 23 29 25.2 81 Colloidal-soluble 10.1 37 52 65 — — Marsh Fraction Total 4.8 100 50 100 2.3 100 Settleable 0 0 0 0 0.3 13 Supracolloidal 1.2 24 4 8 2.0 87 Colloidal-soluble 3.6 76 46 92 — — developing a successful wetlands project (Mitsch and Gosselink, 1993). The following section describes the most common method for characterizing wetland hydrology: the development of a wetland water balance. 4.2.1 Wetland Water Balance The wetland water balance quantifies the hydrologic balance between inflows, outflows, and internal gains and losses of water to a wetland, in relation to the wetland vol¬ ume or storage capacity. The sources of water to a FWS constructed wetland are wastewater inflow and precipita¬ tion, snowmelt and direct runoff from the wetland catch¬ ment (i.e. berms and roads). Water losses from a FWS constructed wetland occur through the outlet, evapotrans- piration, infiltration, and bank storage (wicking). A thorough understanding of the dynamic nature of the wetland water balance, and how this balance affects pollutants, is useful in the planning and design of FWS constructed wetlands. An overall wetland water balance is the first step in de¬ signing a FWS constructed wetland, and should be com¬ pleted prior to the actual design steps described later in this chapter. At a minimum, a detailed monthly or seasonal water balance, which considers all potential water losses and gains, should be conducted for any proposed FWS constructed wetland. An annual water balance may miss important seasonal wetland water gains or losses, such as heavy periods of winter precipitation or high summer evapotranspiration rates, which can affect FWS constructed wetland pollutant effluent concentrations. Water balances performed over shorter time periods than monthly will cap¬ ture additional information about the dynamics of a wet¬ lands hydrology, but the increased cost of data acquisition will not generally be justified. The wetland water balance for a FWS constructed wet¬ land can be expressed in generic units (L=length; T=time) as: ——— = Q 0 + Q f + Q sm -Q b - Q e + (P+ET+I)A W (4-1) dt where: A w = wetland water surface area (L 2 ), ET = evapotranspiration rate (L/T), I = infiltration to groundwater (L/T), P = precipitation rate (L/T), Q b = berm loss rate (L 3 /T), Q c = catchment runoff rate (L 3 /T), Q o = wastewater inflow rate (L 3 /T), Q e = wetland outflow rate (L 3 /T), Q sm = snowmelt rate (L 3 /T), t = time (T), and V w = water volume or storage in wetland (L 3 ). The impact of wet weather and snowmelt on the waste- water inflow (Q o ) is external to the water balance. Some of the terms in Equation 4-1 may be deemed in¬ significant and can be neglected, simplifying calculations and data collection requirements. For example, ground- 64 water infiltration (I) and berm losses (Q b ) can be neglected if the wetland is lined with an impermeable barrier, and the snowmelt (Q sm ) is only important in certain locations. 4.2.2 Wastewater Inflow The daily wastewater inflow flow rate (Q o ) will almost always be the primary inflow into a FWS constructed wet¬ land. If the FWS wetland is being added to an existing wastewater treatment process, wastewater flow rates may already be measured. If the wastewater flow rates and variability are not known, they can be estimated using con¬ ventional engineering methods. Examples of variable wastewater flows include seasonal peaks from vacation communities and seasonal high infiltration and inflow rates into collection systems. 4.2.3 Precipitation, Snowmelt, and Catchment Runoff Depending on the time period of the water balance, daily, monthly or seasonal precipitation and snowmelt data may be required. Precipitation inflows into a wetland come from direct precipitation (P) onto the wetland surface area and runoff from the wetland catchment (Q c ). Snowmelt (Q )accounts for the amount of water entering the wet- lana from melting snow from the wetland catchment. The effects of precipitation on the wetland water balance are normally significant, while snowmelt can be seasonably significant only in certain climates. Q c is a significant factor only in the rarest of circumstances. c 4.2.4 Wastewater Outflow The wastewater outflow (Q e ) corresponds to the amount of treated wastewater leaving the FWS constructed wet¬ land over a specified time period. Wastewater outflow re¬ flects the balance between inflows, additional water gains and losses, and the change in storage of the FWS con¬ structed wetland. 4.2.5 E vapotranspiration Wetland evapotranspiration (ET) is the combined water loss due to evaporation from the water surface and tran¬ spiration from wetland vegetation. The loss of water from ET affects the wetland in two ways. It increases the hy¬ draulic retention time by removing water, and can concen¬ trate certain pollutants, especially conservative dissolved constituents. For non-conservative constituents, such as BOD, an increase in the hydraulic retention time may pro¬ vide a modified removal rate which can either partially off¬ set or enhance the concentrating effects of ET. Specific ET rates have proven difficult to accurately measure in FWS wetlands. As a consequence, it is com¬ mon practice in wetland design to assume that wetland ET rates are equivalent to some percentage of open water or pan evaporation rates. Kadlec and Knight (1996) rec¬ ommend that ET be assumed equal to 70 to 80% of Class A pan evaporation in fully vegetated FWS systems. Reed, et al, (1995) suggest 80% of the pan rate. Since ET rates in FWS systems may vary from those in open waters to those in fully vegetated zones, an overall average rate may be useful. A rate of 70 to 75% of the pan rate is a reason¬ able assumption since the two are not significantly differ¬ ent. Maximum ET rates have been found in smaller wet¬ lands or wetland test cells with small area to perimeter ratios (Gearheart, et al, 1993). ET rates of up to 5 mm/d are found in the southern U.S., and Qe may approach zero during these periods (EPA, 1999). 4.2.6 Infiltration and Berm Losses Infiltration (I) is the loss of water that occurs into the bot¬ tom soils or berms of a FWS constructed wetland. If present, infiltration decreases the outlet flow rate, effec¬ tively increasing the water retention time and increasing the potential for constituent removal. Constituent reduc¬ tion may be further improved by the loss of soluble pollut¬ ants into the soil as the water infiltrates. Infiltration tends to reduce with time as clogging of soil pores progresses (Middlebrooks, et al, 1982). If the FWS constructed wet¬ land is lined with some type of impermeable barrier, infil¬ tration can be neglected in the water balance. If not, siting on more permeable soils might endanger ground water quality. 4.2.7 Wetland Volume The outlet in a FWS constructed wetland generally con¬ sists of a control structure that can regulate water depths in the wetland. Increasing or decreasing water levels changes the wetland volume, which influences the water balance by providing more or less storage capacity. The wetland volume (V w ) or storage capacity directly influences the time required for the wastewater to pass through the wetland. Water storage capacity can be increased to off¬ set the effects of high seasonal precipitation or evapotrans¬ piration. Since FWS constructed wetlands have a continu¬ ous wastewater inflow and some form of outlet water level control, water surface elevations do not change signifi¬ cantly, unless the wetland operation and maintenance schedule dictates water level fluctuations. The type of emergent aquatic plants in each region of an FWS is pri¬ marily determined by the depth of the FWS in that zone. For the most part 1.2m (4 feet) is considered the maxi¬ mum seasonal water depth for fully vegetated sections of the wetland. Normal operating depths vary from 0.5 to 0.75m ( 1.7 to 2.5 feet) depending on the types of plants and types of physical substrate. 4.3 Wetland Hydraulics From a design perspective, wetland hydraulics defines the movement of water through a FWS constructed wet¬ land. A FWS constructed wetland with poor hydraulic de¬ sign can be problematic in terms of effluent water quality, odors, and vector nuisances. This section first defines some basic wetland hydraulics terms, and then briefly summa¬ rizes basic wetland hydraulic principles. 65 4.3.1 Wetland Hydraulics Terminology and Definitions 4.3.1.1 Water Depth Water depth is an important physical measure for the design, analysis, and operation and maintenance of FWS constructed wetlands. The ability to vary water depth in a FWS constructed wetland is one operational control avail¬ able to operators to manipulate wetland performance. The actual water depth at all locations in a FWS con¬ structed wetland will generally not be known with a high degree of accuracy due to basin bottom irregularities. In addition, the water depth in the wetland may decrease due to the buildup of peat from the deposition of detritus and settled solids buildup. Increasing the water depth by chang¬ ing the outlet weir elevation can help offset decreases in water depth. This slow-rate change progresses with time from the inlet toward the outlet. Detrital plant material builds up on and under the water surface of any vegetated zone, especially the initial vegetated zone. Wetlands operating for 15 years have documented a 0.08 -0.12m (3 to 5 inch) depth change due to plant detritus along the initial veg¬ etated zone in an FWS wetland. The largest accumulation was in the inlet region (Kadlecik, 1996). Estimated operating water depths for FWS constructed wetlands in the NADB (1993) have ranged from approxi¬ mately 0.1 to over 2.0m (0.3 to 6+ feet) with typical depths of 0.15 - 0.60m (0.5 to 2 feet). Operating depths are gen¬ erally different for the area with emergent plants (0.6 m) than those areas with submergent plants (1.2m). Since most of the NADB systems were designed to be fully veg¬ etated, these depths are less than one would expect in the future. For some calculations the average water depth (h) can be used, as it represents the average water depth over the total wetland surface area (A w ). 4.3.1.2 Volume The volume (Vw) of a FWS constructed wetland is the potential quantity of water (neglecting vegetation, litter and peat) that could be stored in the wetland basin. The wet¬ land water volume can be determined by multiplying aver¬ age water depth (h) by area (AJ: V w = (AJ(h) (4-2) 4.3.1.3 Wetland Porosity or Void Fraction In a FWS wetland, the vegetation, settled solids, litter and peat occupy a portion of the water column, thereby reducing the space available for water. The porosity of a wetland (e), or void fraction, is the fraction of the total vol¬ ume available through which water can flow. Wetland po¬ rosity has proven difficult to accurately measure in the field. As a result, wetland porosity values listed in the literature are highly variable. For example, Reed, et al (1995) and Crites and Tchobanoglous (1996) suggest wetland poros¬ ity values ranging from 0.65 to 0.75 for fully vegetated wetlands, for dense to less-mature wetlands, respectively. Kadlec and Knight (1996) report that average wetland po¬ rosity values are usually greater than 0.95, and e = 1.0 can be used as a good approximation. Gearheart (1997) found porosity values in the range of 0.75 in dense mature portions of the Areata wetland. For hydrological design, an average porosity value should be used which is based on the areal percent of open water zones (non-emergent veg¬ etation) to vegetated zones. For example, a wetland with 50% open water (e =1.0) and 50% emergent vegetation (e = 0.75), would have an average e = 0.875. The overall effects of decreasing porosity are to reduce the wetland volume available for water, which reduces the retention time of water within the wetland, and to increase flocculation of colloidal material which improves removal by sedimentation. It is recommended that a porosity value of 0.65 to 0.75 for fully vegetated zones be used in FWS constructed wetland design calculations, with lower val¬ ues for the most densely vegetated areas. A value of e = 1.0 should be used for wetland open water zones. The use of conservative average porosity values provides a factor of safety, and results in a more conservative design. 4.3.1.4 Average Wastewater Flow The average wastewater flow accounts for the effects of water gains and losses (precipitation, evapotranspiration and infiltration) that occur in a FWS constructed wetland. Defining Q o as the FWS influent flow rate and Q e as the FWS effluent flow rate, the average wastewater flow rate is expressed as: n _ Qo + Qe Vave 2 (4-3) If actual wastewater inflow and outflow are known, these values can be used in Equation 4-3. If only one of these flows has been measured, a water balance can be con¬ ducted to determine the other. If neither are known, a wa¬ ter balance can be useful to show the relationship between the two under the extreme circumstances of operation. 4.3.1.5 Hydraulic Retention Time The nominal hydraulic retention time (HRT) is defined as the ratio of the useable wetland water volume to the average flow rate (Q ave ). The theoretical hydraulic reten¬ tion time as t can be calculated as: t-(VJ(e)/Q„ (4-4) The flow rate used in the hydraulic retention time calcu¬ lation can be the average wetland flow (Q ave ) or the maxi¬ mum or minimum flows, depending on the a purpose of the calculation. 4.3.1.6 Hydraulic Loading Rate The hydraulic loading rate (q) is the volumetric flow rate divided by the wetland surface area and represents the depth of water distributed to the wetland surface over a specified time interval. The hydraulic loading rate can be written as: q = Q„ / \ (4-5) 66 where q has units of L/T. Generally the hydraulic load¬ ing rate is determined using the wastewater inflow (Q o ). 4.3.2 Water Conveyance Water conveyance in FWS wetlands is hydraulically com¬ plex, varying in both space and time due to wetland veg¬ etation and litter, changing inflow conditions, and the sto¬ chastic nature of hydrologic events. When designing a constructed wetland, it is necessary to understand how water moves through the wetland, and how this water movement influences various design con¬ siderations. 4.3.2.1 Ideal versus Actual Flow in a FWS Constructed Wetland Though plug flow is generally assumed for the purposes of FWS constructed wetland design, actual wetland flow hydraulics do not follow an ideal plug flow model. The de¬ viation from plug flow of an existing FWS constructed wet¬ land can be determined through the use of tracer tests. One result of a tracer test is the determination of the aver¬ age tracer retention time, which is defined as the centroid of the response curve, as shown in Figure 4-11. The aver¬ age tracer retention time is equal to the active water vol¬ ume (V w ) (e) divided by the average volumetric flow rate (Q ave ), and thus represents a direct measure of actual re¬ tention time. Results from some tracer studies have shown that the hydraulic characteristics of a FWS constructed wetland can be approximated by a series of 4 to 6 equally sized complete mix reactors (Kadlec and Knight, 1996; and Crites and Tchobanoglous, 1998). In other studies, the complete mix reactor model has resulted in a poor fit to the data, and other models have been more successful. Figure 4-11 shows the observed tracer concentration from one wetland cell of the Sacramento Regional Wastewater Treatment Plant Demonstration Wetlands Project com¬ pared to the predicted tracer concentrations using the fi¬ nite state model first suggested by Hovorka (1961). The finite stage model integrates components of completely mixed, plug flow, and off line storage addition/feedback into one hydraulic model. Coefficients are unique for each geometry, planting pattern, etc. For any given site with appropriate data the finite stage model gives the best fit of the tracer data. This method was first applied to FWS sys¬ tems at the Areata pilot studies (Gearheart, et al, 1983) and has subsequently been applied to the Sacramento system (Dombeck, 1998). The value of multiple cells and periodic open-water zones have been recognized for mini¬ mizing short-circuiting by numerous authors. 4.3.2.2 Hydraulic Gradient in a FWS Constructed Wetland For FWS constructed wetlands, some assessment of the energy loss or head loss from inlet to outlet is necessary to ensure that the wetland is designed to handle all poten¬ tial flows without creating significant backwater problems, such as flooding the inlet structures or overtopping berms. It has historically been assumed that Manning's equation, which defines flow in open channels, can be adapted to Figure 4-11. Tracer response curve for Sacramento Regional Wastewater Treatment Plant Demonstration Wetlands Project Cell 7 (SERSD, 1998). 67 estimate head loss in FWS wetlands. By assuming that the submerged wetland vegetation, peat and litter provides more frictional resistance to flow than the wetland bottom and sides, Manning's equation has been adapted as fol¬ lows: where: v = average flow velocity (L/T), n = Manning’s resistance coefficient (T/L 1/3 ), h = average wetland depth (L), and S = hydraulic gradient or slope of water surface (L/L). In the above equation, the average wetland depth and water surface slope is fairly easily estimated, and the av¬ erage velocity (v) is defined as the average flow (Q ) di¬ vided by the available average cross sectional area (A v )(e), or (Width)(depth)(e). The determination of Manning's re¬ sistance coefficient (n) is not as straightforward. In wet¬ lands, the vegetation and litter providing resistance to wa¬ ter flow is distributed throughout the water column, with settled particles and detritus on the bottom and a thicker thatch level at the top. Thus, n should be a function of the water depth as well as the resistance of specific surfaces. Measurements of n in operating wetlands range from ap¬ proximately 0.3 to 1.1 s/m 1/3 with the higher numbers cor¬ responding to water depths less than 0.2 m (Kadlec and Knight, 1996). Reed, et al, (1995) use an equation to esti¬ mate n at 0.2m depth to vary from 1 to 14 s/m 1/3 . Linsley, et.al., (1982) offer a series of values for n from0.024 to 0.112. A default value of 0.1 to 0.5 is suggested for those wishing to pursue this issue. Atypical solution provided in Crites and Tchobanoglous (1996) is a slope of 1 in 10,000, or 1cm in 100 meters. Since multiple cells are recom¬ mended as good design practice to minimize short-circuit¬ ing and to maximize treatment performance, the above analysis is superfluous for most applications where aspect ratios (length/width) are within suggested limits of 3:1 to 5:1, or even larger. 4.4 Wetland System Design and Sizing Rationale 4.4.11ntroduction As FWS constructed wetlands became recognized as a viable wastewater treatment process, FWS design mod¬ els soon followed. These models were intended to aid en¬ gineers/designers in the process of FWS wetland design and performance assessment. To date, a number of wet¬ land design methods have been proposed for predicting constituent removals in FWS wetlands. These may be found with explanation in Reed, et al, (1995), Kadlec and Knight, (1996) and Crites and Tchobanoglous, (1998). The design models and methods have been used to attempt to predict the fate of BOD, TSS, TN, NH 4 , N0 3 , TP and fecal coliforms in a FWS system. Free water surface constructed wetlands have usually been modeled as attached growth biological reactors, in which the plants and detrital material uniformly occupy the entire volume of the wetland. The current trend in wetland design modeling is the de¬ velopment of simple mass balance or input/output mod¬ els. These simplified models do not explicitly account for the many complex reactions that occur in a wetland, either in the water column or at interfaces such as the water/ sediment interface. Instead, all reactions are lumped into one overall biological reaction rate parameter that can be estimated from collected FWS wetland performance data. At this stage of wetland understanding, more complex and theoretical wetland models which explicitly describe the kinetics of known wetland processes may not be possible due to severe limitations in almost all of the existing wet¬ lands data. 4.4.2 Existing Models In essence the types of models that have been used in FWS constructed wetland design are known as plug-flow- reactor (PFR) models.. One assumes horizontally based (lin¬ ear) kinetics (Reed, et al,1995; Crites and Tchobanoglous, 1998), while the other assumes vertical (areal) kinetics (Kadlec and Knight, 1996). Several varieties of these mod¬ els exist. Some assume average kinetic rate constants, while others assume retarded kinetic rate constants. All provide a list of effluent background concentrations below which an FWS cannot dependably attain and specific default values for temperature adjustments to correct kinetic rate constants. Some suggest monthly multipliers for average computed design performance. Some include safety factors within the equation while others apply them to the model result. All as¬ sume first-order biological kinetics, despite the fact that the initial fully vegetated treatment zone is anaerobic, and none of these models can account for a sequencing, i.e., fully veg¬ etated and open-water zones in sequence, design which is recommended herein for better performance. Recently, one of the primary model creators has also noted the inadequacy of these models (Kadlec, 2000). Readers are referred to Kadlec and Knight (1996), Reed, et al, (1995), and Crites and Tchobanoglous (1998) for details. For the purpose of this manual, i.e., providing secondary (BOD=SS =30mg/l) and advanced secondary treatment of municipal wastewa¬ ters, none of these equations alone are able to accurately predict the performance of a multi-zone FWS constructed wetland. Even if they could be calibrated “to fit” a specific set of data their non-deterministic basis belies their ability to fit other circumstances of operation. 4.4.3 Areal Loading Rates The areal loading rate method specifies a maximum load¬ ing rate per unit area for a given constituent. These meth¬ ods are common in the design of oxidation ponds and land treatment systems. Areal loading rates can be used to give both planning level and final design sizing estimates for FWS systems from projected pollutant mass loads. For example, knowing the areal BOD loading rate, the expected BOD effluent concentration can be estimated or compared to the long term average performance data of other well- ■ documented, full-scale operating systems. 68 In section 4.1 each pollutant was discussed based on areal loading vs. effluent concentration based on the DMDB, the TADB, specific studies and mechanistic evalu¬ ations of other sources of information. Areal loading does not always correlate to a reasonable design basis, espe¬ cially with regard to nutrients and pathogen removal, and other mechanistic explanations are necessary. However, if typical municipal wastewaters are to be treated which have total and filtered pollutant fractionation which are rea¬ sonably consistent from site to site, a rational design ap¬ proach can be deduced for those parameters which can be removed during the enhanced flocculation/sedimenta¬ tion which occurs in the initial fully vegetated zone of a FWS constructed wetland. Therefore, based on Figures 4-1 and 4-4 the following areal loadings can be employed for this initial zone (zone 1) of the FWS : Parameter Zone 1 Areal Loading Effluent Concentration BOD 40 kg/ha-d 30 mg/L TSS 30 kg/ha-d 30 mg/L The relative areal loadings imply that unless the pre¬ treatment process were to have a BOD concentration of greater than 1.3 times the TSS concentration, the latter would be the critical loading rate for the fully vegetated zone if secondary standards are to be met by a fully veg¬ etated FWS system. If the FWS system were to have significant open areas between fully vegetated zones, a better effluent quality could be attained at areal loadings, based on the entire FWS system area (AJ: Parameter Areal Loading Effluent Concentration BOD 45 kg/ha-d <20 mg/L 60 kg/ha-d 30 mg/L TSS 30 kg/ha-d < 20 mg/L 50 kg/ha-d 30 mg/L These loadings are based on the entire system area, not just zone 1. Therefore, with open-water zones which provide aerobic transformations and removal opportuni¬ ties, a better effluent quality is achievable than with a fully vegetated FWS system. Although there are insufficient data at this time to eliminate the need to provide effluent disin¬ fection, more disinfection interferences are removed which would facilitate that step. Conversely, the open water zones would attract wildlife to a greater degree, and the impacts created by their activities. Similarly, the need to and the power required to reaerate the final effluent will at the least be reduced. The advantages of this design concept have been described by Gearheart and Finney (1996) to include reduced “background” BOD concentrations in the effluent owing to the aerobic biological removals in the open-water zones. As with the fully vegetated systems, the TSS areal loading is more critical. With more quality data these limit¬ ing loadings could be shown to be conservative, especially the BOD loading for attaining secondary effluent standards with open-water FWS systems. 