Difference between revisions of "Oil and Grit Separator"

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[[File:HydrodynamicSeparatorsPage smallpic.jpg|thumb|400px|An exampel of what a typical Oil-Grit Seperator (OGS) pretreatment device looks liked (3P Technik UK Ltd, n.d.)<ref>3P Technik UK Ltd. n.d. HYDROSYSTEM1000 SUDS MULTI-PROCESS TREATMENT DEVICE. Stormwater Treatment. Accessed September 23 2022. https://www.3ptechnik.co.uk/stormwater-treatment/hydrosystem_1000/</ref>]]
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[[File:OGS example.jpg|thumb|450px|Plan view cut out of a typical Oil-Grit Separator (OGS) pretreatment device. In this example, the cylinder chamber and weirs create a "vortex swirling effect", which promotes settling of solids in the bottom of the chamber. In most OGS, there is also an oil storage chamber to capture light liquids and floatables. The accumulated sediment and debris is cleaned out regularly by maintenance professionals once the sediment in the chamber reaches the manufacturer’s recommended sediment maintenance depth or the floatables capture chamber is full.]]
  
 
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==Overview==
 
==Overview==
Oil and Grit Separators (OGS) are Manufactured Treatment Devices (MTDs) used for water quality treatment of stormwater runoff through the removal of large particle suspended solids and associated pollutants, and debris. Some devices can also trap light liquids such as oil and other floatables. These MTDs are typically installed underground within the stormwater sewer system in an on-line or off-line configuration. They are distinguished from [[Pretreatment|Filtration-based MTDs]] by their removal of solids through settling rather than filtration.
+
Oil and Grit Separators (OGS) are Manufactured Treatment Devices (MTDs) used for water quality treatment of stormwater runoff through the removal of large particle suspended solids and associated pollutants, and debris. Some devices can also trap light liquids such as oil and other floatables. These MTDs are typically installed underground within the stormwater sewer system in an on-line or off-line configuration. They are distinguished from [[Filtration Manufactured Treatment Devices]] by their removal of solids through settling rather than filtration.
+
 
 
==Application==
 
==Application==
Oil and Grit Separators are suitable as pre-treatment to other downstream treatment systems such as ponds or LID features.  Cost effective application of OGS for LID typically requires that the practice have a single [[inlet]] with a drainage area larger than 0.2 ha.   
+
Oil and Grit Separators are suitable as pre-treatment to other downstream treatment systems such as ponds or LID features.  Cost effective application of OGS as [[pretreatment]] to a downstream LID practice typically requires that the practice have a single [[inlet]] with a drainage area larger than 0.2 ha
 +
 
 +
OGS normally require maintenance every year to function as designed.  The cost and level of effort required to undertake the maintenance program over the full life cycle of OGS should be carefully considered when implementing this water quality treatment solution.   
  
OGS normally require maintenance every year to function as designed. The cost and level of effort required to undertake the maintenance program over the full life cycle of the practice should be carefully considered when implementing this water quality treatment solution.
+
Further guidance on how the data and information generated from verified laboratory testing of OGS technologies should be interpreted and factored into regulatory agency approvals and procurement decisions for stormwater management is provided in this publicly available specification [https://sustainabletechnologies.ca/app/uploads/2023/07/SETV-Guidance-PAS-2023-07-27-English.pdf '''Guidance on the Use and Application of Results from Verified Laboratory and Field Testing for Stormwater Manufactured Treatment Devices '''], developed by TRCA and the [https://www.scc.ca/ Standards Council of Canada] that addresses both OGS and Filtration MTDs.
  
 
==Testing and Verification==
 
==Testing and Verification==
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For OGS, the ISO 14034 verification process in Canada consists of two parts:
 
For OGS, the ISO 14034 verification process in Canada consists of two parts:
# Third party laboratory testing of MTDs in accordance with the [https://sustainabletechnologies.ca/home/urban-runoff-green-infrastructure/conventional-stormwater-management/hydrodynamic-separators/procedure-for-laboratory-testing-of-oil-grit-separators/ TRCA’s Procedure for Laboratory Testing of Oil Grit Separators] and associated bulletins, and
+
# Third party laboratory testing of MTDs in accordance with the [https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf 2023 Canadian Procedure for Laboratory Testing of Oil Grit Separators] and
 
# Third party verification of the test in accordance with the [https://etvcanada.ca/home/verify-your-technology/ ISO 14034 ETV standard].
 
# Third party verification of the test in accordance with the [https://etvcanada.ca/home/verify-your-technology/ ISO 14034 ETV standard].
The ISO 14034 verification process is currently administered by [https://etvcanada.ca/home/contact/ Globe Performance Solutions and Verify Global]. Completed ISO 14034 verification statements for OGS are posted to the [https://etvcanada.ca/home/verify-your-technology/current-verified-technologies/ website, here].
+
The ISO 14034 verification process is currently administered by [https://globeperformance.com/contact/ Globe Performance Solutions] and [https://www.verifiglobal.com/en/about-us/contact-us VerifiGlobal]. Completed ISO 14034 verification statements for OGS are posted on the former Canadian ETV website [https://etvcanada.ca/home/verify-your-technology/current-verified-technologies/ website, here].
  
