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+ | [[File:mids logo.jpg|300px|right|alt=image of Minimal Impact Design Standards logo]] | ||
+ | |||
+ | {{alert|This section focuses on conformance with the [[Performance goals for new development, re-development and linear projects|Minimal Impact Design Standards performance goal]] of 1.1 inches. However, the methodology can be applied to other performance goals by adjusting the conversion factor in Step 6.|alert-info}} | ||
+ | |||
+ | {{alert|Turf are not included in the [[MIDS calculator|Minimal Impact Design Standards (MIDS) calculator]] because design, construction and maintenance criteria and specifications have not been developed yet.|alert-warning}} | ||
+ | |||
+ | This page includes discussion of volume and associated phosphorus and total suspended sediment reduction credits for disconnection of existing impervious surfaces and for soil improvements to enhance infiltration. | ||
+ | |||
+ | ==Recommended credits for impervious surface disconnection== | ||
+ | {{alert|Impervious surface disconnection does not meet the requirement of the [[Construction stormwater program|Construction Stormwater permit]] (Part III.D.1.e) that the water quality volume be calculated as an instantaneous volume.|alert-danger}} | ||
+ | |||
+ | [[Glossary#I|Impervious surface]] disconnection is the redirection of stormwater runoff from impervious surfaces (e.g., sidewalks, parking lots, rooftops, etc.) to vegetated areas instead of the runoff being discharged offsite via a storm sewer system or other conveyance methods. Redirection of impervious surface runoff to properly maintained vegetated areas promotes increased infiltration and reduces overall site runoff. The reduction in site runoff from impervious surface disconnection can vary considerably, depending on many factors, including the size of the contributing drainage area, size and infiltration capacity of the vegetated area receiving the additional stormwater, and numerous other site conditions such as slope and site grading. | ||
+ | |||
+ | ===Modeling analysis and results=== | ||
+ | [[File:average annual runoff depth.png|300px|thumb|alt=plot of average annual runoff depth from modeling|<font size=3>Average annual runoff depth from 35 years (1972-2006) of continuous simulation modeling using XP-SWMM. The plots show results for varying ratios of impervious area to pervious area (I/P ratio) for A, B, C, and D soils.</font size>]] | ||
+ | [[File:average annual runoff depth reduction.png|300px|thumb|alt=plot of average annual runoff depth reduction from modeling|<font size=3>Average annual runoff depth reduction from 35 years (1972-2006) of continuous simulation modeling using XP-SWMM. The plots show results for varying ratios of impervious area to pervious area (I/P ratio) for A, B, C, and D soils.</font size>]] | ||
+ | [[File:impervious surface example.png|300px|thumb|alt=illustration showing the recommended 100 foot effective pervious area|<font size=3>Illustration showing the recommended effective pervious flow length of 100 feet. This is due to the tendency for flow to channelize beyond 100 feet. In this schematic, the effective pervious area equals 100 feet times the length of parking area adjacent to the pervious surface. The I/P ratio will be the area of parking area redirected to the effective pervious area divided by the effective pervious area.</font size>]] | ||
+ | |||
+ | To estimate the runoff reduction from impervious surface disconnection, two variables were examined: | ||
+ | #ratio of impervious area to pervious area (I/P Ratio); and | ||
+ | #infiltration capacity of the vegetated area. | ||
+ | A modeling analysis was performed to quantify the runoff reduction achieved from redirecting runoff from impervious areas to pervious areas of varying size and soil type. The long-term, 35-year continuous simulation [https://www.innovyze.com/en-us/products/xpswmm XP-SWMM] model developed in support of the [[Performance goals for new development, re-development and linear projects|MIDS performance goal]] development (Barr, 2011) was modified to represent watersheds with I/P ratios ranging from 0.2:1 to 50:1 and [[Glossary#H|hydrologic soil types]] of A, B, C, and D. See the [https://stormwater.pca.state.mn.us/index.php?title=File:Assessment_MIDS_performance_goal_alternatives.pdf Assessment of MIDS Performance Goal Alternatives: Runoff Volumes, Runoff Rates, and Pollutant Removal Efficiencies] report for additional information on the hydrologic model input parameters utilized for this model. As described in the report, all soil types were assumed to be frozen and impervious to infiltration each year from December 6 to April 7. Hydrologic soil type and I/P ratio are therefore assumed to have no effect on runoff volume during the frozen ground period. | ||
+ | |||
+ | The figures to the right show the average annual runoff depths for all modeled I/P ratios and soil types and the average annual runoff reductions for all modeled I/P ratios and soil types. Note that the annual runoff depths are based on the assumption that runoff from the frozen ground period is 4.0 inches for all I/P ratios and soil types. The runoff reduction is greatest from the sites with the smallest I/P ratio of 0.2:1 (for example, 100 square feet of impervious surface redirected to 500 square feet of pervious area) and decreases as the I/P ratio increases. For a given I/P ratio, the runoff reduction is greatest for A soils and least for D soils, as would be expected. | ||
+ | |||
+ | ===Suggested credit calculations=== | ||
+ | Impervious surface disconnection spreads runoff generated from parking lots, driveways, rooftops, sidewalks and other impervious surfaces onto adjacent pervious areas where it can be infiltrated. The larger the pervious area is in comparison to the redirected impervious area, the greater the runoff reduction achieved. However, when applying the modeling results it is important to recognize that the “effective” pervious area on a site may be less than the available pervious area, as redirected flows will tend to channelize at flow lengths greater than 100 feet ([https://data.nal.usda.gov/dataset/small-watershed-hydrology-wintr-55 WinTR-55], 2009) and prevent runoff from being distributed over the entire available area. To prevent overestimating the effectiveness of impervious surface disconnection, we suggest that the “effective” pervious area be limited to a flow length of 100 feet beyond the impervious surface runoff discharge point and have less than a 5 percent slope. | ||
+ | |||
+ | ===Conformance with the MIDS performance goal=== | ||
+ | For new developments that create more than one acre of new impervious surface on sites without restrictions, the MIDS performance goal is that stormwater runoff volumes will be controlled and the post-construction runoff volume shall be retained on site for 1.1 inches of runoff from impervious surfaces statewide. Our suggested approach for quantifying the volume reduction benefit achieved from impervious surface disconnection in terms of the MIDS performance goal is summarized below. An example calculation is included below. | ||
+ | |||
+ | ====Step 1==== | ||
+ | <!--[[File:average annual runoff depth.png|300px|thumb|alt=plot of average annual runoff depth from modeling|<font size=3>Average annual runoff depth from 35 years (1972-2006) of continuous simulation modeling using XP-SWMM. The plots show results for varying ratios of impervious area to pervious area (I/P ratio) for A, B, C, and D soils.</font size>]]--> | ||
+ | |||
+ | <math>Pre-disconnection RO = (Area_{p})(RD_{p}) + (Area_{i})(RD_{i})</math> | ||
+ | |||
+ | where: | ||
+ | :Pre-disconnection RO = runoff volume (cubic feet) from site if impervious surface is not redirected to pervious area; | ||
+ | :Area<sub>p</sub> = total pervious area (square feet); | ||
+ | :RD<sub>p</sub> = runoff depth (feet) from pervious area (4.4 inches for A soil, 5.7 inches for B soil, 6.1 inches for C soil, 7.2 inches for D soil); | ||
+ | :Area<sub>i</sub> = impervious area (square feet); and | ||
+ | :RD<sub>i</sub> = runoff depth (feet) from impervious area (22.5 inches). | ||
+ | |||
+ | ====Step 2==== | ||
+ | <math>I/P Ratio = (Area_{i redirect})/(Area_{p eff})</math> | ||
+ | |||
+ | where: | ||
+ | :I/P Ratio = ratio of redirected impervious area to "effective" pervious area; | ||
+ | :Area<sub>i redirect</sub> = impervious area (square feet) redirected to pervious area; and | ||
+ | :Area<sub>p eff</sub> = “effective” pervious area (square feet) receiving redirected impervious runoff. | ||
+ | |||
+ | The "effective" pervious area is the area over which infiltration of redirected water occurs. In calculating the effective pervious area, the maximum width should be 100 feet. See the discussion of [[Turf#Suggested credit calculations|effective pervious]] and the schematic to the right. | ||
+ | |||
+ | ====Step 3==== | ||
+ | <math>Post-disconnection RO = (Area_{i redirect} + Area_{p eff})(RD_{redirect}) + (Area_{p noneff})(RD_p) + (Area_{i nonredirect})(RD_i)</math> | ||