4.5 Design 4.5.1 Design Sizing and Performance Mechanisms If a pretreatent system already exists, the type of influ¬ ent characterization necessary has already been dis¬ cussed, but at a minimum all pollutants which are of con¬ cern to the NPDES permitting authority should be mea¬ sured as both total and filtered through a standardized glass fiber filter prior to analysis. Ideally, a particle-size distribu¬ tion analysis of the type described in Crites and Tchobanoglous (1998) could be performed for all critical pollutants to aid the designer in predicting what level of removals of each pollutant are likely to be attained by an FWS or other treatment processes. If the pretreatment system does not exist, the designer will need to perform a variety of investigations as described in several engineer¬ ing texts (e.g., Crites and Tchobanoglous,1998; WEF, 1998). A primary supposition of this manual is that a FWS con¬ structed wetland is most likely to treat effluent from a sta¬ bilization or oxidation pond or from primary-treated (settled) municipal wastewater. After the designer determines overall size of the FWS system from these BOD and TSS areal loading rates, he or she can return to evaluate the fate of other constituents. If the total and filtered analyses are available, it is a rea¬ sonable approximation to assume that the filtered analy¬ sis represents a rough approximation of effluent quality attainable from treatment zone 1 (fully vegetated zone) given that the filter pores are generally a bit larger than the specific particle sizes indicated for the “colloidal/soluble” fraction in Table 4-3. Internal loads in the soluble form should also be added to this fraction in estimation of zone 1 effluent(see Figure 4-2 and 4-3). For more stringent ef¬ fluent requirements than those cited above for BOD and TSS, the designer should look at alternative polishing pro¬ cesses such as land treatment or slow sand filtration. While a few physical and chemical processes occur uni¬ formly over the entire wetland volume, many of the most important treatment processes occur in a sequential man¬ ner and the wetland must be designed to accommodate this characteristic. For example, TSS removal and removal of associated BOD, Org N and P, metals, etc., occur in the initial portion of the cell, while the subsequent zones can impact certain soluble constituents. Given sufficient dis¬ solved oxygen in open (unvegetated) areas, soluble BOD removal and nitrification of ammonia can occur. If insuffi¬ cient oxygen is present, soluble BOD is very slowly re¬ moved by anaerobic processes. Wetland design must also consider the background level, or expected lower limit, of water quality constituents in the FWS wetland effluent (see Table 4-4). Particulate and soluble constituents are inter¬ nally produced as a part of the normal decomposition and treatment processes occurring in a constructed wetland. Wildlife contribute fecal coliform and additional organic compounds. During periods of intense activity, wildlife also 69 stir up settled solids contributing to an increase in turbid¬ ity, TSS, and BOD. Table 4-4 shows the typical background levels for the constituents of interest recommended for users of this document. Designs requiring effluent quality close to the values in Table 4-4 must be aware of the natu¬ ral fluctuations about the mean values, as shown in Figure 4-12. For more details on the numerical values in the table, the reader is urged to refer to Reed, et al, (1995), Kadlec and Knight, 1996, and Gearheart, 1992. A similar approach to the one suggested here for de¬ signing FWS wetlands, referred to as the "sequential model", has been developed by Gearheart and Finney (1999). The overall approach of the model is to consider the dominant physical and biological processes respon¬ sible for determining effluent quality from each distinctive area or zone of the constructed wetland and allow the de¬ signer to specify areal requirements and wetland depth for each of these specific functions. This methodology recog¬ nizes that while some of the constituent transformations and removal mechanisms are to some degree occurring simultaneously throughout the wetland, the majority of the removal occurs in a sequential fashion, with one process or mechanism providing the products for the next process or mechanism. The total area required for treatment is then a sum of each of the zones required to reach a specific effluent objective. This approach allows the designer to sequentially determine the range of effluent characteris¬ tics which are attainable in a given definable zone before entering a subsequent reactor (zone) which has known treatment capabilities. Table 4-4. Background Concentrations of Water Quality Constituents of Concern in FWS Constructed Wetlands Range Typical Parameter (mg/L) (mg/L) Factors governing TSS 2-5 3 Plant types, plant coverage, climate, wildlife activity BOD' 2-8 5 Plant types, plant coverage, plant density, climate, wildlife activity BOD 2 5-12 10 Plant types, plant coverage, plant density, climate TN 1 -3 2 Plant types, plant coverage, climate, oxic/anoxic conditions NFF-N 4 0.2- 1.5 1 Plant types, plant coverage, climate, oxic/anoxic conditions TP soil 0.1 -0.5 0.3 Plant types, plant coverage, climate, type FC 3 50 - 5000 200 Plant types, plant coverage, climate, wildlife activity 'FWS with open water and submergent and floating aquatic macro¬ phytes. 2 Fully vegetated with emergent macrophytes and with a minimum of open water. 2 Measured in cfu/100 ml The sequential model approach recognizes that all the treatment objectives beyond secondary require a minimum of three general wetland "compartments" (see Figure 4- 13): (1) an initial compartment where the bulk of the floc¬ culation and sedimentation will occur, (2) an aerobic com¬ partment where soluble BOD reduction and nitrification can occur, and (3) a vegetated polishing compartment where further reductions in TSS and associated constituents and nitrogen (via denitrification) can occur. Permanent phos¬ phorus removal in wetlands is generally small and is largely the result of phosphorus adsorption to solids and plant detritus. Sedimentation and pathogen reduction are related to detention time in zone 1, to retention time and tempera¬ ture in zone 2, and to retention time in zone 3. As noted earlier, the notion of "compartments" is artificial as the treat¬ ment processes overlap in time and space, and no spe¬ cific physical compartment is necessarily implied. However, separation of an FWS into a series of single-function zones (cells) with individual outlet controls is not an unattractive concept. A rational overview of the FWS system is depicted in Figure 4-14. It illustrates that the primary mechanisms in zone 1, which is fully vegetated and anaerobic throughout its depth during the growing season, are sedimentation and flocculation, as determined by transect measurements of dissolved oxygen and pollutant concentrations. Any ex¬ tension of the HRT in zone 1 beyond approximately 2 days at Qmax would be essentially wasteful since the anaero¬ bic conditions will not result in any significant further re¬ moval of soluble constituents and flocculation sedimenta¬ tion has been effectively completed. The TSS and associ¬ ated constituents (particulate BOD, organic nitrogen and phosphorous, metals and certain semivolatile organic com¬ pounds) have also reached this same status. Volatile or¬ ganics are likely to be removed from the wastewater dur¬ ing the collection or oxidation pond treatment processes (Hannah, et al, 1986), while most semivolatiles are removed with the solids in the oxidation pond or in zone 1 of the FWS system. For many years it has been recognized that effluent floc¬ culation is primarily a function of energy input from either external sources or internal hydrodynamic forces, and that reduced Reynolds’ Numbers (Re) induce optimal sedimen¬ tation of particles. Over the past several decades this phe¬ nomena has been applied in the development of hydrody¬ namic devices which accomplish excellent flocculation and/ or sedimentation without moving parts, such as pipe mix¬ ers and flocculators, tube and plate settlers, and pebble bed and wedgewire outlet devices for clairifers. Flow through the emerging vegetation is extremely tortuous and is accompanied by a very small hydraulic radius. The Reynolds Number (Re) is a direct function of the hydraulic radius (diameter, if the path were round (as in a pipe). If the Re falls in a range which corresponds to laminar flow, sedimentation is maximized. Re is several thousand in large basins, and even larger in non-vegetated ponds. No direct measurements of Re or laminar flow have been made at the time of this writing, but analogous results from studies 70 150 O) S Q o CO —Q— Mean -0- Median —A— Minimum —©— Maximum 70 Distance from Influent (m) Figure 4-12. Mean, median, minimum and maximum transect BOD 5 data for Areata Pilot Cell 8 Floating and Inlet Settling Zone Emergent Plants Submerged Growth Plants Floating and Emergent Plants Zone 1 Fully Vegetated D.O. (-) H < 0.75 m Zone 2 Open-Water Surface D.O. (+) FI > 1.2 m Zone 3 Fully Vegetated D.O. (-) H < 0.75 m Figure 4-13. Elements of a free water surface (FWS) constructed wetland 71 Zone 1 Zone 2 Zone 3 Figure 4-14. Generic removal of pollutants in 3-zone FWS system of tube settlers and particle-size removals support this theory, given the large amount of wetted surface available. (Sparham, 1970). This concept also supports the use of fully vegetated areas immediately preceding outlet weirs. In zone 2, which is primarily open-water, the natural reaeration processes are supplemented by submerged macrophytes during daylight periods to elevate dissolved oxygen in order to oxidize carbonaceous compounds (BOD) to sufficiently low levels to facilitate nitrification of the NH 4 -N to N0 3 -N. These processes require large amounts of oxygen and time in a passive system (no me¬ chanical assistance). The maximum HRT in zone 2 is gen¬ erally limited to about 2 to 3 days before unwanted algal blooms occur. Therefore, more than one open zone may be required to complete these reactions. If so, the result would be a five (or more) zone design since each open zone would be followed by a fully vegetated zone. The reactions in zone 2 are essentially the same as in a facul¬ tative lagoon. Therefore, the equations which apply to those systems might offer reasonable approximations to the rate of transformations occurring in this open-water zone. There¬ fore, the first-order Marais and Shaw (1961) equation for fecal coliform dieoff could be applied as an approximation, along with its temperature dependancy: Co (l + tK p ) N where: Co = influent FC concentration, cfu/100 ml Ce = effluent FC concentration, cfu/100 ml N = number of open-water zones in the FWS t = HRT (T) K = fecal coliform removal rate constant (T 1 ) = 2.6 ( 1 . 19) T - 20 ( 4 - 8 ) where: T = temperature, °C BOD removal in the open-water zone should also follow existing equations such as (Crites and Tchobanoglous, 1998); — = -!- w (4-9) Co (l + tK p ) N 72 where: C = BOD, mg/L Kb = specific BODs removal rate constant (T 1 ) Kb = 0.15 (1.04) 1 ' 20 (4-10) Therefore, in analyzing Figure 4-14 the downward stope in FC and BOD in zone 2 can be approximated through the above equations, without considering offsets from wild¬ life. As noted previously, the nitrifying bacteria can prolif¬ erate and convert ammonia-nitrogen to nitrate(N0 3 -N) and will be the primary nitrogen transformation role of zone 2. However, the carbonaceous BOD must be low enough to allow these reactions to occur. In rotating biological contactors this concentration of BOD is about 15 mg/I (USEPA, 1993). As noted by Gearheart (1992) increasing the size of the open-water zone generally increases dis¬ solved oxygen, pH, and N0 3 -N, while decreasing soluble BOD and ammonium. U.K.’s Department of Environment has studied lagoon systems treating similar quality influent to that of zone 2. They have noted that algal growth generally starts to oc¬ cur between days 2 and 3 (UK, 1973). Algal growth can raise pH, interfere with FC kill and the growth of submerged plants, increase NH 3 -N volatilization, and induce phospho¬ rus precipitation. Also, the additional biomass and precipi¬ tates that must be removed in zone 3 will add to the inter¬ nal loading on the FWS system. The primary goal of the open-water zone is to provide dissolved oxygen to remove BOD and convert NH 4 -N to N0 3 -N. Therefore, the optimium sizing of this zone would be an HRT of 2 to 3 days. Assum¬ ing a Q max /Q ave of 2, the designer might choose an HRT of 2 days at x Q max or an HRT of 3 days at Q ave . Climate would likely be the final criterion, with the larger size favored in northern areas and the smaller in southern ones. The third zone is fully vegetated like zone 1 and has a similar function. Zone 3, like zone 1 is also capable of deni¬ trification if the influent flow contains N0 3 -N. Where oxida¬ tion pond pretreatment of municipal wastewaters is em¬ ployed, zone 1 of the FWS system is not generally required to denitrify, but zone 3 will if zone 2 induces nitrification. The primary energy source for successful denitrification is the release of organic substrates from the detritus from decaying plants. However, partially digested, previously removed organics may also be available. Denitrifying bac¬ teria perform only under anaerobic conditions and best when attached to large surface areas, e.g., plants. Denitri¬ fication, like nitrification, is temperature-sensitive. Nitrifi¬ cation and denitrification are greatly impaired when water temperatures are reduced below 10°C. Gearheart (1992) showed total inorganic nitrogen in the Areata Marsh to be reduced from 25 to 5 mg/L. In 1995 he demonstrated pilot- scale removal of N0 3 -N from 130 mg/L to 6 mg/L using no supplemental carbon sources in 80 hours at 15°C. The primary limitation in a three-zone FWS system designed to remove nitrogen is the rate of nitrification in the open- water zone. If the open-water zone succeeds in nitrifying the NH 4 -N, the system should be able to denitrify it. Reed, et al, (1995) indicate that denitrification should require less than one day hydraulic retention time (HRT) for denitrifica¬ tion from municipal wastewater concentrations to an efflu¬ ent requirement of < 10 mg/L. Kadlec and Knight (1996) found that 1 to 2 days should suffice to reach 90% N0 3 -N removal. Therefore the previously- stated requirement for zone 3 (HRT of 2 days) should meet this retention require¬ ment and ensure significant denitrification. WEF Manual of Practice FD-16 (1990) indicates that the denitrification rate can be as high as 10 kg/ha-d. Loadings must be within the limits of available labile carbon to proceed at the maxi¬ mum rate. As with zone 1 there is additional, temporary nutrient (N and P) removal by plant uptake in zone 3, which may be significant at certain times during the year, while release of most of these nutrients occurs at other times. These plant effects can mask the effects of other processes which could be impacting the system performance at the same times. Unfortunately, there are insufficient data to fully quan¬ tify the nutrient cycle for each zone of the FWS system. 4.5.2 Total Suspended Solids Removal Design Considerations Since prior discussion indicates that TSS removal (rather than BOD removal) drives the sizing process, there is a need to provide further discussion of the mechanisms in¬ volved and their implications on design. Treatment mecha¬ nisms which dominate in the vegetated inlet zone of a FWS constructed wetland volume are flocculation, sedimenta¬ tion and anaerobic decomposition. Discrete and flocculent settling occurs as the wastewater flows through the initial fully vegetated zone. Since the FWS was likely preceded by an oxidation pond where most discrete settling has oc¬ curred already, the enhanced settling in zonel is mostly due to flocculation of large supracolloidal solids in pas¬ sage through the emergent vegetation. The processes are generally not temperature dependent and occur at rela¬ tively high hydraulic loading rates. TSS removal rates of 40 to 60% are common with a q of 0.06 m/day to 0.27 m/ day, but relative removals are more accurately determined by influent characteristics and the hydrodynamics of the initial vegetated zone. The majority of incoming solids are removed in this ini¬ tial settling volume. Hyacinth and duckweed systems are similar to (but not as good as) zone 1 of an FWS in the hydrodynamics which promote excellent flocculation and sedimentation. The mechanisms of the fully vegetated zone 1 can be estimated from the use of particle size distribu¬ tion analysis. Generally, wastewaters have been analyzed in form size ranges: Settleable (>100 pm) Supracolloidal (1 to 100 |im) Colloidal (0.001 to 1 pm) Dissolved (< 0.001 pm) 73 Only one study has employed this approach (Gearheart and Finney, 1996) with oxidation ponds followed by FWS constructed wetland treatment. The results shown in Table 4-3, clearly demonstrate the essentially complete removal of the settleable fraction (100% for BOD and 95% for TSS) and progressively reduced removal of the supracolloidal (91 % of BOD and 92% of TSS) and colloidal (66% of BOD) fractions. This progression runs counter to the frequently noted biological reaction rate vs particle size relationship (Levine, et. al., 1991). Therefore, the primary mechanism for removal of TSS and associated pollutants (BOD, or¬ ganic nutrients, metals and toxic organics) is not biologi¬ cal in nature. This would appear to be reinforced by the lack of dissolved oxygen, high oxygen demand, and the slow nature of anaerobic biological reactions which are the predominant biological mechanisms. The solids that are removed undergo incomplete anaero¬ bic decomposition (acidification) resulting in a release of nitrogen, phosphorus, and carbon in the form of volatile fatty acids. The amount of accumulated internal load de¬ pends on the length of time the water temperature stays below 5-10°C since this material does not undergo signifi¬ cant decomposition until the water temperature increases above this threshold value. The longer the uninterrupted period of less than 5-10°C, the greater the initial load and its effect on dissolved BOD at temperatures above this threshold. In most temperate North American climates, the release of this accumulated organic material expresses itself mostly in the late spring and in the early summer, similar to oxidation pond "spring turnover". Some of these impacts are noted by the comments within Figure 4-14, which show how some of these phenomena might impact removal patterns. Non-degradeable material is removed, accumulates and is compressed forming an organic layer of biologically re¬ calcitrant material in the sediments of zone 1. The layer is thicker near the influent end of the wetland and gets shal¬ lower in the direction of flow. This delta of accumulated solid material can eventually reduce the HRT and the avail¬ able solids storage volume of the wetland. These losses are also acerbated by accumulated plant detritus. These accumulated solids ("sludge" or "biosolids") will occasion¬ ally need to be removed and managed, e.g., directly land applied and plowed under as a soil amendment or through some other method as directed by the regulatory authori¬ ties. The reduction in wetland volume due to settled solids, living plants and plant detritus can be significant over the long term. The rate of accumulation of settled suspended solids is a function of the water temperature, mass of influ¬ ent TSS , the effectiveness of TSS removal, the decay rate of the volatile fraction of the TSS, and the settled TSS mass which is non-volatile. The plant detritus buildup is a function of the standing crop and the decay rate of the plant detritus. Accumulation for emergent vegetated areas of the Areata enhancement wetlands was measured to be approximately 12 mm/year of detritus on the bottom due to plant breakdown and 12 to 25 mm/year of litter forming a thatch on the surface (Kadlecik, 1996). The volume of the living plants, specifically the volume of the emergent plants, ranged from 0.005 m 3 /m 2 (low stem density, water depth of 0.3 m) to 0.078 m 3 /m 2 (high stem density, water depth of 0.75 m). This accumulation is more or less con¬ stant from year to year as the wetland matures. The total volume reduction under the initial vegetated zone can be estimated using a mass balance equation: V r = [(VJ(t) + (V d )(t)]A w (4-11) where: V r = volume reduction over period of analysis (m 3 ), V ss = volume reduction due to non-volatile TSS and non-degradable volatile TSS accumulation (m 3 /ha-yr), V d = volume reduction due to non-volatile detrital accumulation as A function of annual production (m 3 /ha-yr), A w = fully vegetated wetland area (ha), t w = period of analysis usually (years). The loss of volume per hectare over a ten year period for a 1 hectare fully vegetated FWS wetland zone with a depth of 0.75 m can be estimated by use of this equation. Based on information in Middlebrooks, et al, (1982) and Carre, et al, (1990) a reasonable default value for V when treating raw wastewater in lagoons) would be 200 to 400 m 3 /ha-yr (2 to 4 cm/yr). Therefore, a conservative default value of 150 m 3 /ha-yr can be used. One hundred percent coverage of emergent vegetation was measured to con¬ tribute 120 m 3 /ha- yr of bottom detritus, and 120 m 3 /ha-yr of surface litter with a standing crop volume of 412 m 3 /ha. Substituting into the equation for a 10-year analysis yields: Vr =[150)(10) + (240)(10)] 1.0 = 3,900m 3 Table 4-5 provides additional examples of wetland vol¬ ume loss due to TSS and plants detritus. Based on the actual Areata experience, it is clear that use of equation 4- 11 is a conservative means of estimating volume reduc¬ tion from TSS deposition and detrital accumulation. Using the initial fully vegetated zone volume (V,) and adding the standing crop (V c ), the total loss of volume can be estimated by addition to be 4,312 m 3 . Since the original volume is area (10,000 m 2 ) times depth(0.75 m) or 7,500 m 3 , the total loss of volume would be 4,312/10,000 or 43%. This corresponds to a new porosity (e) of 0.57. As noted earlier dense, mature stands of emergent plants are as¬ sumed to have a porosity of about 0.65. Table 4-5. Examples of Change in Wetland Volume Due to Deposition of Non-Degradable TSS (V ss ) and Plant Detritus (V d ) Based on 100% Emergent Plant Coverage (Gearheart, et al, 1998) Influent TSS. (mg/L) v s 50% removal (m 3 /yr)ha) 75% removal V d (m 3 /ha/yr) 40 75 113 240 60 80 112 150 168 225 240 240 74 The accumulation computed above indicate that the call is nearly ready for residual solids removal, as its excess storage capacity is essentially used up. However, the Areata facility for which the accumulation measurements were made is still performing well after 12 years (USEPA, 1999). The loss of volume and porosity computed by the previ¬ ous method is obviously conservative, but illustrates how one could conservatively estimate the loss of porosity in the initial settling zone. When designing the primary wetland cell treating oxida¬ tion pond effluent the designer should consider this cumu¬ lative problem by increasing the depth of the inlet zone (up to 1 .Om) to lengthen the period before solids removal would be required. The designer should also provide for easily accessible solids removal in this zone. There may be a need to harvest vegetation and related detritus to maintain fully vegetated and open-water areas in proper proportion. Such controlled harvesting may be extended into the fully vegetated zones to reduce the apparent loss of effective treatment volume and delay the need to re¬ move accumulated solids. The fully vegetated, anaerobic zone 1 of the FWS wet¬ land should be designed based upon the average maxi¬ mum monthly flow rate (G max ) to assure the potential for effective removal of solids during periods of high flow. To facilitate solids removal and handling, this initial compart¬ ment should be designed as at least two equally sized wetlands with a 0.6 to 0.9 m operating depth, which can be operated in parallel. This would allow taking one cell out of operation for maintenance work such as for solids removal, vegetation removal, or replanting. 