Difference between revisions of "Inlet sumps: Gallery"

From LID SWM Planning and Design Guide
Jump to navigation Jump to search
 
(One intermediate revision by the same user not shown)
Line 1: Line 1:
 
<gallery mode="packed" widths=300px heights=300px>
 
<gallery mode="packed" widths=300px heights=300px>
Inlet - clogged - Elm Drive.JPG| A clogged inlet at the bioretention facility on Elm Drive in Mississauga in need of maintenance.  
+
File:SNOUT Myrtle Beach SC.jpg|This [[pretreatment]] device, known as a baffle helps to remove trash, oil, TSS, larger sediments (silts, sands, etc.) and other floatables in roadway catch basins. This picture was taken of a SNOUT BAFL in Myrtle Beach, S.C. (Mullen, 2022)<ref>Mullen, T.J. Prioritizing trash capture and clean oceans: Stormwater hoods and traps lead the way in effectiveness. The Municipal magazine. June 1, 2022. Accessed: https://www.themunicipal.com/2022/06/prioritizing-trash-capture-and-clean-oceans-stormwater-hoods-and-traps-lead-the-way-in-effectiveness/</ref>
 +
File:Rain guardian turret.JPG|Example of an overland flow sump, capturing stormwater runoff from the adjacent roadway. This example showcases a Rain Guardian<sup>(TM)</sup> Turret structure with a metal grate overtop to capture larger floatables, trash and detritus from entering a stormwater facility or in this case a [[bioretention]] LID feature<ref>Erickson, A.J. and Hernick, M.A., 2019. Capture of Gross Solids and Sediment by Pretreatment Practices for Bioretention. Accessed: https://conservancy.umn.edu/handle/11299/201607</ref>.  
 
Inlet Miss rd.jpg|This [[inlet]] channels flow from an underground pretreatment unit onto the surface of a large [[bioswale]], Mississauga Road, ON
 
Inlet Miss rd.jpg|This [[inlet]] channels flow from an underground pretreatment unit onto the surface of a large [[bioswale]], Mississauga Road, ON
Elm Drive Inlet.jpg|This [[bioretention]] facility is sunken from it's surrounding landscape, in part to accommodate the drop from the catchbasin inlet. Elm Drive, Mississauga, ON
 
 
Tree-trench+section+c-02.jpg|400px|A [[stormwater tree trench]], including a sump inlet design used as part of [[pretreatment]]. The feature is located in the City of Cambridge, Massachusetts, US. The design was developed and lead by HDR Inc., and Halvorson, Tighe & Bond Studio (Halvorson, Tighe & Bond Studio, n.d.)<ref>Halvorson, Tighe & Bond Studio. n.d. Halvorson, Tighe & Bond Studio. Retrieved from: https://www.halvorsondesign.com/willard-street-drainage</ref>
 
Tree-trench+section+c-02.jpg|400px|A [[stormwater tree trench]], including a sump inlet design used as part of [[pretreatment]]. The feature is located in the City of Cambridge, Massachusetts, US. The design was developed and lead by HDR Inc., and Halvorson, Tighe & Bond Studio (Halvorson, Tighe & Bond Studio, n.d.)<ref>Halvorson, Tighe & Bond Studio. n.d. Halvorson, Tighe & Bond Studio. Retrieved from: https://www.halvorsondesign.com/willard-street-drainage</ref>
 
Phila gov sump bio.png|Example of a sump inlet being used in conjunction with a large [[bioretention]] basin feature, located in park space receiving stormwater off of the adjacent roadway (Source: Philadelphia Water Department, n.d.)<ref>Philadelphia Water Department. n.d. Chapter 4 Stormwater Management Practice Guidance 4.1 Bioinfiltration/Bioretention. Retrieved from: https://water.phila.gov/development/stormwater-plan-review/manual/chapter-4/4-1-bioinfiltration-bioretention/</ref>
 
Phila gov sump bio.png|Example of a sump inlet being used in conjunction with a large [[bioretention]] basin feature, located in park space receiving stormwater off of the adjacent roadway (Source: Philadelphia Water Department, n.d.)<ref>Philadelphia Water Department. n.d. Chapter 4 Stormwater Management Practice Guidance 4.1 Bioinfiltration/Bioretention. Retrieved from: https://water.phila.gov/development/stormwater-plan-review/manual/chapter-4/4-1-bioinfiltration-bioretention/</ref>
 