+ | |||
+ | where: | ||
+ | :Post-disconnection RO = post-disconnection runoff volume (cubic feet) from entire site; | ||
+ | :RD<sub>redirect</sub> = runoff depth (feet) from redirected impervious area and effective pervious area (determined from modeling results based on soil type and I/P ratio); | ||
+ | :Area<sub>p noneff</sub> = pervious area (square feet) not considered “effective” for receiving redirected impervious runoff; | ||
+ | :RD<sub>p</sub> = runoff depth (feet) from pervious area (4.4 inches for A soil, 5.7 inches for B soil, 6.1 inches for C soil, 7.2 inches for D soil); | ||
+ | :Area<sub>i nonredirect</sub> = impervious area (square feet) not redirected to pervious area; and | ||
+ | :RD<sub>i</sub> = runoff depth (feet) from non-redirected impervious area (22.5 inches). | ||
+ | |||
+ | [[File:average annual runoff depth.png|300px|thumb|alt=plot of average annual runoff depth from modeling|<font size=3>Average annual runoff depth from 35 years (1972-2006) of continuous simulation modeling using XP-SWMM. The plots show results for varying ratios of impervious area to pervious area (I/P ratio) for A, B, C, and D soils.</font size>]] | ||
+ | |||
+ | To calculate RD<sub>redirect</sub>, use the figure on the right. For example, a B soil with an I/P ratio of 2:1 has an RD<sub>Subscript text</sub> of 10.1 inches. | ||
+ | |||
+ | ====Step 4==== | ||
+ | <math>Adjusted impervious RO = (Post-disconnection RO) - (Area_p)(RD_p)</math> | ||
+ | |||
+ | where: | ||
+ | :Adjusted impervious RO = adjusted runoff volume (cubic feet) from impervious area as a result of redirection to pervious area; | ||
+ | :Post-disconnection RO = post-disconnection runoff volume (cubic feet) from entire site; | ||
+ | :Area<sub>p</sub> = total pervious area (square feet); and | ||
+ | :RD<sub>p</sub> = runoff depth (feet) from pervious area (determined from model results based on soil type). | ||
+ | |||
+ | ====Step 5==== | ||
+ | <math>Area_{i,adj} = (Adjusted impervious RO) / (RD_i)</math> | ||
+ | |||
+ | where: | ||
+ | :Area<sub>i,adj</sub> = adjusted impervious area (square feet) for calculation of performance goal conformance; | ||
+ | :Adjusted impervious RO = adjusted runoff volume (cubic feet) from impervious area as a result of redirection to pervious area; and | ||
+ | :RD<sub>i</sub> = runoff depth (feet) from impervious area (determined from model results). | ||
+ | |||
+ | ====Step 6==== | ||
+ | <math>BMP volume credit = 0.092 (Area_i - Area_{i, adj})</math> | ||
+ | |||
+ | where: | ||
+ | :Area<sub>i</sub> = impervious area (square feet); | ||
+ | :Area<sub>i, adj</sub> = adjusted impervious area (square feet) for calculation of performance goal conformance; and | ||
+ | :0.092 is a conversion factor. Note this conversion factor is for the 1.1 inch performance goal. | ||
+ | |||
+ | ===Annual volume reduction=== | ||
+ | [[File:Performance curve for 50% impervious site.png|300 px|thumb|alt=plot showing | ||
+ | Bioretention Basin Volume Reduction Performance Curves for A, B, and C Soil Types on a 50% Impervious Site|<font size=3>Bioretention basin volume reduction performance curves for A, B, and C soil types on a 50 percent impervious site </font size>]] | ||
+ | |||
+ | The approach described in the steps above results in an equivalent BMP volume credit that can be used to evaluate conformance with the MIDS performance goal. To estimate the annual runoff volume reduction that is achieved by implementation of impervious surface disconnection, we recommend applying the performance curves developed for assessing annual performance of bioretention basins. These performance curves, which were developed for sites ranging from 10 to 90 percent imperviousness and hydrologic soils groups A, B, and C, allow for estimation of the average annual runoff volume reduction based on an equivalent BMP volume per tributary drainage area. | ||
+ | |||
+ | ===Annual pollutant removal=== | ||
+ | The MIDS calculator estimates the average annual removal of total phosphorus (TP), dissolved phosphorus (DP), and total suspended solids (TSS) from stormwater runoff as a result of BMP implementation. For runoff that is infiltrated as a result of the impervious surface disconnection, 100 percent pollutant removal is suggested. For runoff that is not infiltrated, but conveyed across the effective pervious area, pollutant removal consistent with that of a filter strip is suggested (current draft of MIDS calculator uses 68 percent annual TSS removal and 0 percent TP and DP removal). If pollutant removal credit is included in the calculator for runoff conveyed over the effective pervious area, additional definition of effective pervious area may be warranted to ensure that the pervious flow length is sufficient to achieve the sedimentation expected to occur during flow through a filter strip. For pervious areas that extend beyond the effective pervious area, a treatment train approach could be used in the MIDS calculator by treating the additional pervious area as a filter strip. | ||
+ | |||
+ | ==Recommended credits for soil improvement== | ||
+ | {{alert|This section focuses on conformance with the [[Performance goals for new development, re-development and linear projects|Minimal Impact Design Standards performance goal]] of 1.1 inches. However, the methodology can be applied to other performance goals by adjusting the conversion factor in Step 5.|alert-info}} | ||
+ | {{alert|Turf is not included in the [[MIDS calculator|Minimal Impact Design Standards (MIDS) calculator]] because design, construction and maintenance criteria and specifications have not been developed yet.|alert-warning}} | ||
+ | |||
+ | The amount of runoff from pervious surfaces is dependent on many characteristics, with a primary factor being the infiltration capacity of the soil. While the infiltration capacity and runoff potential vary among soil types, other factors such as compaction or soil loosening can result in more or less runoff for a given soil type or texture. Maintaining and/or amending soils in vegetated areas to increase infiltration, termed “Soil Improvements” in this memorandum, is a method of reducing runoff from pervious areas. Soil maintenance and amendment includes loosening or ripping of existing soils to decrease the soil density or modifying or replacing existing soil to achieve increased infiltration. | ||
+ | |||
+ | ===Modeling analysis and results=== | ||
+ | [[File:Comparison of Average Annual Runoff Grouped by Soil Type and Condition.png|300px|thumb|alt=graph of average annual runoff by soil type and condition|<font size=3>Comparison of average annual runoff grouped by soil type and soil condition.</font size>]] | ||
+ | |||
+ | Barr conducted a modeling analysis to estimate the runoff reduction from maintaining and/or amending soils in vegetated areas using the long-term, 35-year continuous simulation XP-SWMM model developed in support of the MIDS performance goal development (Barr, 2011). To assess the difference in average annual runoff depths under compacted, average, and loosened soil conditions, the saturated hydraulic conductivity (Ksat) values in the XP-SWMM model were adjusted. “Average” values represent the mean Ksat values for each soil texture based on a national database of over 1,000 observed saturated hydraulic conductivities (Rawls, 1998). “Compacted” and “loosened” values represent the geometric mean Ksat values for soils within the national database developed by Rawls that have bulk densities higher and lower than the NRCS recommended value for the soil texture class, respectively (Rawls, 1998). The figure to the right shows the average annual runoff depths under compacted, average, and loosened soil conditions for A, B, and C hydrologic soil groups, as well as average conditions for D soils. | ||
+ | |||
+ | {{alert|It should be noted that due to the empirical methodology used to define the Ksat values, loosened C soils have a higher Ksat than loosened B soils, and thus a lower runoff depth. Given this, it is suggested that the runoff depth from “loosened” C soils be approximated as equivalent to the runoff from “average” B soils for credit calculations|alert-warning}} | ||
+ | |||
+ | {{:Saturated hydraulic conductivity values used in long-term continuous simulation modeling analysis}} | ||
+ | |||
+ | ===Suggested credit calculations=== | ||
+ | For new developments that create more than one acre of new impervious surface on sites without restrictions, the MIDS performance goal is that stormwater runoff volumes will be controlled and the post-construction runoff volume shall be retained on site for 1.1 inches of runoff from impervious surfaces statewide. Our suggested approach to quantifying the volume reduction benefit achieved from maintaining and/or amending soils in vegetated areas in terms of the MIDS performance goal is summarized below. Note that the determination of appropriate soil conditions prior to and following soil improvements will be site dependent. | ||
+ | |||
+ | ====Step 1==== | ||
