Testing
Section 8.2 - 8.9 content text (only) Appendix C as A SCROLLING DOCUMENT!!!
Mention training courses
Soil Characterization Testing[edit]
The soil component of an LID BMP contributes substantially to its stormwater treatment performance and overall function. If the soil is overly compacted or very finely textured, it may drain too slowly. If the soil is highly organic or contains excessive amounts of chemical fertilizer it may contribute to nutrient loads to receiving waters rather than reduce them. If the soil is too shallow it may not provide adequate treatment of contaminated stormwater or may not support healthy vegetation. Whether it be the engineered filter media of bioretention cells, the growing media of green roofs or the topsoil of enhanced swales, vegetated filter strips and soil amendment areas, it is important that the soil provide a healthy growing environment for plantings while being within design specifications for key parameters specific to the type of BMP.
It is most important to sample and test soil characteristics as a part of Construction and Assumption inspections, to confirm the BMP has been constructed with materials that meet design specifications and that installation of the soil component is acceptable. Testing to confirm that the material meets quality specifications (i.e., particle-size distribution, organic matter, pH, cationic exchange capacity, nutrients and soluble salts) needs to be completed prior to it being delivered to the construction site. Testing to confirm that installation of the soil component is acceptable (i.e., depth and compaction) should be performed after the installed material has been allowed to settle for at least two (2) weeks, and prior to planting.
Sampling and testing is also recommended as a part of Verification inspections, to determine if the BMP is being adequately maintained and if soil characteristics are still within acceptable ranges. It may also be done as part of Forensic inspection and Testing (FIT) work to help diagnose the cause of poor vegetation cover, drainage or treatment performance and decide on corrective actions.
LID BMP Type |
Soil Characteristic |
Acceptance Criteriai |
Test |
---|---|---|---|
Bioretention / Bioswales / Dry swale | |||
Textureii | Loamy Sand or Sandy Loam; 70 to 88% sand-sized particles; 12 to 30% silt- and clay-sized particles; <20% clay-sized particles. | Particle-Size Distribution (PSD), or % Sand/Silt/Clay (i.e., Soil Texture) plus Sand Fraction | |
Organic Matter (OM) | 3 to 10% by dry weightii | Walkley-Black method when OM <7.5% or Loss On Ignition (LOI) method when OM ≥7.5%iii | |
Soil pH | 6.0 to 7.8 | pH of a Saturated Pasteiii | |
Cationic Exchange Capacity (CEC) | >10 meq/100 g | Cationic Exchange Capacity Test | |
Phosphorusiv | 12 to 40 ppm | Extractable Phosphorus | |
Soluble Saltsv | ≤2.0 mS/cm (0.2 S/m) | Electrical Conductivity of a Soil-Water Slurry (2:1 water to soil ratio by volume)iii | |
Depth | +/- 10% of design specification | Soil Cores, Test Pits or Cone Penetration Tests | |
Compactionvi | Surface Resistance: ≤110 PSI; Sub-surface Resistance: ≤260 PSI Bulk Density: ≤1.60 g/cm3 | Cone Penetration Tests or Bulk Density Tests | |
Permeability | i ≥25 mm/h (KS ≥ 1 x 10-5 cm/s); and i ≤203 mm/h (KS ≤ 0.02 cm/s). | Surface Infiltration Rate Tests | |
Enhanced swale (topsoil) | |||
Texture | Same soil texture classification as specified in the final design or recorded on the as-built drawing | Particle-Size Distribution (PSD), or % Sand/Silt/Clay (i.e., Soil Texture) plus Sand Fraction | |
Organic Matter (OM)ii | 5 to 10% by dry weight | Walkley-Black method when OM <7.5% or Loss On Ignition (LOI) method when OM ≥7.5%iii | |
Soil pH | 6.0 to 7.8 | pH of a Saturated Pasteiii | |
Phosphorusiv | 12 to 40 ppm | Extractable Phosphorus | |
Soluble Saltsv | ≤2.0 mS/cm (0.2 S/m) | Electrical Conductivity of a Soil-Water Slurry (2:1 water to soil ratio by volume)iii | |
Depth | +/- 10% of design specification | Soil Cores, Test Pits | |
