European Research into Sewer Sediments and Associated Pollutants and Processes
Publication: Journal of Hydraulic Engineering
Volume 129, Issue 4
Abstract
Research investigating all aspects of solids in sewer systems has been underway in Europe for nearly two decades. Due to the early development of European sewer systems, originally as part of the industrialization process more than 100 years ago, urbanization has caused the original sewer networks to become overloaded and unable to function efficiently. Operational problems of interest include loss of ability to convey (designed) flows and the performance of “overflows” to relieve the high flows discharging directly into rivers and other watercourses. Research has characterized the nature of the solids getting into sewer systems, how they behave in terms of transport, and some of the main aspects of their effects. It has been possible to demonstrate that much of the pollutants found in suspension during storms, and likely to be discharged from overflows, originate from the predominantly organic “near bed solids” which accumulate in systems during dry weather. New ideas for the way in which the sediments are transported and the importance of the transformation processes, are leading toward the development of a unified and integrated understanding of the way in which sewer solids behave and the associated biochemical transformation processes.
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References
Ackers, P. (1991). “Sediment aspects of drainage and outfall design.” Proc., Int. Symposium On Environmental Hydraulics, Hong Kong.
Ackers, J. C., Butler, D., and May, R. W. P. (1996). “Design of sewers to control sediment problems.” Construction Industry Research and Information Association (CIRIA) Rep. No. 141, CIRIA, London.
Ahyerre, M. (1999). “Bilans et mecanismes de migration de la pollution organique en réseau d’assianissement unitaire.” PhD thesis, Univ. of Paris.
Ahyerre, M., Chebbo, G., and Saad, M.(2001). “Nature and dynamics of water sediment interface in combined sewers.” J. Environ. Eng., 127(3), 233–239.
Alloway, B. J., and Ayres, D. C. (1997). Chemical principles of environmental pollution, Blackie, London.
Almeida, M. (1999). “Pollutant transformation processes in sewers under aerobic dry weather flow conditions.” PhD thesis, Dept. of Civil and Environmental Engineering, Imperial College of Science, Technology and Medicine, Univ. of London.
Arthur, S. (1996). “Near bed solids transport in combined sewers.” PhD thesis, Univ. of Abertay, Dundee.
Arthur, S., and Ashley, R. M.(1998). “The influence of near bed solids transport on first foul flush in combined sewers.” Water Sci. Technol., 37(1)
Arthur, S., Ashley, R. M., Tait, S., and Nalluri, C.(1999). “Sediment transport in sewers—A step toward the design of sewers to control sediment problems.” Proc., Inst. Civ. Eng., Waters. Maritime Energ., 136.
Ashley, R. M. (1993). “Cohesive sediment erosion and transport in sewers.” Proc., Scottish Hydraulics study group, Symposium on sediment transport, April.
Ashley, R. M., ed. (1996). “Solids in sewers.” Water Sci. Technol., 33(9).
Ashley, R. M., and Souter, N. (1999). “Urban drainage: The human dimension.” Proc., 8th Int. Conf., on Urban Storm Drainage, Sydney, Australia (keynote paper).
Ashley, R. M., Wotherspoon, D. J. J., Goodison, M. J., Mcgregor, I., and Coghlan, B. P.(1992). “The deposition and erosion of sediments in sewers.” Water Sci. Technol., 26(5–6), 1283–1293.
Ashley, R. M., Verbanck, M. A., Bertrand-Krajewski, J.-L., Hvitved-Jacobsen, T., Nalluri, C., Perrusquia, G., Pitt, R., Ristenpart, E., and Saul, A. J. (1996). “Solids in sewers—state of the art.” Proc., 7th Int. Conf. On Urban Storm Drainage, Hannover, Germany, F. Sieker and H.-R. Verworn, eds.
Ashley, R. M., Tait, S., Fraser, A., McIlhatton, T., Phelan, D., and Arthur, S. (1998). “Toward a model to understand flushes in combined sewers.” Proc., 2nd Int. Symp. On Envrionmental Hydraulics, Hong Kong, Dec.
Ashley, R. M., Hvitved-Jacobsen, T., and Bertrand-Krajewski, J.-L.(1999a). “Quo Vadis sewer process modelling?” Water Sci. Tech., 39(9).