Note that ISO 14034 verification is a necessary, but not sufficient condition for approval agencies using the ISO/ETV process for technology acceptance.  The technology must also be classified as an Oil Grit Separator (i.e. not include a filter) for the [https://sustainabletechnologies.ca/app/uploads/2013/06/ETV-OGS-Procedure_final_revised-June_2014.pdf Procedure for Laboratory Testing of OGS] to have been properly applied. [https://etvcanada.ca/wp-content/uploads/2022/03/ETV-Bulletin-CETV-2022-02-0001_final.pdf This ETV Bulletin] helps to provide clarification on this requirement: See table below for a list of current ISO 14034 verified OGS MTDs.
+
Note that ISO 14034 verification is a necessary, but not sufficient condition for approval agencies using the ISO/ETV process for technology acceptance.  The technology must also be classified as an Oil Grit Separator (i.e. not include a filter) for the [https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf Canadian Procedure for Laboratory Testing of OGS] to have been properly applied. [https://etvcanada.ca/wp-content/uploads/2022/03/ETV-Bulletin-CETV-2022-02-0001_final.pdf This ETV Bulletin] helps to provide clarification on this requirement: See table below for a list of current ISO 14034 verified OGS MTDs.
  
 
{|class="wikitable"
 
{|class="wikitable"
|+ List of OGS MTDs
+
|+ List of ISO 14034 verified OGS MTDs
 
|-  
 
|-  
 
!style="width: 10%;"|Verification Year (Initial)
 
!style="width: 10%;"|Verification Year (Initial)
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!style="width: 25%;"|Company Name
 
!style="width: 25%;"|Company Name
 
!style="width: 25%;"|Verification Statements
 
!style="width: 25%;"|Verification Statements
 +
|-
 +
|'''2023'''
 +
|StormSettler® Oil Grit Separator
 +
|STORMTRAP, LLC.
 +
|[https://www.verifiglobal.com/media/3drliqul/verifiglobal-verification-statement-for-stormtrap-stormsettler-ogs-signed-2023-09-13.pdf Verification Statement]
 
|-
 
|-
 
|'''2022'''
 
|'''2022'''
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|Rainwater Management LTD.
 
|Rainwater Management LTD.
 
|[https://etvcanada.ca/wp-content/uploads/2022/09/ISO-14034-ETV-Verification-Statement_RWM-DM-1200_2022-2025.pdf Verification Statement]
 
|[https://etvcanada.ca/wp-content/uploads/2022/09/ISO-14034-ETV-Verification-Statement_RWM-DM-1200_2022-2025.pdf Verification Statement]
 +
|-
 +
|'''2021'''
 +
|HydroDome® Oil-Grit Separator   
 +
|Hydroworks, LLC
 +
|[https://www.verifiglobal.com/media/ianho5mr/vg-2021-07-01-hw-hd3-final-verification-statement-re-issue-signed-2023-05-17.pdf Verification Statement]
 
|-
 
|-
 
|'''2019'''
 
|'''2019'''
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|'''2018'''
 
|'''2018'''
 
|Hydroworks® HydroStorm (HS) OGS
 
|Hydroworks® HydroStorm (HS) OGS
|HydroWorks, LLC
+
|Hydroworks, LLC
 
|[https://etvcanada.ca/wp-content/uploads/2021/05/ISO14034-VS_Hydroworks_HS_2021-2024.pdf Verification Statement]
 
|[https://etvcanada.ca/wp-content/uploads/2021/05/ISO14034-VS_Hydroworks_HS_2021-2024.pdf Verification Statement]
 
|-
 
|-
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==Performance Test Results==
 
==Performance Test Results==
The Procedure for Laboratory Testing of Oil Grit Separators provides performance testing for the following performance measures based on a standard sediment particle size distribution:
+
The [https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf Canadian Procedure for Laboratory Testing of OGS]  provides performance testing for the following performance measures based on a standard sediment particle size distribution with a median particle size of 75 microns:
# '''Sediment removal performance''':  Mass balance testing at seven surface loading rates to determine the capacity of MTDs to retain solids
+
# '''Sediment removal performance''':  Mass balance testing at a minimum of seven surface loading rates to determine the capacity of MTDs to retain suspended solids
# '''Sediment scour and re-suspension test''':  Sediment is pre-loaded into the unit and effluent concentrations are measure at five surface loading rates to determine how well the units retain captured sediment.
+
# '''Sediment scour and re-suspension test''':  Sediment is pre-loaded into the unit and effluent concentrations are measured at a minimum of five surface loading rates to determine how well the units retain captured sediment.
# '''Light liquid capture and retention test''':  An optional test in which beads with a density similar to motor oil are pre-loaded into the unit and the number of beads in the effluent are measured to assess the capacity of the unit to trap and retain light liquids.  
+
# '''Light liquid capture and retention test''':  An optional test in which beads with a density similar to motor oil are pre-loaded into the unit and the number of beads in the effluent during pre-loading and testing are measured to assess the capacity of the unit to trap and retain light liquids. <br>
 +
</Br>
 +
As of October 2023, there were nine OGS vendors with ISO 14034 verifications (as shown in the [[Oil and Grit Separator#Testing and Verification|table]] above), and 12 different OGS designs that have been verified. 
  
