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− | < | + | [[File:Watershed scale stormwater treatment train.PNG|thumb|500px|alt=photo illustrating a watershed scale treatment train approach using a multi-BMP approach to managing the quantity and quality of stormwater runoff.|<font size=3>Watershed scale stormwater management approach using a multi-BMP approach to managing the quantity and quality of stormwater runoff. The BMP sequence starts with pollution prevention and progresses through source control, on-site treatment, and regional treatment before the runoff water is discharged to a receiving water. On-site and regional practices treat stormwater runoff and can be incorporated into a stormwater treatment train.</font size>]] |
− | + | On a watershed scale, the management of stormwater begins with | |
− | + | <span title="Pollution prevention practices are pro–active activities and strategies instituted to avoid introducing pollution into the environment. Residential pollution prevention practices are household and neighborhood activities that prevent or reduce the contamination of stormwater. Municipal pollution prevention practices prevent or reduce stormwater contamination from public sources such as streets, parking areas, maintenance vehicles, storm and sanitary sewers, dumpsters, swimming pools and other potential stormwater hotspots. Industrial and commercial pollution prevention practices are private operation and maintenance activities implemented by owners or individuals responsible for industrial and commercial sites that prevent or reduce the contamination of stormwater."> [https://stormwater.pca.state.mn.us/index.php?title=Pollution_prevention pollution prevention]</span> | |
− | < | + | (e.g. pet ordinances, buffer requirements, public education), followed by Source Controls (e.g. |
+ | <span title="Street sweeping is a practice to remove debris, such as leaves and sand, from streets. There are three general categories of street sweepers: mechanical broom, regenerative air, and high-efficiency sweepers."> [http://stormwater.pca.state.mn.us/index.php/Street_sweeping_for_trees sweeping]</span>, | ||
+ | Illicit Discharge Detection and Elimination), Onsite Stormwater BMPs (e.g. | ||
+ | <span title="Bioretention, also referred to as rain garden, is a terrestrial-based (up-land as opposed to wetland) water quality and water quantity control process. Bioretention employs a simplistic, site-integrated design that provides opportunity for runoff infiltration, filtration, storage, and water uptake by vegetation. Bioretention areas are suitable stormwater treatment practices for all land uses, as long as the contributing drainage area is appropriate for the size of the facility. Common bioretention opportunities include landscaping islands, cul-de-sacs, parking lot margins, commercial setbacks, open space, rooftop drainage and street-scapes (i.e., between the curb and sidewalk). Bioretention, when designed with an underdrain and liner, is also a good design option for treating stormwater hotspots (PSHs). Bioretention is extremely versatile because of its ability to be incorporated into landscaped areas. The versatility of the practice also allows for bioretention areas to be frequently employed as stormwater retrofits."> [https://stormwater.pca.state.mn.us/index.php?title=Bioretention rain gardens]</span>, | ||
+ | <span title="Permeable pavements allow stormwater runoff to filter through surface voids into an underlying stone reservoir for temporary storage and/or infiltration. The most commonly used permeable pavement surfaces are pervious concrete, porous asphalt, and permeable interlocking concrete pavers (PICP). Permeable pavements have been used for areas with light traffic at commercial and residential sites to replace traditional impervious surfaces in low-speed roads, alleys, parking lots, driveways, sidewalks, plazas, and patios. While permeable pavements can withstand truck loads, permeable pavement has not been proven in areas exposed to high repetitions of trucks or in high speed areas because its’ structural performance and surface stability have not yet been consistently demonstrated in such applications."> [https://stormwater.pca.state.mn.us/index.php?title=Permeable_pavement permeable pavement]</span>), | ||
+ | and Regional BMPs (e.g. | ||
+ | <span title="Generally speaking, the term “stormwater pond” may refer to any constructed basin that is built for the purpose of capturing and storing stormwater runoff, either temporarily or for an extended period of time, in order to prevent or mitigate downstream water quantity or quality impacts. Several distinct structure types (wet ponds, dry ponds, etc.) are included in this general category, and they are discussed in more detail in the Manual."> [https://stormwater.pca.state.mn.us/index.php?title=Stormwater_ponds constructed pond]</span> | ||
+ | or | ||
+ | <span title="Stormwater wetlands are similar in design to stormwater ponds and mainly differ by their variety of water depths and associated vegetative complex. They require slightly more surface area than stormwater ponds for the same contributing drainage area. Stormwater wetlands are constructed stormwater management practices, not natural wetlands. Like ponds, they can contain a permanent pool and temporary storage for water quality control and runoff quantity control. Wetlands are widely applicable stormwater treatment practices that provide both water quality treatment and water quantity control. Stormwater wetlands are best suited for drainage areas of at least 10 acres. When designed and maintained properly, stormwater wetlands can be an important aesthetic feature of a site."> [https://stormwater.pca.state.mn.us/index.php?title=Stormwater_wetlands stormwater wetlands]</span>, | ||
+ | large underground infiltration system). All these practices comprise a stormwater management system. | ||
− | + | Stormwater treatment implies removal of pollutants or stormwater volume once they have been generated. On-site and regional practices treat stormwater runoff. The term Stormwater Treatment Train has loosely been used since the mid-1980s to represent a multi-BMP approach to managing the quantity and quality of stormwater runoff and has often included prevention and source control practices. In this discussion, treatment train refers to treatment practices. | |
− | |||
− | |||