Ashley, R. M., Hvitved-Jacobsen, T., Vollertsen, J., McIlhatton, T., and Arthur, S. (1999b). “Sewer solids erosion, washout, and a new paradigm to control solids impacts on receiving waters.” Proc., 8th Int. Conf. on Urban Storm Drainage, Sydney, Australia.
Ashley, R. M., Fraser, A., Burrows, R., and Blanksby, J.(2000). “The management of sediment in combined sewers.” J. Urban Water, 2(4).
Ashley, R. M., Souter, N., and Hendry, S. (2001a). “The importance of public attitudes and behaviour for the management of urban water systems.” Proc., Int. Symposium “Frontiers of Urban Water Management: Deadlock or Hope?” UNESCO, June.
Ashley, R. M., Smith, H., Jowitt, P. W., Butler, D., Blackwood, D. J., Davies, J. W., Gilmour, D., and Foxon, T. (2001b). “Making more sustainable decisions for asset investment in the water industry—sustainable water industry asset resource decisions—the SWARD project.” Proc., 1st U.K. National Conf. on Sustainable Drainage, Coventry Univ., June.
Bjerre, H. L., Hvitved-Jacobsen, T., Teichgräber, B., and te Heesen, D.(1995). “Experimental procedures characterising transformations of wastewater organic matter in the Emscher river, Germany.” Water Sci. Technol., 31(7), 201–212.
Boon, A.(1995). “Septicity in sewers: Causes, consequences and containment.” Water Sci. Technol., 31(7), 237–254.
Borovsky, I., and Scholz, K. (1996). “Simulation of pollutant loads in sewer systems with respect to sedimentation.” Proc., 7th Int. Conf. Urban Storm Drainage, Hannover.
Burkhard, R., Deletic, A., and Craig, A.(2000). “Techniques for water and wastewater management: A review of techniques and their integration in planning.” Urban Water, 2, 197–221.
Butler, D., and Clark, R. B. (1995). “Sediment management in urban drainage catchments.” CIRIA Rep. No. 134, CIRIA, London.
Butler, D., and Menon, F. A.(1999). “Dynamic modelling of roadside gully pots during wet weather.” Water Res., 33(15).
Crabtree, R. W.(1989). “Sediments in sewers.” J. Inst. Wat. Env. Man., 3.
Crabtree, R. W., Ashley, R., and Gent, R. J.(1995). “MOUSETRAP: Modelling of real sewer sediment characteristics and attached pollutants.” Water Sci. Technol., 31(7), 43–50.
Deletic, A. (1998). “Sediment behaviour in grass filter strips.” Proc., 4th Conf. Developments in Urban Drainage Modelling, Sept, London.
Deletic, A., Maksimovic, C., and Ivetic, M.(1997). “Modelling of storm washoff of suspended solids from impervious surfaces.” J. Hydraul. Res., 35(1), 99–118.
Deletic, A., Ashley, R. M., and Rest, D.(2000). “Modelling input of fine granular sediment into storm drainage systems.” Water Res., 34(15), 3836–3844.
DeSutter, R. (2000). “Erosion and transport of cohesive sediment mixtures in unsteady flow.” PhD thesis, Univ. of Gent.
DeSutter, R., Huygens, M., Verhoeven, R. P., Tait, S., and Saul, A. J. (1999). “Erosion and transport of cohesive mineral and organic sediment mixtures.” Proc., 8th Symposium on the Interactions between Sediment and Water, Theme A Physical Dynamics of Sediment, Beijing, Sept.
Field, R., Heaney, J. P., and Pitt, R., eds. (2000). Innovative wet-weather flow management systems, Technomic.
Fraser, A., and Ashley, R. M. (1999). “A model for the prediction and control of problematic sediment deposits.” Proc., 8th Int. Conf. on Urban Storm Drainage, Sydney, Australia.
Galil, N., and Shpiner, R. (2001). “Additional pollutants and deposition potential from garbage disposers.” J. CIWEM, 15.
Gent, R., Crabtree, R. W., and Ashley, R. M.(1996). “A review of model development based on sewer sediments research in the U.K.” Water Sci. Technol., 33(9)
Gerard, C., and Chocat, B. (1998). “An aid for the diagnosis of sewerage networks: Analysis and modelling of the links between network’s physical structure and the risk of sediment build up.” Proc., 4th Int. Conf. Developments in Urban Drainage Modelling, London.
