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Research Article

Laboratory-scale waste stabilisation pond development

Amanda Inglisa School of Physical and Chemical Sciences, University of Canterbury, Christchurch, New ZealandCorrespondence[email protected] [email protected]
ORCID Iconhttps://orcid.org/0000-0001-5867-6044View further author information
ORCID Icon,
Judith Webberb The Institute of Environmental Science and Research Ltd, Christchurch, New ZealandView further author information
,
Bronwyn Humphriesb The Institute of Environmental Science and Research Ltd, Christchurch, New ZealandView further author information
,
Matthew Ashworthb The Institute of Environmental Science and Research Ltd, Christchurch, New ZealandView further author information
&
Louise Weaverb The Institute of Environmental Science and Research Ltd, Christchurch, New ZealandView further author information
Pages 3888-3904 | Received 20 Aug 2019, Accepted 13 May 2021, Published online: 11 Jun 2021

References

  • United Nations Educational, S.a.C.O.U. The United Nations World Water Development Report 1: Water for People, Water for Life. 2003, World Water Assesment Programme (WWAP).
  • Sperling M, Oliveira SC. Comparative performance evaluation of full-scale anaerobic and aerobic wastewater treatment processes in Brazil. Water Sci Technol. 2009;59(1):15–22.
  • Alves CVP, Chernicharo CAL, Von Sperling M. UV disinfection of stabilization pond effluent: A feasible alternative for areas with land restriction. Water Sci Technol. 2012;65(2):247–253.
  • Bichai F, Polo-López MI, Fernández Ibañez P. Solar disinfection of wastewater to reduce contamination of lettuce crops by Escherichia coli in reclaimed water irrigation. Water Res. 2012;46(18):6040–6050.
  • Blumenthal U, Peasey A. Critical Review of Epidemiological Evidence of the Health Effects of Wastewater and Excreta Use in Agriculture; 2002.
  • Carr RM, Blumenthal UJ, Mara DD. Health guidelines for the use of wastewater in agriculture: developing realistic guidelines. Wallingford: CABI Publishing; 2004. p. 41–58.
  • Scheierling SM, et al. Towards an agenda for improving wastewater use in agriculture. Water International. 2011;36(4):420–440.
  • Olukanni DO, Ducoste JJ. Optimization of waste stabilization pond design for developing nations using computational fluid dynamics. Ecol Eng. 2011;37(11):1878–1888.
  • Toprak H. Empirical modelling of sedimentation which occurs in anaerobic waste stabilization ponds using a lab-scale semi-continuous reactor. Environmental Technology (United Kingdom). 1994;15(2):125–134.
  • Travieso L, et al. Evaluation of a laboratory-scale stabilization pond for tertiary treatment of distillery waste previously treated by a combined anaerobic filter-aerobic trickling system. Ecol Eng. 2006;27:100–108.
  • Von Sperling, M., Waste stabilisation ponds. Vol. 3. London: IWA Pub; 2007.
  • Reinoso R, Torres LA, Bécares E. Efficiency of natural systems for removal of bacteria and pathogenic parasites from wastewater. Sci Total Environ. 2008;395(2-3):80–86.
  • Butler E, et al. Oxidation pond for municipal wastewater treatment. Appl Water Sci. 2015;7:1–21.
  • Mara DD, et al. Waste stabilization ponds: A viable alternative for small community treatment systems. Journal of the Institution of Water and Environmental Management. 1992;6(1):72–78.
  • Spellman FR. Handbook of water and wastewater treatment plant operations. Vol. 3. Boca Raton: CRC Press; 2014.
  • Verbyla ME, Mihelcic JR. A review of virus removal in wastewater treatment pond systems. Water Res. 2015;71:107–124.
  • Pearson HW, Mara D, Mills SW. Rationalizing waste stabilization pond design: the biological factor. In: T Panswad, C Polprasert, K Yamamoto, editors. Water pollution control in Asia. Oxford: Pergamon; 1988. p. 691–697.
  • Hosetti BB, Frost S. A review of the sustainable value of effluents and sludges from wastewater stabilization ponds. Ecol Eng. 1995;5(4):421–431.
  • Bolton NF, et al. A review of the factors affecting sunlight inactivation of micro-organisms in waste stabilisation ponds: preliminary results for enterococci. Water Sci Technol. 2010;61:885–890.
  • Abis KL, Mara D. Research on waste stabilization ponds in the United Kingdom: sludge accumulation in pilot-scale primary facultative ponds. Environ Technol. 2005;26(4):449–458.
  • Kayombo S, et al. Design Manual, in Waste Stabilization Ponds and Constructed Wetlands. United Nations Environment Programme - International Environmental Technology Centre; 2005, p. 59.
  • Kayombo S, et al. Diurnal cycles of variation of physical–chemical parameters in waste stabilization ponds. Ecol Eng. 2002;18(3):287–291.