There are currently eight OGS vendors with ISO 14034 verifications (as shown in the [[Oil and Grit Separator#Testing and Verification|table]] above). A summary of OGS MTD test results from the verification statements is provided [https://etvcanada.ca/home/verify-your-technology/current-verified-technologies/ here]
+
* The list of manufacturers and test results (''Sediment Scour and Light Liquid Test Results, and other relevant operational parameters'') of all OGS products and other verified technologies can be downloaded here (updated as of January 2024):  <br>
 +
{{Clickable button|[[File:Iso ETV 14034 all.JPG|385px|link=https://wiki.sustainabletechnologies.ca/images/2/2d/ISO_ETV_14034_Verified_OGS_MTDs_Sediment_Scour.pdf]]}}
 +
<br>
 +
</br>
  
The list of manufacturers and test results of all OGS products and other verified technologies can be downloaded here: <br>
+
* The list of manufacturers and test results (''Sediment Removal rates'')  of all OGS products and other verified technologies can be viewed and downloaded here (updated as of January 2024): <br>
{{Clickable button|[[Media:OGS_Verification_test_results.xlsx|Download Verification Test Results spreadsheet(.xlsx)]]}}
+
{{Clickable button|[[File:OGS IS 14034 Scours.JPG|320px|link=https://wiki.sustainabletechnologies.ca/images/f/f4/OGS_IS_14034_ETV_Scour_update.pdf]]}}
 
<br>
 
<br>
 
</br>
 
</br>
  
Sediment removal performance results were relatively consistent across different MTD designs, with slightly more variation at higher surface loading rates (see Graph below). <br>
+
The verified OGS technologies can be divided into two groups based on sediment removal performance results (see group 1 and 2 in the graph below). 
'''<small>*Note:''' Oil Grit Separators do not achieve the 80% removal efficiency required for stand alone application in Ontario, even at very low flow rates.</small>
+
* '''Group 1''' includes traditional designs (n=10) with large openings and limited flow restriction.  Results for these OGS types were relatively consistent at low flows and slightly more variation at high surface loading rates.
 +
* '''Group 2''' units with debris filters, fine meshed debris screens or coalescing plates (n=2) showed higher performance (group 2). These units force water to flow through smaller orifices, which increase the risk of [[clogging]], leading to higher maintenance costs in the long run. Test plans for these units should include a scenario that evaluates system hydraulics and removal rates under a scenario where a portion of the small orifices are clogged.  If this has not been done, it would be reasonable to apply a factor of safety to verified results to account for clogging potential over the maintenance cycle. 
 +
 
 +
[[File:OGS-Protocol-Webpage-Image.jpg|thumb|420px|Performance testing of an OGS unit in St Anthony Falls Laboratory in Minnesota (Saddoris, et al. 2010)<ref>Saddoris, D.A., McIntire, K.D., Mohseni, O., and J.S. Gulliver, 2010.  Hydrodynamic Separator Sediment Retention Testing – Final Report. Minnesota Department of Transportation, St. Paul, MN.</ref>]]
 +
 
 +
In general, OGS should not be installed as stand-alone units for [[water quality]] treatment. While every effort has been made to ensure that the ISO 14034 verified lab test is an accurate representation of actual performance, there remains uncertainty about how lab results translate to the field, particularly for group 2 technologies.  Installing OGS only as [[pretreatment]] to other downstream practices helps to mitigate this uncertainty and risk because downstream stormwater treatment practices can be relied on to provide a second line of defense. 
  
 
</br>
 
</br>
[[File:OGS-Protocol-Webpage-Image.jpg|thumb|320px|In lab testing of a Stormceptor OGS device, here seen testing discharge rates and sediment effluent loads at St. Anthony Falls Laboratory, Minneapolis, Minnesota. (Saddoris, et al. 2010)<ref>Saddoris, D.A., McIntire, K.D., Mohseni, O., and J.S. Gulliver, 2010.  Hydrodynamic Separator Sediment Retention Testing – Final Report. Minnesota Department of Transportation, St. Paul, MN.</ref>]]
+
[[File:Surface loading groups 1 & 2 OGS Update.png|800px]]<br>
[[File:OGS min Max.png|900px]]<br>
 
 
</br>
 
</br>
The graph above shows the average, minimum and maximum sediment removal efficiencies for ISO 14034 verified OGS at seven surface loading rates (n = 10).
+
'''''Graph Above''''': Sediment removal efficiencies for ISO 14034 verified OGS.  <span style="color:blue">Group 1</span style="color:blue"> units (n=10) are conventional OGS with large openings.<br> 
 +
<span style="color:orange">Group 2</span style="color:orange">  units (n=2) contain additional components that filter or strain flows. Sediment removal performance results were relatively consistent across<br> 
 +
different MTD designs, with slightly more variation at higher surface loading rates<br>
 +
 
 +
'''<small>*Note:''' Oil Grit Separators do not achieve the 80% removal efficiency required for stand alone application in Ontario, even at very low flow rates.</small><br>
  
