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[[File:No parking for street sweeping sign.PNG|right|thumb|300 px|alt=This image shows a no parking for street sweeping sign. Image Courtesy of Emmons & Olivier Resources, Inc.|<font size=3>No parking for street sweeping sign</font size>]] | [[File:No parking for street sweeping sign.PNG|right|thumb|300 px|alt=This image shows a no parking for street sweeping sign. Image Courtesy of Emmons & Olivier Resources, Inc.|<font size=3>No parking for street sweeping sign</font size>]] | ||
− | Pollutants collect on surfaces in between storm events as a result of atmospheric deposition, vehicle emissions, winter road maintenance, construction site debris, trash, road wear and tear, and litter from adjacent lawn maintenance (grass clippings). Sweeping of materials such as sand, salt, leaves and debris from city streets, parking lots and sidewalks prevents them from being washed into storm sewers and surface waters. | + | Pollutants collect on surfaces in between storm events as a result of atmospheric deposition, vehicle emissions, winter road maintenance, construction site debris, trash, road wear and tear, and litter from adjacent lawn maintenance (grass clippings). Sweeping of materials such as sand, salt, leaves and debris from city streets, parking lots and sidewalks prevents them from being washed into storm sewers and surface waters. Timing, frequency and critical area targeting greatly influence the effectiveness of sweeping. |
− | + | This fact sheet provides an overview of studies assessing the benefits of street and parking lot sweeping and guidance on improving the pollution reduction benefits of sweeping programs applicable to [[Glossary#M|Municipal Separate Storm Sewer System]] (MS4) [[Glossary#S|Stormwater Pollution Prevention Plans]] (SWPPPs). For more information, also [https://stormwater.pca.state.mn.us/index.php?title=Street_sweeping_for_trees link here]. | |
==Benefits and pollution reduction== | ==Benefits and pollution reduction== | ||
Regular street sweeping reduces the amount of pollutants that get washed into the storm drain and ultimately discharge to lakes, rivers and wetlands. Targeted pollutants include sediment, trash and debris, leaves, organic matter and nutrients; metals and hydrocarbons. The following pollutant removal efficiencies for total solids (TS), total phosphorus (TP) and total nitrogen (TN) are from a conceptual model developed by the [https://www.worldsweeper.com/Street/Studies/CWPStudy/CBStreetSweeping.pdf Center for Watershed Protection] based on research findings from a variety of studies. | Regular street sweeping reduces the amount of pollutants that get washed into the storm drain and ultimately discharge to lakes, rivers and wetlands. Targeted pollutants include sediment, trash and debris, leaves, organic matter and nutrients; metals and hydrocarbons. The following pollutant removal efficiencies for total solids (TS), total phosphorus (TP) and total nitrogen (TN) are from a conceptual model developed by the [https://www.worldsweeper.com/Street/Studies/CWPStudy/CBStreetSweeping.pdf Center for Watershed Protection] based on research findings from a variety of studies. | ||
− | The lower removal efficiencies represent monthly street sweeping by a mechanical street sweeper. The upper efficiencies characterize the pollutant removal efficiencies using a regenerative air or vacuum street sweeper at weekly frequencies. Note that the relatively high frequencies of sweeping generate particularly low removal efficiencies, indicating that sweeping, although an effective aesthetic practice, does not necessarily translate into improved water quality. This is a similar finding of | + | The lower removal efficiencies represent monthly street sweeping by a mechanical street sweeper. The upper efficiencies characterize the pollutant removal efficiencies using a regenerative air or vacuum street sweeper at weekly frequencies. Note that the relatively high frequencies of sweeping generate particularly low removal efficiencies, indicating that sweeping, although an effective aesthetic practice, does not necessarily translate into improved water quality. This is a similar finding of Selbig and Bannerman (2007) in their study of street sweeping in Madison, WI. Even so, every pound of trash and debris removed by sweeping is another pound not entering local waterbodies. |
{{:Pollutant Removal Efficiencies from Street Sweeping for Total Solids Total Phosphorus and Total Nirogen}} | {{:Pollutant Removal Efficiencies from Street Sweeping for Total Solids Total Phosphorus and Total Nirogen}} | ||