− | =====Water Quality Pollutant Removal Mechanisms===== | + | The concept of treatment trains has been commonly used in the field of wastewater treatment. Professionals in this field will often describe each component of the treatment train in terms of the structure within the plant, i.e. bar screens, grit chambers, primary settling tanks, secondary treatment tanks. For the purpose of stormwater management, the lexicon differs by focusing on the processes utilized within the BMP, rather than the structural feature of a BMP. For the purpose of the Minnesota Stormwater Manual and the information contained in this article, the definitions of practices vs. processes are based on the recommendations contained in [http://news.wef.org/wef-releases-design-of-urban-stormwater-controls-mop-23/ Design of Urban Stormwater Controls], published jointly by the Water Environment Federation and American Society of Civil Engineers in 2012. The following approach uses different terminology than developed by WEF, which refers to Practices as Unit Operations. Practice has been selected for this article to parallel the common usage in Minnesota of Best Management Practices ([[Glossary#B|BMPs]]) and Stormwater Management Practices (SMPs). |
− | *Screening/[[Filtration]]: The capture of solid pollutants through screens and/or filters which use a media such as sand. Effective for removal of suspended solids. | + | |
− | *[[Infiltration]]/ | + | A closer look at on-site and regional BMPs shows that each BMP utilizes one or more components that work together to remove pollutants utilizing combinations of hydraulic, physical, biological, and chemical methods. A well-developed stormwater treatment train will combine these processes in a manner that ensures management of all pollutants that have been identified as affecting the receiving water. |
− | *Settling: Deposition of solids in a water column, usually in a pond, wetland or hydrodynamic device. Typically a minimum of 12 hours of detention is needed to effectively settle solids in [[stormwater ponds]] and [[stormwater wetlands]]. | + | |
− | *Biological Uptake: Vegetative and microbial uptake of nutrients. Usually accomplished in [[biofiltration]] devices and [[stormwater wetlands]]. | + | ==Practice versus process== |
+ | Stormwater process describes the mechanism by which pollutants are removed. For example, infiltration and evaporation are different processes for managing stormwater volume. Stormwater practices are Best Management Practices. These are the stormwater controls in which the pollutant control process, or multiple processes, takes place. In the stormwater industry, many BMPs have evolved and have been given labels that describe the primary process utilized by that BMP/practice. A key example is the term infiltration, which is used interchangeably as both a process and as a practice. | ||
+ | |||
+ | Physically, each BMP/practice utilizes multiple processes. For example, the practice of a bioinfiltration BMP utilizes the following processes: | ||
+ | *Hydraulic: [[Glossary#I|infiltration]], [[Glossary#T|transpiration]] | ||
+ | *Physical: [[Glossary#S|sedimentation]], [[Glossary#F|filtration]] | ||
+ | *Biological: plant metabolism, [[Glossary#N|nitrification]] / [[Glossary#D|denitrification]], pathogen die-off | ||
+ | *Chemical: [[Glossary#A|adsorption]] / [[Glossary#A|absorption]] / [[Glossary#I|ion exchange]] | ||
+ | *Other: thermal control | ||
+ | |||
+ | The following tables differentiate between stormwater process and practice. To view all the information in these tables in a single Excel file, [http://stormwater.pca.state.mn.us/index.php/File:BMP_processes.xlsx link here]. | ||
+ | |||
+ | *[[Processes for removing pollutants from stormwater runoff]] | ||
+ | *[[Practices for controlling pollutants in stormwater runoff]] | ||
+ | *[[Processes utilized by Best Management Practices - Infiltrators]] | ||
+ | *[[Processes utilized by Best Management Practices - Swales and Strips]] | ||
+ | *[[Processes utilized by Best Management Practices - Filters]] | ||
+ | *[[Processes utilized by Best Management Practices - Constructed Basins]] | ||
+ | *[[Processes utilized by Best Management Practices - Manufactured Devices]] | ||
+ | *[[Processes utilized by Best Management Practices - Storage and Reuse]] | ||
+ | |||
+ | ==Typical stormwater treatment train== | ||
+ | [[file:Process and particle size.jpg|300px|thumb|alt=schematic of treatment processes and particles size|<font size=3>Processes based on particulate sizes (Source: Wong, et. al. 2002. Reprinted with permission of ASCE).</font size>]] | ||
+ | |||
+ | A stormwater treatment train incorporates at least two processes to maximize the control of pollutants from the runoff. The BMP(s) selected may consist of one or multiple practices, depending on many considerations, including available space, physical conditions at a site, and regulatory requirements. See the tables above for a summary of processes and practices. | ||
+ | |||
+ | Hydraulic and physical processes remove larger solids and associated pollutants during storm events while biological and chemical processes that treat the finer solids and dissolved pollutants occur between storms ([[Using the treatment train approach to BMP selection#References|Scholes, et. al]]. 2007, [[Using the treatment train approach to BMP selection#References|Wong, et. al.]] 2001). Once complete, a treatment train can (adapted from [[Using the treatment train approach to BMP selection#References|Strecker]], 2005) | ||
+ | *minimize the rate of runoff by utilizing a hydraulic process; | ||
+ | *remove bulk solids by utilizing a physical process; | ||
+ | *remove settleable solids and floatables by utilizing a physical process; | ||
+ | *remove suspended and colloidal solids by utilizing a physical, biological or chemical process; and | ||
+ | *remove colloidal, dissolved, volatile, and pathogens by using a biological or chemical process. | ||
+ | Using this framework for pollutant removal, particulate size of the pollutant(s) of concern should be matched to the stormwater practice best suited to remove that pollutant from stormwater runoff ([[Using the treatment train approach to BMP selection#References|Wong, et. al.]] 2002, [[Using the treatment train approach to BMP selection#References|Strecker]], 2005). The figure to the right suggests treatment processes for a range of particulate sizes commonly found in stormwater runoff. Chemical processes are rarely utilized, given the higher capital and operating costs of chemical feeds and controls. | ||
+ | |||