 
==Scaling==
 
==Scaling==
The ISO 14034 ETV sediment removal rate data for the tested model at specified surface loading rates may be applied to similar MTDs of smaller or larger size by proper scaling. Scaling the performance results of the tested MTD to other model sizes without completing additional testing is acceptable provided that:
+
Appropriate scaling ensures that performance results from the model tested and verified through [https://www.iso.org/obp/ui/#iso:std:iso:14034:ed-1:v1:en ISO 14034 ETV] can be confidently applied to other model sizes for the same MTD.  Buyers should ensure to ask vendors to provide sizing data and calculations to confirm that the proposed unit is scaled appropriately.  Verifications conducted in 2023 or later will include information on unit scaling in the publicly available verification statement.
# The claimed sediment removal efficiencies for the similar MTD are the same or lower than the tested MTD at identical surface loading rates; and  
+
# The similar MTD is scaled geometrically proportional to the tested unit in all inside dimensions of length and width and a minimum of 85% proportional in depth.   
+
The scaling rules, as stated in the [https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf Canadian Procedure]<ref>Toronto and Region Conservation Authority, 2023. Canadian Procedure for Laboratory Testing of Oil Grit Separators: A Publicly Available Specification, Toronto, Ontario. https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf</ref>, are as follows:
Ensuring the unit is scaled appropriately in all dimensions also helps to ensure that the recommended maintenance intervals for the unit can be achieved.  
+
 
 +
"''The sediment removal rate at the specified SLRs determined for the tested full scale, commercially available MTD may be applied to similar MTDs of smaller or larger size by proper scaling. Scaling the performance results of the tested MTD to other model sizes without completing additional testing is acceptable provided that:''
 +
# '''''The maximum treatment SLR prior to the onset of bypass for the similar MTD shall be the same or less than the tested MTD;'''''
 +
# '''''The claimed sediment removal efficiencies for the similar MTD are the same or lower than the tested MTD at identical SLRs; and'''''
 +
# '''''The similar MTD is scaled geometrically proportional to the tested unit in all inside dimensions of length and width and a minimum of 85% proportional in depth, where the depth dimension is measured from the outlet pipe invert to the floor of the unit.'''''<br>
 +
   
 +
''If requirements (1), (2) and (3) are not met, then a second full scale, commercially available MTD with a difference in maximum treatment SLR prior to the onset of bypass of at least 250% shall be tested to validate the alternative scaling methodology. Testing of the similar models shall follow the same sediment removal performance testing procedures described in section 5.0. The alternative scaling methodology is deemed to be valid if the sediment removal efficiencies do not differ by more than 2% for SLRs up to<br>
 +
''200 L min<sup>-1</sup> m<sup>-2</sup>, and 3% for SLRs greater than 200 L min<sup>-1</sup> m<sup>-2</sup>.''”
  
 
==Sizing==
 
==Sizing==
[[File:OGS Calculation Tool.PNG|thumb|450px|See a screenshot of a recent version of the ''OGS Review Calculator'' used for developers/manufacturers of new OGS MTDs to help with the submission of their devices to the International Working Group on Environmental Technology Verification (IWG-ETV) (Photo Source: City of Toronto, 2020)<ref>City of Toronto. 2020. Proposed Manufactured Treatment Devices Guidelines. Version 0.0. Accessed: https://www.toronto.ca/wp-content/uploads/2020/03/9495-Draft-for-Feedback_Proposed-MTD-Guidelines_3-Mar-20_a.pdf</ref>]]
+
[[File:OGS Calculation Tool 2024.png|thumb|450px|link=https://wiki.sustainabletechnologies.ca/images/e/e6/OGS_Review_Sheet_2024-08-14_LOCKED.xlsx|This is a screenshot of the latest version of STEP’s OGS Review Sheet Calculator.  The calculator has been developed to facilitate use of ISO 14034 ETV verified test data using a standard approach for all OGS MTD designs.]]
 +
 
 +
It is recommended that a standard sizing approach be used for all OGS units to ensure that they are evaluated based on a consistent methodology. The OGS Review Calculator provided here has been developed to facilitate application of ISO 14034 ETV test data through a standard approach applicable to all OGS MTD designs.  The Calculator is intended to be completed by municipal development review staff or their consultants to:
 +
 
 +
# ''Assess proposed OGS device sizing relative to treatment objectives;''
 +
# ''Determine whether a proposed OGS device is to be installed in-line or off-line;''
 +
# ''Verify oil and light liquid capture capabilities for proposed OGS devices;''
 +
# ''Estimate maintenance intervals, and;''
 +
# ''Check whether proposed unit model sizes that differ from the ISO 14034 verified unit are scaled appropriately (as per the scaling rules provided in the previous section).'' 
 +
 
 +
While more complex modelling methodologies may be used for sizing OGS devices, the final sizing recommendation should be consistent with or more conservative than that generated using the OGS Review Calculator, as the latter includes factors of safety and assumptions are more transparent. If less conservative sizing results from more refined modelling methods are to be accepted, a clear and concise rationale should be provided by the proponent to explain the key differences in assumptions and input parameters.<br>
 +
<br>
  