4.5.3 Design Examples Design Example 1 - BOD and TSS to meet secondary effluent requirements Design a FWS wetland to treat lagoon effluent to meet a monthly average 30 mg/I BOD and TSS discharge objec¬ tive. The community has a design population of 50,000 people with an average annual design flow of 18,920 m 3 / day (5 MGD) (Q ave ). Use design loading factors from sec¬ tions 4.4 and 4.5* to meet a 30 mg/I BOD and TSS effluent standard. Since a single fully vegetated FWS system can be employed with maximum areal loading rates for these systems are 40 kg BOD/ha-d and 30 kg TSS/ha-d. Facul¬ tative lagoon effluent typically averages from 30 to 40 mg BOD/L and 40 to 100 mg TSS/L, with the latter being much more variable due to seasonal algal growth and spring and fall overturn periods (WEF, 1998; Middlebrooks, et al, 1982). For this example the average FWS influent BOD is 50 mg/I at Q ave (18,920 m 3 /d), while the average TSS is 70 mg/L at this flow. At the maximum monthly flow (Q max ) of 2 x Q ave the BOD is 40 mg/L and TSS is 30 mg/L. I! Step 1 - Apply areal loading rates(ALR) to average (Q ave ) and maximum monthly flow (Q^J conditions to iden¬ tify the critical conditions for sizing of the facility. ALR = Q Co/A w (4-12) where: ALR = areal loading rates: BOD = 40 kg /ha-d ;TSS = 30 kg /ha-d Q0 = incoming flow rate, in m 3 /d CO = influent concentration, in mg/L A = total area of FWS, in ha w 9 which for BOD yields: for Q ave , A w = (18,920 m 3 /d)(1000 L/m 3 )(50 mg/L)/ (40 kg/ha-d)(106 mg/kg) = 24 ha for Q max , A w = (37,840) (40)/ (40) (106) = 38 ha Similarly, for TSS: for Q ave > A w = (18,920) (70)/(30)(106) = 44 ha for Q max , A w = (37,840)(30)/(30)(106) = 38 ha Therefore, the limiting condition is the TSS loading at average flow conditions, where 44 hectares are required to meet secondary effluent standards with a fully vegetated, single-zone FWS system. However, it has been previously shown that open water zones permit higher areal loading rates (from section 4.4), so the sizing can be recomputed on that basis following the same procedure. From that analysis, with BOD and TSS loading rates of 60 and 50 kg/ha-d, respectively, the critical condition is still the aver¬ age flow condition and the TSS areal loading, but with a requirement of 26 ha instead of 44 ha. Step 2 - Determine the theoretical HRT(days) using equa¬ tion 4-4, assuming h = 0.6 m and e = 0.75 in veg¬ etated zones (1 and 3) and h = 1.2 m and e = 1.0 in the open zone (2). The combined estimate is an aver¬ age depth of 0.8 m and an average e = 0.8. Therefore, the first estimate is for overall HRT, followed by indi¬ vidual cell estimates. f° r Q ave , ^ _ Vvve _ Aw h £ _ Qave Qave (26 ha)(l 0,000 m 2 / ha)(0.8 m)(0.80) 18,920 m 3 d = 8.9 days for 9™, 1 = 4-5 days This last calculation implies that at the maximum monthly flow the overall HRT may not be adequate for the neces¬ sary treatment mechanisms to perform. If these relatively equal-sized zones are employed as a first approximation, there would be less than one day of theoretical HRT in each at this maximum flow condition. For zone 1 the mini¬ mum HRT at Q max should be about 2 days, making 4 days at Q . ave For zone 2 there is an upper limit which depends on climate and temperature. In this example, the concept is 75 that the open-water area will have an HRT exceeding that which is required for an algal bloom, creating a significant additional loading on zone 3. The time required for this condition varies with temperature, e.g., shorter in hotter climates. For most U.S. conditions a maximum HRT of about 2 to 3 days should avoid most blooms. On the other hand, the longer the HRT in zone 2, the better the reduc¬ tion in soluble organics, ammonia-nitrogen and fecal conforms. Therefore, the designer should consider isola¬ tion of this zone from the fully-vegetated zones that pre¬ cede and follow it and provide some flexibility in HRT con¬ trol independent of the other zones to optimize this zone’s treatment performance. For this exercise a minimum HRT of 2 days is chosen, making the average HRT 4 days at average flow. Zone 3 should be provided the same design consider¬ ations as zone 1, since it functions in the same manner. Depending on the performance of zone 2, it may also pro¬ vide denitrification in addition to flocculation and sedimen¬ tation. Therefore, it should have approximately the same HRT as zone 1. The minimum HRT at Q max is therefore 2 + 2 + 2 = 6 days, and the average 12 days with the assumptions cho¬ sen in this example. This would then require (using equa¬ tion 4-4)an overall wetland area of: A w = (t)(Q)/(h)(e) = (12 d)(18,920 m 3 /d) / (0.8 m)(0.80)(10,000 m 2 /ha) = 35 ha ings to meet these effluent concentrations are 45 kg BOD /ha-d and 30 kg TSS /ha-d. Using the same influent condi¬ tions in the first example, the steps of preliminary sizing are the same. Step 1 - Apply areal loading to determine the FWS system’s critical sizing conditions using equation 4-12. BOD: at Q ava , A w = at Q™.. A » = TSS: at Q a>a , A a = al Q™,- A „ - The limiting condition is again the TSS loading at Q ave , where 44 hectares are required. This is a larger require¬ ment than in the previous example, as would be expected since more stringent effluent requirements are being met. Step 2 - Determine the theoretical HRT (t) required for the entire 3-zone FWS system and each specific zone using equation 4-4, assuming an overall average depth (h) of 0.8 m and an overall porosity (e) of 0.8. f Q _ (44 ha)(l 0,000 m 2 / ha)(0.8 m)(0.8) ave ’ ’ 19,920 m 3 /d = 14.9 days (18.920) (50)(1000)/(45)(106) 21 ha (37.840) (40)(1000)/(45)(106) 34 ha (18.920) (70)(1000)/(30)(106) 44 ha (37.840) (30)(1000)/(30)(106) 38 ha Applying the normal additional area for buffers and set¬ backs of 1.25 to 1.4, the total area required for the FWS facility is 45 ha (135 acres). Step 3. - Configuration forQ ma, t = 7.4 days Returning to individual zones and assuming an equal minimum HRT in each, equation 4-4 is used in dimension¬ ing at maximum flow conditions: Given the high TSS of the influent stream and the po¬ tential for short circuiting, the system should be designed with two parallel treatment trains of a minimum of three cells in each. The first cells in each train should normally each get 50% of the flow and may have a deeper (1.0 m) inlet area directly adjacent to the inlet structure to handle any discrete solids settling which might occur at this loca¬ tion. This design option would add approximately one day to the overall HRT, and would only be chosen in situations where pretreatment is likely to allow escape of readily settle- able particulates. Multiple cells allow for redistribution of the primary cell effluent in the subsequent cell which re¬ duces short-circuiting. Flexible intercell piping will facili¬ tate maintenance without a major reduction in the neces¬ sary HRT to produce satisfactory effluent quality. Aspect ratios of the cells should be greater than 3:1 and adapted to the site contours and restrictions. Additional treatment will likely be required after the FWS system to meet fecal coliform and dissolved oxygen permit requirements. Design Example 2 - BOD and TSS < 20mg/L Effluent Requirements To meet this effluent quality an open-water zone will be required in the FWS. From Section 4.4.3 the critical load¬ (2.5 d)(37,840 m 3 / d) 2 (1.0)(1.2 m)( 10,000 m 2 / ha) = 7.9 ha Therefore, the area for zones 1 and 3 are: A 3 =A, = (44 - 7.5 )/2 = 18 ha The overall FWS system area, including buffers, would be about 58 hectares (145 acres). Step 3 - Configuration Again the use of parallel trains is encouraged for all the same reasons as noted in the previous example. Parallel trains of 3 cells in each are recommended which allow any single cell in a train to be removed from service with trans¬ fer of its influent to the same zone cell. By using an aspect ratio in the range of 3 to 5:1 and j complete-cell-width inlets and outlets the intercellular trans- 1 fers should be simplified. 76 Design Example 3 - Estimating from examples 1 and 2. For design example 1, if the influent to the FWS system was facultative lagoon effluent, it would be reasonable to expect the characterization in Table 4-6,with cognizence that the impact of climate and season on the performance of lagoons and the characteristics of municipal wastewa¬ ters vary by orders of magnitude. However, the numbers in the table are within the normally expected ranges. To test the areal loading information presented earlier in this chapter, the loading factors for each chemical constituent can be computed using equation 4-12. These yield aTKN loading of 10.8 kg/ha-d for example 1 and 8.6 kg/ha-d for example 2. Similarly, the TP loadings are 2.7 kg/ha-d and 2.1 kg/ha-d for examples 1 and 2, respectively. Comparing these loadings to Figure 4-5, it is impossible to accurately predict effluent quality for example 1, but it appears that little removal could be expected had the origi¬ nal fully vegetated approach been taken. Mechanistically, the primary mechanisms which are available for TKN re¬ moval in zone 1 are flocculation and sedimentation of or¬ ganic N. Since there are only 4 mg/L of organic N the real¬ istic maximum expectation would be a removal of all but 1 mg/L, while the NH 4 -N may be mostly assimilated by the plants during the active growing rate computed for this example, but most would be returned to the water column during senescence. Therefore, the effluent TKN could av¬ erage anywhere between about 15 and 20 mg/L,depending on the season, and an overall removal of about 2 to 3 mg/ L. With the final open-water design of this example, it is not possible to predict removal without more data from open-zoned systems. As in example 2, the three-zone FWS is likely to produce an effluent TKN of greater than 4 mg/L since all three such systems on the figure were loaded at a lower rate. Actual removal would depend upon nitrifica¬ tion accomplished in zone 2, which would be a function of temperature, HRT and dissolved oxygen in that zone. Since the TKN loading rate is about 4 to 5 times the highest one in the figure for open water systems, a conservative ap¬ proach might be that one-fourth of the nitrogen might be nitrified in the open zone and denitrified in zone 3. This would yield an additional 4 mg/L to the 3 assumed for ex¬ ample 1. This would yield a removal of 7 mg/L and an ef¬ fluent TN of about 13 mg/L which could vary from about 10 to 16 mg/L during the year depending on plant condition and temperature. Conversely, the systems shown in the figure may have had excess capacity in zone 2 to fully nitrify all the ammonium-nitrogen and the same effluent concentration for the lightly loaded open-water systems could also be attained. By having an open-water zone where nitrification can occur, the inherent denitrification ca- Table 4-6. Lagoon Influent and Effluent Quality Assumptions. Parameter Raw Wastewater Lagoon Effluent TKN(mg/L) 40 20 NH 4 -N(mg/L) 10 16 TP(mg/L) 7 5 FC(#/100ml) 106 104 pability of the subsequent fully-vegetated zone creates a potent opportunity for nitrogen control. It is also feasible in the open-water zone to enhance NH3 volatilization, but this mechanism is less likely to be significant owing to the limited size of zone 2 which may not permit increased pH which would enhance volatilization. Such estimates are extremely tenuous until more data is generated on higher loadings to these open water FWS systems, and in the interim the designer would be wise to perform pilot studies where nitrogen limits are part of effluent permit require¬ ments. Areal loading data on total phosphorus (TP) in Figure 4- 6 are inconclusive. The TADB (USEPA, 1999) would sug¬ gest that these example loadings could produce an efflu¬ ent of 3.0 to 4.5 mg/L. At the loadings indicated in these examples, the data of Gearheart (1993) would allow for an overall annual average removal of approximately one mg/ L. This would provide a similar effluent for both examples of about 4 mg/L. The dominant removal mechanisms in both examples are flocculation and sedimentation of or¬ ganic phosphorus, but plant uptake and release will cause the effluent to vary from background levels in the growth- phase to levels at or above the influent concentration dur¬ ing the senescent-phase. This discussion does not include the startup-phase where TP removal will occur for several months until the soil’s phosphorus adsorption capacity is reduced to an equilibrium level by satisfaction of the soil’s calcium, aluminum and iron adsorption sites and comple¬ tion of the initial growth phase of the plants. Fecal coliform (FC) removal is limited by the natural back¬ ground which is depicted in Table 4-4. Figure 4-10 shows that FC removal is based on enhanced sedimentation and flocculation in the fully-vegetated zone of an FWS. There¬ fore, approximately one log (90%) of removal can be safely estimated in that zone. With an open-water zone, the FWS can take advantage of the natural solar disinfection which is described in the international lagoon literature (Mara, 1975). This additional kill of FC is limited by the HRT in the open-water zone and is a temperature-dependent func¬ tion with first-order kinetics. Time limitation and single-cell hydraulics will likely limit additional kill to about one log. Since in zone 3 FC removal would be by sedimentation, less than one additional log of removal could be expected. Based on the prior analyses the total removal for ex¬ amples 1 and 2 would be 2+ logs of kill, with an expected effluent FC count of <100/100ml. A fully vegetated system which has no open zone would likely remove somewhere between 1 and 2 logs to produce an effluent with several hundred FC/100ml. Both would experience a natural varia¬ tion about those means as discussed earlier in the chap¬ ter. One major reason for periodic increases will be wildlife attraction to open water zones. However, with the require¬ ment that the outlet be located at the terminus of the sub¬ sequent fully-vegetated zone 3, the impacts of wildlife should be minimized. However, some spikes of fecal coliform may still be evident. As noted earlier, the impact of the example designs on metals and toxic organics will vary also. Most metals will 77 likely be removed with the TSS by physical means, and effluent metals will probably be similar in ratio to the two TSS effluent concentrations. The average pond effluent had a TSS of 70 mg/I and the two FWS designs should yield 30mg/L and 20mg/L, respectively. Therefore, design examples 1 and 2 should remove about 70% of the heavy metals. Since each metal reacts differently this type of analysis has little meaning. Typically, nickel, boron, sele¬ nium and arsenic are more resistent to removal by sedi¬ mentation than most of the other commonly measured metals. A similar discusion can be provided with regard to semi-volatile toxic organic compounds. Both classes of pollutants may be associated with certain effluent particle- size fractions, which will cause them to follow the removal patterns discussed earlier in concert with Table 4-3. 4.6 Design Issues This subsection describes issues that are important in the design and layout of a FWS constructed wetland. These design issues are separate from wetland area de¬ terminations already described. However, it is important for the engineer/designer to understand that design issues and wetland area determinations are both important. The design issues outlined here are intended to maximize the treatment potential of FWS constructed wetlands and may impact the wetland area determined from the wetland siz¬ ing steps, which should be considered the starting point for a FWS constructed wetland design. Many of the de¬ sign issues outlined below are based on experience with FWS constructed wetland systems currently in operation. 4.6.1 Wetland Layout 4.6.1.1 Site Topography In many cases, the topography of the site will dictate the general shape and configuration of the FWS constructed wetland. On sloping sites, for example, constructing the long dimension of the wetland parallel to the existing ground contours helps minimize grading requirements. With proper design, sloped sites can reduce pumping costs by taking advantage of the existing hydraulic gradients. 4.6.1.2 Aspect (length to width) Ratio The aspect ratio (AR) or length to width ratio (L/W), of a FWS wetland system is defined as the average length di¬ vided by the average width, and can be expressed as: where: L = average length of wetland system, and W = average width of wetland system. FWS constructed wetlands have been designed with ARs from less than 1:1 to over 90:1. Generally, FWS constructed wetlands are designed and built with an AR greater than 1:1. It has been suggested that wetlands with higher ARs help to minimize short circuiting, and force the wetland to more closely conform to plug flow hydraulics (Gearheart, 1996: Dombeck, 1998). However, results of dye studies on existing FWS constructed wetlands have shown that many wetlands deviate from ideal plug flow hydraulics in¬ dependent of the AR. For wetland systems with very high length to width ratios, careful consideration needs to be given to headloss and hydraulic gradient considerations to avoid overflows of confining dikes near the influent end. Use of equation 4-6 and the material in section 4.3.2.2 will permit the designer forced to use high AR cells to evaluate each assumption and make corrections as necessary. When conducting a hydraulic grade line analysis to deter¬ mine if the backwater is at an acceptable elevation near the inlet, the outlet level is normally assumed to be at the midpoint. 4.6.1.3 Wetland configuration The shape of a FWS constructed wetland can be highly variable depending on site topography, land configuration, and surrounding land use activities. FWS constructed wet¬ lands have been configured in a number of shapes, in¬ cluding rectangles, polygons, ovals, kidney shapes, and crescent shapes. There is no data that supports one FWS constructed wetland shape as being superior in terms of constituent removal and effluent quality, over another shape. However, any wetland shape needs to be designed and configured following the general guidelines of this re¬ port. Design concerns such as hydraulic retention time, short-circuiting, headloss, inlet/outlet structures, and inter¬ nal and surface configurations can significantly impact wetland effluent quality. 4.6.1.4 Multiple cells It has been shown in both the design of oxidation ponds and FWS constructed wetlands, that a number of cells in series can consistently produce a higher quality effluent. This is based upon the hydrodynamic characteristics that constituent mass is gathered at the outlet end of one cell, and redistributed to the inlet of the next cell. This process also minimizes the short circuiting effect of any one unit, and maximizes the contact area in the subsequent cell. For treatment and water quality purposes, it is recom¬ mended that a FWS constructed wetland should consist of a minimum of three cells in series. Open water zones have also been used to redistribute flows, but their value in this regard has been overshadowed by their other at¬ tributes. Large wetland cells can have internal berms running parallel to the flow direction, effectively creating smaller parallel cells with better hydraulic properties. Multiple cells with appropriate piping between them offer greater opera¬ tional flexibility. In the event that a wetland cell needs to be taken off line for maintenance reasons, the remaining cell or cells can remain operational. This is made even more important if cells are sized to coincide with zoning. Com¬ pletely vegetated and completely open cells are easier to maintain and are more flexible when sequencing or inde¬ pendent cell HRT adjustments or maintenance is required. 78 4.6.2 Internal Wetland Components 4.6.2.1 Open water/Vegetation ratio The location of emergent vegetation, the type and den¬ sity of this vegetation, and the climate as it relates to plant senescence are important factors in the design of a FWS constructed wetland. Providing adequate open water ar¬ eas is an important, but often overlooked, component in the design and implementation of FWS constructed wet¬ lands (Gearheart, 1986; Hammer, 1996; Hamilton, 1994, Stefan et a!., 1995). Open water is defined as a wetland surface which is not populated by emergent vegetation communities, but may contain submergent aquatic plants as well as unconsolidated groupings of floating aquatic plants. Historically, many FWS constructed wetlands were designed and built as fully vegetated basins with no desig¬ nated open water areas. Many of these systems proved problematic with very low or no water column dissolved oxygen, that resulted in odor production and vector prob¬ lems. Natural wetlands generally contain a mix of open water and emergent vegetation areas. The open water areas provide many functions such as oxygenation of the water column from atmospheric reaeration, submerged macro¬ phytes, and algal photosynthesis. They also permit preda¬ tion of mosquito larvae by fish and other animals and pro¬ vide habitat and feeding areas for waterfowl. Open water areas in FWS constructed wetlands will not only provide the same functions as for natural wetlands, but will also provide the opportunity for increased soluble BOD reduc¬ tion and nitrification of wastewater because of the increase in oxygen levels. It is recommended that a FWS constructed wetland not be fully vegetated, but should include some open water areas. Open water areas in a FWS constructed wetland will result in a more complex, dynamic, and self- sustaining wetland ecosystem, that better mimics a natu¬ ral wetland. Open water wetlands have lower background BOD than fully vegetated wetlands (see Table 4-4), which reflects their improved treatment potential. The ratio of open water to emergent vegetation depends on land availability, costs, and the function and goals of the FWS constructed wetland system. Generally speak¬ ing zones 1 and 3 should be 100% vegetated with the zone 2 surface having > 50% to 100% open water. If denitrifica¬ tion is required, the 3rd zone which is 100% vegetated will accomplish it.. The open-water zones with an HRT in ex¬ cess of 3 days may invite algal blooms. As long as this zone is followed by a fully vegetated zone with an HRT of 2 or more days, this should not represent a problem be¬ yond increased biomass management requirements. The most effective method used for creating open water areas in a single cell is to excavate a zone that is deep enough to prevent emergent vegetation colonization and migration. Some have periodically raised water levels to a depth that limits emergent vegetation growth, but this is operationally demanding and may have negative treatment impacts. The type of dominant macrophyte (i.e., emer¬ gent or submergent) can be controlled by controlling the operating depth. Water column depths greater than ap¬ proximately 1.25 to 1.5 meters planted with submergents such as Potomogeton spp., will not rapidly be encroached upon by emergent macrophytes like bulrushes reeds, and cattails. If the water column depth is between 0.5 to 1.0 meters and planted with emergent vegetation, such as bulrush and cattails, they will prevail over submergents and most other emergents by filling in the surface area through rhizome and tuber propagation. The seasonal change in water levels (hydroperiod) is also a determinant in establishing various aquatic macrophyte communities. Due to the lack of shading, significant blooms of algae can occur in large open water areas, which can have nega¬ tive effects on effluent quality. To help minimize the poten¬ tial for algal growth, open water areas should be designed for less than 2 to 3 days hydraulic retention time. In gen¬ eral, the growth cycle of algae is approximately 7 days, so providing open water areas with less than 2-3 days reten¬ tion time will help minimize algal growth in the open-water zone of the wetland. Sufficient standing crops of submergent macrophytes may also limit algal regrowth in these zones. Conversely, excessive algal growth may im¬ pair the performance of the submergent macrophytes by limiting the solar energy which reaches them. Guidelines for designing a FWS constructed wetland in terms of vegetated covering are as follows: Begin with an emergent vegetation zone covering the volume used in the first 2 days of retention time at maximum monthly flow (Q max ) to provide for influent solids flocculation and sepa¬ ration.. The emergent zone should be followed by an open water zone covering days 3 and 4 in the retention time sequence at Q max . The open water zone should be designed to facilitate production of dissolved oxygen to meet CBOD and NBOD demands. The final 2 days of hydraulic reten¬ tion volume at Q max should be an emergent wetland to reduce any solids (algae, bacteria, etc.) generated in the open water and to supply carbon (decomposing plant ma¬ terial) and anoxic conditions for denitrification. It is also recommended that this final stand of emergent vegetation be as close as possible to the outlet of a FWS constructed wetland. This provides a final level of protection just be¬ fore the effluent leaves the wetland to minimize the impact of wildlife on effluent quality. This recommendation may heighten the maintenance requirements for the outlet de¬ vice, but it will result in less variability in the effluent qual¬ ity. 4.6.2.2 Inlet Settling Zone Depending on the pretreatment process, a substantial portion of the incoming settleable and suspended solids may be removed by discrete settling in the inlet region of a FWS constructed wetland. For example, if the FWS sys¬ tem is to follow an existing treatment facility which is prone to produce high concentrations of settleable TSS, an inlet settling zone should be used. If the pretreatment facility does a good job of solids capture, but has a high concen¬ tration of soluble constituents, an inlet settling zone is of 79 no value. Given that FWS systems are generally preceded by lagoon systems which seasonally produce large TSS concentrations, primarily due to algal mass, the need for an inlet settling zone would be marginal since algal solids will require flocculation and sunlight restriction before be¬ coming settleable. If an inlet settling zone should be desired, it should be constructed across the entire width of the wetland inlet. A recommended guideline is to design a settling zone which provides approximately 1 day hydraulic retention time at the average wastewater flow rate, as most settleable and suspended solids are removed within this time period. The settling zone should be deep enough to provide adequate accumulation and storage of settled solids, but shallow enough to allow the growth of emergent vegetation, such as bulrush and cattails. Recommended depth is approxi¬ mately 1 meter. Most accumulated organic solids will slowly decay and reduce in volume. This decay is one of the two major sources of internal loading and background constituents in the effluent. However, at some time in the future the remaining accumulated solids will need to be removed from the settling zone. 4.6.2.3 Inlet/Outlet Structures Placement and type of inlet and outlet control structures are critical in FWS constructed wetlands to ensure treat¬ ment effectiveness and reliability. To effectively minimize short-circuiting in a FWS constructed wetland, two goals concerning cell inlet/outlet structures are critical: (1) uni¬ form distribution of inflow across the entire width of the wetland inlet, and (2) uniform collection of effluent across the total wetland outlet width. Both of these should mini¬ mize localized velocities, thus reducing potential resuspension of settled solids. It is important that any out¬ let structure be designed so that the wetland can be com¬ pletely drained, if required. Some of the common types of wetland inlet/outlet systems in use today, and general guidelines regarding their design are further discussed in Chapter 6. Depending on the type of wastewater influent, the inlet structure discharge point could be located below or above the wetland water surface. Perforated pipe inlet/outlet struc¬ tures can be difficult to operate and maintain when they are fully submerged. All inlet distribution systems should be accessible for cleaning and inspection by using cleanouts. Outlet structures represent an operational control fea¬ ture that directly affect wetland effluent quality. It is impor¬ tant that outlet structures facilitate a wide range of operat¬ ing depths. By adjusting the outlet structure, both the wa¬ ter depth and hydraulic retention time can be increased or decreased. This and the need to accommodate cell drain¬ age usually results in locating the outlet manifold at the bottom of the outlet zone. The differences in water quality between water depths can also be highly variable. An outlet structure design which allows for maximum flexibility of collection depths may be desirable, but may not always be compatible with collection devices that minimize short- circuiting. With this type of design, the outlet structure can be adjusted to draw wetland effluent from the water depth with the best water quality. This alternative design usually involves multiple drop boxes with openings at different depths. In most cases however the uniform collector set at the bottom is favored owing to its inherent advantages in terms of improved effluent quality and facilitation of cell drainage. Two types of inlet/outlet structures are commonly used in FWS constructed wetlands. For small or narrow (high AR) wetlands, perforated PVC pipe can be used for both inlet and outlet structures. The length of pipe should be approximately equal to the wetland width, with uniform perforations (orifices) drilled along the pipe. The size of the pipes, and size and spacing of the orifices will depend on the wastewater flow rate and the hydraulics of the inlet/ outlet structures. It is important that the orifices be large enough to minimize clogging with solids. Perforated pipes can be connected to a manifold system by a flexible tee joint, which allows the pipes to be adjusted up or down. In some cases wetland designers with this type of inlet/outlet structure will cover the perforated pipes with gravel to pro¬ vide more uniform distribution or collection of flows. This type of inlet/outlet structure requires periodic inspection, some operation and maintenance to maintain equal flow through the pipe, and access at the end to clean clogged orifices. For larger wetland systems, multiple weirs or drop boxes are generally used for inlet and outlet structures. Weirs or drop boxes are generally constructed of concrete, but smaller PVC boxes are also available. These structures should be located no further apart than every 15 m (center to center) across the wetland inlet width, with a preferred spacing of 5 to 10 m. The same spacing requirements apply for the outlet weirs or drop boxes. Depending on the source of the wastewater influent, the inlet weirs or drop boxes can be connected by a common manifold pipe. Whatever the configuration, it is important that the manifold pipes and weirs be hydraulically analyzed to attain reasonably uniform distribution. Simple weir or drop box type inlet struc¬ tures are relatively easy to operate and maintain. Weir overflow rates have not been considered in the design of most wetlands. Weir loading rates of existing wetlands are significantly higher than those required in most biological solids removal processes (i.e., 120 to 190 m 3 /m.d ) (WEF, 1998). Excess weir rates can cause high water velocities near the outlet which could entrain solids which would otherwise be removed from the effluent. Therefore, weir loading rates should be designed to meet the above range for best performance until more quantita¬ tive data are generated. 