+ | The resulting stormwater treatment train may result in a single BMP, such as a stormwater wetland, that utilizes multiple treatment train processes and by definition can be considered a stand-alone stormwater treatment train. Or it could become a multi-BMP treatment train with BMPs operating in series or parallel to each other. Low Impact Development (LID) and Traditional development are two typical configurations of treatment trains currently utilized by site designers that meet the definition of stormwater treatment trains. The focus of LID is to keep the raindrop as close to it's source as possible utilizing techniques such as [http://stormwater.pca.state.mn.us/index.php/Stormwater_infiltration_Best_Management_Practices infiltration] and [http://stormwater.pca.state.mn.us/index.php/Stormwater_re-use_and_rainwater_harvesting capture/storage/reuse]. Traditional development typically employs [http://stormwater.pca.state.mn.us/index.php/Stormwater_filtration_Best_Management_Practices filtration] and [http://stormwater.pca.state.mn.us/index.php/Stormwater_sedimentation_Best_Management_Practices sedimentation] practices such as [[Filtration|swales]] and [[Stormwater ponds|constructed ponds]] and [[Stormwater wetlands|wetlands]]. These practices may or may not treat rainwater close to its source but generally have minor impacts on stormwater volume. Where feasible, LID practices are favored from a stormwater management practice as they reduce both stormwater volume and pollutant loading. LID practices, however, are often constrained by site factors, such as [http://stormwater.pca.state.mn.us/index.php/Shallow_soils_and_shallow_depth_to_bedrock shallow depth to bedrock], [http://stormwater.pca.state.mn.us/index.php/Stormwater_infiltrations_and_contaminated_soils_and_groundwater soil or groundwater contamination], and space limitations (e.g. [[Glossary#U|ultra-urban settings]]). | ||
+ | |||
+ | Examples of these two types of treatment trains are provided below and illustrated in the schematic to the right. In the LID example, water falling on a rooftop is filtered through a green roof, which stores some water for eventual uptake by plants and routes the remaining water to a permeable pavement and then to an infiltration BMP. The traditional configuration routes water off-site through a swale, which provides some treatment, before the water is discharged to a regional system. | ||
+ | |||
+ | [[file:Treatment train schematic 2.png|300px|thumb|alt=schematic for treatment trains|<font size=3>Schematic showing typical treatment trains for Low Impact development and traditional development scenarios.</font size>]] | ||
+ | |||
+ | :'''Example treatment train configuration for Low Impact Development site''' | ||
+ | *[[Green roofs|Green roof]] | ||
+ | **Hydraulic: transpiration, attenuation | ||
+ | **Biological: plant metabolism | ||
+ | *[[Permeable pavement]] | ||
+ | **Hydraulic: infiltration | ||
+ | **Physical: filtration | ||
+ | *[[Bioretention]] | ||
+ | **Hydraulic: infiltration, transpiration | ||
+ | **Physical: filtration, sedimentation | ||
+ | **Biological: plant metabolism, pathogen die-off, nitrification / denitrification | ||
+ | *Cistern for irrigation | ||
+ | **Hydraulic: diversion | ||
+ | |||
+ | :'''Example treatment train configuration for traditional development''' | ||
+ | *[[Filtration|Swales]] | ||
+ | **Hydraulic | ||
+ | **Physical: sedimentation, filtration | ||
+ | *[http://stormwater.pca.state.mn.us/index.php/Flow-through_structures_for_pre-treatment Swirl concentrator] | ||
+ | **Hydraulic: vortex separation | ||
+ | *[[Stormwater wetlands|Stormwater wetland]] | ||
+ | **Hydraulic: peak flow attenuation | ||
+ | **Physical: skimming, sedimentation | ||
+ | **Biological: plant metabolism, pathogen die-off | ||
+ | |||
+ | ==Benefits and Disadvantages== | ||
+ | On-site treatment trains that have been found to be the most effective are those that maintain runoff onsite while allowing sufficient time for hydraulic, physical, biological, and chemical processes to take place ([[Using the treatment train approach to BMP selection#References|Rushton]], 2004). This has been demonstrated to be true in multiple case studies, as well as in Minnesota case studies including the [http://stormwater.pca.state.mn.us/index.php/Case_studies_for_stormwater_treatment_trains#Empire_Wastewater_Treatment_Plant_Stormwater_Improvements Empire Wastewater Treatment Plant project] owned and operated by the Metropolitan Council. | ||
+ | |||
+ | On a larger catchment area or watershed scale the pollution reduction of treatment train BMPs is effective, but less so than on an on-site basis. Generally, the highest level of pollutant reduction is achieved in the first BMP, with each successive BMP becoming less effective. The theory of why this occurs is based on the concept of irreducible pollutants. For more information on irreducible concentration, [https://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=2&ved=2ahUKEwi83obyjdDjAhUNa80KHYJ-AFwQFjABegQIARAC&url=https%3A%2F%2Fowl.cwp.org%2F%3Fmdocs-file%3D4745&usg=AOvVaw0f_0cI6H3DTQU0AR3I00Zm link here]. Essentially the second, third, etc. BMPs in the treatment train are receiving runoff that has considerably less concentration of pollutants and which at some point are below the theoretical irreducible concentration for the BMP. One recommended approach to adjust for the uncertainties of pollutant removals would be to create a prioritized list of BMPs that are listed or ranked according to the pollutant removal effectiveness for each pollutant. Modelers utilizing this technique are advised to adjust the pollutant concentrations and kinetic uptake factor (k) for each pollutant being assessed by the model ([[Using the treatment train approach to BMP selection#References|Scholes, et al,]] 2007). | ||
+ | |||
+ | ==Costs== | ||
+ | A review of literature did not find any studies that assessed the cost effectiveness of stormwater treatment trains. It is assumed that the cost considerations for a stormwater treatment train would parallel these cost considerations for individual stormwater BMPs. | ||
+ | *Cost comparisons should assess the cost through the life cycle of the BMP ([[Using the treatment train approach to BMP selection#References|WEF]], 2012, [[Using the treatment train approach to BMP selection#References|Strecker]], 2005). | ||
+ | *Larger projects typically have a better economy of scale ([[Using the treatment train approach to BMP selection#References|WEF]], 2012). | ||
+ | *Retrofits are more expensive than installation of BMPs in new construction projects ([[Using the treatment train approach to BMP selection#References|WEF]], 2012, Watershed Protection Techniques). The cost to retrofit is 1.5 to 4.0 times the cost of BMP installation in new construction ([[Using the treatment train approach to BMP selection#References|CWP]], 2007). | ||
+ | *Most BMP studies report the construction costs, only. An additional 25 to 32 percent should be added to the capital budget to accommodate design, permitting, and contingency costs ([[Using the treatment train approach to BMP selection#References|Strassler]], 1999) | ||