It is recommended that a standard sizing approach be used for all OGS units to ensure they are evaluated based on a consistent methodology. See a screenshot of the City of Toronto's and STEP's '''''OGS Review Calculator''''' has been developed to facilitate application of ISO 14034 ETV test data through a standard approach applicable to all OGS MTD designs. The following methods and processes are built into the tool:<br>
+
The following methods and processes are built into the tool:
 
<br>
 
<br>
'''Rational Method''' used as a basis for flow calculations:<br>
+
<br>
<math>Q = CiA</math>
+
{{Clickable button|[[File:Cover OGS review sheet.PNG|320 px|link=https://wiki.sustainabletechnologies.ca/images/e/e6/OGS_Review_Sheet_2024-08-14_LOCKED.xlsx]]}}
**<math>C</math> is the site runoff coefficient,
+
<br>
**<math>i</math> is the rainfall intensity, and;
+
<br>
**<math>A</math> is the drainage area)
+
*'''Rational Method''' used as a basis for flow calculations:<br>
 +
<math>Q=CiA</math>
 +
''{{Plainlist|1=Where:
 +
**''Q'' = Peak Discharge _m<sup>3</sup>/s
 +
**''C'' = Runoff coefficient (unitless)<ref>
 +
**''i'' = Rainfall Intensity (mm/hr)
 +
**''A'' = Drainage Area (m<sup>2</sup>)}}''
 
* Target treatment is based on capture and treatment of the average annual runoff volume for the site using ISO 14034 verified sediment removal test results for 7 surface loading rates
 
* Target treatment is based on capture and treatment of the average annual runoff volume for the site using ISO 14034 verified sediment removal test results for 7 surface loading rates
 
* Linear interpolation is used to calculate sediment removal efficiencies between the ISO/ETV tested surface loading rates
 
* Linear interpolation is used to calculate sediment removal efficiencies between the ISO/ETV tested surface loading rates
 
* Surface loading rates below the lowest ISO/ETV tested surface loading rate are assigned a sediment removal efficiency equal to that of the lowest tested rate
 
* Surface loading rates below the lowest ISO/ETV tested surface loading rate are assigned a sediment removal efficiency equal to that of the lowest tested rate
 
* Hourly historical rainfall data greater than 1mm for the April to October period are used to generate the rainfall intensity frequency distribution curves.
 
* Hourly historical rainfall data greater than 1mm for the April to October period are used to generate the rainfall intensity frequency distribution curves.
* Capacity to add historical rainfall record is provided in order to generate the relationship between hourly rainfall intensities vs average annual rainfall volume for the meteorological station of choice.
+
* Users may input their own rainfall intensity frequency distribution curve data for meteorological stations not provided in the tool.
  
 
===Associated Documents Submitted with OGS Review Calculator===
 
===Associated Documents Submitted with OGS Review Calculator===
Line 123: Line 172:
 
* Manufacturer-provided letter/documentation confirming proposed and tested MTD model details (i.e., diameter, depth, treatment depth, max storage depth, sediment storage capacity, hydraulic capacity for bypass), and compliance with sizing and scaling provisions, as per the OGS Procedure scaling provisions
 
* Manufacturer-provided letter/documentation confirming proposed and tested MTD model details (i.e., diameter, depth, treatment depth, max storage depth, sediment storage capacity, hydraulic capacity for bypass), and compliance with sizing and scaling provisions, as per the OGS Procedure scaling provisions
 
* Operations and Maintenance Manual indicating the inspection and maintenance frequencies, methods of maintenance, health and safety considerations and other relevant information.
 
* Operations and Maintenance Manual indicating the inspection and maintenance frequencies, methods of maintenance, health and safety considerations and other relevant information.
 +
 +
====Units tested and ISO 14034 verified using the Procedure for Laboratory Testing of OGS or a modified version of the Procedure include:====
 +
*[https://etvcanada.ca/wp-content/uploads/2022/03/ISO-14034-ETV-VS-ENVIROBASIN_2021-2024.pdf  EnviroPod International Ltd, EnviroBasin]
 +
*[https://etvcanada.ca/wp-content/uploads/2019/10/ISO-14034-ETV-Verification-Renewal-CB-Shield_2019-2022.pdf CB Shield Inc., CB Shield]
  
 
==ISO 14034 verified OGS vendor websites==
 
==ISO 14034 verified OGS vendor websites==
 +
#[https://www.verifiglobal.com/media/3drliqul/verifiglobal-verification-statement-for-stormtrap-stormsettler-ogs-signed-2023-09-13.pdf '''StormSettler® Oil Grit Separator''' - Developed by: StormTrap LLC.]
 
#[http://m.rainwatermanagement.ca/ '''RWM-DM-1200 & DM-1200-OS Stormwater Systems''' - Developed by: Rainwater Management LTD.]
 
#[http://m.rainwatermanagement.ca/ '''RWM-DM-1200 & DM-1200-OS Stormwater Systems''' - Developed by: Rainwater Management LTD.]
 
#[https://hydro-int.com/en/products/downstream-defender '''Hydro International Downstream Defender® OGS''' - Developed by: Hydro International.]
 
#[https://hydro-int.com/en/products/downstream-defender '''Hydro International Downstream Defender® OGS''' - Developed by: Hydro International.]
 
