Storm Drain

A storm drain, storm sewer (U.S.), stormwater drain (Australia and New Zealand) or drainage well system (UK) or simply a drain or drain system is designed to drain excess rain and ground water from paved streets, parking lots, sidewalks, and roofs.

http://upload.wikimedia.org/wikipedia/commons/thumb/0/09/Storm_Drain.JPG/220px-Storm_Drain.JPG

Storm drain in action     

Storm drains vary in design from small residential dry wells to large municipal systems. They are fed by street gutters on most motorways, freeways and other busy roads, as well as towns in areas which experience heavy rainfall, flooding and coastal towns which experience regular storms.

 http://upload.wikimedia.org/wikipedia/commons/thumb/0/03/Kutn%C3%A1_hora_cobblestones5.jpg/220px-Kutn%C3%A1_hora_cobblestones5.jpg

Old storm drain in Kutná Hora

Content Table

Function

Inlet

http://upload.wikimedia.org/wikipedia/en/thumb/4/46/Storm_Drain_Dryden.JPG/220px-Storm_Drain_Dryden.JPG  Full view of a storm drain.

There are two main types of stormwater drain (sewer) inlets; side inlets and grated inlets. Side inlets are located adjacent to the kerb (curb) and rely on the ability of the opening under the backstone or lintel to capture flow. They are usually depressed at the invert of the channel to improve capture capacity.[1] Grated inlets have gratings or grids to prevent large objects and debris from falling into the sewer system. However, their bars are fairly widely spaced so that the flow of water is not impeded. Consequently, many small objects can fall through.

Many of these small objects are caught by the catchbasin, or sump, which lies immediately below the grating. Water from the top of the catchbasin drains into the sewer proper. The catchbasin serves much the same function as the "trap" in household wastewater plumbing in trapping objects.

In the United States, unlike the trap, the catchbasin does not necessarily prevent sewer gases such as hydrogen sulfide and methane from escaping. However in the United Kingdom, where they are called gulley-pots, they are designed as true water-filled traps and do block the egress of gases and rodents.

Most catchbasins will contain stagnant water during the drier parts of the year and can be used by mosquitoes for breeding. The performance of catchbasins at removing sediment and other pollutants depends on the design of the catchbasin (e.g., the size of the sump), and routine maintenance to retain the storage available in the sump to capture sediment. Municipalities typically have large vacuum trucks that perform this task.

Catchbasins act as pretreatment for other treatment practices, such as retention basins, by capturing large sediments.

Piping

Pipes can come in many different shapes (rectangular, square, bread loaf shaped, oval and, more commonly, circular) and have many different features (including waterfalls, stairways, balconies and pits for catching rubbish or Gross Pollutant Traps (GPTs). Several different materials can also be used, such as brick, concrete, metal and even plastic in some cases.

Outlet

Most drains have a single large exit at their point of discharge (often covered by a grating) into a canal, river, lake, reservoir, sea or ocean. Other than catchbasins, typically there are no treatment facilities in the piping system. Small storm drains may discharge into individual dry wells. Storm drains may be interconnected using slotted pipe, to make a larger dry well system. Storm drains may discharge into man-made excavations known as recharge basins or retention ponds.

Environmental impacts

Water quality

Main article: Urban runoffThe first flush from urban runoff can be extremely dirty. Storm water may become contaminated while running down the road or other impervious surface, or from lawn chemical run-off, before entering the sewer.

Water running off these impervious surfaces tends to pick up gasoline, motor oil, heavy metals, trash and other pollutants from roadways and parking lots, as well as fertilizers and pesticides from lawns. Roads and parking lots are major sources of nickel, copper, zinc, cadmium, lead and polycyclic aromatic hydrocarbons (PAHs), which are created as combustion byproducts of gasoline and other fossil fuels. Roof runoff contributes high levels of synthetic organic compounds and zinc (from galvanized gutters). Fertilizer use on residential lawns, parks and golf courses is a significant source of nitrates and phosphorus.[2][3]

Reducing stormwater flows

Runoff into storm sewers can be minimized by including sustainable urban drainage systems (UK term) or low impact development practices (U.S. term) into municipal plans. To reduce stormwater from rooftops, flows from eaves troughs (rain gutters and downspouts) may be infiltrated into adjacent soil, rather than discharged into the storm sewer system. Storm water runoff from paved surfaces can be directed to unlined ditches (sometimes called swales or bioswales) before flowing into the storm sewers, again to allow the runoff to soak into the ground. Permeable paving materials can be used in building sidewalks, driveways and in some cases, parking lots, to infiltrate a portion of the stormwater volume.[4]

Relationship to sanitary sewer systems

Storm drains are often operated independently from sanitary sewer systems. The separation of storm sewers from sanitary sewers helps to prevent sewage treatment plants becoming overwhelmed by the huge influx of water during a rainstorm, which can result in untreated sewage being discharged into the environment.