+ | *Land costs have the greatest impact on stormwater facility costs ([[Using the treatment train approach to BMP selection#References|Strecker]], 2005). | ||
+ | *Cost per volume (gallon, cubic foot, etc) is more reliable than cost per area (acre) when comparing BMP options ([[Using the treatment train approach to BMP selection#References|Strecker]], 2005, [[Using the treatment train approach to BMP selection#References|Weigand]], 1986). | ||
+ | *O&M costs can be calculated as a percentage of construction costs ([[Using the treatment train approach to BMP selection#References|Strassler]], 1999). | ||
+ | |||
+ | ==Stormwater treatment train approach== | ||
+ | |||
+ | ===General considerations=== | ||
+ | A stormwater management system begins at the point that the rainfall hits the ground and becomes runoff. Site owners, maintainers, designers, etc. that are establishing a stormwater management system should consider non-structural practices as well as structural BMPs. A comprehensive stormwater management system includes | ||
+ | *practices that control the development of runoff; | ||
+ | *practices that prevent generation of pollutants, (Pollution Prevention and Education Practices); | ||
+ | *practices that remove pollutants before contact with rainfall (Source Controls); and | ||
+ | *BMPs that utilize multiple processes that remove pollutants in stormwater runoff. | ||
+ | Treatment train implies treatment or removal of stormwater volume or pollutants. Prevention and source control practices are therefore not treatment practices. The remainder of this section therefore details the process of developing the structural practices, or treatment portion, of the stormwater management system. | ||
+ | |||
+ | ===Developing a stormwater treatment train=== | ||
+ | Development of a stormwater treatment train is an iterative process that balances site constraints, project goals, and available budget. The following steps lay out the process for establishing a stormwater treatment train. The results of one of the steps may cause designers to reconsider earlier decisions on sizing, siting, etc., as the project progresses. | ||
+ | :'''Step 1''' - Review project goals and site conditions | ||
+ | The site conditions, regulatory requirements, and project purpose will vary from site to site and from city to city. Information to assemble includes: | ||
+ | *Project goals – is the project intended to solve a drainage problem, meet regulatory requirements, or both? The answer to this question determines whether the goals are related to runoff volume or water quality. If the objectives are related to water quality, the pollutants of concern need to be identified. | ||
+ | *Regulatory requirements – are there any regulatory requirements that will influence the stormwater system? | ||
+ | *Site conditions: collect information on impervious surface, drainage area, runoff quality, soils, topography | ||
+ | :'''Step 2''' - Review pollutant removal processes and identify potential practices | ||
+ | The purpose of this step is to create a list of BMPs that work together to remove the pollutants of concern identified in Step 1. | ||
+ | *Select processes required to manage pollutants | ||
+ | *Identify combination(s) of BMPs that include the processes required to manage the identified pollutants | ||
+ | To make these determinations, use [http://stormwater.pca.state.mn.us/index.php/File:BMP_processes.xlsx this table], which provides a summary of processes and practices. | ||
+ | :'''Step 3''' - Determine site constraints that affect BMP placement and sizing | ||
+ | Site constraints will affect the sizing, location, and performance of the BMPs identified in Step 2. The purpose of this step is to narrow down the BMP options based on such site constraints as: | ||
+ | *Available space | ||
+ | *Access for maintenance | ||
+ | *[http://stormwater.pca.state.mn.us/index.php/Stormwater_infiltration Limitations on infiltration] related to soil type, soil contamination, depth to groundwater, presence of structures, utility conflicts, and/or depth to bedrock | ||
+ | *Regulatory requirements that affect the BMP volume or footprint | ||
+ | *Compatibility with other site uses, including green space requirements, public spaces, structures, etc. | ||
+ | :'''Step 4''' - Select individual BMPs and evaluate range of performance | ||
+ | Review each BMP identified in Step 3 to confirm that each pollutant removal process identified in Step 2 is present in the combination of BMPs selected in Step 3. If not, then Step 3 should be reviewed and alternative BMPs proposed. | ||
+ | :'''Step 5''' - Size BMPs and assess performance | ||
+ | Size the BMP and use the MIDS calculator or other technique detailed in the Credits section of the MN Stormwater Manual to assess the performance. Review results against goals set in Step 1. If goals are not fully achieved, then resize the BMPs or return to Step 3 to select alternative BMPs. | ||
+ | :'''Step 6''' - Review construction and operation criteria | ||
+ | Designers should assess construction and operation considerations that need to be incorporated into the construction plans and/or the Operations and Maintenance Manual that are necessary to ensure the BMP operates as designed and is properly maintained. | ||
+ | |||
+ | ==References== | ||
+ | *Rushton, Betty. 2002. [https://pdfs.semanticscholar.org/4ef7/938089d5c71e433807bf54783985d28b798e.pdf Enhanced parking lot design for stormwater treatment]. In Proc. of 9th International Conference on Urban Drainage, September 8-13, 2002 EWRI/IWA/ASCE. | ||
+ | *Scholes, Lian, D. Michael Revitt, and J. Bryan Ellis. 2008. ''A systematic approach for the comparative assessment of stormwater pollutant removal potentials''. Journal of Environmental Management 88: no. 3: 467-478. | ||
+ | *Schueler, Thomas R. 2000. [https://owl.cwp.org/mdocs-posts/elc_pwp68/ The economics of stormwater treatment: An update]. Article 68: 401-405. | ||
+ | *Schueler, Thomas R., and Jennifer Zielinski. 2007. [https://owl.cwp.org/mdocs-posts/urban-subwatershed-restoration-manual-series-manual-3/ Urban stormwater retrofit practices]. Center for Watershed Protection. | ||
+ | *Strassler, Eric, Jesse Pritts, and Kristen Strellec. 1999. [https://www.epa.gov/sites/production/files/2015-11/documents/urban-stormwater-bmps_preliminary-study_1999.pdf Preliminary data summary of urban storm water best management practices]. United States Environmental Protection Agency, Office of Water. | ||
+ | *Strecker, Eric. 2006. [https://www.iwapublishing.com/books/critical-assessment-stormwater-treatment-and-control-selection-treatment Critical Assessment of Stormwater Treatment and Control Selection Treatment]. | ||