#[https://www.conteches.com/sciclonex '''SciCLONE™ Hydrodynamic Separator''' - Developed by: Bio Clean Environmental Inc. (A Forterra Company).]
 
#[https://www.conteches.com/sciclonex '''SciCLONE™ Hydrodynamic Separator''' - Developed by: Bio Clean Environmental Inc. (A Forterra Company).]
 
#[https://hydro-int.com/en/products/first-defense '''Hydro International First Defense® OGS''' - Developed by: Hydro International]
 
#[https://hydro-int.com/en/products/first-defense '''Hydro International First Defense® OGS''' - Developed by: Hydro International]
#[https://hydroworks.com/hydrostorm.html '''Hydroworks® HydroStorm (HS) OGS''' - Developed by HydroWorks LLC.]
+
#[https://hydroworks.com/hydrostorm.html '''Hydroworks® HydroStorm (HS) OGS''' - Developed by Hydroworks LLC.]
 
#[https://www.imbriumsystems.com/stormwater-treatment-solutions/stormceptor-ef '''Stormceptor® EF and EFO Oil-Grit Separators''' - Developed by: Imbrium Systems, Inc.]
 
#[https://www.imbriumsystems.com/stormwater-treatment-solutions/stormceptor-ef '''Stormceptor® EF and EFO Oil-Grit Separators''' - Developed by: Imbrium Systems, Inc.]
 
#[https://www.conteches.com/stormwater-management/treatment/cds '''CDS Hydrodynamic Separator®''' - Developed by: CONTECH Engineered Solutions LLC]
 
#[https://www.conteches.com/stormwater-management/treatment/cds '''CDS Hydrodynamic Separator®''' - Developed by: CONTECH Engineered Solutions LLC]

Latest revision as of 14:17, 26 August 2024

Plan view cut out of a typical Oil-Grit Separator (OGS) pretreatment device. In this example, the cylinder chamber and weirs create a "vortex swirling effect", which promotes settling of solids in the bottom of the chamber. In most OGS, there is also an oil storage chamber to capture light liquids and floatables. The accumulated sediment and debris is cleaned out regularly by maintenance professionals once the sediment in the chamber reaches the manufacturer’s recommended sediment maintenance depth or the floatables capture chamber is full.

Overview[edit]

Oil and Grit Separators (OGS) are Manufactured Treatment Devices (MTDs) used for water quality treatment of stormwater runoff through the removal of large particle suspended solids and associated pollutants, and debris. Some devices can also trap light liquids such as oil and other floatables. These MTDs are typically installed underground within the stormwater sewer system in an on-line or off-line configuration. They are distinguished from Filtration Manufactured Treatment Devices by their removal of solids through settling rather than filtration.

Application[edit]

Oil and Grit Separators are suitable as pre-treatment to other downstream treatment systems such as ponds or LID features. Cost effective application of OGS as pretreatment to a downstream LID practice typically requires that the practice have a single inlet with a drainage area larger than 0.2 ha.

OGS normally require maintenance every year to function as designed. The cost and level of effort required to undertake the maintenance program over the full life cycle of OGS should be carefully considered when implementing this water quality treatment solution.

Further guidance on how the data and information generated from verified laboratory testing of OGS technologies should be interpreted and factored into regulatory agency approvals and procurement decisions for stormwater management is provided in this publicly available specification Guidance on the Use and Application of Results from Verified Laboratory and Field Testing for Stormwater Manufactured Treatment Devices , developed by TRCA and the Standards Council of Canada that addresses both OGS and Filtration MTDs.

Testing and Verification[edit]

Several agencies across Canada require ISO 14034 Environmental Technology Verification (ETV) as a condition of technology acceptance.
(Note: when visiting the above link click on the "Other" tab on the page to view Specific Testing Protocols for OGS).

For OGS, the ISO 14034 verification process in Canada consists of two parts:

  1. Third party laboratory testing of MTDs in accordance with the 2023 Canadian Procedure for Laboratory Testing of Oil Grit Separators and
  2. Third party verification of the test in accordance with the ISO 14034 ETV standard.

The ISO 14034 verification process is currently administered by Globe Performance Solutions and VerifiGlobal. Completed ISO 14034 verification statements for OGS are posted on the former Canadian ETV website website, here.

Note that ISO 14034 verification is a necessary, but not sufficient condition for approval agencies using the ISO/ETV process for technology acceptance. The technology must also be classified as an Oil Grit Separator (i.e. not include a filter) for the Canadian Procedure for Laboratory Testing of OGS to have been properly applied. This ETV Bulletin helps to provide clarification on this requirement: See table below for a list of current ISO 14034 verified OGS MTDs.

