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Evaluation of the Impact of Filter Media Depth on Filtration Performance and Clogging Formation of a Stormwater Sand Filter
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 Title & Authors
Evaluation of the Impact of Filter Media Depth on Filtration Performance and Clogging Formation of a Stormwater Sand Filter
Segismundo, Ezequiel Q.; Lee, Byung-Sik; Kim, Lee-Hyung; Koo, Bon-Hong;
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 Abstract
Sand filters are widely used in infiltration systems to manage polluted urban runoff. Clogging, which is mainly caused by the deposition of sediments on the filter media, reduces the filter system`s infiltration capacity, which further limits its lifespan and function. The physical, chemical and biological clogging characteristics of sand filter, therefore, need to be known for effective design and maintenance. Physical clogging behavior and variations in the characteristics of sand filters according to different media depths are examined in this paper. The variations were observed from laboratory column infiltration tests conducted in a vertical flow and fluctuating head condition. It can be seen that an increase in filter media depth results in a high sediment removal performance; however, it leads to a shorter lifespan due to clogging. In the choice of filter media depth to be used in field applications, therefore, the purpose of facilities as well as maintenance costs need to be considered. At all filter media depth configurations, premature clogging occurred because sediments of 100~250 μm clogged the top 15% of filter media depth. Thus, scrapping the top 15% of filter media may be suggested as the first operational maintenance process for the infiltration system.
 Keywords
Filter media depth;Infiltration;Physical clogging;Sand filter;Stormwater management;
 Language
English
 Cited by
1.
강우유출수 처리시설 침투특성에 대한 필터여재 파쇄의 영향,;구본홍;김이형;이병식;

한국지반공학회논문집, 2016. vol.32. 2, pp.31-41 crossref(new window)
1.
A Laboratory Study on the Filtration and Clogging of the Sand-Bottom Ash Mixture for Stormwater Infiltration Filter Media, Water, 2017, 9, 12, 32  crossref(new windwow)
 References
1.
Bian, B. and Zhu, W. (2009). Particle Size Distribution and Pollutants in Road-deposited Sediments in Different Areas in Zhenjiang, China, Environmental Geochemistry and Health, 31(4), pp. 511-520. crossref(new window)

2.
Blazejewski, R. and Murat-Blazejewska, S. (1997). Soil Clogging Phenomena in Constructed Wetlands with Subsurface Flow, Water Science and Technology, 35 (5), pp. 183-188. crossref(new window)

3.
Duncan, H. P. (1999). Urban Stormwater Quality: A Statistical Overview, Report No. 99/3, Cooperative Research Centre of Catchment Hydrology, Melbourne, Australia.

4.
Fassman, E. A., Simcock, R., and Wang, S. (2013). Media Specification for Stormwater Bioretention Devices, Technical Report 2013/011, Auckland UniServices for Auckland Council, Auckland, New Zealand, pp. 1-115.

5.
Greenberg, A. E., Clesceri, L. S., and Eaton, A. D. (1992). Standard Methods for the Examination of Water and Wastewater, American Public Health Association (APHA) (18th edn.) Washington, D.C., USA.

6.
Hatt, B. E., Fletcher, T. D., and Deletic, A. (2007). Treatment Performance of Gravel Filter Media: Implications for Design and Application of Stormwater Infiltration Systems, Water Research, 41, pp. 2513-2524. crossref(new window)

7.
Hatt, B. E., Fletcher, T. D., and Deletic, A. (2008). Hydraulic and Pollutant Removal Performance of Fine Media Stormwater Filtration Systems, Environmental Science and Technology, 42(7), pp. 2535-2541. crossref(new window)

8.
Huisman, L. and Wood, W. E. (1974). Slow Sand Filtration, World Health Organization, Geneva, Switzerland, pp. 1-122.

9.
Kandra, H. S., Callaghan, J., Deletic, A., and McCarthy, D. (2014). Bioclogging in Stormwater Filters, Journal of Environmental Engineering, 141(2), 04014057. crossref(new window)

10.
Kandra, H. S., Deletic, A., and McCarthy, D. (2012). Impact of Filter Design Variables on Clogging in Stormwater Filters, In: WSUD 2012: Water Sensitive Urban Design; Building the Water Sensitive Community; 7th International Conference on Water Sensitive Urban Design, Barton, A.C.T.: Engineers Australia, pp. 38-45.