Many storm drainage systems are designed to drain the storm water, untreated, into rivers or streams. Special care must be taken to ensure the citizenry is aware of this, lest waste be dumped into the storm drain system. In the city of Cleveland, Ohio, for example, all new catch basins installed have inscriptions on them not to dump any waste, and usually include a fish imprint as well. Trout Unlimited Canada recommends[5] that a yellow fish symbol be painted next to existing storm drains.

http://upload.wikimedia.org/wikipedia/commons/thumb/7/7c/Storm_Drain_Label_EPA.jpg/120px-Storm_Drain_Label_EPA.jpg  http://upload.wikimedia.org/wikipedia/commons/thumb/8/84/BosHarbor_DrainWan.jpg/130px-BosHarbor_DrainWan.jpg

Sign alerting to avoid dumping waste into storm drains  

Combined sewers

Main article: Combined sewerCities that installed their sewage collection systems before the 1930s typically used single piping systems to transport both urban runoff and sewage. This type of collection system is referred to as a combined sewer system or a CSS. The cities' rationale when these systems were built was that it would be cheaper to build just a single system.[6] In these systems a sudden large rainfall that exceeds sewage treatment capacity will be allowed to overflow directly from the storm drains into receiving waters via structures called combined sewer overflows.[7]

New York City, Washington, D.C., Seattle and other cities with combined systems have this problem due to a large influx of storm water after every heavy rain. Some cities have dealt with this by adding large storage tanks or ponds to hold the water until it can be treated. Chicago has a system of tunnels, collectively called the Deep Tunnel, underneath the city for storing its stormwater.[8]

Separation of undesired runoff can be done within the storm sewer system, but such devices are new to the market and can only be installed with new development or during major upgrades. They are referred to as oil-grit separators (OGS) or oil-sediment separators (OSS). They consist of a specialized manhole chamber, and use the water flow and/or gravity to separate oil and grit.

Local building codes

Building codes and local government ordinances vary greatly on the handling of storm drain runoff. New developments might be required to construct their own storm drain processing capacity for returning the runoff to the water table and bioswales may be required in sensitive ecological areas to protect the watershed.

In the United States, cities, suburban communities and towns with over 10,000 population are required to obtain discharge permits for their storm sewer systems, under the Clean Water Act.[9] The Environmental Protection Agency (EPA) issued stormwater regulations for large cities in 1990 and for other communities in 1999.[10] The permits require local governments to operate stormwater management programs, covering both construction of new buildings and facilities, and maintenance of their existing municipal drainage networks. Many municipalities have revised their local ordinances covering management of runoff. State government facilities, such as roads and highways, are also subject to the stormwater management regulations.[11]

Exploration

An international subculture has grown up around the exploration of stormwater drains. Societies such as the Cave Clan regularly explore the drains underneath cities. This is commonly known as 'urban exploration', but is also known as 'draining' when in specific relation to storm drains.

Ancient history

http://upload.wikimedia.org/wikipedia/commons/thumb/8/87/Ostia_Antica_Gully_Hole.jpg/220px-Ostia_Antica_Gully_Hole.jpg  

Ancient Roman gully hole in Ostia Antica in Italy.

Archaeological studies have revealed use of rather sophisticated stormwater runoff systems in ancient cultures. For example, in Minoan Crete approximately 4000 years before present, cities such as Phaistos were designed to have storm drains and channels to collect precipitation runoff. At Cretan Knossos storm drains include stone lined structures large enough for a person to crawl through.[12] Other examples of early civilizations with elements of stormwater drain systems include early people of Mainland Orkney such as Gurness and the Brough of Birsay in Scotland.