4.6.2.4 Baffles Baffles are internal structures installed either perpen¬ dicular or parallel to the direction of flow. Baffles can be 80 ids, effective in reducing short-circuiting, for mixing waters of different depths, and for improved flocculation performance. Properly designed and placed open water zones can also act as baffles by allowing mixing and redistribution of waste- water before it enters into the next wetland vegetated zone. The use of baffles depends on cell configurations, aspect ratios, treatment goals, and permit compliance. In general, except for special circumstances unforseen in typical mu¬ nicipal wastewater treatment application the use of such structures is not recommended. However, their use in cor¬ recting problems which are due to hydraulic flow difficul¬ ties (short circuiting, dead zones, etc.) make them useful to the operator-owner. 4.6.2.5 Recirculation Recirculation is the process of introducing treated efflu¬ ent back to the inlet or to some other internal location of the wetland. Recycling effluent can decrease influent con¬ stituent concentrations and increase dissolved oxygen concentrations near the inlet. The increased dissolved oxygen concentrations can help reduce inlet odors, lower BOD, and enhance nitrification potential in open-water zones. If recirculation is to be considered, the effects of recirculation on the wetland water balance and wetland hydraulics need to be analyzed. In general, the ability to recycle, like the ability to drain each cell, could be consid¬ ered part of the need to have flexible piping , multiple cells, and multiple trains of cells. The value of recirculation has not been shown to date to be a major factor in improving FWS performance. 4.6.2. 6 Flow Measuring Devices Many existing wetland systems do not have accurate flow measuring devices. Even if accurate estimates of in¬ flows and/or outflows to the treatment plant are known, internal flow distribution to individual wetland cells is not known or measured. Without accurate flow measurements to individual wetland cells, it is impossible to determine internal flow rates, average velocities, and hydraulic re¬ tention times for each cell, thus making system perfor¬ mance adjustments difficult. It is recommended that some type of flow measuring device be either installed in or avail¬ able to be installed in each cell of a FWS constructed wet¬ land. This includes separate flow measuring devices on each inlet for multiple wetland cell configurations. Some examples of flow measuring devices include simple 90 g V- notch or rectangular weirs, and more sophisticated Parshall flumes for larger systems. Depending on the size and lay¬ out of the wetland, cell inlet/outlet structures should be designed to be compatible with available flow measuring devices. 4.6.3 Pretreatment Requirements Examples of treatment that should precede FWS con¬ structed wetlands include all types of stabilization ponds and primary sedimentation systems. The use of wetlands to polish secondary effluent to less than 10 mg/I BOD and TSS has been documented, but is not covered in detail here. The reader is directed to USEPA (1999) for guid¬ ance in these applications. The effluent entering a FWS constructed wetland should be free from floatable and large settleable solids, and excessive levels of oil and grease. Also important to a FWS constructed wetland is the in¬ coming metal concentrations. While a FWS constructed wetland does remove and immobilize many heavy metals along with the TSS, excessive influent concentrations could result in residuals which are unacceptable for subsequent land application. A source reduction program and/or an industrial waste pretreatment ordinance are required if excessive metals concentrations are present in the raw wastewater. 4.7 Construction/Civil Engineering Issues Specific construction/civil engineering design issues that should be considered early in the planning and design phase of a FWS constructed wetland project include site topography and soils, berm construction, impermeable liner materials, wetland vegetation substrate, and internal drain¬ age. Many of these issues should be considered during the site selection process, as they may become difficult or costly to correct later in the actual design and construction phases of the project. The construction/civil engineering requirements for a FWS constructed wetland are similar to other earthen water quality management systems such as oxidation ponds, and are discussed in Chapter 6 and in USEPA (1983) and Middlebrooks, et al (1982). 4.7.1 Site Topography and Soils In general, level land with clay soils affords the optimal physical setting for a FWS constructed wetland. Potential wetland sites with other physical conditions can be used, but may require more substantial engineering, earthwork, construction requirements, and liners. In order to overcome site limitations, the cost of a FWS constructed wetland will also increase proportionally as the wetland site further deviates from optimal site conditions. FWS constructed wetlands can be built on sites with a wide range of topographic relief. Construction costs are lower for flat sites since sloped sites require more grading and berm construction. Site topography will generally dic¬ tate the basic shape and configuration of the FWS con¬ structed wetland. The principal soil considerations in siting and implement¬ ing a FWS constructed wetland are the infiltration capacity of the soils and their suitability as berm material and wet¬ land vegetation substrate. In most cases FWS constructed wetlands are required to meet stringent infiltration restric¬ tions depending on the state regulations for groundwater protection. An exception are wetland systems designed to incorporate infiltration as part of the treatment and dis¬ charge process. In these cases, the underlying soil must have infiltration rates compatible with the design discharge rates. If native site soils are not suitable, separate infiltra¬ tion trenches can be added to increase the infiltration sur¬ face area. In some cases, it will be necessary to import berm and/or bottom materials or use synthetic liners (see Chapter 6) to prevent infiltration. 81 Interior berms containing FWS wetland cells should be built with up to 3:1 side slopes as the soil characteristics allow. A minimum freeboard of 0.6 m above the peak flow operating depth in the wetland is required. For wetlands that will receive exceptionally high peak inflows, additional freeboard may be required to ensure that berm overtop¬ ping does not occur. Additional freeboard may also be de¬ signed to accommodate long-term solids and peat buildup during the operation of the wetland, and to allow appropri¬ ate water depths to be maintained as sludge builds up in the initial cells over time. All FWS-cell external berms should have a minimum top width of 3 m, which provides an adequate road width for most standard service vehicles. In some cases, internal berms can have smaller top widths, as routine operation and maintenance can be carried out by small motorized vehicles, such as ATVs. Road surfaces should be an all weather type, preferably gravel, which also minimizes di¬ rect runoff into the wetland. Berm integrity is critical to the long term operational ef¬ fectiveness of FWS constructed wetlands. Common berm failure causes include burrowing by mammals, such as beaver nutria and muskrat, and holes from root penetra¬ tion by trees and other vegetation growing on or near the berms. Several design features can eliminate and/or mini¬ mize these problems. A thin impermeable wall, or internal layer of gravel, can be installed during construction, which will minimize mammal burrowing and/or root penetration. Planting the berm using vegetation with a shallow root sys¬ tem can also be effective. Unlike oxidation ponds, berm erosion in fully vegetated zones and/or cells from wave action is generally not a concern due to the dampening effect of the wetland vegetation. However, in larger cells with open zones it could be an issue, and stabilization pond texts should be consulted for solutions (Middlebrooks, et al, 1982)(USEPA, 1983). In the design and site selection process, an important consideration is the amount of additional area required for berms. In general, the higher the aspect ratio for a FWS constructed wetland, the more area that will be required for the berms and for the entire wetland system. This in¬ crease in required total wetland area to accommodate berms is more pronounced for smaller wetlands than for larger wetlands. A factor of 1.2 to 1.4 times the cell area is usually employed to determine the total site area for the FWS system. 4.7.2 Impermeable Liner Materials A concern with FWS constructed wetlands is the poten¬ tial loss of water from infiltration and contamination of groundwater below the wetland site. While there are some wetland applications where infiltration is desirable, the majority of the applications require some type of barrier to prevent groundwater contamination. Under ideal condi¬ tions, the wetland site will consist of natural soils with low permeability that restrict infiltration. However, many wet¬ lands have been constructed on sites where soils have high permeability. In these cases, some type of liner or barrier will likely be required to minimize infiltration. Liner requirements can also add significantly to the construction cost of a FWS constructed wetland. Existing natural soils with permeability less then approxi¬ mately 10~ 6 cm/s are generally adequate as an infiltration barrier. For site soils with higher permeabilities, some type of liner material will likely be required. Some examples of wetland liner materials include imported clay fill, bentonite soil layers, chemical treatment of existing soils, asphalt, and synthetic membrane liners such as PVC or HDPE. In some instances, it will be possible to compact the existing site soils to acceptable permeability. Due to their ability to be placed in shaped wetland cells, clay liners are gener¬ ally a more sustainable component of the wetland than synthetic membrane liners. Whatever liner material is cho¬ sen, an important consideration is to provide adequate soil cover and depth that protects the liner from incidental dam¬ age and root penetration from the wetland vegetation (see Chapter 6). 4.7.3 Soil Substrates for Plants Aquatic macrophytes generally reproduce asexually by tuber runners. Soils with high humic and sand components are easier for the tubers and runners to migrate through, and plant colonization and growth is more rapid. The soil substrate for wetland vegetation should be agronomic in nature (e.g. loam), well loosened, and at least 150 mm (6 inches) deep. Depending on the liner material, deeper soil substrates may be required to protect the liner. If this type of soil layer exists at the site, it should be saved. After the wetland basin, berms and other earthen structures are constructed, and the liner is installed (if required), the origi¬ nal soil substrate can be placed back into the excavated region. To meet soil specifications, it may be necessary to amend the saved soils with other materials. While soils such as loam and silt are good for plant growth, they can allow large vegetation mats to float when large water level fluctuations occur in the wetland. Float¬ ing vegetation mats can significantly alter the treatment capabilities of FWS constructed wetlands by allowing wastewater to flow between the floating mats and substrate, not in contact with any vegetation treatment media. To cir¬ cumvent this potential problem, denser soil substrates such as a sandy loam, or a loam gravel mix can be used. This will be more important in FWS constructed wetlands where large water depth fluctuations will be part of the operation and maintenance procedure. 4.7.4 Internal Drainage and Flexible Piping In the event a FWS constructed wetland needs to be drained, the wetland bottom should have a slope of 1% or less. Drainage may be required for maintenance reasons such as liner repair, sludge removal, vegetation manage¬ ment, and berm repair. Deeper channels may be employed to allow for drainage and/or continued use when serial cells are taken out of service. Channels can also be used to 82 connect deeper open water areas where these are part of a larger cell, rather than separate cells. In general the more complete the intercellular piping, the greater the opera¬ tional flexibility is for the entire system. 4.8 Summary of Design Recommendations A summary of the design recommendations for FWS wetland treatment systems is presented in Table 4-7. As more quality-assured data become available allowable pollutant areal loadings will likely be revised. Table 4-7. Recommended Design Criteria for FWS Constructed Wetlands Parameter Design Criteria Effluent Quality BOD < 20 or 30 mg/L TSS < 20 or 30 mg/L Pretreatment Oxidation Ponds (lagoons) Design Flows Q max (maximum monthly flow) and Q™ (average flow) Maximum BOD Loading (to entire system) to Meet: 20 mg/L: 45 kg/ha-d 30 mg/L: 60 kg/ha-d Maximum TSS Loading (to entire system) to Meet: 20 mg/L: 30 kg/ha-d 30 mg/L: 50 kg/ha-d Water Depth 0.6 - 0.9 m Fully vegetated zones 1.2-1,5m Open-water zones 1.0m Inlet settling zone (optional) Minimum HRT (at Qmax) in Zone 1 (and 3) 2 days fully vegetated zone Maximum HRT (at Qave) in Zone 2 2 - 3 days open-water zone (climate dependent) Minimum Number of Cells 3 in each train Minimum Number of Trains 2 (unless very small) Basin Geometry (Aspect Ratio) Optimum 3:1 to 5:1, but subject to site limitations AR > 10:1 may need to calculate backwater curves Inlet Settling Zone Use Where pretreatment fails to retain settleable particulates Inlet Outlet Uniform distribution across cell inlet zone Uniform collection across cell outlet zone Outlet Weir Loading <200 m3/m-d Vegetation Emergent - Typha or Scirpus (native species preferred) Submerged - Potamogeton, Elodea, etc (see chapter 2). Table 4-7. Continued Parameter Design Criteria Design Porosities 0.65 for dense emergents in fully vegetated zones 0.75 for less dense stand of emergents in same zones 1.0 for open-water zones Cell Hydraulics Each cell should be completely drainable Flexible intercell piping to allow for required maintenance Independent, single-function cells could maximize treatment 4.9 References Balmer, P. and B.Vik.. 1978. “Domestic Wastewater Treat¬ ment with Oxidation Ponds in Combination with Chemi¬ cal Precipitation,“ Prog. Water Tech, Vol 10, No. 5-6, pp867-880. Carre, J., M. P. Loigre, and M. Leages 1990. “Sludge Re¬ moval from Some Wastewater Stabilization Ponds.” Water Science Technology, Vol 22, No 3-4, pp 247- 252. Cole, S. 1988. "The Emergence of Treatment Wetlands". ES&T. Vol 3, No. 5, pp. 218-223. Crites, R.W., and G. Tchobanoglous. 1998. “Small and De¬ centralized Wastewater Management Systems, WCB - McGraw-Hill, NY. Dombeck, G. 1998. Sacramento Regional Wastewater Treatment Plant Demonstration Wetland Project. 1997 Annual Report, Nolte and Associates, Sacramento, Ca. Frankenbach, R.l and J.S Meyer. 1999. Nitrogen Removal in A Surface Flow Wetland Wastewater Treatment Wet¬ lands, 1999, Wetlands, Volume la, No. 2, June 1999 pp.403-412. Gearheart, R.A., and B. Finney. 1999. “The Use of Free Surface Constructed Wetlands as An Alternative Pro¬ cess Treatment Train to Meet Unrestricted Water Rec¬ lamation Standards”, Wat. Sci. Tech. Vol. 40, No. 4-5, pp. 375-382. Gearheart, R.A., B. A. Finney, M. Lang, and J. Anderson. 1998. “A Comparison of System Planning, Design and Sizing Methodologies for Free Water Surface Con¬ structed Wetlands”. 6th International Conference on Wetland Systems for Water Pollution Control. Gearheart, R.A. and B. A. Finney. 1996. Criteria for De¬ sign of Free Surface Constructed wetlands Based Upon a Coupled Ecological and Water Quality Model. Presented at the Fifth International Conference on Wetland Systems for Water Pollution Control, Vienna, Austria. 83 Gearheart, R. A. 1995. Watersheds - Wetlands - Wastewa¬ ter Management. In Natural and Constructed Wetlands for Wastewater Treatment. Ramadori, R., L. Cingolani, and L. Cameroni, eds., Perugia, Italy, pp 19-37. Gearheart, R. A. 1993. “Phosphorus Removal in Constructed Wetlands”. Presented at the 66th WEF Conference and Exposition, Anaheim, Ca. Gearheart, R.A. 1992. Use of Constructed Wetlands to Treat Domestic Wastewater, City of Areata, California”, Wat. Sci. Tech., Vol. 26, No. 7-8, pp. 1625-1637. Gearheart, R.A., F. Klopp, and G. Allen. 1989. Constructed Free Surface Wetlands to Treat and Receive Wastewa¬ ter Pilot Project to Full Scale, In D.A. Hammer (ed.) Con¬ structed Wetlands for Wastewater Treatment, pp. 121- 137, Lewis Publisher, Inc., Chelsea, Ml Gearheart, R.A., B. A. Finney, S. Wilbur, J. Williams, and D. Hall. 1984. ‘The Use of Wetland Treatment Processes in Water Reuse”, Future of Water Reuse, Volume 2, Pro¬ ceedings of Symposium III Water Reuse, AWWA Re¬ search Foundation, pp. 617-638. Gearheart, R.A., S. Wilbur, J. Williams, D. Hull, B. A. Finney, and S. Sundberg. 1983. City of Areata Marsh Pilot Project: effluent quality results-system design and man¬ agement. Final report. Project No. C-06-2270, State Water Resources Control Board, Sacramento, CA. Gregg, J., and A. Horne. 1993. "Short-term Distribution and Fate of Trace Metals in a Constructed Wetland Receiv¬ ing Treated Municipal Wastewater", Environmental En¬ gineering and Health Sciences Laboratory Report No. 93-4. University of California, Berkeley, CA. Hammer, D, 1992,"Creating Freshwater Wetlands", Lewis Publishers, Chelsea, Ml Hannah, S.A, B.M. Austern, A.E. Eralp, and R.H. Wise, 1986. Journal WPCF, Vol 55, No 1, pp 27-34. Hovorka, R.B. 1961. An Asymmetric Residence-time Distri¬ bution Model for Flow Systems, Dissertation, Case In¬ stitute of Technology. Kadlec. R.H. 2000. The Inadequecy of First-Order Treatment Wetland Models. Ecological Engineering, vol. 15, pp 105- 109; Kadlec, R.H. and R.L. Knight. 1996. Treatment Wetlands. Boca Raton, FL: Lewis-CRC Press. Kadlecik, L. 1996. Organic Content of Wetland Soils, Areata Enhancement Marsh, Special Project, ERE Department Wetland Workshop. Levine, A. D., G. Tchobanoglous and T. Asano, 1991. Size Distributions of Particulate Contaminants in Wastewa¬ ter and Their Impact on Treatability. Water Research, Vol. 25, No 8, pp. 911-922. Linsley, R.K. Jr., M.A. Kohler, and J.L.H. Paulhus, 1982. Hydrology for Engineers, 3rd Ed., McGraw-Hill, NY. Mara, D.D. 1975 Proposed Design for Oxidation Ponds in Hot climates. Journal ASCE-EE, Vol.101, No 2, pp 296- 300. Marais, C. V. R., and V. A. Shaw. 1961. A Rational Theory for the Design of Sewage Stabilization Ponds in Central and South Africa. Transactions South African Institute of Civil Engineers, Vol. 3, pp. 205ff. Middlebrooks, E. J., C. E. Middlebrooks, T. H. Reynolds, G.Z. Watters, S.C. Reed, and D.B.George. 1982. Wastewa¬ ter Stabilization Lagoon Design, Performance and Up¬ grading, MacMillen, New York, NY. Mitsch, W.J. and J.G. Gosselink.1993. Wetlands. Van Nostrand Reinhold, NY. NADB (North American Treatment Wetland Database). 1993. Electronic database created by R. Knight, R. Ruble, R. Kadlec, and S. Reed for the U.S. Environmental Protec¬ tion Agency. Cincinnati, OH. Odegaard, H. 1987. Particle Separation in Wastewater Treat¬ ment. In Proceedings EWPCA 7th European Sewage and Refuse Symposium, pp. 351-400. Reckhow, K., and S. S. Qian. 1994. Modeling Phosphorus Trapping in Wetlands Using General Models. Water Resources Research, Vol. 30, No. 11, pp. 3105-3114. Reddy, K. R., and W.R. De Busk. 1987. Nutrient Storage Capabilities of Aquatic and Wetland Plants for Water Treatment and Resource Recovery. Magnolia Pub., Inc., Orlando, FL. Reed, S. C., R. Crites, and E. J. Middlebrooks, 1995 ."Natu¬ ral Systems for Waste Management and Treatment, McGraw-Hill, San Francisco, Ca. Reed, S.C., R.W. Crites, and E.J. Middlebrooks. 1995. Natu¬ ral Systems for Waste Management and Treatment. 2nd Ed., McGraw-Hill, NY. Sartoris, J., J. Thullen, L. Barber, and D. Salas. 1999. Inves¬ tigation of Nitrogen Transformations in a Southern Cali¬ fornia Constructed Wastewater Treatment Wetland, Eco¬ logical Engineering, Vol 14, pp. 49-65. SCRSD. 1998. Constructed Wetlands Demonstration Project. 1997 Annual Report, Sacramento, CA. Sparham, V.R. 1970. “Improved Settling Tank Efficiency by Upward Flow Clarification,” JWPCF, Vo. 42, No 5, pp 801-811. Tchobanoglous, G., R. W. Crites, R.A. Gearheart, and S. C. Reed. 2000. A Review of Treatment Kinetics for Con¬ structed Wetlands. Presented to WEF Specialty Con¬ ference Disinfection, 2000. New Orleans, LA. 84 Tchobanoglous, G., F. Meitski, K. Thompson and T.H. Chadwick. 1989. Evolution and Performance of City of San Diego Pilot-Scale Aquatic Wastewa¬ ter Treatment System Using Water Hyacinths. Research Journal WPCF, Vol 61, No. 11-12, pp 1625-1655. Tchobanoglous, G. and E. D. Schroeder. 1985. Wa¬ ter Quality: Characteristics, Modeling, Modifica¬ tion. Addison-Wesley, Reading, MA. United Kingdom, Dept, of Environment. 1973. Treat¬ ment of Secondary Sewage Effluent in Lagoons. Notes on Water Pollution #63. London, U.K. United States Environmental Protection Agency. 1999. FWS Wetlands for Wastewater Treatment: A Technology Assessment. EPA 832/R-99/002. Office of Water, Washington, DC. U.S. Environmental Protection Agency. 1988. Design Manual. Constructed Wetlands and Aquatic Plant Systems for Municipal Wastewater Treatment. EPA/625/1 -88/022. Cincinnati, OH. U.S. Environmental Protection Agency, 1983. Design Manual - Municipal Wastewater Stabilization Ponds. EPA/625/1-83-015. Cincinnati, OH. U.S. Environmental Protection Agency, 1993. Manual: Nitrogen Control. USEPA Publication No. EPA/625/R-93/010. Cincinnati, OH. Water Environment Federation, 1998. Design of Mu¬ nicipal Wastewater Treatment Plants, 4th Ed, MOP#8. Alexandria, VA. Water Environment Federation, 1990. Natural Sys¬ tems for Wastewater Treatment. MOP FD-16, Al¬ exandria, VA. 85 Chapter 5 Vegetated Submerged Bed Systems 5.1 Introduction The pollutant removal performance of vegetated sub¬ merged bed (VSB) systems depends on many factors in¬ cluding influent wastewater quality, hydraulic and pollut¬ ant loading, climate, and the physical characteristics of the system. The main advantage of a VSB system over a free water surface (FWS) wetland system is the isolation of the wastewater from vectors, animals and humans. Concerns with mosquitoes and pathogen transmission are greatly reduced with a VSB system. Properly designed and oper¬ ated VSB systems may not need to be fenced off or other¬ wise isolated from people and animals. Comparing con¬ ventional VSB systems to FWS systems of the same size, VSB systems typically cost more to construct, primarily because of the cost of media (Reed et al., 1985). Because of costs, it is likely that the use of the conventional VSB systems covered in this manual will be limited to individual homes, small communities, and small commercial opera¬ tions where mosquito control is important and isolation fenc¬ ing would not be practical or desirable. A conventional VSB system is described in Chapter 2 and depicted in Figure 2-3. The typical components in¬ clude (1) inlet piping, (2) a clay or synthetic membrane lined basin, (3) loose media filling the basin, (4) wetland vegetation planted in the media, and (5) outlet piping with a water level control system. The vast majority of VSB sys¬ tems have used continuous and saturated horizontal flow, but several systems in Europe have used vertical flow. Alternative VSB systems are defined here as VSBs that have been modified to improve their treatment performance (George et al., 2000, Young et al., 2000, Behrends et al., 1996). Typical modifications involve some type of cyclic filling and draining of the system to improve the oxygen input into the media. The potential improvement in perfor¬ mance with alternative VSB systems is offset to some de¬ gree by a more complex and expensive operating system. It is too early to predict whether alternative VSB designs will prove to be more cost effective or practical than con¬ ventional VSB systems, although they appear to provide significantly better removal of certain pollutants. This chapter will discuss VSB systems that treat (1) septic tank and primary sedimentation effluents, (2) pond efflu¬ ents, and (3) secondary and non-algal pond effluents. The most common VSB systems in the U.S. treat septic tank and pond effluents for BOD and TSS removal. In Europe, VSB systems are most often used to treat septic tank ef¬ fluents, although they have also been used extensively in the U.K. for polishing activated sludge and RBC effluents, and for treating combined sewer bypass flows (Cooper, 1990, Green and Upton, 1994). This chapter provides a summary of the theoretical and practical considerations in the design of conventional VSB systems. VSB systems, like other natural treatment sys¬ tems, are less understood than highly-engineered waste treatment systems because they (1) have more variable, complex, and less controllable flow patterns, (2) have re¬ action rates and sites within the system that vary with time and location, and (3) are subject to the inconsistencies of climate and growth patterns. This complexity makes the development and use of design equations based on ideal¬ ized reactor and reaction kinetic theory difficult, if not im¬ practical and unrealistic. Furthermore, because pollutant removal performance can be quite variable, designs must be conservative if a guaranteed effluent quality is required. 