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*What surfaces or streets in the community are dirtier than others (e.g. have higher street particulate matter loadings compared to others)? Which streets drain to sensitive water bodies? Prioritize streets with higher loadings. The City of Rochester, New York, has an online street sweeping request form. This contributes to the City’s ability to identify dirty streets and surfaces for more frequent cleaning. | *What surfaces or streets in the community are dirtier than others (e.g. have higher street particulate matter loadings compared to others)? Which streets drain to sensitive water bodies? Prioritize streets with higher loadings. The City of Rochester, New York, has an online street sweeping request form. This contributes to the City’s ability to identify dirty streets and surfaces for more frequent cleaning. | ||
− | :Many cities identify street areas draining to sensitive receiving waters, such as lakes, or to BMPs that could clog with debris and prioritize sweeping on those streets. Consider conducting a street and storm drains investigation, a visual inspection of pollutant accumulation along streets, curbs and gutters, in lake deltas, and storm drain inlets based on the Center for Watershed Protection’s [ | + | :Many cities identify street areas draining to sensitive receiving waters, such as lakes, or to BMPs that could clog with debris and prioritize sweeping on those streets. Consider conducting a street and storm drains investigation, a visual inspection of pollutant accumulation along streets, curbs and gutters, in lake deltas, and storm drain inlets based on the Center for Watershed Protection’s [https://owl.cwp.org/mdocs-posts/urban-subwatershed-restoration-manual-series-manual-11/ Urban Subwatershed Restoration Manual No. 11: Unified Subwatershed and Site Reconnaissance: A User's Manual]. |
*What proportion of streets and surfaces in the community is swept? Increase this proportion to the extent feasible. The City of Rochester, New York, developed a database to track street sweeping and calculate the total lane miles swept annually. This provides a benchmark for setting goals for future years. | *What proportion of streets and surfaces in the community is swept? Increase this proportion to the extent feasible. The City of Rochester, New York, developed a database to track street sweeping and calculate the total lane miles swept annually. This provides a benchmark for setting goals for future years. | ||
*What is the frequency of street sweeping for public streets? Ensure the frequency is at a minimum twice per year (in the fall after the leaves have fallen and in the spring after the snow is gone to get the sand and winter debris); see the recommendations in the Key Program Elements section below. | *What is the frequency of street sweeping for public streets? Ensure the frequency is at a minimum twice per year (in the fall after the leaves have fallen and in the spring after the snow is gone to get the sand and winter debris); see the recommendations in the Key Program Elements section below. | ||
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*'''Types of sweepers''' - There are three main types of sweepers including mechanical broom, regenerative-air, and vacuum-assist. Mechanical broom sweepers are typically the least expensive but are better suited to pick up large-grained sediment particles and clean wet surfaces. They tend to create dust during operation, potentially increasing atmospheric loading of dust and/or increasing the amount of fine particles on the pavement that could ultimately wash through storm drains to surface waters. Regenerative air and vacuum-assist sweepers are better at removing fine-grained sediment particles, but are less effective on wet surfaces and are more expensive. Using a mechanical sweeper for large particles followed by a regenerative-air cleaner can be effective. No matter the equipment, tandem sweeping (when one sweeper follows another along the same route to pick up missed material) improves removal efficiency. A single sweeper that makes multiple passes on a surface has the same effect. | *'''Types of sweepers''' - There are three main types of sweepers including mechanical broom, regenerative-air, and vacuum-assist. Mechanical broom sweepers are typically the least expensive but are better suited to pick up large-grained sediment particles and clean wet surfaces. They tend to create dust during operation, potentially increasing atmospheric loading of dust and/or increasing the amount of fine particles on the pavement that could ultimately wash through storm drains to surface waters. Regenerative air and vacuum-assist sweepers are better at removing fine-grained sediment particles, but are less effective on wet surfaces and are more expensive. Using a mechanical sweeper for large particles followed by a regenerative-air cleaner can be effective. No matter the equipment, tandem sweeping (when one sweeper follows another along the same route to pick up missed material) improves removal efficiency. A single sweeper that makes multiple passes on a surface has the same effect. | ||