Compaction | Surface Resistance: ≤110 PSI; Sub-surface Resistance: Use soil texture class and "Soil & Texture Class Table" (below) to determine maximum acceptable value; Bulk Density: Use PSD to interpolate maximum bulk density value from bulk density figure beside this table. | Cone Penetration Tests or Bulk Density Tests | |
Permeability | i ≥15 mm/h (KS ≥ 1 x 10-6 cm/s) | Surface Infiltration Rate Tests | |
Vegetated filter strips and Soil Amendment Areas (topsoil) | |||
Texture | Same soil texture classification as specified in the final design or recorded on the as-built drawing | Particle-Size Distribution (PSD), or % Sand/Silt/Clay (i.e., Soil Texture) plus Sand Fraction | |
Organic Matter (OM)ii | 5 to 10% by dry weight | Walkley-Black method when OM <7.5% or Loss On Ignition (LOI) method when OM ≥7.5%iii | |
Soil pH | 6.0 to 7.8 | pH of a Saturated Pasteiii | |
Phosphorusiv | 12 to 40 ppm | Extractable Phosphorus | |
Soluble Saltsv | ≤2.0 mS/cm (0.2 S/m) | Electrical Conductivity of a Soil-Water Slurry (2:1 water to soil ratio by volume)iii | |
Compaction | Surface Resistance: ≤110 PSI; Sub-surface Resistance: Use soil texture class and "Soil & Texture Class Table" (below) to determine maximum acceptable value; Bulk Density: Use PSD to interpolate maximum bulk density value from bulk density figure beside this table. | Cone Penetration Tests or Bulk Density Tests | |
Permeability | i ≥15 mm/h (KS ≥ 1 x 10-6 cm/s) | Surface Infiltration Rate Tests | |
Green roof (growing media) | |||
Texture | See product vendor or BMP designer for specifications | Particle-Size Distribution (PSD), or % Sand/Silt/Clay (i.e., Soil Texture) plus Sand Fraction | |
Maximum Media Density | See product vendor or BMP designer for specification | Maximum Media Density Test (ASTM E2399/E2399M-15) | |
Water Storage Capacityvii | Extensive: ≥35% by volume / Intensive: ≥45% by volume | Both part of Maximum Media Density Test (ASTM E2399/E2399M-15) | |
Air-Filled Porosityvii | ≥10% by volume | Part of Maximum Media Density Test (ASTM E2399/E2399M-15) | |
Permeability, Saturated Media | See product vendor or BMP designer for specification | Part of Maximum Media Density Test (ASTM E2399/E2399M-15) | |
Organic Matter | See product vendor or BMP designer for specification | Walkley-Black method when OM <7.5% or Loss On Ignition (LOI) method when OM ≥7.5%iii | |
Soil pHviii | 6.5 to 7.8 | pH of a Saturated Paste | |
Soluble Saltsviii | ≤0.85 mS/cm (0.085 S/m) | Electrical Conductivity of a Saturated Media Extract (SME)solution | |
Phosphorusix | 2.2 to 40 ppm | Electrical Conductivity of a Saturated Media Extract (SME)solution |
Notes |
---|
i Values represent acceptable ranges for established BMPs (i.e., in operation for 3 years or more). For Construction and Assumption inspections, final design and soil or media product specifications and permissible tolerance ranges should be used as the acceptance criteria, which may be smaller ranges than the values in this table. |
ii Suggested range for diagnosing suspected problems with drainage function, vegetation cover or vegetation condition for established BMPs constructed with filter media that meets recommended guidelines (CVC & TRCA, 2010)[2]. For proprietary filter media products, different ranges may be acceptable. Product specifications should be provided by the media supplier. Test results should be compared to the media supplier’s specifications and permissible tolerance ranges |
iii Based on Ontario Ministry of Food and Rural Affairs’ Soil Fertility Handbook guidance on soil fertility testing for crop production (OMAFRA, 2006)[3]. |
iv Based on Minnesota Pollution Control Agency (MPCA, 2015) for minimum to sustain plant growth and Ontario Ministry of Agriculture, Food and Rural Affairs (OMAFRA, 2014) for a maximum to avoid unnecessary fertilization that would have low or no effect on plant health. |
v Based on the threshold for non-saline soils (Whitney, 2012). |
vi Interpolated value from bulk density figure beside this table. based on a sandy loam soil containing at least 70% sand-sized particles. |
vii Based on German green roof standards (FLL 2008). Specifications will vary depending on the green roof growing media product. Product specifications should be provided by the media supplier. Test results should be compared to the media supplier’s specifications and permissible tolerance ranges. |