Nacto Sumpinlet bio.jpg| An inlet sump leading into a bioretention bump out for traffic calming. Inlet sumps help both settle and separate sediment from stormwater road runoff before depositing excess sediment and silt into an infiltration BMP. These sumps allow stormwater to flow into the feature through an [[underdrain]] pipe (Source: NACTO, 2017)<ref>National Association of City Transportation Officials (NACTO). 2017. Urban Street Stormwater Guide - Inlet Design. Retrieved from: https://nacto.org/publication/urban-street-stormwater-guide/stormwater-elements/bioretention-design-considerations/inlet-design/</ref>
 
Nacto Sumpinlet bio.jpg| An inlet sump leading into a bioretention bump out for traffic calming. Inlet sumps help both settle and separate sediment from stormwater road runoff before depositing excess sediment and silt into an infiltration BMP. These sumps allow stormwater to flow into the feature through an [[underdrain]] pipe (Source: NACTO, 2017)<ref>National Association of City Transportation Officials (NACTO). 2017. Urban Street Stormwater Guide - Inlet Design. Retrieved from: https://nacto.org/publication/urban-street-stormwater-guide/stormwater-elements/bioretention-design-considerations/inlet-design/</ref>
 
File:Sump inelt to chamber system.JPG| Example of a sump inlet allowing sediment to settle out of influent stormwater before entering a large [[infiltration chamber]] housed under the parking lot (Source: Philadelphia Water Department. 2020)<ref>Philadelphia Water Department. 2020. Stormwater Management Guidance Manual: Version 3.2. Accessed from: https://www.pwdplanreview.org/upload/manual_pdfs/PWD-SMGM-v3.2-20201001.pdf</ref>
 
File:Sump inelt to chamber system.JPG| Example of a sump inlet allowing sediment to settle out of influent stormwater before entering a large [[infiltration chamber]] housed under the parking lot (Source: Philadelphia Water Department. 2020)<ref>Philadelphia Water Department. 2020. Stormwater Management Guidance Manual: Version 3.2. Accessed from: https://www.pwdplanreview.org/upload/manual_pdfs/PWD-SMGM-v3.2-20201001.pdf</ref>
 +
File:Bioretention inlet.JPG| Example of a proprietary inlet device known as a [https://rainguardian.biz/project-planing/chamber-selection Rain Guardian Bunker], that was installed at the [https://www.deeproot.com/case-studies/silva-cell/morningside-avenue-in-toronto-utilizes-low-impact-development-in-pedestrian-friendly-project/ Morningside Extension Project] in Scarborough, ON.
 
</gallery>
 
</gallery>

Latest revision as of 15:54, 12 February 2024

  1. Mullen, T.J. Prioritizing trash capture and clean oceans: Stormwater hoods and traps lead the way in effectiveness. The Municipal magazine. June 1, 2022. Accessed: https://www.themunicipal.com/2022/06/prioritizing-trash-capture-and-clean-oceans-stormwater-hoods-and-traps-lead-the-way-in-effectiveness/
  2. Erickson, A.J. and Hernick, M.A., 2019. Capture of Gross Solids and Sediment by Pretreatment Practices for Bioretention. Accessed: https://conservancy.umn.edu/handle/11299/201607
  3. Halvorson, Tighe & Bond Studio. n.d. Halvorson, Tighe & Bond Studio. Retrieved from: https://www.halvorsondesign.com/willard-street-drainage
  4. Philadelphia Water Department. n.d. Chapter 4 Stormwater Management Practice Guidance 4.1 Bioinfiltration/Bioretention. Retrieved from: https://water.phila.gov/development/stormwater-plan-review/manual/chapter-4/4-1-bioinfiltration-bioretention/
  5. National Association of City Transportation Officials (NACTO). 2017. Urban Street Stormwater Guide - Inlet Design. Retrieved from: https://nacto.org/publication/urban-street-stormwater-guide/stormwater-elements/bioretention-design-considerations/inlet-design/
  6. Philadelphia Water Department. 2020. Stormwater Management Guidance Manual: Version 3.2. Accessed from: https://www.pwdplanreview.org/upload/manual_pdfs/PWD-SMGM-v3.2-20201001.pdf