+ | <math>Pre-soil improvement RO = (Area_p)(RD_{po}) + (Area_i)(RD_i)</math> | ||
+ | |||
+ | where: | ||
+ | :Pre-Soil Improvement RO = runoff volume (cubic feet) from site if soils not improved; | ||
+ | :Area<sub>p</sub> = total pervious area (square feet); | ||
+ | :RD<sub>po</sub> = runoff depth (feet) from pervious area reflecting pre-project soil conditions, typically compacted or average (determined from model results); | ||
+ | :Area <sub>i</sub> = impervious area (square feet); and | ||
+ | :RD<sub>i</sub> = runoff depth from impervious area (1.875 feet (22.5 inches)). | ||
+ | |||
+ | ====Step 2==== | ||
+ | <math>Post-soil improvement RO = (Area_{p imp})(RD_{p imp}) + (Area_{p unimp})(RD_{po}) + (Area_i))(RD_i)</math> | ||
+ | |||
+ | where: | ||
+ | :Post-Soil Improvement RO = runoff volume (cubic feet) from site following soil improvements; | ||
+ | :Area<sub>p imp</sub> = pervious area (square feet) with improved soils; | ||
+ | :RD<sub>P imp</sub> = runoff depth (feet) from pervious area reflecting improved soil conditions, typically average or loosened (determined from model results); | ||
+ | :Area<sub>p unimp</sub> = pervious area (square feet) without improved soils; | ||
+ | :RD<sub>po</sub> = runoff depth (feet) from pervious areas with unimproved soil conditions, typically compacted or average (determined from model results); | ||
+ | :Area<sub>i</sub> = impervious area (square feet); and | ||
+ | :RD<sub>i</sub> = runoff depth from impervious area (1.875 feet (22.5 inches), based on impervious surface disconnection modeling). | ||
+ | |||
+ | ====Step 3==== | ||
+ | <math>Adjusted impervious RO = post-soil improvement RO - (Area_p)(RD_{po})</math> | ||
+ | |||
+ | where: | ||
+ | :Adjusted impervious RO = adjusted impervious runoff volume (cubic feet) to represent equivalent runoff reduction from pervious soil improvements; | ||
+ | :Post-soil improvement RO = runoff volume (cubic feet) from site following soil improvements; | ||
+ | :Area<sub>p</sub> = total pervious area (square feet); and | ||
+ | :RD<sub>po</sub> = runoff depth (feet) from pervious areas with unimproved soil conditions, typically compacted or average (determined from model results). | ||
+ | |||
+ | ====Step 4==== | ||
+ | <math>Area_{i adj} = (Adjusted impervious RO) / RD_i</math> | ||
+ | |||
+ | where: | ||
+ | :Area<sub>i adj</sub> = adjusted impervious area (square feet) for calculation of performance goal conformance; | ||
+ | :Adjusted impervious RO = adjusted impervious runoff volume to represent equivalent runoff reduction from pervious soil improvements; and | ||
+ | :RD<sub>i</sub> = runoff depth from impervious area (1.875 feet (22.5 inches)). | ||
+ | |||
+ | ====Step 5==== | ||
+ | <math>BMP volume credit = 0.092 (Area_i - Area_{i adj})</math> | ||
+ | |||
+ | where: | ||
+ | :Area<sub>i</sub> = impervious area (square feet); and | ||
+ | Area<sub>i adj</sub> = adjusted impervious area (square feet) for calculation of of performance goal conformance. | ||
+ | |||
+ | ===Annual volume reduction=== | ||
+ | The approach described in the steps above results in an equivalent BMP volume credit that can be used to evaluate conformance with the MIDS performance goal. To estimate the annual runoff volume reduction that is achieved by implementation of soil improvements, we recommend applying the performance curves developed for assessing the annual performance of bioretention basins. These performance curves, which were developed for sites ranging from 10 to 90 percent imperviousness and hydrologic soils groups A, B, and C, allow for estimation of the average annual runoff volume reduction based on an equivalent BMP volume per tributary drainage area. | ||
+ | |||
+ | ===Annual pollutant removal=== | ||
+ | The MIDS calculator estimates the average annual removal of total phosphorus, dissolved phosphorus, and total suspended solids from stormwater runoff as a result of BMP implementation. For runoff that is infiltrated as a result of soil improvements in the vegetated pervious areas, 100 percent pollutant removal is suggested. For runoff that is not infiltrated, 0 percent pollutant removal is suggested. For example, if a 5 percent annual runoff volume reduction is estimated as a result of soil improvements, the average annual total phosphorus, dissolved phosphorus, and total suspended sediment reductions will be 5 percent. For the 95 percent of annual runoff discharged from a site, no additional pollutant removal will be credited. | ||
+ | |||
+ | ===Example calculations=== | ||
+ | [[File:image for example.png|300px|thumb|alt=illustration used for example calculations|<font size=3>Schematic used for the example calculations</font size>]] | ||
+ | [[File:Performance curve for 50% impervious site.png|300 px|thumb|alt=plot showing | ||
+ | Bioretention Basin Volume Reduction Performance Curves for A, B, and C Soil Types on a 50% Impervious Site|<font size=3>Bioretention basin volume reduction performance curves for A, B, and C soil types on a 50 percent impervious site </font size>]] | ||
+ | |||
+ | Three example calculations are presented below. The 1st two examples are for disconnected impervious surfaces (A and B soils, respectively) and the 3rd is for improved soil. | ||
+ | |||
+ | ====Scenario 1==== | ||
+ | *3 acres consisting of 1.5 acres of impervious parking lot and 1.5 acres of pervious turf | ||
+ | *50 percent impervious | ||
+ | *A soils, with all of the impervious area draining to the pervious area next to a parking lot. The length of the impervious area is 350 feet. | ||
+ | |||
+ | :'''Calculate conformance with the performance goal (1.1 inches)''' | ||
+ | :*Calculate the effective pervious area: Effective pervious area = (100 feet)(350 feet) = 35,000 square feet or 0.8 acres | ||
+ | :*The runoff depth from impervious area (RD<sub>i</sub> = 22.5 inches (from model results)) | ||
+ | :*Step 1: Pre-disconnection site runoff = ((1.5 acres)(4.4 inches) + (1.5 acres)(22.5 inches))(43560 square feet per acre)(1 foot/12 inches) = 146471 cubic feet | ||
+ | :*Step 2: I/P<sub>eff</sub> ratio = (1.5 acres)/(0.8 acres) = 1.9 | ||
+ | :*Step 3: Post-disconnection site runoff volume = ((1.5 acre + 0.8 acre)(6.55 inches)+(1.5 acre – 0.8 acre)(4.4 inches))(43560 square feet/acre)(1 foot/12 inches) = 65866 cubic feet | ||
+ | :*Step 4: Adjusted impervious runoff = (65866 cubic feet)-(1.5 acre)(4.4 inches)(43560 square feet/acre)(1 foot/12inches) = 41908 cubic feet | ||
+ | :*Step 5: Adjusted impervious area = (41908 cubic feet)/((22.5 inches)(1 foot/12 inches)) = 22351 square feet | ||
+ | :*Step 6: BMP volume credit = (1.5 acre - 0.51 acre)(1.1 inches)(43560 square feet/acre)(1 foot/12 inches)) = 3941 cubic feet | ||
+ | |||
+ | :'''Calculate annual volume reduction using performance curve for 50 percent impervious site.''' | ||
+ | :*BMP Volume /Drainage Area = (3941 cubic feet)/(43560 aquare feet/acre)/(3 acres) = 0.03 | ||
+ | :*Corresponding annual volume removal (from performance curve, for A soils, 50% impervious site) = 91 percent | ||
+ | :*Annual TP removal = annual volume removal = 91 percent | ||
+ | :*Annual TSS removal = (91 percent)(100 percent) + (9 percent)(68 percent) = 97 percent | ||
+ | |||
+ | ====Scenario 2==== | ||
+ | *3 acres consisting of 1.5 acres of impervious parking lot and 1.5 acres of pervious turf | ||
+ | *50 percent impervious | ||
+ | *B soils, with all of the impervious area draining to the pervious area next to a parking lot. The length of the impervious area is 350 feet. | ||
+ | |||
+ | |||
+ | :'''Calculate conformance with the performance goal (1.1 inches)''' | ||
+ | :*Calculate the effective pervious area: Effective pervious area = (100 feet)(350 feet) = 35,000 square feet or 0.8 acres | ||
+ | :*The runoff depth from impervious area (RD<sub>i</sub> = 22.5 inches (from model results) | ||
+ | :*Step 1: Pre-disconnection site runoff = ((1.5 acres)(5.7 inches) + (1.5 acres)(22.5 inches))(43560 square feet per acre)(1 foot/12 inches) = 153549 cubic feet | ||
+ | :*Step 2: I/P<sub>eff</sub> ratio = (1.5 acres)/(0.8 acres) = 1.9 | ||
+ | :*Step 3: Post-disconnection site runoff volume = ((1.5 acre + 0.8 acre)(9.84 inches)+(1.5 acre – 0.8 acre)(5.7 inches))(43560 square feet/acre)(1 foot/12 inches) = 65601 cubic feet | ||
+ | :*Step 4: Adjusted impervious runoff = (96638 cubic feet)-(1.5 acre)(5.7 inches)(43560 square feet/acre)(1 foot/12inches) = 65601 cubic feet | ||
+ | :*Step 5: Adjusted impervious area = (65601 cubic feet)/((22.5 inches)(1 foot/12 inches) = 34987 square feet | ||
+ | :*Step 6: BMP volume credit = (1.5 acre - 0.8 acre)(1.1 inches)(43560 square feet/acre)(1 foot/12 inches)) = 2795 cubic feet | ||
+ | |||
+ | :'''Calculate annual volume reduction using performance curve for 50 percent impervious site.''' | ||
+ | :*BMP Volume /Drainage Area = (2795 cubic feet)/(43560 aquare feet/acre)/(3 acres) = 0.02 | ||
+ | :*Corresponding annual volume removal (from performance curve, for B soils, 50% impervious site) = 68 percent | ||
+ | :*Annual TP removal = annual volume removal = 68 percent | ||