+ | *Water Environment Federation. 2012. ''Design of urban stormwater controls'' (2nd ed.). New York: McGraw-Hill Professional. | ||
+ | *Wiegand, Cameron, Thomas Schueler, Wendy Chittenden, and Debra Jellick. 1986. ''Cost of urban runoff quality controls''. In Urban Runoff Quality@ sImpact and Quality Enhancement Technology, pp. 366-380. ASCE. | ||
+ | *Wong, Tony HF. 2001. ''A changing paradigm in Australian urban stormwater management''. In 2nd South Pacific Stormwater Conference, pp. 1-18. 2001. | ||
+ | *Wong, Tony HF, Tim D. Fletcher, Hugh P. Duncan, John R. Coleman, and Graham A. Jenkins. 2002. ''A model for urban stormwater improvement conceptualization''. Global Solutions for Urban Drainage (2002): 8-13. | ||
+ | |||
+ | ==Related articles== | ||
+ | *[[Using the treatment train approach to BMP selection]] | ||
+ | *[[Scenario for developing a stormwater treatment train for a parking lot]] | ||
+ | *[[Scenario for developing a stormwater treatment train for an ultra-urban setting]] | ||
+ | *[[Scenario for developing a stormwater treatment train for a site with limited infiltration capacity]] | ||
+ | *[[Scenario for developing a stormwater treatment train for a retrofit site]] | ||
+ | *[[Scenario for developing a stormwater treatment train for constructed ponds in new development]] | ||
+ | *[[Case studies for stormwater treatment trains]] | ||
+ | |||
+ | <noinclude> | ||
+ | [[Category:Level 1 - Best Management practices]] | ||
+ | [[Category:Level 2 - Best management practices/Guidance and information]] | ||
+ | [[Category:Level 2 - Management/Watershed scale and treatment train]] | ||
+ | </noinclude> | ||
+ | |||
+ | |||
+ | <!-- | ||
+ | BELOW IS TEXT FROM THE ORIGINAL MANUAL | ||
+ | The basic premise for selection of a Best Management Practice (BMP) or group of BMPs is to follow the treatment train approach. Under the treatment train approach, stormwater management begins with simple methods that minimize the amount of runoff that occurs from a site and methods that prevent pollution from accumulating on the land surface and becoming available for wash-off. Even though we know that we will never be able to fully accomplish either of these goals, we can make substantial progress using the [[Better site design|Better Site Design]], Low Impact Development (LID), [[Pollution prevention|pollution prevention]], volume minimization, and [[Temporary construction erosion and sediment control|temporary construction erosion and sediment control]] techniques. | ||
+ | <p>After all of the efforts possible are made to minimize runoff and surface wash-off, we must recognize that some potential for runoff will occur. The next major BMP then becomes collection and treatment of runoff locally and regionally, either as stand-alone practices or in treatment train combinations. Some of the available BMPs are best used to reduce runoff volume, while others focus on water quality improvement. Some BMPs will be easy to implement, while others involve serious engineering and sophisticated design. Other BMPs used in a treatment train include [[Bioretention|bioretention]] devices, filtration practices such as [[Swales|swales]], infiltration practices such as [[Infiltration trench|infiltration trenches]] and infiltration basins, [[Stormwater ponds|stormwater ponds]] and [[Stormwater wetlands|stormwater wetlands]].</p> | ||
+ | |||
+ | ==Proper Treatment Accounting== | ||
+ | [[File:Treatment train schematic.png|thumb|300px|alt=schematic showing the treatment train approach to stormwater runoff management|<font size=3>The treatment train approach to stormwater management includes a sequence of BMPs that treat stormwater, starting with pollution prevention and continuing through source control, on site water treatment, and regional water treatment before stormwater is discharged to a receiving water.</font size>]] | ||
+ | |||
+ | When evaluating the benefits of various BMPs, it is essential to account for the amount of water that will enter the system versus the amount that will be by-passed or diverted. Water that does not fall within the design parameters of a BMP will be sent either to another down-gradient BMP or simply routed to a receiving water untreated (not recommended). Although some BMPs, such as ponds and wetlands, will minimally treat excess water because it is routed through the BMP, other such as filtration and infiltration systems, cannot operate properly if excess water flows into them. This is an important distinction that must be evaluated for each BMP installation. | ||
+ | <p>The design recommendations and expected BMP performance contained within this Manual assume that only the amount of water contained within the design will actually be treated. It is not acceptable to assume that all water falling in any event and within the area draining to a BMP will, in fact, be treated by that BMP. An analysis of every BMP installation should include an identification of where by-passed water will flow and how it could be treated.</p> | ||
+ | |||
+ | ==Pollutant Removal Mechanisms== | ||
+ | The key to proper selection of a single or series of BMPs is to match the pollutant to be controlled against the pollutant removal mechanism of a specific BMP. For example, it is not appropriate to use a stormwater pond when temperature control is necessary; however it is very appropriate to use a pond for purposes of rate control. The definition of pollutant being utilized by the Minnesota Stormwater Manual includes both the traditional pollutants (nutrients, solids, etc.) plus the negative effects caused by thermal increases and excessive rate/speed of stormwater flows. Stormwater planners and designers will first need to understand the pollutant(s) of concern that may be generated at their sites. At the early stages of design, stormwater managers should be contacting local water management agencies (watershed districts, watershed management organizations, soil and water conservation districts, counties and/or cities) to learn which pollutants are necessary to control prior to discharge of new stormwater runoff to local waterbodies. | ||
+ | <p>Pollutant removal mechanisms vary with each BMP. The key mechanisms for each group of structural BMPs can be used by stormwater managers as a preliminary screening tool.</p> | ||
+ | |||
+ | ===Water Quality Pollutant Removal Mechanisms=== | ||
+ | *Screening/[[Swales|Filtration]]: The capture of solid pollutants through screens and/or filters which use a media such as sand. Effective for removal of suspended solids. | ||
+ | *[[Infiltration trench|Infiltration]]/Groundwater Recharge: A technique to discharge stormwater runoff to groundwater. Effective when runoff volume controls are required and surface water temperatures must be controlled. | ||