  • Nameche T, Vasel JL. Hydrodynamic studies and modelization for aerated lagoons and waste stabilization ponds. Water Res. 1998;32(10):3039–3045.
  • Mara DD. Pond process design - a practical guide. In: AN Shilton, editor. Pond treatment technology. London: IWA Publishing; 2005. p. 168–187.
  • Sweeney D. Hydraulic design. In: AN Shilton, editor. Pond treatment technology. London: IWA Publishing; 2005. p. 188–217.
  • Arceivala SJ. Hydraulic modeling for waste stabilization ponds. Journal of Environmental Engineering (United States). 1983;109(1):265–268.
  • Polprasert C, Bhattarai KK. Dispersion model for waste stabilization ponds. Journal of Environmental Engineering (United States). 1985;111(1):45–59.
  • Agunwamba JC, Egbuniwe N, Ademiluyi JO. Prediction of the dispersion number in waste stabilization ponds. Water Res. 1992;26(1):85–89.
  • Shilton A. Studies into the hydraulics of waste stabilisation ponds, in Environmental Engineering. 2001, Massey University.
  • Abbas H, Nasr R, Seif H. Study of waste stabilization pond geometry for the wastewater treatment efficiency. Ecol Eng. 2006;28(1):25–34.
  • Persson J. The hydraulic performance of ponds of various layouts. Urban Water. 2000;2(3):243–250.
  • Shilton A, Harrison J. Development of guidelines for improved hydraulic design of waste stabilisation ponds. Water Sci Technol. 2003;48(2):173–180.
  • Ray D. New Zealand municipal wastewater monitoring guidelines, M.f.t. Environment, Editor. New Zealand Water Environment Research Foundation: NZ; 2002.
  • Mara D, Pearson HW. Design manual for waste stabilization ponds in Mediterranean countries. Leeds: Lagoon Technology International; 1998.
  • Meysurova A, Notov A. Physicochemical analysis of indicator lichens as a component of conservation area baseline monitoring. J Appl Spectrosc. 2016;82(6):1005–1012.
  • Metcalf and Eddy, Wastewater engineering treatment, disposal and reuse. 2nd ed. McGraw-Hill Series in Water Resources and Environmental Engineering. G. Tchobanoglous, editor. New York: McGraw-Hill; 1979.
  • Clark S, Cameron S. Oxidation pond management guidelines. New Zealand Environmental Technologies; New Zealand Water and Wastes Association; Ministry for the Environment; 2005.
  • Shilton A, Bailey D. Drouge tracking by image processing for the study of laboratory scale pond hydraulics. Flow Meas Instrum. 2006;17(1):69–74.
  • Bareither R, Pollard D. A review of advanced small-scale parallel bioreactor technology for accelerated process development: current state and future need. Biotechnol Prog. 2011;27(1):2–14.
  • Hwang KJ, Liao CY, Tung KL. Analysis of particle fouling during microfiltration by use of blocking models. Journal of Membrance Science. 2007;287:287–298.
  • Liu QF, Kim SH. Evaluation of membrane fouling models based on bench-scale experiments: a comparison between constant flowrate blocking laws and artificial neural network (ANNs) model. Journal of Membrance Science. 2008;310:393–401.
  • Hosetti B, Frost S. A review of the control of biological waste treatment in stabilization ponds. Crit Rev Environ Sci Technol. 1998;28(2):193–218.
  • Sonune A, Ghate R. Developments in wastewater treatment methods. Desalination. 2004;167(1-3):55–63.
  • Persson J, Wittgren HB. How hydrological and hydraulic conditions affect performance of ponds. Ecol Eng. 2003;21(4-5):259–269.
  • Berg G. Removal of viruses from sewage, effluents, and waters. II. Present and future trends. Bull World Health Organ. 1973;49(5):461–469.
  • Qiu Y, et al. A one-step centrifugal ultrafiltration method to concentrate enteric viruses from wastewater. J Virol Methods. 2016;237:150–153.
  • Symonds EM, Breitbart M. Affordable enteric virus detection techniques are needed to support changing paradigms in water quality management. CLEAN - Soil Air Water. 2015;43(1):8–12.
  • NIWA. The national climate database. New Zealand.
  • Lin S, Lee CC. Water and wastewater calculations manual, Vol. 2. New York: McGraw-Hill; 2007.
  • Featherstone RE, Nalluri C. Civil engineering hydraulics: essential theory with worked examples. 3rd ed. Oxford: Blackwell Science; 1995.
  • Kobus H, Abraham G. Hydraulic modelling, Vol. 7. Hamburg: Parey; 1980.
  • Badrot-Nico F, Guinot V, Brissaud F. Taking wind into account in the design of waste stabilisation ponds. Water Sci Technol. 2010;61(4):937–944.
  • Coggins LX, et al. Impact of Hydrodynamic reconfiguration with baffles on treatment performance in waste stabilisation ponds: A full-scale experiment. Water (Basel). 2018;10(2):109.