5.2 Theoretical Considerations 5.2.1 Potential Value of Wetland Plants in VSB Systems In several recent studies that have compared the pollut¬ ant removal performance of planted and unplanted VSB systems, it has been found that plants do not have a major impact on performance (Young et al, 2000, George et al., 2000, Liehr et al., 2000). There is however significant cost and time associated with the establishment and mainte¬ nance of the wetland plants in a VSB system. Neverthe¬ less, planted systems have a significant aesthetic advan¬ tage over unplanted systems and may be of value as wet¬ land habitat in some cases. Unfortunately, the aesthetic value of plants and the value of VSB wetland systems as wetland habitat are difficult to quantify, and no mitigation credit is given by the USEPA for the habitat value they provide. In the following sections the potential value of wetland plants in VSB systems is discussed in more de¬ tail. 5.2.1.1 Type of Wetland Plants Several studies have attempted to determine if pollutant removal performance differs with various types of wetland 86 plants (Gersberg et al., 1986, Young et al., 2000). Although some researchers have claimed a relationship, these claims have not been substantiated by others (Gersberg et al., 1986). It is not clear if it is desirable to maintain a single plant species, or a prescribed collection of plant species, for any treatment purpose. Single plant (monoculture) systems are more susceptible to catastrophic plant death due to pre¬ dation or disease (George et al., 2000). It is generally as¬ sumed that multiple plant and native plant systems are less susceptible to catastrophic plant death, although no studies have confirmed this assumption. Plant invasion and plant dominance further complicate the issue; in several cases researchers have found that, with time and without operator intervention, one of the planted species or an in¬ vader species has become the dominant species in all or part of the system (Young et al., 2000, Liehr et al., 2000). This occurs less frequently and more slowly in VSB sys¬ tems than in FWS systems. The impact of wetland plants on pollutant removal per¬ formance appears to be minimal based on current knowl¬ edge, so the selection of plants species should be based on aesthetics, impacts on operation, and long-term plant health and viability in a given geographical area. Local wetland plants experts should be consulted when making the selection. 5.2.1.2 Plant Mediated Gas Transfer Wetland plants can facilitate gas transfer both into and out of the wastewater of a VSB system. The focus of most studies has been oxygen transfer into the wastewater. However, methane and other dissolved gases in the waste- water can be transferred out of the wastewater by wetland plants. The mechanisms of plant-mediated gas transfer are described in detail in Chapter 3. The potential amount of oxygen transferred by plant roots into the wastewater depends on many factors including dissolved oxygen con¬ centration in the wastewater, root depth in the wastewater, air and leaf temperatures, and plant growth status (rapid growth vs. senescence). Most studies to determine the rates of plant-mediated oxygen transfer have been per¬ formed in laboratory microcosms or mesocosms under controlled conditions.(George et al., 2000, Liehr, et al., 2000) It is not clear if these results are transferable to full- scale systems. Based on a review of the literature, the likely rate of oxy¬ gen transfer is between zero and 3.0 g-0 2 /m 2 -d (0 - 0.6 lbs/1000 ft 2 -d). While this maximum value is within the BOD loading range of lightly loaded VSB systems, (3 g/m 2 -d = 30 kgBOD/ha-d = 27 lb BOD/ac-d), there is very little evi¬ dence to support the assumption that plants add signifi¬ cant amounts of oxygen to VSB systems. Typical values of dissolved oxygen in VSB systems are very low (<1 .Omg/ L), but because of the difficulty in obtaining an accurate in- situ oxygen reading, the actual values are probably even lower. In VSB systems where oxidation-reduction poten¬ tial (ORP) has been measured, values were typically quite negative, indicating strong reducing conditions. Unplanted systems have been found to perform as well as planted systems in both BOD and ammonia nitrogen removal (George et al., 2000, Liehr et al., 2000, Young, et al., 2000). Furthermore, investigations of root depth and flow pathways have found that the roots do not fully pen¬ etrate to the bottom of the media and there is substantially more flow under the root zone than through it (Young et al., 2000, George et al., 2000, Bavor et al. 1989, Fisher, 1990, DeShon et al., 1995, Sanford et al., 1995a & 1995b, Sanford, 1999, Rash and Liehr, 1999, Breen and Chick, 1995, Bowmer, 1987). The oxygen supply from the roots is also likely to be unreliable due to yearly plant senes¬ cence, plant die-off due to disease and pests, and vari¬ able plant coverage from year to year. Considering all of these factors, it is recommended that designers assume wetland plants provide no significant amounts of oxygen to a VSB system. Plants will also affect the other potential source of oxy¬ gen to VSBs — the direct oxygen transfer from the atmo¬ sphere to the wastewater. Researchers at TVA have esti¬ mated oxygen transfer from the atmosphere to be between 0.50 and 1.0 g-0 2 /m 2 -d (0.1-0.2 lbs/1000 ft 2 -d) (Behrends et al., 1993). Decomposing plant matter on top of the me¬ dia would likely cause even lower rates of oxygen trans¬ port into the wastewater because the plant matter acts as a diffusion barrier and, ultimately, an oxygen demand. 5.2.1.3 Nutrient and Metals Removal by Wetland Plants Wetland plants take up macro-nutrients (such as N and P) and micro-nutrients (including metals) through their roots during active plant growth. At the beginning of plant se¬ nescence most of the nutrients are translocated to the rhi¬ zomes and roots. A significant proportion of the nutrients may also be exuded from the plant (Gearheart et al., 1999). Estimates of net annual nitrogen and phosphorus uptake by emergent wetland species vary from 12 to 120 gN/m 2 -y and 1.8 to 18 gP/m 2 -y respectively (Reddy and DeBusk, 1985). Reeds and bulrush are at the lower end of both ranges while cattails are at the higher end. These esti¬ mates are based on annual growth rates and nutrient con¬ centrations of the whole plant, but since in a VSB system only the shoots can be harvested, the values should be reduced by at least 50%. Plant uptake of metals can also be estimated by this method. To maximize nutrient removal by the plants in a VSB system, shoot harvesting must be done before senescence. Harvesting of wetland plants is not recommended during the growing season because the warm temperatures may cause plant stress, substantial stem death, and significant delay in re-growth in some wetland plants (George, et al., 2000). The expected maximum removal rates of nitrogen, phos¬ phorus and metals by direct plant uptake and harvesting are small compared to typical loadings in VSB systems. Furthermore, nitrogen, phosphorus and metals removal by plant uptake will vary with time. Most of the nutrient up¬ take occurs during rapid plant growth in the spring and summer, and if the plant is not harvested before senes- 87 cence a significant portion of the plant-sequestered nutri¬ ents are released back into the water. Therefore, unless the nutrient removal standards for a VSB system are also variable and synchronous with plant uptake and release, the presence of plants may be more harmful than helpful in meeting nutrient removal standards. Finally, it is unlikely that the nutrients or metals removal obtained by harvest¬ ing are worth the considerable time and labor required to harvest and reuse or dispose of the biomass. 5.2.1.4 Plant-Supplied Carbon Sources for Denitrification Because of the inherent anaerobic conditions associ¬ ated with VSB systems, they are good candidates for deni¬ trification. The likely limiting factor for denitrification in VSB systems is biodegradable organic carbon. The value of plant-supplied organic carbon for denitrification in a VSB system depends on the wastewater COD to nitrogen ratio and the forms of nitrogen in the influent to the system. Plant-supplied organic carbon is most important in VSB systems treating nitrate-rich influents deficient in biode¬ gradable organic carbon such as effluents from nitrifying activated sludge plants. The minimum COD to nitrate-ni¬ trogen ratio for denitrification is 2.3 g-C0D/g-N0 3 -N. Since oxygen is used preferentially over nitrate as the electron acceptor by the microbes that carry out denitrification, the required C0D/N0 3 -N ratio can be significantly higher if any oxygen is present in the system. Decomposing wetland plants and plant root exudates are potential sources of biodegradable organic carbon for denitrification but are also sources of organic nitrogen, which is easily converted to ammonia. Plant root exudates of organic carbon and nitrogen are the largest at the be¬ ginning of senescence. Because of the predominantly anaerobic conditions in VSB systems, decomposition of plant biomass within the media of a VSB system will likely provide more organic carbon (and ammonia) to the waste- water than will decomposition of the plant biomass on top of the media, which takes place in largely aerobic condi¬ tions. Some of the decomposition products of biomass on top of the media (including nitrates) are transported into the wastewater by precipitation infiltration. In one study of a VSB system treating a nitrified second¬ ary effluent, nitrate removal improved from 30% to 80% when mulched biomass including straw, wetland plants, and grass was applied to the top of the media (Gersberg et al., 1983). Another study with a VSB system treating a nitrified landfill leachate found that nitrate removal was lim¬ ited by biodegradable organic carbon (Liehr et al., 2000). 5.2.1.5 Plant Role in Thermal Insulation One potential advantage of a planted over an unplanted VSB system is the role of plants in providing thermal insu¬ lation to the wastewater during cold weather. Dead plant biomass on top of the media helps to limit both convective heat losses from the wastewater and infiltration of melted snow into the wastewater. Two researchers have devel¬ oped methods to estimate the effect of plants in prevent¬ ing heat loss from the wastewater of a VSB system (Reed et al., 1995, Smith et al., 1997). However, it is not clear how important this factor is in pollutant removal perfor¬ mance because 1) it has not been shown that planted VSB systems perform better than unplanted systems, even in winter, and 2) the dead plant material on top of the media also acts as a barrier to oxygen transfer and a potential source of biodegradable carbon and nutrients to the waste- water. 5.2.1.6 Plant Impact on Hydraulic Conductivity (Clogging) and Detention Time Several VSB systems have experienced conditions called “surfacing” where a portion of the wastewater flows on top of the media. Surfacing (1) creates conditions fa¬ vorable for odors and mosquito breeding, (2) creates a potential health hazard for persons and animals that may come into contact with the wastewater, and (3) reduces the hydraulic retention time (HRT) and performance of a VSB system. Surfacing occurs whenever the hydraulic conductivity of the media is not sufficient to transport the desired flow within the usable headloss of the media. The usable headloss is defined by the difference in the eleva¬ tions of the outlet piping and the top of the media. Surfac¬ ing can result from a number of factors including (1) poor design of the system inlet and outlet piping, (2) an inaccu¬ rate estimate of the clean hydraulic conductivity of the media, (3) improper construction, and (4) an inaccurate estimate of the reduction in hydraulic conductivity, or “clog¬ ging”, that will occur due to solids accumulation and/or growth of plant roots. Several researchers have found that clogging was the most severe within the first 1/4 to 1/3 of the system (Young et al., 2000, George et al., 2000, Bavor et al. 1989, Fisher, 1990, Sapkota and Bavor, 1994, Tan¬ ner and Sukias, 1995, Tanner et al., 1998). The hydraulic conductivity was found to be less restricted and fairly uni¬ form over the remaining length of the system. Based on studies in Europe during the 1980s, some re¬ searchers proposed that plant roots significantly increased the hydraulic conductivity in VSBs with soil media by open¬ ing up preferential pathways for the wastewater flow (Kickuth, 1981). Later studies of these systems found that a significant portion of flow occurred on top of the soil (Coo¬ per et al., 1989). Based on recent studies, the presence of plant roots in the gravel media of a VSB system will have a negative effect on hydraulic conductivity (George et al., 2000, Young et al., 2000, DeShon et al., 1995, Sanford et al., 1995a and 1995b, Breen and Chick, 1995). Research¬ ers at TTU compared the reduction in void volume due to root and non-root solids. They estimated that the reduc¬ tion in void volume due to root solids (2 - 8%) was much larger than the reduction in void volume due to non-root solids (0.1 - 0.4%). Even though the overall estimated re¬ duction in void volume was small, there was a 98% reduc¬ tion in hydraulic conductivity. The primary functions of a plant’s roots are to supply water and nutrients and to physically anchor or support the above-ground portions on the plants. Water and nutri- 88 ents will be plentiful at all depths of a VSB, so the plant roots will typically penetrate only 15 - 25 cm (6“ -10") as needed to anchor the plant. In most VSB systems the plant roots do not fully penetrate the entire depth of the media and the reduction in hydraulic conductivity in the root zone results in the creation of “short-circuiting” under the root zone, and more flow through the portion of the media with¬ out roots (Bavor et al., 1989, Fisher, 1990, DeShon et al., 1995, Sanford et al., 1995a and 1995b, Sanford, 1999, Rash and Liehr, 1999, Tanner and Sukias, 1995, Breen and Chick, 1995). This situation may also lead to the cre¬ ation of stagnant zones within the media ("dead volume") which results in lower actual HRTs as the water preferen¬ tially flows through a smaller volume of the media. The decrease in HRT will depend in part on the fraction of the depth that is occupied by the roots; that is, deeper beds will have more a greater proportion of the media that is not impacted by roots. From tracer studies, researchers have found significant differences between actual and theoretical HRTs in their VSB systems and attributed it to dead volume in the upper zone of the media where the majority of the roots grow (Liehr et al., 2000, Young et al., 2000, Bavor et al., 1989, Fisher, 1990, DeShon et al., 1995, Sanford et al., 1995a and 1995b, Breen and Chick, 1995). However, the re¬ searchers at TTU did not find a significant reduction in HRT in three of the cells they studied. (George et al., 2000) The researchers at North Carolina State University (NCSU) attributed part of the dead volume in their sys¬ tems to stratification of the water caused by less dense rain water infiltration ponding within the media on top of higher density leachate. This phenomenon has also been reported by others (DeShon et al., 1995, Sanford et al., 1995a and 1995b, Sanford,1999, Rash and Liehr, 1999). NCSU found that the short-circuiting was greater in an unplanted VSB system than in a planted system. While rain water ponding may be a problem with some VSB sys¬ tems, the effect at NCSU was magnified by the relatively large catchment area (due to the shallow side slopes used in the system) and the salinity of the leachate. The CU researchers performed two sets of tracer studies in the three cells of the Minoa system. The first set was performed in the clean media of each cell before planting. The sec¬ ond set was performed after plant establishment on the one cell that was half planted and half unplanted. From the first study they concluded that there was short circuit¬ ing through the lower media and dead volume resulting in the actual HRTs being only 75% of the theoretical values, even in the clean media. They attributed these results to media compaction during construction and intermixing of the upper pea gravel with the lower larger media. From the second tracer study they concluded that plants roots, which penetrated only half of the media depth, resulted in more short circuiting and dead volume than in the unplanted media. Tanner & Sukias (1995) also reported more accu¬ mulation of solids in the root zone, which further contrib¬ uted to preferential flow around the root zone. 5.2.2 Removal Mechanisms 5.2.2.1 BOD and TSS VSB systems have been used for secondary treatment (i.e. 30 mg/L of BOD and TSS) for a variety of wastewa¬ ters including: primary and septic tank effluents; pond ef¬ fluent; and effluents from activated sludge, RBC, and trick¬ ling filter systems that don’t consistently meet secondary standards. As discussed in Chapter 3, the primary mecha¬ nisms for BOD and TSS removal are flocculation, settling, and filtration of suspended and large colloidal particles. VSB systems are effective for TSS and BOD because of relatively low flow velocities and a high amount of media surface area. They typically do better at TSS removal, be¬ cause TSS removal is a completely physical mechanism, while BOD removal is more complex. Larger biodegrad¬ able particles that have been quickly removed by physical mechanisms will be degraded over time and be converted into particles in the soluble and small colloidal size range. As such they become an internal “source” of BOD as they degrade and reenter the water. Some material is also in¬ corporated into microbial biomass. Some material will accumulate in a VSB, but the amount of long term solids accumulation is unknown. Tanner and Sukias (1995) reported finding less solids accumulation than would be expected based on the load in the influent wastewater. Researchers at Richmond, Australia (Bavor et al., 1989, Fisher, 1990) found that most solids were re¬ moved in the initial section of the VSB and that the “solids accumulation front” stabilized after a year and did not ad¬ vance. These findings support the idea that trapped mate¬ rial will degrade over time. VSB systems treating pond wastewater are likely to accumulate more solids, and be more susceptible to clogging, because TSS in pond waste- water is predominantly algae, which are slightly less bio¬ degradable and degrade more slowly than typical primary or secondary wastewater solids. BOD and TSS in the effluent from a VSB are probably not materials that have passed through the VSB, but rather are converted or internally produced material. As such it is likely to be quite different in size or composition from influ¬ ent BOD and TSS. For example, the influent TSS in the Las Amimas system were predominantly algal cells, but there were almost no algal cells in the effluent even thought the effluent TSS averaged 30 mg/L (Richard & Synder, 1994). True BOD removal only occurs when the material caus¬ ing the BOD is completely converted by anaerobic biologi¬ cal processes to gaseous end products. The two most likely anaerobic pathways are methane fermentation and sul¬ fate reduction. Because methane fermentation is severely inhibited at temperatures below 10°C, sulfate reduction probably predominates for soluble BOD removal during colder months. However, seasonal performance does not vary as much as would be expected based on the typical temperature dependence of biological reactions. A likely explanation, illustrated in Figure 5-1, is that biodegradable particles that are physically removed during colder months 89 BOD (mg/L) TSS (mg/L) Figure 5-1. Seasonal cycle in a VSB 90 are degraded more slowly and accumulate (Kadlec and Knight, 1996). As the temperature warms up the rate of degradation of trapped particles increases, leading to a reduction of accumulated solids and a release of BOD. This theory would explain why summer BOD removal rates, based on influent BOD loading, do not appear to be sig¬ nificantly greater than winter removal rates. The need for insulation of the surface of VSB systems in northern cli¬ mates has been discussed, but the need has not been quantified (Jenssen, etal, 1993). Alternative VSB systems should achieve higher oxygen transfer rates, so BOD removal should improve because aerobic biological processes will become more prevalent. However, microbial biomass production should also in¬ crease, which may lead to increased clogging problems. The potential of alternative VSB systems for TSS and BOD removal is unclear, but performance at Minoa, NY has been very good (Reed and Giarrusso, 1999). 5.2.2.2. Nitrogen Several conventional VSB systems have been designed, built and operated to remove ammonia from various waste- waters. While partial ammonia removal has been achieved in some systems, the removals have been less than pre¬ dicted (George et al., 2000, Liehr et al., 2000, Young et al., 2000). Ammonia can be removed by microbial reactions or plant uptake. Because VSB systems are predominantly anaerobic, microbial removal via nitrification is very lim¬ ited. As discussed in Section 5.2.1.3, plant uptake is also very limited. Very lightly loaded systems have achieved partial ammonia removal (George et al., 2000,1999; Young et al., 2000), but if ammonia removal is required, a sepa¬ rate ammonia removal process should be used in conjunc¬ tion with a VSB system. The predominantly anaerobic condition of VSB systems seems well suited for microbial removal of nitrate via deni¬ trification, but there are relatively few studies to document their use for this specific purpose (Gersberg, et al, 1983; Stengel and Schultz-Hock, 1989). Systems treating well oxidized secondary effluents or other carbon limited waste- waters may have inadequate carbon for denitrification to proceed efficiently (Liehr et al., 2000). Systems treating wastewaters with more carbon, and that have achieved partial nitrification, typically achieve almost complete deni¬ trification (George et al., 2000, Young et al., 2000). Crites and Tchobanoglous (1998) suggest that significant denitri¬ fication of municipal wastewaters can occur in VSB sys¬ tems at a detention time of 2 to 4 days, but Stengel and Schultz-Hock (1989) demonstrated with methanol addition that denitrification was carbon limited. Alternative VSB systems should achieve higher oxygen transfer rates, so they should be more efficient at ammo¬ nia removal via nitrification (George et al., 2000, Reed & Giarusso, 1999, Behrends et al., 1996, May et al., 1990) and less efficient for nitrate removal via denitrification than conventional VSBs. 5.3 Hydrology 5.3.1 Evapotransporation and Precipitation Impacts The avoidance of surfacing is a major design criterion and high amounts of precipitation or snowmelt can increase the flow in a VSB system. In climates with extended peri¬ ods of precipitation or heavy snowmelt, the runoff from the total catchment area that drains into the VSB must be es¬ timated and included in the design flow. Evapotransporation (ET) decreases the hydraulic loading and will not contrib¬ ute to surfacing. Except in very wet climates, flows from precipitation events will probably not adversely affect performance be¬ cause VSB systems have a relatively small surface area (compared to FWS wetlands) and effluent controls should be sufficient to prevent surfacing. Precipitation dilutes pol¬ lutants in the system, temporarily raises the water level, and decreases the HRT, while ET concentrates pollutants, temporarily lowers the water level, and increases the HRT. ET rates will vary depending on plant species and density, but rates from 1.5 to 2 times the pan evaporation rate have been reported in the literature (refs). Except in very wet or dry climates, the two results are probably offsetting, re¬ ducing the overall impact on water level and effluent val¬ ues. Unfortunately, the specific effects of ET and precipi¬ tation on VSB performance are not documented because good estimates of ET and precipitation are hard to obtain, and precise influent and effluent flow measurements are seldom available, even in research systems. 