viii Based on Penn State University Center for Green Roof Research (Berghage et al. 2008). |
ix Based on Penn State University Center for Green Roof Research (Berghage et al. 2008) for the minimum to sustain plant growth and Ontario Ministry of Agriculture, Food and Rural Affairs (OMAFRA, 2014) for the maximum to avoid unnecessary fertilization that would have low or no effect on plant health. |
Surface Resistancei |
'Sub-surface Resistancei | ||
---|---|---|---|
All Soil Textures | Sandy (includes loamy sand, sandy loam, sandy clay loam and sandy clay) | Silty (includes loam, silty loam, silty clay loam, and silty clay) | Clayey (includes clay loam and clay) |
≤ 110 PSIii | ≤ 260 PSI | ≤ 260 PSI | ≤ 225 PSI |
≤ 7.7 kg/cm2 | ≤ 18.3 kg/cm2 iii | ≤ 18.3 kg/cm2 | ≤ 15.8 kg/cm2 |
≤ 758 kPaiv | ≤ 1793 kPa | ≤ 1793 kPa | ≤ 1551 kPa |
Notes |
---|
i Adapted from Gugino et al. (2009)[4] |
ii PSI = pounds per square inch (lb/in2) |
iii kg/cm2 = kilogram per square centimetre. |
iv kPa = kilopascals |
For further information regarding soil characteristics, acceptance criteria per LID BMP type and associated testing tools and protocols scroll down to the embedded 2016 guide below.
Sediment Accumulation Testing[edit]
A primary function of LID BMPs is to capture and retain sediment, trash and debris that are suspended in stormwater runoff. Over time, sediment and natural debris accumulates in certain portions of a BMP, particularly in pretreatment devices (e.g., forebays, gravel diaphragms, hydrodynamic separators, vegetated filter strips, grass swales, catchbasin/manhole sumps) and at inlets, where inflowing runoff is slowed down and spread out, which promotes sedimentation of suspended materials by design.
Without adequate inspection and maintenance (at least annually), accumulated sediment and debris in pretreatment devices and inlets can inhibit the flow of stormwater into the BMP or be transported onto the filter bed . Extensive sediment accumulation on the surface of a filter bed will eventually lead to drainage problems due to clogging of the filter media with fine-textured sediment. When sediment accumulation on the surface of a filter strip or swales becomes excessive the BMPs begin to export sediment and associated pollutants into receiving waters rather than retain them.
Key Components, Test Methods and Equipment[edit]
Key components of LID BMPs that should be the subject of sediment accumulation testing (i.e., depth measurements) are described in the table below along with recommended test methods. Depth measurements should be recorded on inspection field data forms provided on each associated BMP's I&M page on the wiki, used to determine if sediment removal maintenance is needed.
Surface Infiltration Rate Testing[edit]
Natural or Simulated Storm Event Testing[edit]
Continuous Monitoring[edit]
Green Roof Irrigation System Testing[edit]
Green Roof Leak Detection Testing[edit]
Cistern Pump Testing[edit]
References[edit]
- ↑ Sustainable Sites Initiative. 2009. The Sustainable Sites Initiative: Guidelines and Performance Benchmarks. American Society of Landscape Architects, Lady Bird Johnson Wildflower Center at The University of Texas at Austin, United States Botanic Garden and Sustainable Sites Initiative, Austin, TX. https://digital.library.unt.edu/ark:/67531/metadc31157/
- ↑ CVC and TRCA, 2010. Low Impact Development Stormwater Management Planning and Design Guide. Version 1.0. https://cvc.ca/wp-content/uploads/2014/04/LID-SWM-Guide-v1.0_2010_1_no-appendices.pdf
- ↑ OMAFRA. 2006. Soil Fertility Handbook Publication 611. Guelph, Ontario, Canada. http://www.omafra.gov.on.ca/english/crops/pub611/pub611.pdf.
- ↑ Gugino, B.K., Idowu, O.J., Schindelbeck, R.R., van Es, H.M., Wolfe, D.W., Moebius, B.N., Thies, J.E., and Abawi, G.S. 2009. Cornell Soil Health Assessment Training Manual, Edition 2.0, 2009, Cornell University, College of Agriculture and Life Sciences, New York State Agricultural Experiment Station(NYSAES), Geneva, New York. ISBN 0-9676507-4-7. https://www.canr.msu.edu/foodsystems/uploads/files/cornell_soilhealth.pdf