+ | *Settling: Deposition of solids in a water column, usually in a pond, wetland or hydrodynamic device. Typically a minimum of 12 hours of detention is needed to effectively settle solids in [[Stormwater ponds|stormwater ponds]] and [[Stormwater wetlands|stormwater wetlands]]. | ||
+ | *Biological Uptake: Vegetative and microbial uptake of nutrients. Usually accomplished in [[Bioretention|biofiltration]] devices and [[Stormwater wetlands|stormwater wetlands]]. | ||
*Temperature Control: Techniques to reduce the heating effects when runoff flows across hot pavements. Most effective technique is for groundwater to cool treated runoff. | *Temperature Control: Techniques to reduce the heating effects when runoff flows across hot pavements. Most effective technique is for groundwater to cool treated runoff. | ||
*Soil Adsorption: The physical attachment of a particle, usually nutrients and heavy metals, to the soil. | *Soil Adsorption: The physical attachment of a particle, usually nutrients and heavy metals, to the soil. | ||
− | + | ===Water Quantity Control Mechanisms=== | |
*Volume Control: Methods to limit the net increase in stormwater runoff volume caused by the creation of new impervious surfaces. Most common techniques include limitation of new surface areas, infiltration, and re-use by vegetation. | *Volume Control: Methods to limit the net increase in stormwater runoff volume caused by the creation of new impervious surfaces. Most common techniques include limitation of new surface areas, infiltration, and re-use by vegetation. | ||
*Rate Control: Detention of stormwater runoff to slow the discharge of runoff to surface waters to rates comparable with pre-development conditions. Effective for peak rate control, but can significantly increase the time period of the peak flows. | *Rate Control: Detention of stormwater runoff to slow the discharge of runoff to surface waters to rates comparable with pre-development conditions. Effective for peak rate control, but can significantly increase the time period of the peak flows. | ||
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==BMP Organization== | ==BMP Organization== | ||
− | The following | + | The following BMPs that are recommended for Minnesota. Note that the order of the BMP presentation follows the treatment train sequence. |
+ | |||
===Non-Structural or Planning Level BMPs=== | ===Non-Structural or Planning Level BMPs=== | ||
The first level of BMP application occurs at the planning stage and is intended to minimize the impact of development. These practices are intended to prevent pollution and minimize the increase in stormwater volume and are considered prior to initiation of construction or land altering activity. | The first level of BMP application occurs at the planning stage and is intended to minimize the impact of development. These practices are intended to prevent pollution and minimize the increase in stormwater volume and are considered prior to initiation of construction or land altering activity. | ||
+ | |||
====Pollution Prevention Practices==== | ====Pollution Prevention Practices==== | ||
− | |||
Specific recommended practices include such things as: | Specific recommended practices include such things as: | ||
*Housekeeping including landscaping, street sweeping, pavement maintenance, catch basin maintenance, yard waste reduction and litter control | *Housekeeping including landscaping, street sweeping, pavement maintenance, catch basin maintenance, yard waste reduction and litter control | ||
Line 39: | Line 208: | ||
*Animal waste management | *Animal waste management | ||
*Streambank stabilization | *Streambank stabilization | ||
− | *Public works activities including chemical and sanitary wastes, and sewer maintenance | + | *Public works activities including chemical and sanitary wastes, and sewer maintenance. |
+ | |||
+ | [[Pollution prevention|Fact sheets]] exist for residential, municipal and industrial/commercial pollution practice categories (Water Quality Focus). | ||
+ | |||
====Better Site Design ==== | ====Better Site Design ==== | ||
− | ( | + | [[Better site design|Better site design]] includes a series of techniques that reduce impervious cover, conserve natural areas, and use pervious areas to more effectively treat stormwater runoff (Center for Watershed Protection, 1998a) and promote the treatment train approach to runoff management. The goal of better site design is to reduce runoff volume and mitigate site impacts when decisions are being made about proposed layout of a development site. |
+ | |||
====Runoff Volume Minimization ==== | ====Runoff Volume Minimization ==== | ||
− | + | Typical runoff volume reduction techniques include: | |
− | |||
*Compost amended soils | *Compost amended soils | ||
− | *Green roofs/rooftop gardens | + | *[[Green roofs|Green roofs/rooftop gardens]] |
− | *Pervious pavement/lattice blocks | + | *[[Permeable pavement|Pervious pavement/lattice blocks]] |
− | *Rainwater harvesting (barrels/cisterns, evaporative and irrigation systems) | + | *[[Stormwater re-use and rainwater harvesting|Rainwater harvesting]] (barrels/cisterns, evaporative and irrigation systems) |
====Temporary Construction Sediment Control ==== | ====Temporary Construction Sediment Control ==== | ||
− | + | [[Temporary construction erosion and sediment control|Temporary construction and sediment control]] practices are described in terms of perimeter, slope, drainageway and “other” criteria, and include: | |
*Vegetated buffers | *Vegetated buffers | ||
*Silt fence | *Silt fence | ||
*Access/egress and drainage inlet protection | *Access/egress and drainage inlet protection | ||
*Soil and slope stabilization | *Soil and slope stabilization | ||
− | *Exposed soil covers and reinforcement | + | *Exposed soil covers and reinforcement |
===Structural BMPs=== | ===Structural BMPs=== | ||
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====Bioretention==== | ====Bioretention==== | ||
− | + | [[Bioretention|Bioretention]] BMPs include vegetated systems that provide a combination of filtration and infiltration into a bio-system consisting of plants and soil, including: | |
*Rain gardens | *Rain gardens | ||
*Depressed parking lot/traffic islands | *Depressed parking lot/traffic islands | ||
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====Filtration==== | ====Filtration==== | ||
− | *Media (sand) filters (surface, underground, perimeter/Delaware filter) | + | Filtration BMPs include: |
− | *Surface (vegetative) flow (grass channels, dry or wet swales, filter strips) | + | *[[Filtration|Media (sand) filters]] (surface, underground, perimeter/Delaware filter) |