− | :In early 2008, Minnesota Local Road Research Board’s Research Implementation Committee (LRRB-RIC) completed helpful guides to street sweeping. Specifically, the Resource for Implementing a Street Sweeping Practice includes information sheets that provide guidance for technical staff, policy and decision makers on: best practices overview, types of sweepers, reasons for sweeping and sweeping and roadway function. | + | :In early 2008, Minnesota Local Road Research Board’s Research Implementation Committee (LRRB-RIC) completed helpful guides to street sweeping. Specifically, the [https://www.lrrb.org/PDF/2008RIC06.pdf Resource for Implementing a Street Sweeping Practice] includes information sheets that provide guidance for technical staff, policy and decision makers on: best practices overview, types of sweepers, reasons for sweeping and sweeping and roadway function. |
*'''Sweeper frequency''' - Part of the LRRB-RIC research identified that Minnesota falls behind other states in terms of street sweeping frequency. Study surveys showed that Minnesota street sweeping frequency falls lower than nationwide averages. A typical Minnesota city sweeps two times annually, in spring and fall, while the national average was 10 times each year. At a minimum, sweeping should occur in early spring (before rainfall) and in the fall after most leaves have dropped. Early spring sweeping gathers remnant pollutants from winter activities including sand and de-icing material. Fall street sweeping should be coordinated with leaf pickup especially in MS4s with substantial deciduous trees. An additional sweeping in June, after trees drop seeds and flowers, will provide additional targeted phosphorus removal. Make it a priority to sweep surfaces adjacent to MS4 infiltration practices, if applicable. The Center for Watershed Protection recommends an optimal sweeper frequency of about twice between each runoff-producing rainfall event. The cities of Rochester, New York, and Rochester, MN, have more aggressive street sweeping programs focused on maximum water quality protection. | *'''Sweeper frequency''' - Part of the LRRB-RIC research identified that Minnesota falls behind other states in terms of street sweeping frequency. Study surveys showed that Minnesota street sweeping frequency falls lower than nationwide averages. A typical Minnesota city sweeps two times annually, in spring and fall, while the national average was 10 times each year. At a minimum, sweeping should occur in early spring (before rainfall) and in the fall after most leaves have dropped. Early spring sweeping gathers remnant pollutants from winter activities including sand and de-icing material. Fall street sweeping should be coordinated with leaf pickup especially in MS4s with substantial deciduous trees. An additional sweeping in June, after trees drop seeds and flowers, will provide additional targeted phosphorus removal. Make it a priority to sweep surfaces adjacent to MS4 infiltration practices, if applicable. The Center for Watershed Protection recommends an optimal sweeper frequency of about twice between each runoff-producing rainfall event. The cities of Rochester, New York, and Rochester, MN, have more aggressive street sweeping programs focused on maximum water quality protection. | ||
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==Typical cost== | ==Typical cost== | ||
− | Staffing and equipment are the largest costs for street sweeping programs. Conventional street sweepers can range from | + | Staffing and equipment are the largest costs for street sweeping programs. Conventional street sweepers can range from $60,000 to $125,000, depending on the make, model and equipment enhancements. Prices can be as high as $180,000 for newer technologies. The average useful life is about four years, varying based on frequency of use. Cost savings can be seen by using equipment that can be converted to other uses. For example, the City of Jordan, MN, purchased a sweeper that converts to a sander and snowplow in the winter. Training for operators must be included in operation and maintenance budgets. Costs are small for parking restriction notifications/signage. Parking tickets are an effective reminder to obey parking restrictions and can be used as a source of revenue for the program. |
+ | |||
+ | <noinclude> | ||
+ | [[Category:Level 3 - Regulatory/Municipal (MS4)/Fact sheet]] | ||
+ | </noinclude> |
Pollutants collect on surfaces in between storm events as a result of atmospheric deposition, vehicle emissions, winter road maintenance, construction site debris, trash, road wear and tear, and litter from adjacent lawn maintenance (grass clippings). Sweeping of materials such as sand, salt, leaves and debris from city streets, parking lots and sidewalks prevents them from being washed into storm sewers and surface waters. Timing, frequency and critical area targeting greatly influence the effectiveness of sweeping.