+ | :*Annual TSS removal = (68 percent)(100 percent) + (32 percent)(68 percent) = 90 percent | ||
+ | |||
+ | ====Scenario 3==== | ||
+ | *10-acre, 50% impervious site | ||
+ | *B soils, with all of the impervious area being "improved" from "compacted" to "average". | ||
+ | |||
+ | To perform the calculations to determine volume credits for improved turf, runoff depth must be known for the three soil conditions (compacted, average, loosened) and the three soil types being considered (A, B, C. Note that D soils are not considered for this credit.). These values were determined from continuous simulation modeling using XP-SWMM and they are summarized below: | ||
+ | :A soil | ||
+ | ::Compacted soil = 4.4 inches | ||
+ | ::Average soil = 4.1 inches | ||
+ | ::loosened soil = 4.0 inches | ||
+ | :B soil | ||
+ | ::Compacted soil = 5.2 inches | ||
+ | ::Average soil = 4.9 inches | ||
+ | ::loosened soil = 4.7 inches | ||
+ | :C soil | ||
+ | ::Compacted soil = 5.5 inches | ||
+ | ::Average soil = 5.2 inches | ||
+ | ::loosened soil = 4.9 inches | ||
+ | |||
+ | [[File:Summary of BMP Volume Credits for range of sites.png|300px|thumb|alt=Table showing summary of BMP Volume Credits for range of sites and soil types from XP-SWMM modeling|<font size=3>Summary of BMP volume credits for range of sites (20%, 50%, 80% impervious) and soil types (A, B, C). The data assume a 10 acre site. For example, on a site that is 50% impervious and having B soils, improving the soil from compacted to loosened provides 0.024 equivalent inches off impervious surface.</font size>]] | ||
+ | |||
+ | The runoff depth from impervious surfaces is 22.5 inches. | ||
+ | |||
+ | :'''Calculate conformance with performance goal''' | ||
+ | :*Treatment volume required to meet 1.1-inch performance goal = (10 acres)(0.50)(43560 square feet/acre)(1.1 inches)(1 foot/12 inches) = 19965 cubic feet | ||
+ | :*Step 1: Calculate site runoff prior to soil improvements = (Area<sub>p</sub>)(RD<sub>po</sub>) + (Area<sub>i</sub>)(RD<sub>i</sub>) = (5 acres)(5.2 inches)(43560 square feet/acre)(1 foot/inch) = 502755 cubic feet | ||
+ | :*Step 2: Calculate site runoff following improvements = (Area<sub>p imp</sub>)(RD<sub>p imp</sub>) + (Area<sub>p unimp</sub>)((RD<sub>po</sub>) + (Area<sub>i</sub>)(RD<sub>i</sub>) = (5 acres)(43560 square feet/acre)(4.9 inches)(1 foot/inch) + (5 acres)(43560 square feet/acre)(22.5 inches)(1 foot/acre) = 497310 cubic feet | ||
+ | :*Step 3: Calculate adjusted impervious runoff to determine credit = (Post-soil improvement runoff) - ((Area<sub>p</sub>)(RD<sub>po</sub>)) = 497310 - (5 acres(43560 acres/square feet)(5.2 inches)(1 foot/12 inches) = 402930 square feet | ||
+ | :*Step 4: Calculate ajusted impervious area = (Adjusted impervious runoff)/(RD<sub>i</sub>) = (402930)/((22.5inches)(1 foot/12 inches)) = 214896 square feet | ||
+ | :*Step 5: Calculate performance goal credit = (217800 - 214896)(1.1 inches)(1 foot/12 inches) = 266.2 cubic feet | ||
+ | :*BMP volume credit in inches off impervious surface = (performance goal credit)/(performance goal volume) = 266.2/19965 = 0.013 inches | ||
+ | |||
+ | The figure at the right summarizes BMP volume credits for a range of site conditions (20, 50, and 80% impervious) and soil types (A, B, and C soils). | ||
+ | |||
+ | ==Spreadsheet for calculating disconnection credit== | ||
+ | [[file:Schematic for disconnection credit 2.png|300 px|left|thumb|alt=schematic used for disconnection credit|<font size=3>Schematic illustrating the terms used to calculate the impervious surface disconnection. Note that the maximum flowpath length for the effective pervious area (the area receiving runoff from the redirected impervious surface) is 100 feet.</font size=3>]] | ||
+ | [[File:average annual runoff depth.png|300px|thumb|alt=plot of average annual runoff depth from modeling|<font size=3>Average annual runoff depth from 35 years (1972-2006) of continuous simulation modeling using XP-SWMM. The plots show results for varying ratios of impervious area to pervious area (I/P ratio) for A, B, C, and D soils.</font size>]] | ||
+ | |||
+ | A simple calculator allows you to calculate the credit for impervious surface disconnection ([[file:Disconnection credit calculator.xlsx]]). You will need the following information to use the calculator: | ||
+ | *soil type; | ||
+ | *area of non-redirected impervious surface (the impervious area that does not run off to the pervious area); | ||
+ | *area of redirected impervious surface (the impervious area that runs off to the pervious area); | ||
+ | *effective pervious area (the pervious area that receives runoff from the redirected impervious); and | ||
+ | *ineffective impervious area. | ||
+ | |||
+ | Another input in the spreadsheet, the I/P ratio, is the area of redirected impervious surface to effective pervious area. Using the I/P ratio for the appropriate soil in the figure to the right allows determination of the runoff depth, which is input into the spreadsheet. | ||
+ | |||
+ | Note that the spreadsheet generates a volume credit for disconnection. It does not calculate the percent credit toward the performance goal. The performance goal includes runoff from both the non-redirected and redirected impervious areas. Thus, the greater the percent of redirected impervious area relative to total impervious area at a site, the greater the volume credit as a percent of the performance goal. | ||
+ | |||
+ | =Compost= | ||
+ | {{:Compost and stormwater management}} | ||
+ | |||
+ | <!--{{alert|Information for this page has not developed. It is anticipated this page will be populated in spring of 2013|alert-danger}} | ||
+ | |||
+ | For information on turf as a stormwater BMP please see [http://www.pca.state.mn.us/index.php/view-document.html?gid=18021]. | ||
<div class="center">[[Overview for turf]]</div> | <div class="center">[[Overview for turf]]</div> | ||
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<div class="center">[[Additional considerations for turf]]</div> | <div class="center">[[Additional considerations for turf]]</div> | ||
<div class="center">[[Links for turf]]</div> | <div class="center">[[Links for turf]]</div> | ||
− | <div class="center">[[References for turf]]</div> | + | <div class="center">[[References for turf]]</div>--> |
+ | |||
+ | <noinclude>[[Category:Level 2 - Best management practices/Nonstructural practices]] | ||
+ | [[Category:Level 2 - Technical and specific topic information/vegetation]]</noinclude> |
This page includes discussion of volume and associated phosphorus and total suspended sediment reduction credits for disconnection of existing impervious surfaces and for soil improvements to enhance infiltration.
Impervious surface disconnection is the redirection of stormwater runoff from impervious surfaces (e.g., sidewalks, parking lots, rooftops, etc.) to vegetated areas instead of the runoff being discharged offsite via a storm sewer system or other conveyance methods. Redirection of impervious surface runoff to properly maintained vegetated areas promotes increased infiltration and reduces overall site runoff. The reduction in site runoff from impervious surface disconnection can vary considerably, depending on many factors, including the size of the contributing drainage area, size and infiltration capacity of the vegetated area receiving the additional stormwater, and numerous other site conditions such as slope and site grading.
To estimate the runoff reduction from impervious surface disconnection, two variables were examined:
A modeling analysis was performed to quantify the runoff reduction achieved from redirecting runoff from impervious areas to pervious areas of varying size and soil type. The long-term, 35-year continuous simulation XP-SWMM model developed in support of the MIDS performance goal development (Barr, 2011) was modified to represent watersheds with I/P ratios ranging from 0.2:1 to 50:1 and hydrologic soil types of A, B, C, and D. See the Assessment of MIDS Performance Goal Alternatives: Runoff Volumes, Runoff Rates, and Pollutant Removal Efficiencies report for additional information on the hydrologic model input parameters utilized for this model. As described in the report, all soil types were assumed to be frozen and impervious to infiltration each year from December 6 to April 7. Hydrologic soil type and I/P ratio are therefore assumed to have no effect on runoff volume during the frozen ground period.
The figures to the right show the average annual runoff depths for all modeled I/P ratios and soil types and the average annual runoff reductions for all modeled I/P ratios and soil types. Note that the annual runoff depths are based on the assumption that runoff from the frozen ground period is 4.0 inches for all I/P ratios and soil types. The runoff reduction is greatest from the sites with the smallest I/P ratio of 0.2:1 (for example, 100 square feet of impervious surface redirected to 500 square feet of pervious area) and decreases as the I/P ratio increases. For a given I/P ratio, the runoff reduction is greatest for A soils and least for D soils, as would be expected.