− | *Combination media/vegetative filters | + | *[[Filtration|Surface (vegetative) flow]] (grass channels, dry or wet swales, filter strips) |
+ | *[[Filtration|Combination media/vegetative filters]] | ||
====Infiltration==== | ====Infiltration==== | ||
− | *Trenches | + | Infiltration BMPs include: |
− | *Basins | + | *[[Infiltration trench|Trenches]] |
+ | *[[Infiltration trench|Basins]] | ||
*Dry wells | *Dry wells | ||
*Underground systems | *Underground systems | ||
====Stormwater Ponds==== | ====Stormwater Ponds==== | ||
− | + | [[Stormwater ponds|Stormwater pond]] design is based upon components needed to fulfill the desired function. | |
*Components include forebay/pre-treatment, various storage volumes, physical configuration | *Components include forebay/pre-treatment, various storage volumes, physical configuration | ||
*Functions include water quality (including thermal impact) and flow control (rate and volume), which determine whether they are wet/dry or some combination | *Functions include water quality (including thermal impact) and flow control (rate and volume), which determine whether they are wet/dry or some combination | ||
+ | |||
====Constructed Wetlands==== | ====Constructed Wetlands==== | ||
− | Selection criteria are similar to stormwater ponds. | + | Selection criteria for [[Stormwater wetlands|stormwater wetlands]] are similar to stormwater ponds. |
*Components include pre-treatment, various storage volumes (detention needed), biologic character | *Components include pre-treatment, various storage volumes (detention needed), biologic character | ||
*Functions include primarily water quality and flow control, but could also include ecological factors | *Functions include primarily water quality and flow control, but could also include ecological factors | ||
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The final category of BMPs present those that are generally, but not always, included in the stormwater treatment train as a supplement to the primary treatment device. Although this is not generally recommended, there is the possibility that these devices could be the only BMP used. These are described in less detail than the previous sections. The designer will be guided through a process of determining the function a generic device serves within the treatment train and evaluating the proposed device against the needed function and manufacturer claims. Proprietary devices are generically described rather than listed as individual companies to avoid risking some omissions and claims of certification in the Manual. | The final category of BMPs present those that are generally, but not always, included in the stormwater treatment train as a supplement to the primary treatment device. Although this is not generally recommended, there is the possibility that these devices could be the only BMP used. These are described in less detail than the previous sections. The designer will be guided through a process of determining the function a generic device serves within the treatment train and evaluating the proposed device against the needed function and manufacturer claims. Proprietary devices are generically described rather than listed as individual companies to avoid risking some omissions and claims of certification in the Manual. | ||
− | |||
*Hydrodynamic | *Hydrodynamic | ||
− | *Proprietary sediment and oil/grease removal devices | + | **Proprietary sediment and oil/grease removal devices |
− | *Wet vaults | + | **Wet vaults |
− | *Sorbents | + | **Sorbents |
− | *Skimmers | + | **Skimmers |
− | + | *Filtration | |
− | + | **Catch basin inserts | |
− | *Catch basin inserts | + | **Sorbents |
− | *Sorbents | + | **Proprietary filtration devises |
− | *Proprietary filtration devises | + | *Chemical/biological treatment |
− | + | **Chemical treatment (ferric chloride, alum, polyacrylamides). Note that these chemical treatments could be limited in the State of Minnesota because of the potential toxic effects associated with them; care will be taken to assess these impacts in the BMP discussion. | |
− | + | **Biological additives (ex. chitosan) | |
− | *Chemical treatment (ferric chloride, alum, polyacrylamides). | ||
− | *Biological additives (ex. chitosan) | ||
+ | {{:Primary and secondary pollutant removal mechanisms}} | ||
− | + | {{:Primary and secondary volume removal mechanisms}} | |
− | + | --> |
On a watershed scale, the management of stormwater begins with pollution prevention (e.g. pet ordinances, buffer requirements, public education), followed by Source Controls (e.g. sweeping, Illicit Discharge Detection and Elimination), Onsite Stormwater BMPs (e.g. rain gardens, permeable pavement), and Regional BMPs (e.g. constructed pond or stormwater wetlands, large underground infiltration system). All these practices comprise a stormwater management system.
Stormwater treatment implies removal of pollutants or stormwater volume once they have been generated. On-site and regional practices treat stormwater runoff. The term Stormwater Treatment Train has loosely been used since the mid-1980s to represent a multi-BMP approach to managing the quantity and quality of stormwater runoff and has often included prevention and source control practices. In this discussion, treatment train refers to treatment practices.
The concept of treatment trains has been commonly used in the field of wastewater treatment. Professionals in this field will often describe each component of the treatment train in terms of the structure within the plant, i.e. bar screens, grit chambers, primary settling tanks, secondary treatment tanks. For the purpose of stormwater management, the lexicon differs by focusing on the processes utilized within the BMP, rather than the structural feature of a BMP. For the purpose of the Minnesota Stormwater Manual and the information contained in this article, the definitions of practices vs. processes are based on the recommendations contained in Design of Urban Stormwater Controls, published jointly by the Water Environment Federation and American Society of Civil Engineers in 2012. The following approach uses different terminology than developed by WEF, which refers to Practices as Unit Operations. Practice has been selected for this article to parallel the common usage in Minnesota of Best Management Practices (BMPs) and Stormwater Management Practices (SMPs).
A closer look at on-site and regional BMPs shows that each BMP utilizes one or more components that work together to remove pollutants utilizing combinations of hydraulic, physical, biological, and chemical methods. A well-developed stormwater treatment train will combine these processes in a manner that ensures management of all pollutants that have been identified as affecting the receiving water.