Gromaire-Mertz, M. C., Chebbo, G., and Saad, M.(1998). “Origins and characteristics of urban wet weather pollution in combined sewer systems; The experimental catchment 《Le Marais》 in Paris.” Wat. Sci. Technol., 37(1).
Gupta, K., and Saul, A. J.(1996). “Specific relationships for the first flush load in combined sewer flows.” Water Res., 30(5)
Hager, W. H. (1999). Wastewater hydraulics, Springer, Berlin.
Huisman, J. L., Gienal, C., Kuhni, M., Krebs, P., and Gujer, W. (1999). “Oxygen mass transfer and biofilm respiration rate measurement in a long sewer evaluated with a redundant oxygen balance.” Proc., 8th Int. Conf. on Urban Storm Drainage, Sydney, Australia.
Huisman, J. L. (2001). “Transport and transformation processes in combined sewers.” PhD thesis, Univ. of Dresden.
Hvitved-Jacobsen, T., ed. (1998). “The sewer as a physical, chemical, and biological reactor. II.” Water Sci. Technol., 37(1), 357.
Hvitved-Jacobsen, T. (2001). Sewer processes, CRC, Boca Raton, Fla., p. 256.
Hvitved-Jacobsen, T., Nielsen, P. H., Larsen, T. T., and Jensen, N. A.(ed.) (1995). “The sewer as a physical, chemical, and biological reactor.” Water Sci. Technol., 31(7), 330.
Hvitved-Jacobsen, T., Vollertsen, J., and Nielsen, P. H.(1998). “A process and model concept for microbial wastewater transformations in gravity sewers.” Water Sci. Technol., 37(1), 233–241.
Hvitved-Jacobsen, T., Vollertsen, J., and Matos, J.(2002). “The sewer as a bioreactor—dry weather approach.” Water Sci. Technol., 45(3), 11–24.
International Water Association (IWA). (2000). 〈http://www.sspwg.civil.auc.dk〉.
Johnstone, F. M., Ashley, R. M., Souter, N. H., Davies, J., Milne, D., and Schuetze, M. (1999). “Developing mass balances for sanitary solids in sewers for use in life cycle assessment.” Proc., 8th ICUSD, Sydney, Sept., Vol. 2, 618–625.
Laplace, D., Bachoc, A., Sanchez, Y., and Dartus, D.(1992). “Trunk sewer clogging development: Description and solutions.” Water Sci. Technol., 25(8), 91–100.
May, R. W. P., Ackers, J. C., Butler, D., and John, S.(1996). “Development of design methodology for self-cleansing sewers.” Water Sci. Technol., 33(9), 195–206.
McIlhatton, T., Sakrabani, R., Ashley, R. M., and Burrows, R.(2002). “Erosion mechanisms in combined sewers and the potential for pollutant release to receiving waters and water treatment plants.” Water Sci. Technol., 45(3), 61–69.
Mehta, A., and Partheniades, E. (1982). “Resuspension of deposited cohesive sediment beds.” Proc., 18th Coastal Engineering Conf., Vol. 2.
Noorman, K. J., and Uiterkamp, T. S., eds. (1998). Green households? Earthscan Publication, U.K.
Parchure, T. M., and Mehta, A. J.(1985). “Erosion of soft cohesive sediment deposits.” J. Hydraul. Eng., 111(10), 1308–1326.
Pisano, W. C., Connick, D., Quieroz, C., and Aronson, J. (1979). “Dry weather deposition and flushing for CSO pollution control.” Rep. No. EPA/600/2-79-133, United States Environmental Protection Agency, Cincinnati.
Pisano, W. C., Barsanti, J., Joyce, J., and Sorensen, H. (1998). “Sewer and tank sediment flushing: case studies.” Rep. No. EPA/600/R-98/157 (NTIS PB99-127839INZ), United States Environmental Protection Agency, Cincinnati.
Rauch, W., Aalderink, H., Krebs, P., Schilling, W., and Vanrolleghem, P. (1998). “Requirements for integrated wastewater models—driven by receiving water objectives.” Proc., 19th IAWQ Biennial Conf., Vancouver, June.