List of ISO 14034 verified OGS MTDs
Verification Year (Initial) Technology Name Company Name Verification Statements
2023 StormSettler® Oil Grit Separator STORMTRAP, LLC. Verification Statement
2022 RWM-DM-1200 & DM-1200-OS Stormwater Systems Rainwater Management LTD. Verification Statement
2021 HydroDome® Oil-Grit Separator Hydroworks, LLC Verification Statement
2019 Hydro International Downstream Defender® OGS Hydro International Verification Statement
2019 SciCLONE™ Hydrodynamic Separator Bio Clean Environmental Inc. (A Forterra Company) Verification Statement
2018 Hydro International First Defense® OGS Hydro International Verification Statement
2018 Hydroworks® HydroStorm (HS) OGS Hydroworks, LLC Verification Statement
2017 Stormceptor® EF and EFO Oil-Grit Separators Imbrium Systems, Inc., Verification Statement
2017 CDS Hydrodynamic Separator® CONTECH Engineered Solutions LLC Verification Statement
2016 SDD3 Oil Grit Separator® Next Stormwater Solutions (8091200 Canada Inc.) Verification Statement

Performance Test Results[edit]

The Canadian Procedure for Laboratory Testing of OGS provides performance testing for the following performance measures based on a standard sediment particle size distribution with a median particle size of 75 microns:

  1. Sediment removal performance: Mass balance testing at a minimum of seven surface loading rates to determine the capacity of MTDs to retain suspended solids
  2. Sediment scour and re-suspension test: Sediment is pre-loaded into the unit and effluent concentrations are measured at a minimum of five surface loading rates to determine how well the units retain captured sediment.
  3. Light liquid capture and retention test: An optional test in which beads with a density similar to motor oil are pre-loaded into the unit and the number of beads in the effluent during pre-loading and testing are measured to assess the capacity of the unit to trap and retain light liquids.


As of October 2023, there were nine OGS vendors with ISO 14034 verifications (as shown in the table above), and 12 different OGS designs that have been verified.

  • The list of manufacturers and test results (Sediment Scour and Light Liquid Test Results, and other relevant operational parameters) of all OGS products and other verified technologies can be downloaded here (updated as of January 2024):

Iso ETV 14034 all.JPG

  • The list of manufacturers and test results (Sediment Removal rates) of all OGS products and other verified technologies can be viewed and downloaded here (updated as of January 2024):

OGS IS 14034 Scours.JPG

The verified OGS technologies can be divided into two groups based on sediment removal performance results (see group 1 and 2 in the graph below).

  • Group 1 includes traditional designs (n=10) with large openings and limited flow restriction. Results for these OGS types were relatively consistent at low flows and slightly more variation at high surface loading rates.
  • Group 2 units with debris filters, fine meshed debris screens or coalescing plates (n=2) showed higher performance (group 2). These units force water to flow through smaller orifices, which increase the risk of clogging, leading to higher maintenance costs in the long run. Test plans for these units should include a scenario that evaluates system hydraulics and removal rates under a scenario where a portion of the small orifices are clogged. If this has not been done, it would be reasonable to apply a factor of safety to verified results to account for clogging potential over the maintenance cycle.
Performance testing of an OGS unit in St Anthony Falls Laboratory in Minnesota (Saddoris, et al. 2010)[1]

In general, OGS should not be installed as stand-alone units for water quality treatment. While every effort has been made to ensure that the ISO 14034 verified lab test is an accurate representation of actual performance, there remains uncertainty about how lab results translate to the field, particularly for group 2 technologies. Installing OGS only as pretreatment to other downstream practices helps to mitigate this uncertainty and risk because downstream stormwater treatment practices can be relied on to provide a second line of defense.


Surface loading groups 1 & 2 OGS Update.png

Graph Above: Sediment removal efficiencies for ISO 14034 verified OGS. Group 1 units (n=10) are conventional OGS with large openings.
Group 2 units (n=2) contain additional components that filter or strain flows. Sediment removal performance results were relatively consistent across
different MTD designs, with slightly more variation at higher surface loading rates

*Note: Oil Grit Separators do not achieve the 80% removal efficiency required for stand alone application in Ontario, even at very low flow rates.

Scaling[edit]

Appropriate scaling ensures that performance results from the model tested and verified through ISO 14034 ETV can be confidently applied to other model sizes for the same MTD. Buyers should ensure to ask vendors to provide sizing data and calculations to confirm that the proposed unit is scaled appropriately. Verifications conducted in 2023 or later will include information on unit scaling in the publicly available verification statement.

The scaling rules, as stated in the Canadian Procedure[2], are as follows:

"The sediment removal rate at the specified SLRs determined for the tested full scale, commercially available MTD may be applied to similar MTDs of smaller or larger size by proper scaling. Scaling the performance results of the tested MTD to other model sizes without completing additional testing is acceptable provided that:

  1. The maximum treatment SLR prior to the onset of bypass for the similar MTD shall be the same or less than the tested MTD;
  2. The claimed sediment removal efficiencies for the similar MTD are the same or lower than the tested MTD at identical SLRs; and
  3. The similar MTD is scaled geometrically proportional to the tested unit in all inside dimensions of length and width and a minimum of 85% proportional in depth, where the depth dimension is measured from the outlet pipe invert to the floor of the unit.

If requirements (1), (2) and (3) are not met, then a second full scale, commercially available MTD with a difference in maximum treatment SLR prior to the onset of bypass of at least 250% shall be tested to validate the alternative scaling methodology. Testing of the similar models shall follow the same sediment removal performance testing procedures described in section 5.0. The alternative scaling methodology is deemed to be valid if the sediment removal efficiencies do not differ by more than 2% for SLRs up to
200 L min-1 m-2, and 3% for SLRs greater than 200 L min-1 m-2.