Stormwater process describes the mechanism by which pollutants are removed. For example, infiltration and evaporation are different processes for managing stormwater volume. Stormwater practices are Best Management Practices. These are the stormwater controls in which the pollutant control process, or multiple processes, takes place. In the stormwater industry, many BMPs have evolved and have been given labels that describe the primary process utilized by that BMP/practice. A key example is the term infiltration, which is used interchangeably as both a process and as a practice.
Physically, each BMP/practice utilizes multiple processes. For example, the practice of a bioinfiltration BMP utilizes the following processes:
The following tables differentiate between stormwater process and practice. To view all the information in these tables in a single Excel file, link here.
A stormwater treatment train incorporates at least two processes to maximize the control of pollutants from the runoff. The BMP(s) selected may consist of one or multiple practices, depending on many considerations, including available space, physical conditions at a site, and regulatory requirements. See the tables above for a summary of processes and practices.
Hydraulic and physical processes remove larger solids and associated pollutants during storm events while biological and chemical processes that treat the finer solids and dissolved pollutants occur between storms (Scholes, et. al. 2007, Wong, et. al. 2001). Once complete, a treatment train can (adapted from Strecker, 2005)
Using this framework for pollutant removal, particulate size of the pollutant(s) of concern should be matched to the stormwater practice best suited to remove that pollutant from stormwater runoff (Wong, et. al. 2002, Strecker, 2005). The figure to the right suggests treatment processes for a range of particulate sizes commonly found in stormwater runoff. Chemical processes are rarely utilized, given the higher capital and operating costs of chemical feeds and controls.
The resulting stormwater treatment train may result in a single BMP, such as a stormwater wetland, that utilizes multiple treatment train processes and by definition can be considered a stand-alone stormwater treatment train. Or it could become a multi-BMP treatment train with BMPs operating in series or parallel to each other. Low Impact Development (LID) and Traditional development are two typical configurations of treatment trains currently utilized by site designers that meet the definition of stormwater treatment trains. The focus of LID is to keep the raindrop as close to it's source as possible utilizing techniques such as infiltration and capture/storage/reuse. Traditional development typically employs filtration and sedimentation practices such as swales and constructed ponds and wetlands. These practices may or may not treat rainwater close to its source but generally have minor impacts on stormwater volume. Where feasible, LID practices are favored from a stormwater management practice as they reduce both stormwater volume and pollutant loading. LID practices, however, are often constrained by site factors, such as shallow depth to bedrock, soil or groundwater contamination, and space limitations (e.g. ultra-urban settings).
Examples of these two types of treatment trains are provided below and illustrated in the schematic to the right. In the LID example, water falling on a rooftop is filtered through a green roof, which stores some water for eventual uptake by plants and routes the remaining water to a permeable pavement and then to an infiltration BMP. The traditional configuration routes water off-site through a swale, which provides some treatment, before the water is discharged to a regional system.
On-site treatment trains that have been found to be the most effective are those that maintain runoff onsite while allowing sufficient time for hydraulic, physical, biological, and chemical processes to take place (Rushton, 2004). This has been demonstrated to be true in multiple case studies, as well as in Minnesota case studies including the Empire Wastewater Treatment Plant project owned and operated by the Metropolitan Council.
On a larger catchment area or watershed scale the pollution reduction of treatment train BMPs is effective, but less so than on an on-site basis. Generally, the highest level of pollutant reduction is achieved in the first BMP, with each successive BMP becoming less effective. The theory of why this occurs is based on the concept of irreducible pollutants. For more information on irreducible concentration, link here. Essentially the second, third, etc. BMPs in the treatment train are receiving runoff that has considerably less concentration of pollutants and which at some point are below the theoretical irreducible concentration for the BMP. One recommended approach to adjust for the uncertainties of pollutant removals would be to create a prioritized list of BMPs that are listed or ranked according to the pollutant removal effectiveness for each pollutant. Modelers utilizing this technique are advised to adjust the pollutant concentrations and kinetic uptake factor (k) for each pollutant being assessed by the model (Scholes, et al, 2007).
A review of literature did not find any studies that assessed the cost effectiveness of stormwater treatment trains. It is assumed that the cost considerations for a stormwater treatment train would parallel these cost considerations for individual stormwater BMPs.
A stormwater management system begins at the point that the rainfall hits the ground and becomes runoff. Site owners, maintainers, designers, etc. that are establishing a stormwater management system should consider non-structural practices as well as structural BMPs. A comprehensive stormwater management system includes
Treatment train implies treatment or removal of stormwater volume or pollutants. Prevention and source control practices are therefore not treatment practices. The remainder of this section therefore details the process of developing the structural practices, or treatment portion, of the stormwater management system.
Development of a stormwater treatment train is an iterative process that balances site constraints, project goals, and available budget. The following steps lay out the process for establishing a stormwater treatment train. The results of one of the steps may cause designers to reconsider earlier decisions on sizing, siting, etc., as the project progresses.
The site conditions, regulatory requirements, and project purpose will vary from site to site and from city to city. Information to assemble includes:
The purpose of this step is to create a list of BMPs that work together to remove the pollutants of concern identified in Step 1.
To make these determinations, use this table, which provides a summary of processes and practices.
Site constraints will affect the sizing, location, and performance of the BMPs identified in Step 2. The purpose of this step is to narrow down the BMP options based on such site constraints as:
Review each BMP identified in Step 3 to confirm that each pollutant removal process identified in Step 2 is present in the combination of BMPs selected in Step 3. If not, then Step 3 should be reviewed and alternative BMPs proposed.
Size the BMP and use the MIDS calculator or other technique detailed in the Credits section of the MN Stormwater Manual to assess the performance. Review results against goals set in Step 1. If goals are not fully achieved, then resize the BMPs or return to Step 3 to select alternative BMPs.
Designers should assess construction and operation considerations that need to be incorporated into the construction plans and/or the Operations and Maintenance Manual that are necessary to ensure the BMP operates as designed and is properly maintained.
This page was last edited on 16 February 2023, at 22:06.