Rauch, W., Bertrand-Krajewski, J.-L., Krebs, P., Marks, O., Schilling, W., Schutze, M., and Vanrolleghem, P.(2002). “Deterministic modelling of integrated urban drainage systems.” Water Sci. Technol., 45(3), 81–94.
Ristenpart, E. (1995). “Festoffe in der Mischwasserkanalisation Vorkommen, Bewegung und Versschmutzungpotential.” PhD, Univ. of Hannover, p. 311.
Ristenpart, E. (1996). “Modelling of sediment erosion in a combined sewer.” Proc., 7th Int. Conf. Urban Storm Drainage, Hannover, Germany, Sept, F. Seiker and R. Verworn, eds.
Saul, A. J. (1998). “CSO state of the art review: A UK perspective.” Proc., 4th Conf. Development in Urban Drainage Modelling, Sept, London.
Saul, A. J., Houldsworth, J. K., Meadowcroft, J., Balmforth, D. J., Digman, C., Butler, D., and Davies, J. (1999). “Predicting aesthetic pollutant loadings from combined sewer overflows.” Proc., 8th Int. Conf., on Urban Storm Drainage, Sydney, Australia.
Saul, A. J., Skipworth, P., Tait, S., and Rushforth, P. (2003). “The movement of total suspended solids in combined sewers.” J. Hydraul. Eng., 129(4).
Skipworth, P. J., Tait, S. J., and Saul, A. J.(1999). “Erosion of sediment beds in sewers: Model development.” J. Environ. Eng., 125(6), 566–573.
Stockhausen, E. M., and Souter, N. (1996). “International survey of sanitary waste disposal practices.” Rep. No. WW5008R/2, Wastewater Technology Centre, Univ. of Abertay, Dundee.
Techniques Sciences Methodes. (1993). Special edition: Les solide en resaux d’assainisement. Oct.
Thistlethwayte, D. K. B. (ed.). (1972). The control of sulfides in sewerage systems, Butterworth, Sydney, Australia.
United States Environmental Protection Agency (USEPA). (1974). Process design manual for sulfide control in sanitary sewerage systems, USEPA Technology Transfer, Washington, D.C.
United States Environmental Protection Agency (USEPA). (1992). “Wastewater treatment/disposal for small communities.” Rep. No. EPA/625/R-92/005, USEPA, Cincinnati.
Verbanck, M. A., ed. (1992). “Origin, occurrence, and behaviour of sediments in sewer systems.” Water Sci. Technol., 25(8)
Verbanck, M. A.(1995). “Capturing and releasing settleable solids—the significance of dense undercurrents in combined sewer flows.” Water Sci. Technol., 31(7).
Verbanck, M. A.(2002). “Computing near-bed solids transport in sewers and similar sediment-carrying open-channel flows.” Urban Water, 2(4).
Vollertsen, J. (1998). “Solids in combined sewers—characterisation and transformation.” PhD, Aalborg Univ., Denmark.
Vollertsen, J., and Hvitved-Jacobsen, T.(1998). “Aerobic microbial transformations of resuspended sediments in combined sewers—a conceptual model.” Water Sci. Technol., 37(1), 69–76.
Vollertsen, J., Hvitved-Jacobsen, T., McGregor, I., and Ashley, R. M.(1998). “Aerobic microbial transformations of pipe and silt trap sediments from combined sewers.” Water Sci. Technol., 39(2), 233–249.
Vollertsen, J., and Hvitved-Jacobsen, T.(2000). “Resuspension and oxygen uptake of sediments in combined sewers.” Urban Water, 2, 21–27.
van der Wijst, M. A. J. E., and Groot-Marcus, J. P.(1999). “Consumption and domestic waste water demographic factors and developments in society.” Water Sci. Technol., 39(5).
Wotherspoon, D. J. J. (1994). “The movement of cohesive sediment in a large combined sewer.” PhD thesis, Univ. of Abertay Dundee.
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Published In
Journal of Hydraulic Engineering
Volume 129 • Issue 4 • April 2003
Pages: 267 - 275
Copyright
Copyright © 2003 American Society of Civil Engineers.
History
Received: Oct 29, 2001
Accepted: Apr 11, 2002
Published online: Mar 14, 2003
Published in print: Apr 2003
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