Impervious surface disconnection spreads runoff generated from parking lots, driveways, rooftops, sidewalks and other impervious surfaces onto adjacent pervious areas where it can be infiltrated. The larger the pervious area is in comparison to the redirected impervious area, the greater the runoff reduction achieved. However, when applying the modeling results it is important to recognize that the “effective” pervious area on a site may be less than the available pervious area, as redirected flows will tend to channelize at flow lengths greater than 100 feet (WinTR-55, 2009) and prevent runoff from being distributed over the entire available area. To prevent overestimating the effectiveness of impervious surface disconnection, we suggest that the “effective” pervious area be limited to a flow length of 100 feet beyond the impervious surface runoff discharge point and have less than a 5 percent slope.
For new developments that create more than one acre of new impervious surface on sites without restrictions, the MIDS performance goal is that stormwater runoff volumes will be controlled and the post-construction runoff volume shall be retained on site for 1.1 inches of runoff from impervious surfaces statewide. Our suggested approach for quantifying the volume reduction benefit achieved from impervious surface disconnection in terms of the MIDS performance goal is summarized below. An example calculation is included below.
\(Pre-disconnection RO = (Area_{p})(RD_{p}) + (Area_{i})(RD_{i})\)
where:
\(I/P Ratio = (Area_{i redirect})/(Area_{p eff})\)
where:
The "effective" pervious area is the area over which infiltration of redirected water occurs. In calculating the effective pervious area, the maximum width should be 100 feet. See the discussion of effective pervious and the schematic to the right.
\(Post-disconnection RO = (Area_{i redirect} + Area_{p eff})(RD_{redirect}) + (Area_{p noneff})(RD_p) + (Area_{i nonredirect})(RD_i)\)
where:
To calculate RDredirect, use the figure on the right. For example, a B soil with an I/P ratio of 2:1 has an RDSubscript text of 10.1 inches.
\(Adjusted impervious RO = (Post-disconnection RO) - (Area_p)(RD_p)\)
where:
\(Area_{i,adj} = (Adjusted impervious RO) / (RD_i)\)
where:
\(BMP volume credit = 0.092 (Area_i - Area_{i, adj})\)
where:
The approach described in the steps above results in an equivalent BMP volume credit that can be used to evaluate conformance with the MIDS performance goal. To estimate the annual runoff volume reduction that is achieved by implementation of impervious surface disconnection, we recommend applying the performance curves developed for assessing annual performance of bioretention basins. These performance curves, which were developed for sites ranging from 10 to 90 percent imperviousness and hydrologic soils groups A, B, and C, allow for estimation of the average annual runoff volume reduction based on an equivalent BMP volume per tributary drainage area.
The MIDS calculator estimates the average annual removal of total phosphorus (TP), dissolved phosphorus (DP), and total suspended solids (TSS) from stormwater runoff as a result of BMP implementation. For runoff that is infiltrated as a result of the impervious surface disconnection, 100 percent pollutant removal is suggested. For runoff that is not infiltrated, but conveyed across the effective pervious area, pollutant removal consistent with that of a filter strip is suggested (current draft of MIDS calculator uses 68 percent annual TSS removal and 0 percent TP and DP removal). If pollutant removal credit is included in the calculator for runoff conveyed over the effective pervious area, additional definition of effective pervious area may be warranted to ensure that the pervious flow length is sufficient to achieve the sedimentation expected to occur during flow through a filter strip. For pervious areas that extend beyond the effective pervious area, a treatment train approach could be used in the MIDS calculator by treating the additional pervious area as a filter strip.
The amount of runoff from pervious surfaces is dependent on many characteristics, with a primary factor being the infiltration capacity of the soil. While the infiltration capacity and runoff potential vary among soil types, other factors such as compaction or soil loosening can result in more or less runoff for a given soil type or texture. Maintaining and/or amending soils in vegetated areas to increase infiltration, termed “Soil Improvements” in this memorandum, is a method of reducing runoff from pervious areas. Soil maintenance and amendment includes loosening or ripping of existing soils to decrease the soil density or modifying or replacing existing soil to achieve increased infiltration.
Barr conducted a modeling analysis to estimate the runoff reduction from maintaining and/or amending soils in vegetated areas using the long-term, 35-year continuous simulation XP-SWMM model developed in support of the MIDS performance goal development (Barr, 2011). To assess the difference in average annual runoff depths under compacted, average, and loosened soil conditions, the saturated hydraulic conductivity (Ksat) values in the XP-SWMM model were adjusted. “Average” values represent the mean Ksat values for each soil texture based on a national database of over 1,000 observed saturated hydraulic conductivities (Rawls, 1998). “Compacted” and “loosened” values represent the geometric mean Ksat values for soils within the national database developed by Rawls that have bulk densities higher and lower than the NRCS recommended value for the soil texture class, respectively (Rawls, 1998). The figure to the right shows the average annual runoff depths under compacted, average, and loosened soil conditions for A, B, and C hydrologic soil groups, as well as average conditions for D soils.
Saturated hydraulic conductivity values used in long-term continuous simulation modeling analysis
Link to this table.
Hydrologic soil group | Representative soil texture | Saturated hydraulic conductivity (in/hr) | ||
---|---|---|---|---|
Compacted | Average1 | Loosened2 | ||
A | sandy loam | 0.50 | 0.90 | 2.20 |
B | loam | 0.15 | 0.205 | 0.24 |
C | sandy clay loam | 0.11 | 0.14 | 0.30 |
D | silty clay | N/A | 0.06 | N/A |
1
The Ksat values termed “average” for the modeling analysis represent the mean Ksat values for each soil texture based on a national database of over 1,000 observed saturated hydraulic conductivities (Rawls, 1998).
2The Ksat values termed “compacted” and “loosened” for the modeling analysis represent the geometric mean Ksat values for soils within the national database developed by Rawls that have bulk densities higher and lower than the NRCS recommended value for the given soil texture class, respectively (Rawls, 1998).
For new developments that create more than one acre of new impervious surface on sites without restrictions, the MIDS performance goal is that stormwater runoff volumes will be controlled and the post-construction runoff volume shall be retained on site for 1.1 inches of runoff from impervious surfaces statewide. Our suggested approach to quantifying the volume reduction benefit achieved from maintaining and/or amending soils in vegetated areas in terms of the MIDS performance goal is summarized below. Note that the determination of appropriate soil conditions prior to and following soil improvements will be site dependent.
\(Pre-soil improvement RO = (Area_p)(RD_{po}) + (Area_i)(RD_i)\)
where:
\(Post-soil improvement RO = (Area_{p imp})(RD_{p imp}) + (Area_{p unimp})(RD_{po}) + (Area_i))(RD_i)\)
where:
\(Adjusted impervious RO = post-soil improvement RO - (Area_p)(RD_{po})\)
where:
\(Area_{i adj} = (Adjusted impervious RO) / RD_i\)
where:
\(BMP volume credit = 0.092 (Area_i - Area_{i adj})\)
where:
Areai adj = adjusted impervious area (square feet) for calculation of of performance goal conformance.
The approach described in the steps above results in an equivalent BMP volume credit that can be used to evaluate conformance with the MIDS performance goal. To estimate the annual runoff volume reduction that is achieved by implementation of soil improvements, we recommend applying the performance curves developed for assessing the annual performance of bioretention basins. These performance curves, which were developed for sites ranging from 10 to 90 percent imperviousness and hydrologic soils groups A, B, and C, allow for estimation of the average annual runoff volume reduction based on an equivalent BMP volume per tributary drainage area.
The MIDS calculator estimates the average annual removal of total phosphorus, dissolved phosphorus, and total suspended solids from stormwater runoff as a result of BMP implementation. For runoff that is infiltrated as a result of soil improvements in the vegetated pervious areas, 100 percent pollutant removal is suggested. For runoff that is not infiltrated, 0 percent pollutant removal is suggested. For example, if a 5 percent annual runoff volume reduction is estimated as a result of soil improvements, the average annual total phosphorus, dissolved phosphorus, and total suspended sediment reductions will be 5 percent. For the 95 percent of annual runoff discharged from a site, no additional pollutant removal will be credited.
Three example calculations are presented below. The 1st two examples are for disconnected impervious surfaces (A and B soils, respectively) and the 3rd is for improved soil.
To perform the calculations to determine volume credits for improved turf, runoff depth must be known for the three soil conditions (compacted, average, loosened) and the three soil types being considered (A, B, C. Note that D soils are not considered for this credit.). These values were determined from continuous simulation modeling using XP-SWMM and they are summarized below:
The runoff depth from impervious surfaces is 22.5 inches.
The figure at the right summarizes BMP volume credits for a range of site conditions (20, 50, and 80% impervious) and soil types (A, B, and C soils).
A simple calculator allows you to calculate the credit for impervious surface disconnection (File:Disconnection credit calculator.xlsx). You will need the following information to use the calculator:
Another input in the spreadsheet, the I/P ratio, is the area of redirected impervious surface to effective pervious area. Using the I/P ratio for the appropriate soil in the figure to the right allows determination of the runoff depth, which is input into the spreadsheet.