This fact sheet provides an overview of studies assessing the benefits of street and parking lot sweeping and guidance on improving the pollution reduction benefits of sweeping programs applicable to Municipal Separate Storm Sewer System (MS4) Stormwater Pollution Prevention Plans (SWPPPs). For more information, also link here.
Regular street sweeping reduces the amount of pollutants that get washed into the storm drain and ultimately discharge to lakes, rivers and wetlands. Targeted pollutants include sediment, trash and debris, leaves, organic matter and nutrients; metals and hydrocarbons. The following pollutant removal efficiencies for total solids (TS), total phosphorus (TP) and total nitrogen (TN) are from a conceptual model developed by the Center for Watershed Protection based on research findings from a variety of studies.
The lower removal efficiencies represent monthly street sweeping by a mechanical street sweeper. The upper efficiencies characterize the pollutant removal efficiencies using a regenerative air or vacuum street sweeper at weekly frequencies. Note that the relatively high frequencies of sweeping generate particularly low removal efficiencies, indicating that sweeping, although an effective aesthetic practice, does not necessarily translate into improved water quality. This is a similar finding of Selbig and Bannerman (2007) in their study of street sweeping in Madison, WI. Even so, every pound of trash and debris removed by sweeping is another pound not entering local waterbodies.
Pollutant removal efficiencies from street sweeping for total solids, total phosphorus, and total nitrogen. Source: Deriving Reliable Pollutant Removal Rates for Municipal Street Sweeping and Storm Drain Cleanout Programs in the Chesapeake Bay Basin. Center for Watershed Protection.
Link to this table
Frequency | Technology | TS % | TP % | TN % |
---|---|---|---|---|
Monthly | Mechanical | 9 | 3 | 3 |
Regenerative Air/Vacuum | 22 | 4 | 4 | |
Weekly | Mechanical | 13 | 5 | 6 |
Regenerative Air/Vacuum | 31 | 8 | 7 |
The Center for Watershed Protection recommends considering the following questions in order to improve the efficiency and effectiveness of your surface sweeping program.
The key maintenance issue for street sweeping programs is maintenance of the street sweepers. Street sweepers should be maintained to function at optimal efficiency and the vehicle fleet should be kept up to date with new technologies that improve pollutant removal (e.g. fine-grained particle pick-up). Installing an automatic greasing system on sweepers can decrease maintenance time and reduce wear on critical parts, which can keep the sweeper on the job longer with fewer unscheduled maintenance hassles. Maintaining surfaces through more frequent sweeping may reduce the frequency necessary for catch basin cleaning.
Staffing and equipment are the largest costs for street sweeping programs. Conventional street sweepers can range from $60,000 to $125,000, depending on the make, model and equipment enhancements. Prices can be as high as $180,000 for newer technologies. The average useful life is about four years, varying based on frequency of use. Cost savings can be seen by using equipment that can be converted to other uses. For example, the City of Jordan, MN, purchased a sweeper that converts to a sander and snowplow in the winter. Training for operators must be included in operation and maintenance budgets. Costs are small for parking restriction notifications/signage. Parking tickets are an effective reminder to obey parking restrictions and can be used as a source of revenue for the program.
This page was last edited on 23 January 2023, at 22:42.