11.
Kandra, H. S., Deletic, A., and McCarthy, D. (2014). Assessment of Impact of Filter Design Variables on Clogging in Stormwater Filters, Journal Water Resources Management, 28(7), pp. 1873-1885. crossref(new window)

12.
Kandra, H. S., McCarthy, D., Fletcher, T. D., and Deletic, A. (2014). Assessment of Clogging Phenomena in Granular Filter Media used for Stormwater Treatment, Journal of Hydrology, 512, pp. 518-527. crossref(new window)

13.
Knowles, O., Dotro, G., Nivala, J., and Garcia, J. (2011). Clogging in Subsurface-flow Treatment Wetlands: Occurrence and Contributing Factors, Ecological Engineering, 37, pp. 99-112. crossref(new window)

14.
Langergraber, G., Haberl, R., Laber, J., and Pressl, A. (2003). Evaluation of Substrate Clogging Processes in Vertical Flow Constructed Wetlands, Water Science and Technology, 48(5), pp. 25-34.

15.
Larmet, H., Delolme, C., and Bedell, J. P. (2007). Bacteria and Heavy Metals Concomitant Transfer in an Infiltration Basin: Columns Study Under Realistic Hydro Dynamical Conditions, In: NOVATECH 2007: 6ht International Conference on Sustainable Techniques and Strategies in Urban Water Management, Lyon, France, 25-28 June 2007, pp. 615-622.

16.
Le Coustumer, S., Fletcher, T. D., Deletic, A., Barraud, S., and Lewis, J. F. (2009). Hydraulic Performance of Biofilter Systems for Stormwater Management: Influences of Design and Operation, Journal of Hydrology, 376(1-2), pp. 16-23. crossref(new window)

17.
Maniquiz, M. C., Lee, S. Y., and Kim, L. H. (2010). Multiple Linear Regression Models of Urban Runoff Pollutant Load and Event Mean Concentration Considering Rainfall Variables, Journal of Environmental Sciences, 22(6), pp. 946-952. crossref(new window)

18.
Mercado, J. M. R., Maniquiz-Redillas, M. C., and Kim, L. H. (2015). Laboratory Study on the Clogging Potential of a Hybrid Best Management Practice, Desalination and Water Treatment, 53(11), pp. 3126. crossref(new window)

19.
Ministry of Environment (MOE). (2014). Manual of Nonpoint Source Pollutant Treatment Facility: Establishment, Management, and Operation, Sejong City, Korea.

20.
Morganti, L. (2002). Sodium Hypochlorite Generation for Household Water Disinfection: A Case Study in Nepal, Massachusetts Institute of Technology, Boston, USA, pp. 1-131.

21.
Roger, S., Montrejaud-Vignoels, M., Andral, M. C., Herremans, L., and Fortune, J. P. (1998). Mineral, Physical and Chemical Analysis of the Solid Matter Carried by Motorway Runoff Water, Water Resources, 32(4), pp. 1119-1125.

22.
Siriwardene N., Deletic A., and Fletcher, T. D. (2007). Clogging of Stormwater Gravel Infiltration Systems and Filters: Insights from a Laboratory Study, Water Research, 41(7), pp. 1433-1440. crossref(new window)

23.
Vaze, J. and Chiew, F. H. (2004). Nutrient Loads Associated with Different Sediment Sizes in Urban Stormwater and Surface Pollutants, Journal of Environmental Engineering, 130(4), pp. 391-396. crossref(new window)

24.
Wang, Z., Du, X., Yang, Y., and Ye, X. (2012). Surface Clogging Process Modeling of Suspended Solids during Urban Stormwater Aquifer Recharge, Journal of Environmental Sciences, 24(8), pp. 1418-1424. crossref(new window)

25.
Winter, K. J. and Goetz, D. (2003). The Impact of Sewage Composition on the Soil Clogging Phenomena of Vertical Flow Constructed Wetlands, Water Science and Technology, 48(5), pp. 9-14.

26.
Yong C. F., McCarthy, D. T., and Deletic, A. (2013). Predicting Physical Clogging of Porous Permeable Pavements, Journal of Hydrology, 481, pp. 48-55. crossref(new window)