Note that the spreadsheet generates a volume credit for disconnection. It does not calculate the percent credit toward the performance goal. The performance goal includes runoff from both the non-redirected and redirected impervious areas. Thus, the greater the percent of redirected impervious area relative to total impervious area at a site, the greater the volume credit as a percent of the performance goal.
Compost is the product resulting from the controlled biological decomposition of organic materials that have been sanitized (pathogens removed) through the generation of heat and stabilized to the point that it is beneficial to plant growth. It is an organic matter resource that can improve the chemical, physical, and biological characteristics of soil. It is derived from several sources, including composted yard waste, food waste, manure, leaves, grass clippings, straw, or biosolids. Media mixes specified in this manual call for leaf compost or MnDOT Grade 2 compost (See Specification 3890).
Undisturbed soils provide important stormwater management functions including efficient water infiltration and storage, adsorption of excess nutrients, filtration of sediments, biological decomposition of pollutants, and moderation of peak stream flows and temperatures. In addition, healthy soils support vigorous plant growth that intercepts rainfall, returning much of it to the sky through evaporation and transpiration. Common development practices include removal of topsoil during grading and clearing, compaction of remaining soil, and planting into unimproved soil or shallow depths of poor quality imported topsoil. These conditions typically produce unhealthy plants that require excessive water, fertilizers and pesticides, further contaminating runoff.
To maintain the natural soil qualities, impacts to undisturbed soils should be avoided and minimized during the construction process. When impacts are unavoidable and soils have been compacted or otherwise disturbed, compost can be used as an amendment to regain some of the characteristics of undisturbed soils.
Compaction of soils significantly affects infiltration of water into sandy and clay soils. When compacted, soil infiltration rates decrease by 90 percent or more. Compacted soils contribute a significantly greater volume of runoff to the storm water system. Compost can help to off-set the effect of compaction.
Establishing soil quality and depth regains greater stormwater function in the post development landscape, provides increased treatment of pollutants and sediments that result from development and habitation, and minimizes the need for some landscaping chemicals, thus reducing pollution through prevention. Establishing a minimum soil quality and depth is not the same as preservation of naturally occurring soil and vegetation. However, establishing a minimum soil quality and depth will provide improved onsite management of stormwater flow and water quality.
Compost can be used as a soil amendment to
Minnesota has about 8 large-scale compost sites that actively accept food waste and are permitted. There are also several yard waste compost sites that have a permit by rule to compost yard-waste only. All of these permitted sites annually report to the MPCA. They are required to test their compost products for pathogens and for maturity to prove their compost meets “Class 1 “ standards as described by the compost rule.
If a site does not meet class 1 standards, they must seek commissioner approval from MPCA in order to distribute their material. Compost from permitted compost sites must meet the following criteria:
When amending disturbed soils with compost, it is important to use a compost product that fits the specific situation. In Minnesota, compost is made from a variety of feed-stocks, including yard and leaf debris, residential or commercial food residuals, and animal manure. Each type of feedstock produces a slightly different compost. For example, a yard and leaf compost is lower in nutrients and the particle size is generally coarser than a manure compost, which has higher nutrient content and a finer, more uniform particle size. Thus, a yard-leaf compost may be more appropriate when applying compost to a project site close to a water source impaired for phosphorus. Because of the coarser texture, a yard-leaf compost is a better choice for a blanket, filter sock, or berm to control erosion. Both yard–leaf compost and the manure compost could be used for turf applications.
Compost maturity is another important factor. Using compost that has been properly aged or "cured" as a post-construction soil amendment promotes healthy root and plant growth and will prevent damage to turf and plantings. When immature compost is applied to soils it continues to decompose and the process of decomposition robs nitrogen from the plants and stunts plant growth, possibly even killing the plant. To facilitate the creation of consistent compost products throughout the United States, the U.S. Composting Council (USCC) created the Seal of Testing Assurance Program (STA). This voluntary program requires participating compost facilities to perform a uniform set of tests on their compost products. Composters who are STA participants are required to furnish test information to compost buyers. This gives the purchaser of the compost the agronomic information needed (such as pH, particle size and test results from a number of other parameters) to successfully use the compost. If a compost site in Minnesota accepts food waste, they are also required to have a permit from the MPCA. This permit requires the compost site to comply with the compost rule thereby meeting the process to further reduce pathogens (PFRP) and for the compost to spend time “curing” until it reaches maturity which is documented by solvita testing. Compost operators are required to submit annual reports to the MPCA to ensure they are meeting these health and safety standards. For more information on compost maturity, link here.
Leaching is the process of removing soluble constituents. In nature, leaching occurs as water passes through a material such as soil. Leached constituents may then be transported with water, where the constituents may enter surface water or groundwater. Leaching of nutrients, specifically phosphorus and nitrogen, may be harmful to a receiving water.
Most soil phosphorus exists in stable chemical compounds with only a small amount dissolved into the soil solution which makes itself available to plants. This dissolved phosphorus is also the phosphorus that can leach and cause environmental concerns. Phosphorus is provided through the weathering of phosphorus rich minerals naturally found in soil and also through the addition of chemical or inorganic forms of phosphorus fertilizer.
A number of factors can contribute to the potential for phosphorus leaching. These include:
Nutrients in compost are subject to leaching. The extent of leaching varies with the characteristics of the compost, such as the source and age of compost. Compared to composted tree and grass material, peat (Glader, 2013) and coir (Lucas, 2012) compost are lower in phosphorus and do not typically leach phosphorus.
The test methods used to determine the phosphorus content in chemical phosphorus (inorganic) fertilizers are not the most appropriate methods for determining the phosphorus content in carbon-based products (e.g., compost, biosolids, manure). The amount of WEP (Water extractable phosphorus) is a good predictor of runoff P loss from surface applied organic materials. The table below shows the WEP in various organic matter sources.
Water extractable phosphate in composts and land-applied organic materials
Link to this table.
Feedstock | Biosolids treatment | Total solids(%) | pH | P2O5 (% dry wt) | P (% dry wt) | WEPa(% of Total P) |
---|---|---|---|---|---|---|
Leaf / yard wastes | NA | 39.4 | 7.7 | 0.34 | 0.15 | 8.4 |
Leaf / yard wastes / food | NA | 47.5 | 7.4 | 0.42 | 0.18 | 7.4 |
NA | 53.9 | 7.4 | 0.43 | 0.19 | 6.8 | |
Biosolids / wood chips2 | No P removal | 39.8 | 7.2 | 0.78 | 0.34 | 20.5 |
An. digest /No P removal | 59.2 | 7.2 | 1.87 | 0.82 | 7.7 | |
No P removal | 48.1 | 6.7 | 1.6 | 0.7 | 22.3 | |
Chemical P removal | 38.8 | 5.5 | 3.65 | 1.59 | 1.8 | |
Biosolids / wood chips / yard wastes2 | No P removal | 72.1 | 6.6 | 0.81 | 0.35 | 12.2 |
Biosolids / yard wastes / WTRb2 | No P removal | 53.5 | 8.3 | 1.67 | 0.73 | 4.6 |
No P removal | 47.8 | 7.9 | 1.68 | 0.73 | 4.1 | |
Leaf / yard wastes / gelatin residuals | NA | 51.1 | 8.3 | 2.19 | 0.96 | 2.0 |
Biosolids / wood shavings2 | Biological P removal | 42.8 | 5.7 | 2.41 | 1.05 | 13.3 |
aWEP = Water extractable phosphorus, bWTR = water treatment residuals (Source: Phosphorus and Compost Use Dynamics, Alexander, 2016)
2Minnesota does not compost biosolids per rule. Only source separated organic matter and yard waste are allowed in compost.
Data generated through product testing by Agresource, Inc. (Rowley, MA), and distilled by Dr. John Spargo at Penn State University, illustrates the following (Alexander, 2016).
At active construction sites, practices such as compost socks or filter bags may leach phosphorus but retain sediment. Consequently, these practices may lead to elevated phosphorus concentrations in runoff but reduced total phosphorus export from the site due to sediment retention. Exercise the following cautions when considering compost near receiving waters where nutrients are a concern.
Compost has several beneficial uses, including improving the stormwater management functions of compacted soils. Many of the uses of compost overlap and can serve both construction and post-construction purposes.
A. Description: Compost is a popular soil amendment used to improve the physical, chemical and biological properties of soil. It is primarily used as a means to improve soil structure, especially in areas where soil compaction is a common concern due to construction practices or land usage patterns (e.g., athletic fields), but also contains plant required nutrients such phosphorus, nitrogen, and potassium.
B. Materials: When purchasing compost to be used for turf establishment or incorporation into soil as a post-construction soil amendment, look for a Class 1 compost with the specifications listed in the table below.
Product parameters for compost used for soil amendment and turf establishment
Link to this table.