5.3.2 Water Level Estimation An important step in the design process is to estimate the elevation of the water surface throughout the VSB to ensure that surfacing of the wastewater does not occur. As in all gravity flow systems the water level in a VSB sys¬ tem is controlled by the outlet elevation and the hydraulic gradient, or slope, which is the drop in the water level (headloss) over the length from the inlet to the outlet. The relationship between flow through a porous media and the hydraulic gradient is typically described by the general form of Darcy’s Law (Eq. 5.1). This form assumes laminar flow through media finer than coarse gravel, and many authors have modified it for other applications including other me¬ dia and turbulent flow. However, use of the general form without modification is recommended as sufficient to esti¬ mate the water level within a VSB. Q = (K)(A)(S) = (K)(W)(DJ(dh/dL) or, for a defined length of the VSB, (5-1) dh = (Q)(L) / (K)(W)(D w ) (5-2) where Q= flow rate, m 3 /d K = hydraulic conductivity, m 3 /m 2 -d, or m/d A = cross-sectional area normal to wastewater flow, m 2 C = (W)(DJ where W = width of VSB, m D w = water depth, m 91 L = length of VSB, m dh = head loss (change in water level) due to flow re sistance, m S = dh/dL = hydraulic gradient, m/m The water level at the inlet of a VSB will rise to the level required to overcome the head loss in the entire VSB. Therefore, the VSB must be designed to prevent surfac¬ ing. K for an operating VSB varies with time and location within the media and will have a major impact on the head loss. K is very difficult to determine because it is influenced by factors that cannot be easily accounted for, including flow patterns (affected by preferential flow and short cir¬ cuiting), and clogging (affected by changes in root growth/ death and solids accumulation/degradation). Therefore, a value must be assumed for design purposes. Typical val¬ ues for various sizes of rock and gravel are shown in Table 5-1. Several of the references listed in Table 5-1 also noted that K was much less in the initial 1/4 to 1/3 of the VBS than in the remainder of the bed. Based on the studies listed in Table 5-1 and many observed cases of surfacing in VSB systems, the following conservative values are rec¬ ommend for the long-term operating K values: initial 30% of VSB K = 1 % of clean K final 70% of VSB K ( = 10% of clean K. 5.3.3 Hydraulic Retention Time and Contaminant Dispersion The theoretical HRT in any reactor is defined as the liq¬ uid volume of the reactor divided by the flow rate through it. The liquid volume in a VSB system is difficult to accu¬ rately determine because of the loss of pore volume to roots and other accumulated solids, such as recalcitrant biomass and chemical precipitates. The lost pore volume will vary with both location in the VSB and time, both sea¬ sonally and yearly, because of root growth and decay, and solids accumulation and degradation. Preferential flow (see section 5.2.1.6) as illustrated in Figure 5-2 will also have a direct impact on HRT and has not been correlated with changes in pore volume. For design purposes the volume occupied by roots and other solids is assumed to be insig¬ nificant and the theoretical HRT is estimated using the average flow (including precipitation and ET for very wet or dry climates) through the system, the system dimen¬ sions, the operating water level, and the initial (clean) po¬ rosity of the media, which is either estimated or experi¬ mentally determined. The actual HRT has been frequently reported to be 40- 80% less than the theoretical HRT (based on pore vol¬ ume) either due to loss of pore volume, dead volume, or preferential flow (Fisher, 1990, Sanford et al., 1995b, Bhattarai and Griffin, 1998, Batchelor and Loots, 1997, Rash and Liehr, 1999, Tanner and Sukias, 1995, Breen and Chick, 1995, Tanner et al., 1998, Bowmer, 1987). A rough approximation of the liquid volume can be deter¬ mined by measuring the volume of water drained from an operating bed, but water held in small pores or adhering to biomass will remain in the system. Draining will also not be able to account for preferential flow. Tracer studies are recommended as a more realistic measure of the HRT in a VSB system, using one of a variety of tracers (Young et al., 2000, Young et al., 2000, George et al., 2000, Netter Table 5-1. Hydraulic Conductivity Values Reported in the Literature. Size and type' of Media “CleanTDirty” K (m/d) Type of Wastewater (Typical TSS, mg/L) 2 Length of Operation Notes & References 5-10 mm gravel 34,000/12,000 2° effluent (100) 2 years K = 12,000 is for downstream portion (last 80 m) of VSB 5-10 mm gravel 34,000/900 2° effluent (100) 2 years K = 900 is for inlet zone (first 20 m) of VSB Bavor et al (1989), Fisher (1990), Bavor & Schulz (1993) 17 mm creek rock 100,000/44,000 nutrient solution (neg) 4 months neg = negligible TSS 6 mm pea gravel 21,000/9000 nutrient solution (neg) 4 months Macmanus et al (1992), DeShon et al (1995) 30-40 mm coarse gravel NR/1000 2° effluent (30 w/a) 2 years w/a = with algae; pond effluent; gravel bed only- no plants 5-14 mm fine gravel NR/12,000 2° effluent (30 w/a) 2 years coarse gravel is first 6m of bed; fine is last 9 m of bed Sapkota & Bavor (1994) 20-40 mm coarse gravel NR/NR landfill leachate (neg) 26 months for coarse gravel, headloss was controlled by outlet, not K 5 mm pea gravel 6200/600 landfill leachate (neg) 26 months Sanford et al (1995a & 1995b), Sanford (1999), Surface et al (1993) 19 mm rock 120,000/3000 septic tank effluent (50) 7 months George et al (2000) 14 mm fine gravel 15,000/see note aerated pond (60 w/a) 2 years K of combined gravel (fine overlaid coarse) was 22 mm coarse gravel 64,000/see note aerated pond (60 w/a) 2 years 2000 at 50 m from inlet; 27,000 at 300 m from inlet Kadlec & Watson (1993), Watson et al (1990) 'Type as defined in the reference(s) 2 neg = negligible; w/a = with algae 92 Wetland Plants Jntlet _YT"} Outlet 'Zone Intlet Zone 0.6m Not to Scale & Dimensions Are “Typical” Figure 5-2. Preferential Flow in a VSB and Bischofsberger, 1990, Fisher, 1990, Netter 1994, Sanford et al., 1995b, Bhattarai and Griffin, 1998, Bowmer, 1987). Some of the current design equations for VSB systems assume plug flow conditions. However, tracer studies per¬ formed on VSB systems have found significant amounts of dispersion as shown in Figure 5-3 (Sanford et al., 1995b, Bhattarai and Griffin, 1998, Liehr et al., 2000, George et al., 2000). Based on current data it appears that VSB sys¬ tems can not be accurately modeled as either plug flow or complete mix reactors. The simplest model that can pro¬ vide a reasonable fit to the tracer curves is a series of equal volume complete mix reactors. However, while this model may mathematically fit the tracer data, it does not realistically represent physical flow through porous media. Intuitively it would seem that a plug flow reactor with dis¬ persion would most closely represent the actual conditions in a VSB. This model allows greater flexibility in determin¬ ing a fit of the tracer data but typically results in a complex mathematical model of pollutant removal. Estimates of the dispersion number for VSB systems have ranged from 0.050 to 0.31 (George et al., 2000, Bhattarai and Griffin, 1998), with greater numbers for systems with small length- width ratios. Dispersion numbers less than 0.025 are in¬ dicative of near-plug flow conditions while values above 0.20 indicate a high degree of dispersion. The modeling of flow and dispersion is complicated by the non-uniformity of flow and pore volume in space and time as previously discussed, and by other factors including precipitation and ET. At this point in time there appears to be little justification for using complex flow models, because of a lack of data and the unpredictable and constantly varying conditions within a VSB. 5.4 Basis of Design 5.4.1 Introduction Attempting to fully describe pollutant removal in VSB systems is at least as complex as trying to describe VSB hydraulics. Many authors have examined several relation¬ ships as a model for pollutant removal, including zero and first order reactions in both plug flow and complete mix reactor models. None of the relationships were found to reasonably fit of the all data that are available. Further¬ more, data from VSB systems are typified by a wide vari¬ ability, as would be expected of dynamic natural systems that are influenced by many factors. This variability is evi¬ dent in the plots of TSS, BOD, TKN and TP data in this section. Data scatter is not reduced by comparing pollut¬ ant removal with a variety of factors (e.g. area, volume, HRT, percent removals or loading rate), or by normalizing the data (C e /C 0 ). Expected trends, such as temperature dependence for BOD removal or better removal with lower D) E c o fc k- c a> o c o o E 3 Figure 5-3. Lithium Chloride Tracer Studies in a VSB System (George et al., 2000) pollutant loading, are often not apparent due to the scatter of the data. Therefore, the design approach recommended here is to use the maximum pollutant loading rates that have been shown to meet discharge standards. This ap¬ proach yields a much more conservative design than other common design approaches. As additional quality data be¬ comes available in the future, it may be possible to extend these conservative loading rates with confidence. Two types of pollutant loading rates were considered, an areal loading rate (ALR), g/m 2 -d, and a volumetric load¬ ing rate (VLR), g/m 3 -d. Both ALRs and VLRs have been used by researchers to describe VSB performance. ALR is calculated by multiplying the influent flow rate (m 3 /d) by the influent pollutant concentration (mg/L = g/m 3 ), and di¬ viding by the surface area of the VSB system (m 2 ). Be¬ cause sedimentation, plant growth and oxygen transfer are theoretically dependent on the surface area, ALR may be a characteristic parameter for some pollutants. VLR is cal¬ culated by multiplying the influent flow rate (m 3 /d) by the influent pollutant concentration (mg/L = g/m 3 ), and divid¬ ing by the pore volume of the VSB system (m 3 ). Because the removal of certain pollutants could be dependent on the HRT, the VLR could be a characteristic parameter for some pollutants. However, because the actual saturated pore volume is seldom known and the HRT may not be directly related to the pore volume due to preferential flow, the utility of VLR for design purposes is limited. Also, a comparison of Figures 5-4 through 5-7, which are typical of scatter for all pollutants, shows that data scatter is not reduced by the use of VLR. Therefore, the design recom¬ mendations in this chapter are based on ALRs. Finally, because the type of pre-treatment has a major impact on the characteristics of the wastewater being treated, the following discussions are organized by the type of wastewater being treated: septic tank and primary efflu¬ ents, pond effluents, and secondary treatment effluents. 5.4.2 TSS and BOD Removal for Septic Tank and Primary Effluents Two recent studies, one conducted by Tennessee Tech¬ nological University (TTU) and one conducted by Clarkson University (CU) at the Village of Minoa, New York, have provided the majority of data used to establish the design recommendations for this section (George et al., 2000, Young et al., 2000). These two studies were chosen be¬ cause their research objectives were to provide design in¬ formation, they utilized several VSBs with different mea¬ sured loadings, and the data are of good quantity and qual¬ ity. Influents in the TTU and CU studies were respectively a low strength septic tank effluent and a fairly typical pri¬ mary effluent. Each data point in the following figures rep¬ resents a quarterly average of biweekly (every 2 weeks) sampling for the TTU data, and a quarterly average of at least two monthly samples for the CU data. The results from one other VSB system treating septic tank effluent studied by University of Nebraska - Lincoln (UNL) research¬ ers are also included in these figures (Vanier & Dahab, 1997). After reviewing the literature, no other studies with 94 50 40 o) 30 E ★ ★ • TTU1 A TTU2 ★ TTU3 ▼ UNL ♦ CU ■ NADB • TSS Areal Loading Rate (g/m2-d) Figure 5-4. Effluent TSS vs areal loading rate 50 40 30 O) E CO co © 20 3= 111 10 0 7^2 n r* o —i— 100 • TTU1 A TTU2 ★ TTU3 ▼ UNL ♦ CU —i-1-1 200 300 400 TSS Volumetric Loading Rate (g/m3-d) 500 600 Figure 5-5. Effluent TSS vs volumetric loading rate 95 c d) J3 3 = LU 70 60 50 g 40 Q o CD • TTU1 A TTU2 ★ TTU3 ▼ UNL ♦ CU ■ NADB BOD Areal Loading Rate (g/m2-d) Figure 5-6. Effluent BOD vs areal loading rate O O m c < 1 > I3 LU BOD Volumetric Loading Rate (g/m3-d) Figure 5-7. Effluent BOD vs volumetric loading rate 96 septic tank or primary wastewater were found to have data with similar quality and quantity as these three studies. Data from the NADB for VSBs treating primary effluent, some of which are of unknown quality, are also shown in Figures 5-4 and 5-6. TSS removal is quite good; effluent TSS was consis¬ tently less than 30 mg/L at TSS ALRs as high as 20 g/m 2 - d (Figure 5-4). The two data points in Figure 5-4 that are above 30 mg/L are from systems at TTU that were inten¬ tionally overloaded to failure, and are not typical. Other researchers have reported plugging of the surface of the media (as opposed to clogging of the pore volume) when excessively high TSS loadings were applied (Tanner & Sukias, 1995, Tanner et al., 1998, van Oostrom & Cooper, 1990). Additional data may extend these limited ALRs when it becomes available. However, it should be noted that the typical sustained influent TSS concentrations for the data plotted in these figures were less than 100 mg/L. It is rec¬ ommended that TSS ALR be limited to 20 g/m 2 -d, based on the maximum monthly influent TSS. This would corre¬ spond to a loading of 2 cm/d for an influent concentration of 100 mg/L of TSS, 4 cm/d for an influent concentration of 50 mg/L of TSS, and so on. BOD removal is not as good as TSS removal, so the size of a VSB designed to meet secondary treatment standards will generally be controlled by the requirements for BOD re¬ moval. Effluent BOD values were found to periodically ex¬ ceed 30 mg/L at BOD ALRs greater than 6 g/m 2 -d (Figure 5-6). It is recommended that BOD ALR be limited to 6 g/m 2 -d, based on the maximum monthly influent BOD, to produce a maximum effluent BOD of 30 mg/L. Table 5-2 compares the size of a VSB designed with this ALR compared to the size of VSBs designed using several common approaches. As expected the other design approaches result in VSB systems significantly smaller than that using the conser¬ vative design approach presented here. 5.4.3 Nutrient Removal for Septic Tank and Primary Effluents Most of the organic nitrogen in septic tank and primary effluents is associated with suspended solids that are easily removed in VSB systems. It is generally assumed that the organic nitrogen will be converted to ammonia in VSB sys¬ tems, but spiked concentrations of urea (a soluble form of organic nitrogen) were often not completely converted in one study (George et al., 2000). Ammonia removal in VSB systems is severely oxygen limited, and it is inversely re¬ lated to the ultimate (carbonaceous and nitrogenous) BOD loading. Also, the conversion of organic nitrogen into am¬ monia via ammonification or hydrolysis masks any attempt to relate ammonia removal to other design factors. For this reason Total Kjeldahl Nitrogen (TKN) data rather than ammonia data are presented in Figure 5-8. The TKN re¬ moval performance is generally poor and highly variable. Therefore, VSB systems should not be used alone to treat pre-settled municipal wastewaters if significant amounts of ammonia must be consistently removed. Although the data are not presented here, if any nitrate is produced in VSB systems treating septic tank and pri¬ mary effluents, it is likely that the nitrate will be removed by denitrification. Table 5-2. Comparison of VSB Area Required for BOD Removal Using Common Design Approaches. Design criteria Flow (Q) = 400 m 3 /d (105,680 gpd) Influent BOD 5 (Ci) = 125 mg/L Effluent BOD 5 (Ce) = 30 mg/L Design Approach Rate Constant Loading Constant Other Factors Required Area m 2 (ac) This Manual 6 g/m 2 -d (54 Ib/ac-d) 8,330 (2.0) European (Cooper, 1990) K BO o = 0Vd 5710(1.4) Kadlec & Knight (1996) 180 m/yr (590 ft/yr) Background Concentration 2 = 10 mg/L 1420 (0.4) Reed, etal. (1995) Temperature Dependent 2 K10 = 0.62/d K20 = 1.104/d Water Depth 1 = 0.4 m (16") Media Porosity’ = 0.38 at 10°C, 6090 (1.5) at 20°C, 3400 (0.8) TVA (1993) 5.3 g/m 2 -d (48 Ib/ac-d) Derived from TVA design Assumes septic tank effluent 9430 (2.3) ’Values chosen by user; these are not necessarily the values recommended by the design’s author. 2 Values calculated per instructions of design’s author. 97 50 40 t A A A ± • • •: ★ ★ * • L '.*! »♦ •: • • ★ ★ ♦ ▲ ★ O) E c d) LU 30 20 10 4 t 1U» 4 * ♦ ★ 0 2 T- 4 —i— 10 • TTU1 A TTU2 ★ TTU3 T UNL ♦ CU —t— 12 0 6 8 TKN Areal Loading Rate (g/m2-d) 14 Figure 5-8. Effluent TKN vs areal loading rate Although phosphorus is partially removed in VSB sys¬ tems treating septic tank and primary effluents, VSBs are not very effective for long-term phosphorus removal (Fig¬ ure 5-9). It should be noted that the phosphorus data shown in Figure 5-9 are from VSB systems that are relatively new, when it can be assumed that the phosphorus precipitation and adsorption capacity of the media would be at its great¬ est. Because plant uptake of phosphorus is quite small compared to typical loadings (Reed, et al, 1995; Crites & Tchobanoglous, 1998), the phosphorus removal capacity will decrease with time. Estimates of realistic long-term phosphorus removal by plant harvesting is limited to about 0.055 g/m 2 -d (0.5 Ib/ac-d) (Crites & Tchobanoglous, 1998). VSB systems should not be expected to remove phospho¬ rus on a long-term basis. 5.4.4 TSS, BOD and Nutrient Removal for Pond Effluents There is much less quality data comparable to the TTU and CU studies for VSB systems treating pond effluents. Data from a study conducted at three experimental VSB systems at Las Animas, Colorado by Colorado State Uni¬ versity (Richard & Synder, 1994) were used to support design recommendations for VSB systems treating pond effluents (Table 5-3). The pollutant removal performance for the Las Animas VSBs treating oxidized pond effluent was not as good as the performance of the TTU and CU systems. NABD data for VSBs treating pond effluent (Fig¬ ure 5-10), which are not as reliable as the Las Animas data, show similar performance. Several of the NABD sys¬ tems have experienced surfacing caused by clogging of the media surface (as opposed to clogging of the pore vol¬ ume) by algae. For Las Animas, the average TSS ALR was 6.2 g/m 2 -d (55 Ib/ac-d) and produced an overall average effluent TSS of 35 mg/L. The average BOD ALR was 2.0 g/m 2 -d (18 lb/ ac-d) and produced an overall average effluent BOD of 25 mg/L. There was essentially no nitrogen or phosphorus removal on average in the three VSBs. The poor overall percent removal of BOD of 35% might be related to the relatively high concentrations of algal cells in the influent during several months of each year. The measured BOD of pond effluent typically does not account for the true BOD of algal cells because algal cells degrade more slowly than other organic matter. A VSB system in Mesquite, Nevada has been used since 1992 in parallel with overland flow and oxidation ditch sys¬ tems to treat an aerated pond effluent. One year of monthly data for the Mesquite system is summarized in Chapter 8. Over the one-year sampling period the effluent BOD aver¬ aged 29 mg/L when loaded at an average BOD ALR of 2.5 g/m 2 -d (22 Ib/ac-d). Better BOD and TSS removals than at Las Animas and Mesquite are reported in a 1993 EPA re¬ port for several VSB systems treating pond algal effluents. However, the sparse amount of data of unproven quality represented by the average values given in the report is 98 3.5 c a> 3 = LU 3 2.5 2 1.5 1 0.5 0 ♦ 4 ~*-♦- ♦ ★ - ,-*-- A • # ♦ . # * _•. •!. . 1 •• • * • TTU1 ▲ TTU2 ★ TTU3 ♦ CU •. * i l-1-1-1-r 0 0.2 0.4 0.6 0.8 1 1.2 TP Areal Loading Rate (g/m2-d) Figure 5-9. Effluent TP vs areal loading rate inadequate to use with confidence. Sapkota and Bavor (1994) report similar TSS removal, but do not report BOD removal. The upgrading of pond effluent with rock filters is similar to the use of VSBs after ponds. However, because of vari¬ able results from rock filters, their use is generally cau¬ tioned due to a lack of reliable design information (Reed, et al, 1995). Performance of rock filters is also plagued by H S generation and high effluent ammonia. Illinois requires effluent aeration and recommends disinfection before dis¬ charge for pond rock filter systems. Because of the limited data and uncertainty about similar rock filter systems, VSB systems are not recommended for treating pond effluents if the system must consistently meet a 30/30 standard. 5.4.5 BOD, TSS and Nutrient Removal for Secondary and Non-algal Pond Effluents There are very few quality-assured data available from VSB systems in the U.S. treating secondary effluents. The 1993 U.S. EPA report included data collected over a three month period from three systems. Additional data from one of these systems, Mandeville, LA, is included in Chapter 8. The Mandeville VSB treats an aerated lagoon effluent which has little or no algae. The average influent BOD and TSS were 40 and 16 mg/L, respectively. The average ef¬ fluent BOD and TSS were 5 and 3 mg/L, respectively at a BOD ALR of 7.9 g/m2-d (70 Ib/ac-d). Representatives from Severn Trent Water, Ltd., have reported on the performance of VSB ("reed bed") systems treating activated sludge and RBC effluents in small treat¬ ment plants (less than 2000 people) in the U.K. (Green and Upton, 1994). The goal for these VSB systems is to provide additional treatment of secondary effluents so that they consistently meet discharge limitations, which can vary from 30/20 to 15/10 TSS/BOD. Essentially these systems serve as aesthetic and sometimes economical substitutes for tertiary filters for small treatment plants. In some cases in the U.K. they have been used to treat storm water by¬ pass flows at secondary treatment plants. While the Severn Trent systems typically remove some nitrogen and phos¬ phorus, they are not capable of meeting typical discharge standards for nutrients in the U.S. The primary design ba¬ sis used by Severn Trent is a hydraulic surface loading rate of 0.20 m 3 /m 2 -d (5 gpd/sq ft) for the average daily flow (Green and Upton, 1994). This value is derived from the design recommendation of the European task group on VSB systems (Cooper, 1990). For systems with an aver¬ age influent BOD < 40 mg/L, this results in average areal BOD loading of less than 8.0 g/m 2 -d (71 Ib/ac-d). Typical systems are 0.6 m (24 in) deep, 0.4 m wide per m 3 /d (5 ft per 1000 gpd) of flow, and 12.5 m (41 ft) long. Based on the success of the Mandeville and Severn Trent systems, it appears that VSB systems can be effectively used to help small secondary systems consistently meet secondary effluent standards. The recommended approach 99 Table 5-3. Data from Las Animas, CO VSB Treating Pond Effluent. Time Period 1 Inf. TSS mg/L Eff. TSS mg/L Inf. BOD mg/L Eff. BOD mg/L Inf. TKN mg/L Eff. TKN mg/L Inf. TP mg/L Eff. TP mg/L Cell 1 Winter 91 89.7 43.0 26.7 37.5 ND ND 1.57 1.9 Srping 92 146.0 28.7 34.0 22.7 7.2 11.4 1 1.67 Summer 92 178.0 41.7 49.7 29.0 6.1 8.7 1.17 1.68 Fall 92 223.0 34.3 54.0 30.0 7.3 10.7 1.47 1.9 Winter 92 50.0 34.3 33.7 32.7 14.1 14.0 2.25 2.3 Spring 93 66.0 24.0 41.0 32.0 16.1 16.3 2.55 2.6 Summer 93 95.3 33.3 30.0 9.3 3.9 5.3 0.67 0.78 Fall 93 127.0 38.0 40.3 16.0 4.0 3.4 0.65 0.6 Average 121.9 34.7 38.7 26.2 8.4 10.0 1.42 1.68 Cell 2 Winter 91 89.7 51.0 26.7 37.0 ND ND 1.57 2.57 Srping 92 146.0 34.0 34.0 35.0 7.2 14.1 1 2.37 Summer 92 178.0 43.3 49.7 29.3 6.1 9.0 1.17 1.72 Fall 92 223.0 26.0 54.0 40.0 7.3 8.8 1.47 1.78 Winter 92 50.0 33.0 33.7 29.7 14.1 14.2 2.25 2.28 Spring 93 66.0 26.7 41.0 35.3 16.1 15.2 2.55 2.68 Summer 93 95.3 27.0 30.0 15.0 3.9 5.5 0.67 0.82 Fall 93 127.0 33.3 40.3 21.3 4.0 4.8 0.65 0.65 Average 121.9 34.3 38.7 30.3 8.4 10.2 1.42 1.86 Cell 3 Winter 91 89.7 46.0 26.7 11.3 ND ND 1.57 1.47 Srping 92 146.0 47.0 34.0 22.0 7.2 5.4 1 1.43 Summer 92 178.0 33.3 49.7 20.3 6.1 9.6 1.17 1.62 Fall 92 223.0 41.3 54.0 27.0 7.3 8.1 1.47 1.72 Winter 92 50.0 34.3 33.7 25.7 14.1 13.0 2.25 2.2 Spring 93 66.0 23.7 41.0 29.7 16.1 13.9 2.55 2.53 Summer 93 95.3 29.3 30.0 8.3 3.9 4.7 0.67 0.82 Fall 93 127.0 34.3 40.3 8.0 4.0 5.6 0.65 0.55 Average 121.9 36.2 38.7 19.0 8.4 8.6 1.42 1.54 'Each of the values in the table is the average of three monthly samples. BOD or TSS Areal Loading Rate (g/m2-d) NADB Systems Treating Pond Effluent Figure 5-10. NADB VSBs Treating Pond Effluent 100 is to limit the BOD ALR to a maximum monthly value of 8 g/m2-d (71 Ib/ac-d). However, VSB systems are not rec¬ ommended as a remedy for inadequately operated acti¬ vated sludge systems. Process upsets in poorly operated activated sludge systems can quickly fill a VSB system with mixed liquor solids, resulting in surface flow due to clogging of the media. 5. 4.6 Metals Removal for AII Types of Wastewater Metals are removed in a VSB by two primary mecha¬ nisms. First, because many metals (e.g. Zn, Cr, Pb, Cd, Fe, Al) are associated with particles (Heukelekian & Balmat, 1959; SWEP, 1985), the high efficiency of particulate sepa¬ ration in a VSB should remove these metals accordingly. Second, sulfide precipitation occurs due to the reduction of sulfates to sulfides in the absence of nitrate, and ren¬ ders some metals insoluble, resulting in significant remov¬ als, as described in Reed, etal (1995) for Cu, Cd, and Zn. As long as the system ORP remains low, which is likely given the anaerobic nature of VSBs, it is unlikely that met¬ als precipitated in the sulfide form will re-enter the water column (Bounds, et al, 1998; Reed, et al, 1995). Some metals such as Ni and Cd are more mobile and less likely to be removed, but they are not normally present in toxic quantities in municipal wastewater. There is relatively little data on metals removal by VSB systems and no known information from long-term stud¬ ies. Gersberg et al. (1984) found significant removal of Cu, Zn and Cd, and determined that plant uptake was respon¬ sible for only 1 % of the Cu and Zn removal. In a study with a VSB system treating a landfill leachate, researchers found only a small increase in the Pb, Cd, and Cu levels on root surfaces, and no increase in any of the metals measured in any plant tissue compared to plants from a control sys¬ tem (Peverly et al., 1995). They concluded that the in¬ creased metal concentrations on the root surface was due to metal precipitation and adsorption. Metal removal by plant uptake should not be counted on in any VSB system over the long term. 5.4.7 Pathogen Remo val for AII Types of Wastewater While pathogens will be partially removed in a VSB sys¬ tem, a disinfection step after the VSB will normally be re¬ quired to meet discharge limits. Researchers in Nebraska found a three log reduction in fecal coliforms from 10 6 to 10 3 /100mL in a VSB system treating a septic tank effluent (Vanier and Dahab, 1997). Gersberg et al. (1989) found a two log reduction in total coliforms in a VSB system treat¬ ing primary effluent. The coliform removal in two VSB sys¬ tems in England treating secondary effluents varied be¬ tween 40% and 99%, but effluent values did not meet dis¬ charge requirements (Griffin et al., 1998). Fecal coliform reductions were typically two logs (1 x 10 6 to 1 x 10 4 /1 OOmL) in several experimental VSB systems in Tennessee, ex¬ cept for two cells operated in a fill and drain mode. These fill and drain cells achieved a three log reduction with the same influent wastewater (George et al., 2000). For de¬ sign purposes a two log reduction is a reasonable esti¬ mate of VSB performance. 