Related Articles

References

  1. ^ Kerb Inlet, Local Government & Municipal Knowledge Base, accessed February 6 2010
  2. ^ Water Environment Federation, Alexandria, VA; and American Society of Civil Engineers, Reston, VA. "Urban Runoff Quality Management." WEF Manual of Practice No. 23; ASCE Manual and Report on Engineering Practice No. 87. 1998. ISBN 1-57278-039-8. Chapter 1.
  3. ^ G. Allen Burton, Jr., Robert Pitt (2001). Stormwater Effects Handbook: A Toolbox for Watershed Managers, Scientists, and Engineers. New York: CRC/Lewis Publishers. ISBN 0-87371-924-7. http://unix.eng.ua.edu/~rpitt/Publications/BooksandReports/Stormwater%20Effects%20Handbook%20by%20%20Burton%20and%20Pitt%20book/MainEDFS_Book.html.  Chapter 2.
  4. ^ Brattebo, B. O., and D. B. Booth. 2003. "Long-Term Stormwater Quantity and Quality Performance of Permeable Pavement Systems." Water Research. 37: 4369-4376. doi:10.1016/S0043-1354(03)00410-X
  5. ^ http://www.yellowfishroad.org/about.html
  6. ^ Burrian, Steven J., et al. (1999)."The Historical Development of Wet-Weather Flow Management." U.S. Environmental Protection Agency (EPA), National Risk Management Research Laboratory, Cincinnati, OH. Document No. EPA/600/JA-99/275.
  7. ^ U.S. Environmental Protection Agency, Washington, D.C. "Combined Sewer Overflow (CSO) Control Policy." Federal Register, 59 FR 18688. April 19, 1994.
  8. ^ American City & County (1996). "Chicago digs deep to better manage stormwater." 1996-06-01.
  9. ^ Water Quality Act of 1987, P.L. 100-4.
  10. ^ EPA, Washington, DC. "Stormwater Discharges From Municipal Separate Storm Sewer Systems (MS4s)." 2009-03-11.
  11. ^ Woelkers, David A. (2002). "Tidal Wave: Stormwater Ordinances as a BMP for Phase II." Stormwater, September-October 2002.
  12. ^ C. Michael Hogan (2007). "Knossos fieldnotes." Modern Antiquarian.

Related Publications

Source Separation and Decentralization for Wastewater Management - Tove A. Larsen, Kai M. Udert and Judit Lienert
 Publication Date: Nov 2012 - ISBN - 9781843393481

Automatic Vacuum Flushing Technology for Combined Sewer Solids - Qizhong (George) Guo 
Publication Date: Nov 2012 - ISBN - 9781780400471

Impacts of Climate Change on Rainfall Extremes and Urban Drainage Systems - Patrick Willems, Jonas Olsson, Karsten Arnbjerg-Nielsen, Simon Beecham, Assela Pathirana, Ida Bulow Gregersen, Henrik Madsen, Van-Thanh-Van Nguyen
 Publication Date: Sep 2012 - ISBN - 9781780401256

Impacts of Climate Change on Rainfall Extremes and Urban Drainage Systems - Patrick Willems, Jonas Olsson, Karsten Arnbjerg-Nielsen, Simon Beecham, Assela Pathirana, Ida Bulow Gregersen, Henrik Madsen, Van-Thanh-Van Nguyen
 Publication Date: Sep 2012 - ISBN - 9781780401256

Impacts of Climate Change on Rainfall Extremes and Urban Drainage Systems - Patrick Willems, Jonas Olsson, Karsten Arnbjerg-Nielsen, Simon Beecham, Assela Pathirana, Ida Bulow Gregersen, Henrik Madsen, Van-Thanh-Van Nguyen
 Publication Date: Sep 2012 - ISBN - 9781780401256

Flood Risk - P.B. Sayers
 Publication Date: Jul 2012 - ISBN - 9781780404561

Water, Wastewater and Stormwater Infrastructure Management - Neil S. Grigg 
Publication Date: Jul 2012 - ISBN - 9781780400334

Flood Risk and Social Justice - Zoran Vojinovic and Michael B. Abbott 
Publication Date: Mar 2012 - ISBN - 9781843393870

WaterWiki Newsletter

Share the WaterWiki

Share the WaterWiki!

Add this button to your site to share the WaterWiki with your users. Just copy and paste the HTML code below into your website.

WaterWiki