Parameter | Parameter definition | Range (Provided by G. Black, MPCA, 2007) |
---|---|---|
Source mater/nutrient content | Compost typically comes from biosolids/animal manure or yard wastes. Compost made from biosolids and animal manure typically contains more nutrients.1 |
|
Maturity | Maturity refers to the level of completeness of the composting process. Composts that have not progressed far enough along the decomposition process may contain phytotoxic compounds that inhibit plant growth.2 | Seed emergence and seed vigor = minimum 80% relative to positive control |
Stability | Compost stability refers to the biological activity in the composted material. Unstable composts may use available nitrogen in the soil and stunt plant growth. | CO2 Evolution rate: < 8 mg CO2-C/g-OM/day |
pH | pH is a measure of acidity/alkalinity. Amending soil with compost can alter soil pH, which in turn can improve plant growth. | 5.5-8.5 |
Soluble salts | The term “soluble salts” refers to the amount of soluble ions in a solution of compost and water. Because most plant nutrients are supplied in soluble form, excess non-nutrient soluble salts can inhibit plant growth. | Varies widely according to source materials for compost, but should be < 10 dS/m (mmhos/cm) |
Organic matter | Organic matter is a measure of the amount of carbon-based materials in compost. There is no ideal range of organic matter for compost, but knowing the amount of organic matter in compost may help determine application rates for specific applications. | 30-65% dry weight basis |
Particle size | It is helpful to know the size of particles in a compost product. There is no ideal range for particle size, as it varies according to use. Specifications can be found on the USEPA web site and MnDOT Grade 2 compost (See Specification 3890). | Pass through 1-inch screen or less; 3/4 inch is preferable per MnDOT Specification 3890 |
Biological contaminants (weed seeds and pathogens) | Biological contaminants consist of pathogens (disease causing organisms) and weed seeds. High temperatures will inactivate both types of biological contaminants. Minnesota State composting rules require commercial composting operations to hold temperatures over 55 degrees C over an extended period of time to destroy pathogens. In addition, compost operations must monitor the process to prove that these conditions have been met. | Meet or exceed US EPA Class A standards, 40 CFR §503.32(a) levels |
Physical contaminants (inerts)3 | Inerts are materials (e.g. rocks, plastic, glass) that do not decompose. There is no ideal range but they may be aesthetically unpleasing and add no value to the compost. | < 1% dry weight basis4 |
Trace metals | Trace metals are elements that can be toxic to humans, animals, or plants at elevated concentrations | Meet or exceed US EPA Class A standards, 40 CFR §503.32(a) levels |
1MnDOT Grade 1 compost is derived from animal material; Grade 2 compost is derived from leaves and yard wastes, and/or SSOM compost with STA certification. See MnDOT Specification 3890
2MnDOT Specification 3890 states: "Considered mature and useable when 60 percent decomposition has been achieved as determined by an ignition-loss analysis test method and any one additional test method including the Solvita test value of equal to or greater than 5. This means that the compost product has no offensive smell, no identifiable organic materials, and will not reheat to more than 20 °F [11 °C] above the ambient temperature." Note, however, that desired maturity may vary depending on the application and time of application.
3Inert material should not be present in adequately screened, vegetated waste compost. Caution should be used when the compost originates as mixed municipal or unscreened compost.
4MnDOT Specification 3890 states: "< 3% at 0.15 in [4 mm]"
C. Application Guidelines: The goal in amending compacted soils with compost is to reach or exceed the stormwater management benefits of naturally occurring soil and vegetation. Compost amended soils will improve on-site stormwater management and reduce long term operation and maintenance costs for off-site water treatment best management practices. Developing a Soil Management Plan is an important first step in minimizing and mitigating impacts to native soils and maximizing onsite stormwater management benefits.
In areas where remaining topsoil or subsoil will be amended in place, it is important that, at a minimum, certain soil quality and depth improvements are achieved, as follows.
O&M Performance Standards
Warning: Immature compost will not provide the benefits of mature compost. When immature compost is applied to soils it will continue to decompose and the process of decomposition and the by-products it creates and nutrients it demands may be harmful to plants growing in the soil (Garland and Grist, 1995). These effects may be eliminated by adding additional fertilizer, thereby supplying the nitrogen needed for the continued decomposition of the compost and plant needs. You can ensure that you are receiving a mature compost if the composter is permitted as a solid waste or source-separated organics facility by the MPCA and/or if they have passed their Seal of Testing Assurance testing. You can always ask a composter to see their data sheets from their solvita testing for compost maturity.
Application guidelines for compost.
Link to this table
Planting areas | Turf areas | |
---|---|---|
High-traffic areas | (18 inch uncompacted depth) Incorporate 3 inches of compost into the top 5 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 10 inches. | Incorporate 1.75 inches of compost into the top 6.25 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 10 inches |
Construction limits | (12 inch uncompacted depth) Incorporate 3 inches of compost into the top 5 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 4 inches | Incorporate 1.75 inches of compost into the top 6.25 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 4 inches |
A. Use and description: A compost blanket is a layer of loosely applied composted material placed on the soil in disturbed areas to reduce stormwater runoff and erosion (EPA). The use of compost as an erosion control blanket has become a popular tool for managing both soil erosion and storm water on sloped surfaces. Compost blankets should only be used in applications where water moves as a sheet (not concentrated) flow. Link to compost blanket as an erosion control practice for construction stormwater.
B. Materials: If you are considering using compost as a “blanket” to reduce or prevent erosion the soil blanket should be a composted, weed free organic matter source derived from agricultural, food, or industrial residuals; yard trimmings; or source-separated or mixed solid waste. Particle size shall be as described below in the product parameters table. The compost should meet Class 1 standards.
Well-composted product will provide the best planting medium for grass, wildflower, legume seeding or ornamental planting. Very coarse composts may need to be avoided if the slope is to be landscaped or seeded, as it will make planting and crop establishment more difficult. Composts containing fibrous particles that range in size produce a more stable mat.
Product parameters for compost blanket
Link to this table
Parameters1,4 | Reported as (units of measure) | Blanket Media to be Vegetated | Blanket media to be left Unvegetated |
---|---|---|---|
pH2 | pH units | 6.0 - 8.5 | N/A |
Soluble Salt Concentration2 (electrical conductivity) | dS/m (mmhos/cm) | Maximum 5 | Maximum 5 |
Moisture Content | %, wet weight basis | 30 – 60 | 30 – 60 |
Organic Matter Content | %, dry weight basis | 25 – 65 | 25-100 |
Particle Size | % passing a selected mesh size, dry weight basis |
|
|
Stability3 Carbon Dioxide Evolution Rate | mg CO2-C per g OM per day | < 8 | N/A |
Physical Contaminants (man-made inerts) | %, dry weight basis | < 1 | < 1 |
1 Recommended test methodologies are provided in Test Methods for the Examination of Composting and Compost (TMECC, The US Composting Council)
2 Each specific plant species requires a specific pH range. Each plant also has a salinity tolerance rating, and maximum tolerable quantities are known. When specifying the establishment of any plant or turf species, it is important to understand their pH and soluble salt requirements, and how they relate to the compost in use.
3 Stability/Maturity rating is an area of compost science that is still evolving, and as such, other various test methods could be considered. Also, never base compost quality conclusions on the result of a single stability/maturity test.
4 Landscape architects, plant specialists and project (field) engineers may modify the allowable compost specification ranges based on specific field conditions and plant requirements.
C. Application Guidelines: Compost mulch shall be uniformly applied to a depth described below. Areas receiving greater precipitation, possessing a higher erosivity index, or which will remain unvegetated, will require greater application rates.
When placing compost blanket on a 1:2 (V:H) slope, place and anchor open weave textile netting over the top. Alternatively, apply compost using a pneumatic (blower) or slinger type spreader unit. Project compost directly at soil surface, thereby preventing water from moving between the soil-compost interface. Apply compost layer approximately 3 feet beyond the top of the slope or overlap it into existing vegetation. On highly unstable soils, use compost in conjunction with appropriate structural, stabilization and diversion measures. Follow by seeding or ornamental planting if desired.
Summary of construction requirements: Compost blanket application.
Link to this table
Annual Rainfall/Flow Rate | Total Precipitation & Rainfall Erosivity Index | Application Rate For Vegetated1 Compost Surface Mulch | Application Rate For Unvegetated Compost Surface Mulch |
---|---|---|---|
Low | 1-25”, 20-90 | ½ - ¾ ” (12.5 mm – 19 mm) | 1” – 1 ½” (25 mm – 37.5mm) |
Average | 26-50”, 91-200 | ¾ - 1” (19 mm – 25 mm) | 1 ½” – 2” (37 mm – 50 mm) |
High | 51” and above, 201 and above | 1-2” (25 mm – 50 mm) | 2-4” (50mm – 100mm) |
1These lower application rates should only be used in conjunction with seeding, and for compost blankets applied during the prescribed planting season for the particular region.
A. Description and use: This work consists of constructing a raised berm of compost on a soil surface to contain soil erosion, control the movement of sediment off site, and to filter storm water. Filter berms are most effective in managing sediment from sheet flows of water, while filter socks can be used to remove sediment from both sheet and concentrated flows of water.