5.5 Design Considerations 5.5 .1 Media Size and Hardness The media of a VSB system perform several functions; they (1) are rooting material for vegetation, (2) help to evenly distribute/collect flow at the inlet/outlet, (3) provide surface area for microbial growth, and (4) filter and trap particles. For successful plant establishment, the upper¬ most layer of media should be conducive to root growth. A variety of media sizes and materials have been tried, but there is no clear evidence that points to a single size or type of media, except that the media should be large enough that it will not settle into the void spaces of the underlying layer. It is recommended that the planting me¬ dia not exceed 20 mm (3/4 in) in diameter, and the mini¬ mum depth should be 100 mm (4 in). The media in the inlet and outlet zones (see Figure 5- 11) should be between 40 and 80 mm (1.5-3 in) in diam¬ eter to minimize clogging and should extend from the top to the bottom of the system. The inlet zone should be about 2 m long and the outlet zone should be about 1 m long. These zones with larger media will help to even distribute or collect the flow without clogging. The use of gabions (wire rock baskets used for bank stabilization) to contain the larger media simplifies construction. Gabions may also make it easier to remove and clean the inlet zone media if it becomes clogged. Any portion of the media that is wetted is a surface on which microbes grow and solids settle and/or accumulate. Media in VSBs have ranged from soil to 100 mm (4 in.) rock. Experience with soil and sand media shows that it is very susceptible to clogging and surfacing of flows, even if influent TSS concentrations are minimal, so soil or sand media should be avoided. Gravel and rock media have been used successfully, with smaller diameter media be¬ ing more susceptible to clogging, and larger media more difficult to handle during construction or maintenance. Crushed limestone can be used, but is not recommended for VSB systems because of the potential for media breakup and dissolution under the strongly reducing environment of a VSB, which can lead to clogging. Media with high iron or aluminum will have more sites for phosphorus binding and should enhance phosphorus removal, but only during the first few months of operation. The limited removal ca¬ pability is probably not worth an added expense if it is not available locally at a reasonable cost. Alternative media such as shredded tires, plastic trickling filter media, ex¬ panded clay aggregates and shale with potentially high phosphorus absorptive capacity have been used, but there is inadequate data to make a recommendation for or against their use. There does not appear to be a clear advantage in pollut¬ ant removal with different sized media in the 10 to 60 mm (3/8 - 2 in.) range. Therefore, it is recommended that the 101 Media Surface ; k E CD O / f Inlet Zone Treatment Zone Outlet Zone Zone 1 Zone 2 2 m 30% of Length 70% of Length 1 m Outlet Side View Figure 5-11. Proposed Zones in a VSB average diameter of the treatment zone media be between 20 and 30 mm (3/4 - 1 in.) in diameter as a compromise between the potential for clogging and ease of handling. To minimize settling of the media smooth, rounded media with a Mohs hardness of 3 or higher is recommended if it is available locally at a reasonable cost. Based on the data in Table 5-1, the hydraulic conductivity of the 20 - 30 mm diameter clean media is assumed to be 100,000 m/d. 5.5.2 Slopes The top surface of the media should be level or nearly level for easier planting and routine maintenance. Theo¬ retically, the bottom slope should match the slope of the water level to maintain a uniform water depth throughout the VSB. However, because the hydraulic conductivity of the media varies with time and location, it is not practical to determine the bottom slope this way, and the bottom slope should be designed only for draining the system, and not to supplement the hydraulic conductivity of the VSB. A practical approach is to uniformly slope the bottom along the direction of flow from inlet to outlet to allow for easy draining when maintenance in required. No research has been done to determine an optimum slope, but a slope of 1/2 to 1% is recommended for ease of construction and proper draining (Chalk & Wheale, 1989). Care should be taking when grading the bottom slope to eliminate low spots, channels and side-to-side sloping which will pro¬ mote dead volume or short-circuiting. The slope of the berms containing a VSB should be as steep as possible, consistent with the soils, construction methods and materials. Shallow side slopes create larger areas which capture and route precipitation into the VSB, which may be detrimental to system performance. Also, the site should be graded to keep off-site runoff out of the VSB. 5.5.3 Inlet and Outlet Piping The inlet piping must be designed to minimize the po¬ tential for short-circuiting and clogging in the media, and maximize even flow distribution. For VSBs with length-width ratios less than one, additional care must be taken to spread the influent across the whole width of the VSB. Standard hydraulic design principles and structures (e.g. adjustable weirs and orifices) are used to split, balance evenly dis¬ tribute flows (WEF, 1998). The recommended method to evenly distribute flows is to use reducing tees or 90 de¬ gree elbows which can be rotated on the header (see Chap¬ ter 6). The main advantage of a rotating fitting is that it allows the operator to easily adjust the distribution of the influent, which may help in reducing media clogging. When the potential for public access exists, a cover over the in¬ fluent distribution system must be used. Possible covers include half sections of pipe or cavity chambers, as used in leach fields. If piping with orifices is used to distribute flows instead of a pipe with rotating fittings, it is necessary to minimize the headloss in the distribution piping so that the headloss through the orifices controls the flow. This requirement limits the number and size of orifices used, and makes the distribution piping large enough so that the velocity in it is low. The orifices should be evenly spaced at a distance approximately equal to 10% of the cell width. For example, a system 20 m (65 ft) wide should have ori¬ fices placed every 2 m (6.5 ft). If poor design causes waste- water to always discharge through only some of the ori¬ fices, clogging of the media or accumulation of a surface 102 layer of solids near those orifices can become a problem, especially for an influent with relatively high suspended solids, such as pond effluent. Finally, the inlet piping should be designed to allow for inspection and clean-out by the operator. The outlet piping must be designed to minimize the po¬ tential for short-circuiting, to maximize even flow collec¬ tion, and to allow the operator to vary the operating water level and drain the bed. For VSBs with length-width ratios less than one, additional care must be taken to collect the influent from the whole width of the VSB. A collection header with orifices that is placed across the entire width of the bottom of the VSB is recommended to promote even flow. The collection header should be designed with the same hydraulic principles used for inlet distribution piping. Slot¬ ted or perforated drainage pipe can be used if the collec¬ tion header is not too long, but properly sized and spaced orifices in a large diameter collection header allow a de¬ signer to use a longer collection header and still achieve balanced flow collection. The recommended maximum dis¬ tance between orifices in the collection header is 10% of the cell width. The relative potential for clogging with slot¬ ted or perforated drainage pipe versus a longer collection header with fewer orifices is unknown. Finally, the outlet piping should be designed to allow for clean-out by the operator. A simple device to adjust the water level in a separate, covered, outlet box is recommended to achieve variable water level control (see Chapter 6). It is recommended that there be only one collection header and adjustable-level device per cell of a multiple cell VSB system. The adjust¬ able device should allow the operator to flood the VSB to a depth of 50 mm (2 in.) above the surface of the media (for help in weed control), and to draw-down or drain the cell for maintenance. 5.5.4 System Depth, Width and Length The impact of water depth on pollutant removal is not clear. One problem with almost all published information on VSB systems is that even though the media depth may be known, the actual operating water level is not known. The TTU study found slightly better BOD removal with greater media depth, when comparing 45 cm (18 in) with 30 cm (12 in) systems operated at same areal loading, but it is unclear if this was due only to the increased HRT. No other study has tested this result or determined the opti¬ mum depth for a VSB system (George et al., 2000). One study suggested that total root penetration of the media was critical to pollutant removal and recommended that system depth be set equal to the maximum root depth of the wetland species to be used in the VSB (Gersberg et al. 1983). However, as discussed previously, plants supplied with abundant nutrients near the surface will not neces¬ sarily grow roots to their maximum depth. As a safety fac¬ tor Kadlec and Knight (1996) recommend allowing room for solids accumulation in the bottom of the VSB, but the need for this has not been proven. Typical average media depths in VSB systems have ranged from 0.3 to 0.7 m (12 to 28 in.), and various researchers have recommended depths from 0.4 to 0.6 m (16 to 24 in.). As discussed previously there is evidence for preferen¬ tial flow below the root zone through media with a higher conductivity. In order to minimize this flow, a shallower depth would be required. On the other hand, a shallower depth may require a greater area to achieve a desired HRT. Until future studies provide better information on optimum water depth, it is recommended to use a design maximum water depth (at the inlet of the VSB) of 0.40 m (16 in.). The depth of the media will be defined by the level of the waste- water at the inlet and should be about 0.1 m (4 in.) deeper than the water. The overall width of a treatment system using VSBs is defined by Darcy’s Law, which is a function of the flow, ALR, water depth and hydraulic conductivity. The width of a individual VSB is set by the ability of the inlet and outlet structures to uniformly distribute and collect the flow with¬ out inducing short-circuiting. The recommended maximum width in a TVA design manual is 61 m (200 ft.). If the de¬ sign produces a larger value, the user should divide the VSB into several cells that do not exceed 61 m in width. As discussed previously, several researchers have noted that most BOD and TSS is removed in the first few meters of a VSB, but some recommend minimum lengths ranging from 12 to 30 m (40 to 100 ft) to prevent short-circuiting. The recommended minimum length for this manual is 15 m (50 ft). Although much has been made of the aspect (length- width) ratio in early constructed wetlands literature, the only prerequisite for treatment is the area as defined by the ALR. A study by Bounds, et.al. (1998) found that there was no significant difference in TSS or CBOD removal in three parallel VSB systems with aspect ratios of 4:1, 10:1, and 30:1. In all three systems the majority of TSS and CBOD was removed in the first third on the VSB. Removals were also unaffected by stressing the systems with large hy¬ draulic spikes and intermittent loading. The TTU study also found no significant difference in systems with 1:4 and 4:1 aspect ratios (George et al., 2000). Therefore, the aspect ratio is not a factor in the overall design. However, the rec¬ ommended values for maximum width and minimum length discussed previously will tend to result in individual VSB cells with an length-width ratio between 1:1 and 1:2. 5.6 Design Example for a VSB Treating Septic Tank or Primary Effluent The design has two basic assumptions. First, the total VSB has four zones (see Figure 5-11). The inlet and outlet zones were discussed in section 5.5.1. Based on the lit¬ erature as discussed previously, the initial treatment zone will (1) occupy about 30% of the total area, (2) perform most of the treatment, and (3) have a big decrease in hy¬ draulic conductivity (use K = 1 % of clean K). The final treat¬ ment zone will occupy the remaining 70% of the area and have little change in hydraulic conductivity (use K = 10% of clean K). The second basic assumption is that Darcy’s 103 Law, while not exact, it is good enough for design pur¬ poses. The sizing of the initial and final treatment zones follows these steps: 1) determine the surface area, using recommended ALR 2) determine the width, using Darcy’s Law 3) determine the length and headloss of the initial treat¬ ment zone, using Darcy’s Law 4) determine the length and headloss of the final treat¬ ment zone, using Darcy’s Law 5) determine bottom elevations, using bottom slope 6) determine water elevations throughout the VSB, using headloss 7) determine water depths, accounting for bottom slope and headloss 8) determine required media depth 9) determine the number of VSB cells For this example the following values are given: • Maximum Monthly Flow (Q) = 200 m 3 /d • Maximum Monthly Influent (CO) BOD = 100 mg/L = 100 g/m 3 • Maximum Monthly Influent (CO) TSS = 100 mg/L = 100 g/m 3 • Required discharge limits = 30 mg/L BOD and TSS Recommended values for VSBs (see Table 5-4) are: • ALR for BOD = 6 g/m 2 -d • ALR for TSS = 20 g/m 2 -d • Use washed, rounded media 20-30 mm in diameter, clean K = 100,000 m/d • Hydraulic conductivity of initial treatment zone (K) = 1 % of 100,000 = 1000 m/d • Hydraulic conductivity of final treatment zone (K ( ) = 10% of 100,000 = 10,000 m/d • Bottom slope (s) = _% = 0.005 • Design water depth at inlet (D w0 ) = 0.4 m • Design water depth at beginning of final treatment zone (D J = 0.4 m • Design media depth (D m ) = 0.6 m • Maximum allowable headloss through initial treatment zone (dti) = 10% of D m = 0.06 m 5.6.1 Determine the Surface Area (As) for Both Pollutants A=(Q)(C 0 )/ALR For BOD, A s = (200 m 3 /d)(100 g/m 3 ) / 6 g/m 2 -d = 3333 m 2 For TSS, A s = (200 m 3 /d)(100 g/m 3 ) / 20 g/m 2 -d = 1000 m 2 Use the larger area requirement, or 3333 m 2 . The surface area for the initial treatment zone (A sj ) = (30%) (3333 m 2 ) = 1000 m 2 The surface area for the final treatment zone (A s( ) = (70%) (3333 m 2 ) = 2333 m 2 5.6.2 Determine the Width Determine the minimum width (W) needed to keep the flow below the surface, using Darcy’s Law (Eq. 5-1) and recommended values for the initial treatment zone. Q = (K)(W)(D w0 )(dh/L) where: L = length of initial treatment zone = (A sj ) / (W) Substitute and rearrange equation to solve for W: W 2 = (Q)(A si ) / (K)(dh.)(D w0 ) (5-3) For this example: W 2 = (200 m 3 /d)(1000 m 2 ) / (1000 m/d)(0.06 m)(0.4 m) = 8333 m 2 W =91.3 m This is the width for which the headloss equals 0.06 m, given all the parameters as defined. The designer must use a width equal to or greater than this to ensure that the headloss is less than or equal to the design value. 5.6.3 Determine the Length and Headloss (Eq. 5-2) of the Initial Treatment Zone (L) L = (A sj ) / (W) = (1000 m 2 ) / (91.3 m) = 11.0 m This is the length for which the headloss equals 0.06 m, given all the parameters as defined. The designer must use a length less than or equal to this to ensure that the headloss is less than or equal to the recommended value. dh j= (Q)(L) / (K)(W)(DJ = (200 m 3 /d)(11.0 m) / (1000 m/d)(91.3 m)(0.4 m) = 0.06 m 5.6.4 Determine the Length and Headloss of the Final Treatment Zone (L) L, = (A,) / (W) = (2333 m 2 ) / (91.3 m) = 25.6 m This is the length where the total area of the VSB will be exactly equal to the value set by the ALR. The designer must use a length equal to or greater than this to ensure 104 that the surface area is equal to or greater than the recom¬ mended value. dh,= (Q)(L f ) / (K f )(W)(D wf ) = (200 m 3 /d)(25.6 m) / (10,000 m/d)(91.3 m)(0.4 m) = 0.01 m 5.6.5 Determine Bottom Elevations E be = elevation of bottom at outlet = 0 (reference point for all elevations) E bf = elevation of bottom at beginning of final treatment zone = (s)(L f ) = (0.005)(25.6 m) = 0.13 m E b0 = elevation of bottom at inlet = (s)(L + L ( ) = (0.005)(11.0 m +25.6 m) = 0.18 m 5.6.6 Determine the Water Surface Elevations E^ = elevation of water surface at beginning of final treatment zone = E bf + = 0.13 m + 0.4 m = 0.53 m (D^ = 0.4 m was an initial recommended value) E a = elevation of water surface at outlet = E - dh = we wf f 0.53 m - 0.01 m = 0.52 m E = elevation of water surface at inlet = E . + dh = w0 wf i 0.53 m + 0.06 m = 0.59 m 5.6.7 Determine Water Depths D w0 = depth of water at inlet = E w0 - E b0 = 0.59 m - 0.18 m = 0.41 m (about equal uTdesign D w0 , so okay.) D wf = depth of water at beginning of final treatment zone = E^ - E bf = 0.53 m - 0.13 m = 0.40 m (equal to design D^, so okay.) D we = depth of water at outlet = E we - E be = 0.52 m - 0 = we 0.52 m 5.6.8 Determine the Media Depth The media depth will depend on whether the designer wants a level media surface, or a minimum depth-to-water (DJ throughout the VSB. a) If a level surface is desired, the elevation must be greater than the highest water elevation, which is at the inlet, E _ = 0.59 m. A media elevation set at 0.65 m would be reasonable, and the following media depths and Dtw’s result: D m0 = depth of media at inlet = 0.65 m - E b0 = 0.65 m - 0.18 m = 0.47 m D = depth of media at beginning of final treatment zone = 0.65 m - E bf = 0.65 m - 0.13 m = 0.52 m D me = depth of media at outlet = 0.65 m - 0 = 0.65 m D tw0 = depth-to-water at inlet = 0.65 m - E w0 = 0.65 m - 0.59 m = 0.06 m D tw( = depth-to-water at beginning of final treatment zone = 0.65 m - E . = 0.65 m - 0.53 m = 0.12 m wf D, a = depth-to-water at outlet = 0.65 m - E,= 0.65 m two 1 we - 0.52 m = 0.13 m The depth-to-water is small at the inlet (0.06 m) and the designer may want to add an additional layer of media in the first few meters of the initial treatment zone as an added precaution against surfacing, even though the design ALR and K values is very conservative. The resulting D tw in the final treatment zone would be 0.12 to 0.13 m, which should not inhibit the growth of aquatic species. b) If a constant depth-to-water throughout the VSB is desired (e.g. 0.1 m), then the media depth would be calcu¬ lated as follows: E m0 = elevation of media surface at inlet = E w0 + 0.1 m = 0.59 m + 0.1 m = 0.69 m E mf = elevation of media surface at beginning of final treatment zone = E . + 0.1 m = 0.53 m + 0.1 m = 0.63 m w( E = elevation of media surface at outlet = E +0.1 me we m = 0.52 m + 0.1 m = 0.62 m D m0 = depth of media at inlet = E m0 - E b0 = 0.69 m - 0.18 m = 0.51 m D mf = depth of media at beginning of final treatment zone = E - E = 0.63 m - 0.13 m = 0.56 m mf bf D = depth of media at outlet = E - 0 = 0.52 m - 0 = 0.52 m This approach would result in a drop in the media sur¬ face of (0.69 m - 0.51 m) of 0.18 m over the 11.0 m length of the initial treatment zone (slope = 1.6%), which would probably not impair operation and maintenance activities. 5.6.9 Determine Number of VSB Cells It is recommended that at least two VSBs be used in parallel in all but the smallest systems, so that one of the VSBs can be taken out of service for maintenance or re¬ pairs without causing serious water quality violations. In this example, the total size of the VSB system is 91.3 m wide by 36.6 m long. Therefore, use two VSBs, each 46 m wide and 37 m long could be used. Other combinations of length and width that have the required surface area will also work as long as the hydraulics conditions are meet. Also remember that inlet and outlet zones will add to the overall length of the VSB. 105 Table 5-4. Summary of VSB Design Guidance. Recommended for use after primary sedimentation (e.g. septic tank, Imhoff tank, primary clarifier) VSBs not recommended for use after ponds Pretreatment because of problems with algae Surface Area Based on desired effluent quality and areal loading rates as follows: BOD BOD TSS TKN TP 6 g/m 2 -d (53.5 Ib/ac-d) to attain 30 mg/L effluent 1.6 g/m 2 -d (14.3 Ib/ac-d) to attain 20 mg/L effluent 20 g/m2-d (178 Ib/ac-d) to attain 30 mg/L effluent Use another treatment process in conjunction with VSB VSBs not recommended for phosphorus removal Depth Media (typical) 0.5 - 0.6 m (20 - 24 in.) Water (typical) 0.4 - 0.5 m (16 - 20 in.) coming the inadequate purification capacity of certain soils. They view VSBs as passive systems with low operation and maintenance requirements. A review of various on-site VSB design guidelines by Mankin and Powell (1998) revealed that there was a large variation among the designs. Recommended depth var¬ ied from 0.3 to 0.8 m (1 to 2.5 ft), with the great majority between 0.3 and 0.5 m (1 and 1.5 ft). For a three bedroom house typical VSB areas varied from < 10 m 2 to > 100 m 2 (104 to 1088 ft 2 ), HRTs varied from 1.3 to 6.5 d, and length- width ratio varied from 71:1 to 1.8:1. Median values were a depth of 0.45 m (1.5 ft), area of 30 m 2 (315 ft 2 ), and HRT of 4.7 d. Gravel size guidelines varied from 0.65 cm (0.25 in.) to 7.5 cm (3.0 in.) These authors sampled three typical VSB systems in Kansas and compared them with other reported data. De¬ spite employing a larger than average area, the units failed to meet a 30/30 BOD/TSS requirement at two of the three sites. Length Width Bottom slope As calculated (see design example); minimum of 15 m (49 ft) As calculated (see design example); maximum of 61 m (200 ft) 0.5- 1% Top slope level or nearly level Hydraulic Conductivity First 30% of length 1% of clean K Last 70% of length 10% of clean K Given the general lack of operation and maintenance requirements and the potential aesthetic appearance of VSB systems, their attractiveness to local and state regu¬ lators is quite predictable. As a passive system potentially capable of meeting a 30/30 BOD/TSS requirement, they have obvious advantages over mechanical systems which require a significant management program and electrical support to function satisfactorily. Also, their general reli¬ ability, when compared to mechanical systems, offers ad¬ ditional protection against clogging of the soil’s infiltrative surface. Media All media should be washed clean of fines and debris; more rounded media will generally have more void spaces; media should be resistant to crushing or breakage. Inlet zone 40 - 80 mm (1.5 - 3.0 in) (1st 2 m (6.5 ft)] Treatment zone 20 - 30 mm (3/4 -1 in) [use clean K = 100,000, if actual K not known] Outlet zone 40 - 80 mm (1.5 - 3.0 in) [last 1 m (3.2 ft)] Planting media 5 - 20 mm (1/4 - 3/4 in) [top 10 cm (4 in.)] Miscellaneous Use at least 2 VSBs in parallel Use adjustable inlet device with capability to balance flows Use adjustable outlet control device with capability to flood and drain system 5.7 On-site Applications A number of states, including Louisiana, Kentucky, Kan¬ sas, Arkansas, Texas and Indiana, have used VSBs for on-site wastewater management. Kentucky alone lists over 4000 such installations (Thom et al., 1998). Most of these states have adopted VSBs as a pretreatment step prior to soil infiltration in an effort to protect groundwater by over- Based on the VSB design guidance presented previously, a three bedroom home would require a VSB of 100 m 2 , assuming six persons and a BOD loading of 100 g/cap-d. As expected, due to the conservative nature of the design approach presented in this chapter, this area is at the high end of the areas found by Mankin and Powell (1998). There should be minimal deviation from the recommen¬ dations of Table 5-4, except that simplified inlet and outlet configurations, appropriate for small on-site systems, can be used. As with larger VSBs, some means of post-aera¬ tion and disinfection will be required if surface discharge is contemplated. Discharge to soil infiltration is more likely, and soil absorption guidelines provided by the State will apply. 5.8 Alternative VSB Systems Alternative VSB systems are those that operate with some schedule of filling and draining the media. Fill and drain VSB systems are similar to sequencing batch reac¬ tors, intermittent sand filters, or overland flow systems in that the flow into a single cell of a system is intermittent. Draining a VSB system is a simple way to introduce more oxygen into the media. Clearly plants are playing a lesser role in these systems and they are inherently quite differ¬ ent from a natural wetland. Nevertheless they are discussed here because they have been identified as constructed 106 wetlands and have evolved from conventional VSB sys¬ tems. They are more complex to operate than a conven¬ tional VSB system. One of the first and more unconventional alternative VSB systems was developed in England and tested in England and Egypt in the late 1980s (May et al., 1990). The sys¬ tem, called a gravel bed hydroponic system, is very simi¬ lar to an overland flow process except that the wastewater flows through 8-10 cm (3-4 in) of gravel. Loading is typi¬ cally intermittent except when denitrification is desired. Researchers at TTU (1999) experimented with alternat¬ ing fill and drain VSB wetlands for one year in 1994 and compared the results to conventional VSBs in side by side testing. The alternating fill and drain cells followed a con¬ ventional VSB cell. Effluent from the fill and drain cells was recycled back to the conventional cell. They found some improvement in nitrogen removal but overall the results were not as good as they had expected. Researchers at TVA have developed (and patented) a system in which the wastewater is quickly drained from one wetland cell and pumped into a second parallel cell (Behrends, et al., 1996). The draining and filling occurs within 2 hours and then the process is reversed; the sec¬ ond cell is drained quickly and the first cell is refilled. The reciprocating flow process is repeated continuously, with a small amount of influent continually added to the first cell and a fraction of the wastewater continually drawn from the second cell as effluent. The reciprocating two cell sys¬ tem was compared with a conventional two cell system for six months in side by side testing in late 1995 and early 1996 at Benton, Tennessee. Continued operation of both two-cell pairs in the reciprocating mode has continued since May of 1996. Comparing conventional operation to the reciprocating mode, the reciprocating mode produced sig¬ nificantly lower effluent BOD and ammonia nitrogen. One of the most studied full-scale VSB systems is lo¬ cated at the Village of Minoa in New York State (see Chap¬ ter 9). Two New York State agencies and the USEPA pro¬ vided grant funds to the Village for incorporation of sev¬ eral special features in the VSB system and for a research and technology transfer study of the system by research¬ ers at Clarkson University, Potsdam, NY. The system was originally designed and operated as a conventional VSB system, but during 15 months treating a primary effluent, the system performed very poorly compared to its design expectations. Faced with numerous complaints from nearby residents about hydrogen sulfide odors, the opera¬ tors started operating the system with occasional draw¬ down periods to control odors. The drawdown significantly reduced odors. In April 1997, when the experimental plan for the system called for the three cells to operated in se¬ ries, the Minoa operators decided to increase the flow by 100% and change the operation to a fill and drain mode. The fill and drain operation included a resting period dur¬ ing the drained condition and continuous operation for some time after filling. The fill and drain operation eliminated the hydrogen sulfide odors and also resulted in a significant improvement in the effluent quality. However, the opera¬ tors were not satisfied with the improved performance and experimented further. In 1998 they changed the operation to a mode that continued to the writing of this manual. Two of the wetland cells operate in a parallel fill and drain mode very similar to sequencing batch reactors. The third cell is operated in a conventional mode but in series with the first two cells. This mode of operation has resulted in an addi¬ tional significant improvement in effluent quality over the previous fill and drain mode of operation. See section 9.8 for a more detailed description of the operation and the results. Within the last five years, several unsaturated vertical flow systems have been constructed and tested in Europe. Most have been used for tertiary treatment of secondary effluents but they have also been used for treating septic tank and sugar beet processing effluents. They appear to perform significantly better than conventional VSB systems. Recommended design loadings are approximately twice that for conventional VSB systems. 