Sizing[edit]

This is a screenshot of the latest version of STEP’s OGS Review Sheet Calculator. The calculator has been developed to facilitate use of ISO 14034 ETV verified test data using a standard approach for all OGS MTD designs.

It is recommended that a standard sizing approach be used for all OGS units to ensure that they are evaluated based on a consistent methodology. The OGS Review Calculator provided here has been developed to facilitate application of ISO 14034 ETV test data through a standard approach applicable to all OGS MTD designs. The Calculator is intended to be completed by municipal development review staff or their consultants to:

  1. Assess proposed OGS device sizing relative to treatment objectives;
  2. Determine whether a proposed OGS device is to be installed in-line or off-line;
  3. Verify oil and light liquid capture capabilities for proposed OGS devices;
  4. Estimate maintenance intervals, and;
  5. Check whether proposed unit model sizes that differ from the ISO 14034 verified unit are scaled appropriately (as per the scaling rules provided in the previous section).

While more complex modelling methodologies may be used for sizing OGS devices, the final sizing recommendation should be consistent with or more conservative than that generated using the OGS Review Calculator, as the latter includes factors of safety and assumptions are more transparent. If less conservative sizing results from more refined modelling methods are to be accepted, a clear and concise rationale should be provided by the proponent to explain the key differences in assumptions and input parameters.

The following methods and processes are built into the tool:

Cover OGS review sheet.PNG

  • Rational Method used as a basis for flow calculations:

Where:

    • Q = Peak Discharge _m3/s
    • C = Runoff coefficient (unitless)<ref>
    • i = Rainfall Intensity (mm/hr)
    • A = Drainage Area (m2)

  • Target treatment is based on capture and treatment of the average annual runoff volume for the site using ISO 14034 verified sediment removal test results for 7 surface loading rates
  • Linear interpolation is used to calculate sediment removal efficiencies between the ISO/ETV tested surface loading rates
  • Surface loading rates below the lowest ISO/ETV tested surface loading rate are assigned a sediment removal efficiency equal to that of the lowest tested rate
  • Hourly historical rainfall data greater than 1mm for the April to October period are used to generate the rainfall intensity frequency distribution curves.
  • Users may input their own rainfall intensity frequency distribution curve data for meteorological stations not provided in the tool.

Associated Documents Submitted with OGS Review Calculator[edit]

Other documents typically submitted with the OGS Review Calculator would include:

  • Signed Stormwater Management (SWM) Report, engineering drawings, and specifications by the design engineer (Professional Engineer in Ontario) on behalf of their respective clients/owners
  • Applicable third-party testing and verification/certification statements and documentation supporting performance claims
  • Manufacturer-provided letter/documentation confirming proposed and tested MTD model details (i.e., diameter, depth, treatment depth, max storage depth, sediment storage capacity, hydraulic capacity for bypass), and compliance with sizing and scaling provisions, as per the OGS Procedure scaling provisions
  • Operations and Maintenance Manual indicating the inspection and maintenance frequencies, methods of maintenance, health and safety considerations and other relevant information.

Units tested and ISO 14034 verified using the Procedure for Laboratory Testing of OGS or a modified version of the Procedure include:[edit]

ISO 14034 verified OGS vendor websites[edit]

  1. StormSettler® Oil Grit Separator - Developed by: StormTrap LLC.
  2. RWM-DM-1200 & DM-1200-OS Stormwater Systems - Developed by: Rainwater Management LTD.
  3. Hydro International Downstream Defender® OGS - Developed by: Hydro International.
  4. SciCLONE™ Hydrodynamic Separator - Developed by: Bio Clean Environmental Inc. (A Forterra Company).
  5. Hydro International First Defense® OGS - Developed by: Hydro International
  6. Hydroworks® HydroStorm (HS) OGS - Developed by Hydroworks LLC.
  7. Stormceptor® EF and EFO Oil-Grit Separators - Developed by: Imbrium Systems, Inc.
  8. CDS Hydrodynamic Separator® - Developed by: CONTECH Engineered Solutions LLC
  9. SDD3 Oil Grit Separator® - Developed by: Next Stormwater Solutions (8091200 Canada Inc.)

Disclaimer[edit]

In our effort to make this guide as functional as possible, we have decided to include proprietary systems and links to manufacturers websites. Inclusion of such links does not constitute endorsement by the Sustainable Technologies Evaluation Program. Lists are ordered alphabetically; link updates are welcomed using the form below.

References[edit]

  1. Saddoris, D.A., McIntire, K.D., Mohseni, O., and J.S. Gulliver, 2010. Hydrodynamic Separator Sediment Retention Testing – Final Report. Minnesota Department of Transportation, St. Paul, MN.
  2. Toronto and Region Conservation Authority, 2023. Canadian Procedure for Laboratory Testing of Oil Grit Separators: A Publicly Available Specification, Toronto, Ontario. https://sustainabletechnologies.ca/app/uploads/2023/06/SETV-OGS-PAS-2023-06-01-English-1.pdf