B. Materials: Filter berm media should be a composted, weed free organic matter source derived from: agricultural, food, or industrial residuals; yard trimmings; source-separated or mixed solid waste. Particle size may vary widely. The compost shall be Class 1 material and will meet the product parameters outlined below.
Where seeding of the berm is planned, use only well composted product that contains no substances toxic to plants. Avoid coarse composts if the berm is to be seeded, as it will make establishment more difficult.
The Landscape Architect/Designer shall specify the berm dimensions depending upon specific site (e.g., soil characteristics, existing vegetation) and climatic conditions, as well as particular project related requirements. The severity of slope grade, as well as slope length, will also influence compost application.
Product parameters for compost filter berm application
Link to this table
Parameters1,4 | Reported as (units of measure) | Filter Berm to be Vegetated | Filter Berm to be left Un-vegetated |
---|---|---|---|
pH2 | pH units | 6.0 - 8.5 | N/A |
Soluble Salt Concentration2 (electrical conductivity) | dS/m (mmhos/cm) | Maximum 5 | N/A |
Moisture Content | %, wet weight basis | 30 – 60 | 30 – 60 |
Organic Matter Content | %, dry weight basis | 25 – 65 | 25-100 |
Particle Size | % passing a selected mesh size, dry weight basis |
|
|
Stability3 Carbon Dioxide Evolution Rate | mg CO2-C per g OM per day | < 8 | N/A |
Physical Contaminants (man-made inerts) | %, dry weight basis | < 1 | < 1 |
1Recommended test methodologies are provided in Test Methods for the Examination of Composting and Compost (TMECC, The US Composting Council)
2Each specific plant species requires a specific pH range. Each plant also has a salinity tolerance rating, and maximum tolerable quantities are known. When specifying the establishment of any plant or turf species, it is important to understand their pH and soluble salt requirements, and how they relate to the compost in use.
3Stability/Maturity rating is an area of compost science that is still evolving, and as such, other various test methods could be considered. Also, never base compost quality conclusions on the result of a single stability/maturity test.
4Landscape architects, plant specialists and project (field) engineers may modify the allowable compost specification ranges based on specific field conditions and plant requirements.
C. Construction Requirements: Parallel to the base of the slope or other affected areas, construct a berm of compost to size specifications. In extreme conditions and where specified by the Landscape Architect/Designer, a second berm shall be constructed at the top of the slope or silt fencing shall be installed in conjunction with the compost berm. Where the berm deteriorates, it shall be reconstructed. Do not use filter berms in any runoff channels (concentrated flows).
Construction requirements for compost filter berm.
Link to this table
Annual Rainfall/Flow Rate | Total Precipitation & Rainfall Erosivity Index | Dimensions for the Compost Filter Berm (height x width) |
---|---|---|
Low | 1-25”, 20-90 | 1’x 2’ – 1.5’ x 3’ (30 cm x 60 cm – 45 cm x 90 cm) |
Average | 51” and above, 201 and above | 1’x 2’ - 1.5’ x 3’ (30 cm x 60 cm – 45 cm x 90 cm) |
High | 51” and above, 201 and above | 1.5’x 3’ – 2’ x 4’ (45 cm x 90 cm – 60cm x 120 cm) |
A. Description and use: The compost filter sock is a tubular mesh sleeve that contains compost of a particular specification suitable for stormwater filtration applications. The compost filter sock is a linear, land-based treatment that removes stormwater pollutants through filtration of soluble pollutants and sediments and by deposition of suspended solids (USDA, 2010).
The flexible nature of filter socks allow them to be filled in placed or filled and moved into position, allowing them to be placed on rocky or steep slopes where installation of other erosion control tools is not feasible. The three dimensional shape allows for greater surface contact as well, reducing the potential for runoff to create rills under the device or channels to carry unfiltered sediment.
B. Materials: Filter socks are applicable to construction sites or other disturbed areas where stormwater runoff occurs as sheet flow. In areas where the receiving waters contain high nutrient levels, the site operator should choose a mature, stable compost that is compatible with the nutrient and pH requirements of the selected vegetation. This will ensure that the nutrients in the composted material are in organic form and are therefore less soluble and less likely to migrate into receiving waters. Very coarse (woody) composts that contain less than 30 percent of fine particles (1mm in size) should be avoided if optimum reductions in total suspended solids (TSS) is desired or if the berm is to be seeded.
MnDOT 3897.2 E requires the following characteristics in sediment control logs containing compost.
C. Construction Requirements: The filter sock is placed perpendicular to sheet-flow runoff to control erosion and retains sediment in disturbed areas, often placed along the perimeter of a site or at interval along a slope. They can also be placed adjacent to each other and perpendicular to stormwater flow to reduce velocity and soil erosion, and as inlet protection.
Compost filter socks can be used on steeper slopes with faster flows than other compost filter devices if spaced closely, stacked beside and/or on top of each other, made larger diameters or used in combination with other stormwater BMPs such as compost blankets.
Filter socks are round to oval in cross section; they are assembled by tying a knot in one end of the mesh sock, filling the sock with the composted material (usually using a pneumatic blower), then knotting the other end once the desired length is reached.
Construction requirements for compost filter sock.
Link to this table
Parameters1, 4 | Reported as (units of measure) | Vegetated Filter Sock5 | Unvegetated Filter Socka6 |
---|---|---|---|
pH2 | pH units | 5-8.5 | 6-8 |
Soluble Salt Concentration2(electrical conductivity) | dS/m (mmhos/cm) | Maximum 5 | NA |
Moisture content | %, wet weight basis | 30-60 | 30-60 |
Organic matter content | %, dry weight basis | 25-65 | 25-65 |
Particle size | % passing a selected mesh size, dry weight basis |
|
|
Stability3 Carbon Dioxide Evolution Rate | mg CO2-C per g OM per day | <8 | <8 |
Physical Contaminants (man-made inerts) | %, dry weight basis | <1 | <1 |
1Recommended test methodologies are provided in Test Methods for the Examination of Composting and Compost (TMECC, The US Composting Council)
2Each specific plant species requires a specific pH range. Each plant also has a salinity tolerance rating, and maximum tolerable quantities are known. When specifying the establishment of any plant or turf species, it is important to understand their pH and soluble salt requirements, and how they relate to the compost in use.
3Stability/Maturity rating is an area of compost science that is still evolving, and as such, other various test methods could be considered. Also, never base compost quality conclusions on the result of a single stability/maturity test.
4Landscape architects, plant specialists and project (field) engineers may modify the allowable compost specification ranges based on specific field conditions and plant requirements.
5Alexander, 2003
6Personal communication, B. Faucette, R. Tyler, N. Goldstein, R. Alexander, 2005
Suggested compost filter sock flow rates. Source: Alexander, R. (2006)
Link to this table
Annual Rainfall/Flow Rate | Flow rates |
---|---|
Low | 4-6 gallons/minute |
Average | 6-10 gallons/minute |
High | >10 gallons/minute |
A. Description and uses: In many jurisdictions, compost is a major component to the primarily sand-based bioretention media. Compost can act as a carbon filter for the media. Since it possesses a high cation exchange capacity, it can bind certain heavy metals, and through its biologic activity, it can degrade certain petroleum hydrocarbons. That stated, compost does contain both P and N, and since they are considered to be contaminants to potable and non-potable water resources, concern exists about their leaching from the bioretention media.
B. Specifications: Engineered media mixes described in this manual contain from 2 to 30 percent organic matter. MnDOT Grade 2 compost (See Specification 3890) is recommended as the organic matter source. Specifications for engineered media mixes are discussed on this page.
C. Application Guidelines: Although the bioretention soil mix is effective at removing pollutants through sedimentation, filtration, and adsorption, the media itself can act as a pollutant source if not properly configured. Fine sands and associated bound pollutants will export during a flushing period of variable duration. Additionally, labile nutrients and other bound pollutants will leach from the compost fraction for an undetermined amount of time (Herrera Environmental Consultants, Inc., 2004). Lab studies looking at both pure compost products and compost/sand based bioretention media found that concentrations of nitrogen, phosphorus, and copper were high in the initial few storms and then decreased (Flury, et, al., 2015).
When considering the risks of loss of phosphorus through leaching, it is important to consider the compost may only make up 10 to 30 percent of the media. It’s presence in the media can be an effective method to capture heavy metals and can aid in keeping vegetation alive in the bioretention feature, which improves the overall functionality of the feature. Additionally, research indicates that the addition of iron or aluminum rich water treatment residuals to bioretention media containing compost and biosolids treated solids can substantially bind soluble phosphorus (O’Connor & Chinault, 2007).
In addition to improving the stormwater management functions of compacted soils, compost has several other beneficial uses.
The literature cited below was reviewed as part of a literature review conducted for the original stormwater manual. Some of the references and material may therefore be dated or inaccurate. For example, some studies pertaining to removal of dissolved phosphorus removal were conducted with high influent phosphorus concentrations (e.g. > 1.0 mg/L) and do not reflect typical stormwater.
This page was last edited on 16 February 2023, at 21:31.