5.9 References Batchelor, A. and R Loots. 1997. A critical evaluation of a pilot scale subsurface flow wetland: 10 years after com¬ missioning. Water Science & Technology, 35(5):337-343. Bavor, H.J., D.J. Roser, RJ. Fisher, and I.C. Smalls. 1989. Performance of solid-matrix wetland systems viewed as fixed-film bioreactors. In: D.A. Hammer (ed.) Constructed Wetlands for Wastewater Treatment. Chelsea, Ml: Lewis Publishers, pp. 646-656. Bavor, H.J. and T.J. Schulz. 1993. Sustainable suspended solids and nutrient removal in large-scale, solid matrix, constructed wetland systems. In: G.A. Moshiri (ed.) Con¬ structed wetlands for water quality improvement. Boca Raton, FLLewis Publishers, pp. 219-225. Behrends, L.L., Coonrod, H.S., Bailey E. and M.J. Bulls. 1993. Oxygen Diffusion Rates in Reciprocating Rock Biofilters: Potential Applications for Subsurface Flow Constructed Wetlands, In: Proceedings Subsurface Flow Constructed Wetlands Conference, August 16-17, 1993, University of Texas at El Paso. Behrends, L.L., F. J. Sikora, H.S. Coonrod, E. Bailey and C. McDonald. 1996. Reciprocating Subsurface-Flow Con¬ structed Wetlands for Removing Ammonia, Nitrate, and Chemical Oxygen Demand: Potential for Treating Do¬ mestic, Industrial and Agricultural Wastewater. Vol 5, Pp 251-263. In: Proceedings of the Water Environment Federation 69th Annual Conference. Dallas, TX. Bhattarai, R.R. and D.M. Griffin, Jr. 1998. Results of tracer tests in rock plant filters. Department of Civil Engineer¬ ing, Louisiana Tech University, Ruston, LA. Bounds, H.C., J. Collins, Z. Liu, Z. Qin, andT.A. Sasek. 1998. Effects of length-width ratio and stress on rock-plant fil¬ ter operation. Small Flow Journal, 4(1 ):4-14. 107 Bowmer, K.H. 1987. Nutrient removal from effluents by an artificial wetland: influence of rhizosphere aera¬ tion and preferential flow studied using bromide and dye tracers. Water Research, 21 (5):591-599. Breen, P.F. and A.J. Chick. 1995. Rootzone dynamics in constructed wetlands receiving wastewater: a comparison of vertical and horizontal flow systems. Water Science & Technology, 32(3):281-290. Chalk, E. and G. Wheale. 1989. The root-zone process at Holtby Sewage Treatment Works. Journal IWEM, 3:201-207. Cooper, P.F. 1990. European Design and Operations Guidelines for Reed Bed Treatment Systems, Rep. UI17, Water Research Centre, Swindon, U.K. Cooper, P.F., J.A. Hobson and S. Jones. 1989. Sewage Treatment by Reed Bed Systems. Journal of the In¬ stitution of Water and Environmental Management. 3 (1) 60. Crites, R. and G.Tchobanoglous. 1998. Small and de¬ centralized wastewater management systems. San Francisco, CA: McGraw-Hill. Dahab, M.F. and R.Y. Surampalli. 1999. Predicting Sub¬ surface Flow constructed Wetlands Performance: A Comparison of Common Design Models. In: Pro¬ ceedings of the Water Environment Federation 72th Annual Conference. New Orleans, LA. DeShon, G.C., A.L. Thompson, and D.M. Sievers. 1995. Hydraulic properties and relationships for the de¬ sign of subsurface flow wetlands. Presented at Ver¬ satility of Wetlands in the Agricultural Landscape Conference, Tampa, FL, Sept. 17-20, 1995. Fisher, P.J. 1990. Hydraulic characteristics of con¬ structed wetlands at Richmond, NSW, Australia. In: P.F. Cooper and B.C. Findlater (eds.) Constructed Wetlands in Water Pollution Control. Oxford, UK: Pergamon Press, pp. 21-31. Gearheart, R.A. 1998. Use of FWS constructed wetlands as an alternative process treatment train to meet unrestricted water reclamation standards. Presented at AWT-98, Advanced Wastewater Treatment, Re¬ cycling and Reuse, Milan, Italy, pp. 559-567. Gearheart, R.A. et al. 1999. Free water surface wet¬ lands for wastewater treatment: a technology as¬ sessment. USEPA, Office of Water Management, US Bureau of Reclamation, City of Phoenix, AZ. George, D.B. et al. 2000. Development of guidelines and design equations for subsurface flow con¬ structed wetlands treating municipal wastewater. USEPA, Office of Research and Development, Cin¬ cinnati, OH. Gersberg, R.M., B.V. Elkins and C.R. Goldman. 1983. Nitrogen Removal in Artificial Wetlands. Water Re¬ search 17 (9) 1009. Gersberg, R.M. et al. 1984. The Removal of Heavy Met¬ als by Artificial Wetlands, In: Proc Water Reuse Symp. Ill, Vol 2, AWWA Research Foundation, 639. Gersberg, R.M., et al. 1986. Role of Aquatic Plants in Wastewater Treatment by Artificial Wetlands. Wa¬ ter Research 20 (3) 363. Gersberg, R.M., Gearheart, R.A., and M. Ives. 1989. Pathogen Removal in Constructed Wetlands, Proc. From First International Conference on Wetlands for Wastewater Treatment, Chattanooga, TN, June 1988, Ann Arbor Press. Green, M.B. and J. Upton. 1994. Constructed Reed Beds: A Cost-Effective Way to Polish Wastewater Effluents for Small Communities. Water Env. Res. 66 (3) 188. Griffin, P., B. Green and A.Pritchard. 1998. Pathogen Removal in Subsurface Flow Constructed Reed Beds. In: Proceedings of the Water Environment Federation 71st Annual Conference. Orlando, FL. Heukelekian, H. and J.L. Balmat. 1959. Chemical com¬ position of the particulate fractions of domestic sew¬ age. Sewage & Industrial Wastes, 81:413-423. Jenssen, P.T. M. Muehlan, and T. Kregstad. 1993. Po¬ tential use of constructed wetlands for wastewater treatment in northern environments. In: Proceedings of 2nd International Conference on Design and Op¬ eration of Small Wastewater Treatment Plants, pp. 193-200. Kadlec, R.H. and R.L. Knight. 1996. Treatment Wet¬ lands. Boca Raton, FL: Lewis-CRC Press. Kadlec, R.H. and J.T. Watson. 1993. Hydraulics and sol¬ ids accumulation in a gravel bed treatment wetland. In: G.A. Moshiri (ed.) Constructed wetlands for wa¬ ter quality improvement. Boca Raton, FL:Lewis Pub¬ lishers, pp. 227-235. Kickuth, R. 1981. Abwasserreinigung in mosaikmatrizen aus aeroben und anaerobenteilbezirken. In: F. Moser (Ed), Grundlagen der Abwassereinigung, pp 639-665. King, A.C., C.A. Mitchell, and T. Howes. 1997. Hydrau¬ lic tracer studies in a pilot scale subsurface flow con¬ structed wetland. Water Science & Technology, 35(5): 189-196. Liehr, R.K. et al. 2000. Constructed wetlands treatment of high nitrogen landfill leachate. Project Number 94-IRM-U, Water Environment Research Founda¬ tion, Alexandria, VA. 108 Macmanus, B.E., A.L. Thompson, and D.M. Sievers. 1992. Predicting water mounding in subsurface rock bed wetlands. Presented at the Mid-Central Con¬ ference of the American Society of Agricultural En¬ gineers, St. Joseph, MO, March 13-14, 1992. Mankin, K.R. and G.M. Powell. 1998. Onsite rock-plant filter monitoring and evaluation in Kansas. In: Pro¬ ceedings of 8th National Symposium on Individual and Small Community Sewage Systems, ASAE, St. Joseph, Ml. May, E., J.E. Bulter, M.G. Ford, R.F. Ashworth, J.S. Wil¬ liams and M.M.M. Baghat. 1990. Comparison of Chemical and Microbiological Processes in Gravel Bed Hydroponic (GBH) Systems for Sewerage Treatment. In: Constructed Wetlands in Water Pol¬ lution Control. Cooper and Findlater (Eds) Pergamon Press U.K. Netter, R. and W. Bischofsberger. 1990. Hydraulic in¬ vestigations on planted soil filters. In: P.F. Cooper and B.C. Findlater (eds.) Constructed Wetlands in Water Pollution Control. Oxford, UK: Pergamon Press, pp. 11-20. Netter, R. 1994. Flow characteristics of planted soil fil¬ ters. Water Science & Technology, 29(4):37-44. Odegaard, M. 1987. Particle separation in wastewater treatment. In: Proceedings of 7th European Sew¬ age and Refuse Symposium, EWPCA, pp. 351-400. Peverly, J.H., J.M. Surface and T. Wang. 1995. Growth and Trace Metal Absorption by Phragmites austra¬ lis in Wetlands constructed for Landfill Leachate Treatment. Ecological Engineering 5, 21. Rash, J.K. and S.K. Liehr. 1999. Flow pattern analysis of constructed wetlands treating landfill leachate. Water Science & Technology, 40(3):309-315. Reedy, K.R. and W.F. DeBusk. 1985. Nutrient removal potential of selected aquatic macrophytes. J. Envi¬ ronmental Quality, 19:261. Reed, S.C., R.W. Crites and E.J. Middlebrooks. 1995. Natural Systems for Waste Management and Treat¬ ment. 2nd Ed. NY: McGraw Hill. Reed, S.C. and S. Giarrusso. 1999. Sequencing Op¬ eration Provides Aerobic Conditions in a Con¬ structed Wetland. In: Proceedings of the Water En¬ vironment Federation 72th Annual Conference. New Orleans, LA. Richard, M. and J. Snyder. 1994. Results of the pilot wetlands study at Las Amimas, CO. Report to the City of Las Animas, Colorado State University, CO. Sanford, W.E., T.S. Steenhuis, J-Y. Parlange, J.M. Sur¬ face, and J.H. Peverly. 1995a. Hydraulic conductiv¬ ity of gravel and sand as substrates in rock-reed filters. Ecological Engineering, 4:321-336. Sanford, W.E., T.S. Steenhuis, J.M. Surface, and J.H. Peverly. 1995b. Flow characteristics of rock-reed fil¬ ters for treatment of landfill leachate. Ecological Engi¬ neering, 5:37-50. Sanford, W.E. 1999. Substrate type, flow characteristics, and detention times related to landfill leachate treat¬ ment efficiency in constructed wetlands. In: G. Mulamootil, E.A. McBean, and F. Rovers (eds.) Con¬ structed wetlands for the treatment of landfill leachate. Boca Raton, FL:Lewis Publishers, pp. 47-56. Sapkota, D.P. and H.J. Bavor. 1994. Gravel bed filtration as a constructed wetland component for the reduction of suspended solids from maturation pond effluent. Water Science & Technology, 29(4):55-66. Smith, I.D., G.N. Bis, E.R. Lemon and L.R, Rozema. 1997. A Thermal Analysis of a Sub-surface, Vertical Flow Constructed Wetland. Wat. Sci. Tech. 35 (5) 55. Stengel, E. and Schultz-Hock, R. 1989. Denitrification in artificial wetlands. In: D.A. Hammer (ed.) Constructed Wetlands for Wastewater Treatment. Chelsea, Ml: Lewis Publishers, pp. 484-492. Surface, J.M., J.H. Peverly, T.S. Steenhuis, and W.E. Sanford. 1993. Effect of season, substrate composi¬ tion, and plant growth on landfill leachate treatment in a constructed wetland. In: G.A. Moshiri (ed.) Con¬ structed wetlands for water quality improvement. Boca Raton, FL:Lewis Publishers, pp. 461-472. Tanner, C.C. and J.P. Sukias. 1995. Accumulation of or¬ ganic solids in gravel-bed constructed wetlands. Wa¬ ter Science & Technology, 32(3):229-239. Tanner, C.C., J.P.S. Sukias, and M.P. Upsdell. 1998. Or¬ ganic matter accumulation during maturation of gravel- bed constructed wetlands treating farm dairy waste- waters. Water Research, 32(10):3046-3054. Thom, W.O., Y.T. Yang, and J.S. Dinger. 1998. Long-term results of residential constructed wetlands. In: Proceed¬ ings of 8th National Symposium on Individual and Small Community Sewage Systems, ASAE, St. Joseph, Ml. USEPA. 1993. Subsurface Flow Constructed Wetlands for Wastewater Treatment, A Technology Assessment. EPA 832-R-93-008. Vanier, S.M. and M.F. Dahab. 1997. Evaluation of Subsur¬ face Flow Constructed Wetlands for Small Commu¬ nity Wastewater Treatment in the Plains. In: Proceed¬ ings of the Water Environment Federation 70th An¬ nual Conference. Chicago, IL. van Oostrom, A.J. and R.N. Cooper. 1990. Meat process¬ ing effluent treatment in surface-flow and gravel-bed 109 constructed wastewater wetlands. In: P.F. Cooper and B.C. Findlater (eds.) Constructed Wetlands in Water Pollution Control. Oxford, UK: Pergamon Press, pp. 321-332. Watson, J.T., K.D. Choate, and G.R. Steiner. 1990. Per¬ formance of constructed wetland treatment systems at Benton, Hardin, and Pembroke, Kentucky, during the early vegetation establishment phase. In: P.F. Coo¬ per and B.C. Findlater (eds.) Constructed Wetlands in Water Pollution Control. Oxford, UK: Pergamon Press, pp. 171-182. WEF. 1998. Manual of Practice #8. Water Environment Federation, Alexandria, VA. Young, T.C., A.G. Collins, and T.L. Theis. 2000. Subsur¬ face flow wetland for wastewater treatment at Minoa, NY. Report to NYSERDA and USEPA, Clarkson Uni¬ versity, NY. 110 Chapter 6 Construction, Start-up, Operation, and Maintenance 6.1 Introduction Constructed wetland systems require infrequent opera¬ tion and maintenance activities to achieve performance goals if they are designed and constructed properly. This chapter discusses construction details, start-up procedures, and operation and maintenance activities for both free water surface wetlands and vegetated submerged beds. 6.2 Construction Construction of wetland systems primarily involves com¬ mon earth moving, excavating, backfilling, and grading. Most of the equipment and procedures are the same as those employed for construction of lagoons, shallow ponds, and similar containment basins. However, there are as¬ pects that require special attention to ensure flow through the wetland is uniform over the design treatment volume. Also, establishment of vegetation is unique to the basin construction and not always within the repertoire of con¬ struction contractors. It is the intent of this section to pro¬ vide guidance on these special and unique aspects of wetland construction. 6.2.1 Basin Construction The basic containment structure of constructed wetlands consists of berms and liners. The structural and watertight integrity of the liner and surrounding berm are critical. Fail¬ ure of either will result in loss of water, risk of ground water pollution, and possible loss of plants due to the decline of the water level in the wetland. 6.2.1.1 Basin Layout The topography of the site will dictate the general shape and configuration of the wetland. Constructing the wetland on sloping sites with the long axis along the contour will minimize the grading requirements. With proper layout, long sloping sites can reduce pumping costs by taking advan¬ tage of the available fall. 6.2.1.2 Site Preparation Clearing and grubbing, rough grading, and berm con¬ struction use the same procedures, techniques, and equip¬ ment used for lagoons and conventional water contain¬ ment basins. If possible, it is desirable to balance the cut and fill on the site to avoid the need for remote borrow pits or soil disposal. If agronomic-quality topsoil exists on the site, it should be stripped and stockpiled. In the case of FWS wetlands, the topsoil can be utilized as the rooting medium for the emergent vegetation and revegetation of the berm surfaces. A soil-rooting medium is not required for VSB systems. To meet its performance expectations, it is critically im¬ portant for the water to flow uniformly through the entire wetland area. Severe short-circuiting of flow can result from improper grading or nonuniform subgrade compaction. The operating water depth may be 60 cm (2 ft) or less, so ir¬ regularities in the bottom surface can induce preferential flow paths. Specified tolerances for grading will depend on the size of the wetland. A very large FWS wetland of several thousand acres cannot afford the effort to fine grade to very close tolerances. Therefore, the wetland should be subdivided into several smaller cells or the design should incorporate a sizing safety factor to compensate for po¬ tential short-circuiting. For smaller wetlands of a few hun¬ dred hectares or less, it is usually cost effective to specify closer grading tolerances. Bottom grades are an impor¬ tant consideration when converting existing lagoons to wet¬ lands. Because of the design depths in lagoons, careful grading of the bottom may not have been required. In many cases in which conversions were made without careful regrading, significant short-circuiting has occurred that re¬ duced the wetland treatment performance. Uniform compaction of the subgrade is also important to protect the liner integrity from subsequent construction activity (i.e., liner placement, soil placement for FWS wet¬ lands, gravel placement for VSB systems) and from stress when the wetland is filled. The loading on the liner is ap¬ proximately 2,200 kg/m 2 (450 lbs/ft 2 ) including the plant mass. Short-circuiting of flow through a FWS wetland also can result from ruts and low areas in the subgrades. The subgrade should be uniformly compacted to the same lev¬ els used for native soils in road subgrades. Fine grading and compaction of the native subgrade soils also depends on the liner requirements. Most wetland cells are graded level from side to side and either level or with a slight slope in the direction of flow. Wetlands are often con¬ structed with a bottom slope of 1% or less which is suffi¬ cient to drain the cell if and when maintenance is required. Ill 6.2.1.3 Berms Berms in constructed wetlands contain water within spe¬ cific flow paths. Exterior berms are designed to prevent unregulated flow releases. Interior berms are used to aug¬ ment flow distribution. External berms are typically built to provide 0.6 to 1 m (2-3 ft) of freeboard with a width at least 3 m (10 ft) at the top to permit service vehicle ac¬ cess. The amount of freeboard should be enough to con¬ tain a given storm rainfall amount. Side slopes should be a maximum of 3:1; however, slopes of 2:1 have been used for internal side slopes, particularly when liners or erosion control blankets are used. Access ramps into each cell of the system should be shallow enough for maintenance equipment to enter. All berms should be constructed in conformance with standard geotechnical considerations, for they may be subject to local dam safety regulations. Design considerations for internal berms, however, are less critical since they are not designed for water containment. See Figure 6-1 for typical design features of constructed wetland berms. Short-circuiting around the edges of cells has been ex¬ perienced in some FWS wetlands where vegetation on the berm slope is absent. This is a particular problem if syn¬ thetic liners are used. The liners do not provide a good rooting medium and so may remain bare. The open water gap between the berm and the vegetated area in the wet¬ land proper provides a preferential flow path. A soil layer can be placed on the berm side slope to establish vegeta¬ tion, but the slope is very susceptible to erosion, particu¬ larly near the water line. The soil loss from erosion will have the added impact of reducing the detention time in the wetland. This has not been a problem in clay-lined wetlands because the clay provides a good rooting me¬ dium. 6.2.1.4 Liners Liners used for wetlands are the same as those typically used for lagoons and ponds. The materials include: Polyvinyl chloride (PVC) Polyethylene (PE) Polypropylene Most systems typically use 30 mil polyvinyl chloride (PVC) or high-density polyethylene (HDP). These may be prefabricated for small, individual-residence wetlands, but Grassed Berm (> 3:1 typical) Figure 6-1. Examples of constructed wetland berm construction 112 they are usually constructed in place using conventional procedures for assembly, joint bonding, and anchoring. Liners also may include scrims, which are more costly. The scrim is a woven nylon or polypropylene net embedded in plastic or surrounding bentonite. Plastic liners with scrims are marketed under trade names such as Hypalon or XR- 5. Several good resources are available for liner applica¬ tion and selection (EPA, 1993; EPA, 1994; Rumer and Mitchell, 1996). Liner punctures must be prevented during placement and subsequent construction activity. If the subgrade contains sharp stones, a geotextile fabric should be placed beneath the liner. A geotextile fabric or a layer of sand approximately 5 cm (2 in) thick should be placed on top of the liner if crushed rock is used in a VSB system. The engineer should specify that the liner installer provides written approval of the condition of the subgrade as a condition prior to liner installation. Many membrane liners currently used require protec¬ tion from ultraviolet solar radiation. Conventional methods can be used to achieve protection, but VSB systems should not use a soil cover as UV protection since erosion may wash soil into the bed and result in local media clogging. Riprap material consisting of aggregate approximately 8- 15 cm (3-6 in) in size is recommended for this application. This larger riprap will reduce the potential for weeds to become established and spread into the wetland. It can also withstand foot traffic for the life of the system. Clay liners also have been used. Manufactured liners using bentonite are common. The bentonite may be mixed with the native soils and compacted, or it may be in the form of pads or blankets consisting of bentonite between two scrims of finely woven polypropylene or polyethylene. Native soils may be used if they have sufficiently high clay content to achieve the necessary permeability. Usu¬ ally the state regulatory agency will specify the acceptable permeability. Typically, the clay liner must be 0.3 m (1 ft) or more in thickness to provide the necessary hydraulic bar¬ rier. In the case of a FWS, the surface of the clay layer should be well compacted to discourage root penetration by the emergent vegetation as the wetland matures. 6.2.1.5 Inlet and Outlet Structures Inlet and outlet structures distribute the flow into the wetland, control the flow path through the wetland, and control the water depth. Multiple inlets and outlets spaced across either end of the wetland are essential to ensure uniform influent distribution into and flow through the wet¬ land. These structures help to prevent “dead zones” where exchange of water is poor, resulting in wastewater deten¬ tion times that can be much less than the theoretical de¬ tention times. In small- to medium-sized wetlands, perforated or slot¬ ted manifolds running the entire wetland width typically are used for both the inlets and outlets. Sizes of the mani¬ folds, orifice diameters, and spacing are a function of the projected flow rate. For example, the first cell of the FWS wetland in West Jackson County, Ml, is designed for an average flow of 2,270 m 3 /d (600,000 gpd). It uses a 300 mm (12 in)-diameter PVC manifold for the inlet that ex¬ tends the full 76 m (250 ft) width of the cell. The manifold is perforated with 50 mm (2 in)-diameter orifices on 3 m (10 ft) centers. It rests on a concrete footing to ensure sta¬ bility and discharges to a 150 mm (6 in)-thick layer of coarse aggregate. A single inlet would not be suitable for a wide wetland cell such as this because it would not be possible to achieve uniform flow across the cell. Multiple weir boxes could be used as an alternative. Splitter boxes using “V” notched weirs or other methods can be used to divide the influent flow equally between the individual weir boxes. The weir boxes also can be used for measuring the influ¬ ent flow. Examples of these types of structures can be found in irrigation engineering textbooks. Where possible, the inlet manifold should be installed in an exposed position to allow access by the operator for flow adjustment and maintenance. Several alternatives to the simple drilled orifice can be used for flow distribution control. See Figure 6-2 for examples of inlet manifolds. In cold climates where extended periods of freezing weather are possible or where public exposure is an is¬ sue, a submerged inlet is necessary. In these instances, the simple perforated inlet manifold is used. Since it is not possible to adjust the level of the submerged manifolds after construction is completed, extra effort should be ex¬ pended to compact and grade the inlet and outlet zones to limit subsequent settling. It may be necessary to support the manifold on concrete footings where the underlying soils are potentially unstable. An accessible cleanout should be provided at each end of the submerged manifold to allow flushing if the manifold becomes clogged. Shut-off devices should be provided on all inlets to permit mainte¬ nance or resting of the wetland. In FWS wetlands, the encroachment of adjacent emer¬ gent vegetation may clog the manifold outlets with plant litter and detritus. This problem may be eliminated by con¬ structing a deep water zone approximately 1-1.3 m (3-4 ft) deeper than the bottom of the rest of the wetland. The open area should be limited to 1 m (3 ft) in width. The manifold also can be enclosed in a berm of coarse riprap 8-15 cm (3-6 in) in size. The coarse riprap inhibits plant growth. The open water design, however, allows easier access to the manifold for maintenance, but may encour¬ age wildlife visitation and the potential effluent quality deg¬ radation that accompanies it. Outlet structures help to control uniform flow through the wetland as well as the operating depth. If submerged out¬ let manifolds are used, they must be connected to a level control device that permits the operator to adjust the water depth in the wetland. This device can be an adjustable weir or gate, a series of stop logs, or a swiveling elbow (Figure 6-3). An alternative to submerged manifolds for inlet and out¬ let structures is multiple weir or drop boxes. These are 1 13 Cleanout (both ends) 3E ®o o° oU fig °o°> otf o9o 0 OoQ » 96 rr fl ° 0 °lo 0 •\° 0 o 0 o *n * <<*, „ * Va, a. iK. ^