  • Ashworth J, Skinner M. Waste stabilisation pond design manual. Power and Water Corporation Australia; 2011.
  • Curtis TP, et al. Light penetration in waste stabilization ponds. Water Res. 1994;28(5):1031–1038.
  • Gerba CP, Gramos DM, Nwachuku N. Comparative inactivation of enteroviruses and adenovirus 2 by UV light. Appl Environ Microbiol. 2002;68(10):5167–5169.
  • Gerba CP, Kitajima M, Iker B. 15 - Viral presence in waste water and sewage and control methods. In: N Cook, editor. Viruses in Food and water. Cambridge: Woodhead Publishing; 2013. p. 293–315.
  • Agency, U.S.E.P. Ultraviolet disinfection guidance manual for the final long term 2 enhanced surface water treatment rule; 2006.
  • American Public Health Association, American Water Works Association, and Water Environment Federation, Standard methods for the examination of water and wastewater. Clesceri L. S., Greenberg A. E., Eaton A. D., editors. Washington, DC: American Public Health Association; 1998.
  • Pinto F, Maillard J-Y, Denyer SP. Effect of surfactants, temperature, and sonication on the virucidal activity of polyhexamethylene biguanide against the bacteriophage MS2. Am J Infect Control. 2010;38(5):393–398.
  • Farkas K, et al. A Gel filtration-based method for the purification of infectious rotavirus particles for Environmental Research applications. Food Environ Virol. 2013;5:231–235.
  • Arens M, Swierkosz E, Dilworth V. Effects of sonication and centrifugation of clinical specimens on the recovery of herpes simplex virus. Diagn Microbiol Infect Dis. 1988;11(3):137–143.
  • American Public Health Association, American Water Works Association, and Water Environment Federation. Standard methods in the examination of water & wastewater. In: Clesceri L. S., Greenberg A. E., Eaton A. D., editors. Heterotrophic plate count. Washington D.C.: American Public Health Association; 1998. p. 9-34–9-40.
  • Allwood PB, et al. Survival of F-specific RNA coliphage, feline calicivirus, and escherishia coli in water: a Comparative study. Appl Environ Microbiol. 2003;69(9):5707–5710.
  • Baggi F, Demarta A, Peduzzi R. Persistence of viral pathogens and bacteriophages during sewage treatment: lack of correlation with indicator bacteria. Res Microbiol. 2001;152(8):743–751.
  • Boudaud N, et al. Removal of MS2, qbeta and GA bacteriophages during drinking water treatment at pilot scale. Water Res. 2012;46(8):2651–2664.
  • Grabow WOK. Bacteriophages: update on application as models for viruses in water. Water SA. 2001;27(2):251–268.
  • Havelaar AH, et al. Bacteriophages as model viruses in water quality control. Water Res. 1991;25(5):529–545.
  • Havelaar AH, Van Olphen M, Drost YC. F-specific RNA bacteriophages are adequate model organisms for enteric viruses in fresh water. Appl Environ Microbiol. 1993;59(9):2956–2962.
  • American Public Health Association, American Water Works Association, and Water Environment Federation. Standard methods for the examination of water & wastewater. In: Clesceri L. S., Greenberg A. E., Eaton A. D., editors. Detection of enteric viruses. Washington D. C.: American Public Health Association; 1998. p. 9-115–9-128.
  • Reed LJ, Muench HA. A simple method of estimating fifty percent endpoints. Am J Hyg. 1938;27:493–497.
  • Paterson C, Curtis T. Physical and chemical environments. In: AN Shilton, editor. Pond treatment technology. London: IWA Publishing; 2005. p. 49–65.
  • Adlerberth I, Wold AE. Establishment of the gut microbiota in western infants. Acta Pædiatrica. 2009;98(2):229–238.
  • Gilmore MS, et al. The enterococci. Washington D. C.: American Society of Microbiology; 2002.
  • Sadowsky MJ, Whitman RL. The fecal bacteria. 1st ed. Washington (DC): ASM Press; 2011.
  • Fritz JJ, Middleton AC, Meredith DD. Dynamic process modeling of wastewater stabilization ponds. J Water Pollution Control Federation. 1979;51(11):2724–2743.
  • Davies-Colley RJ, et al. Inactivation of faecal indicator micro-organisms in waste stabilisation ponds: interactions of environmental factors with sunlight. Water Res. 1999;33(5):1220–1230.
  • Craggs RJ, et al. Modelling sunlight disinfection in a high rate pond. Ecol Eng. 2004;22(2):113–122.
  • Dochain D, et al. Dynamic modelling of a waste stabilisation pond. Bioprocess Biosyst Eng. 2003;26:19–26.
  • Abdel-Raouf N, Al-Homaidan AA, Ibraheem IBM. Microalgae and wastewater treatment. Saudi J Biol Sci. 2012;19(3):257–275.
  • Muñoz R, Guieysse B. Algal-bacterial processes for the treatment of hazardous contaminants: a review. Water Res. 2006;40(15):2799–2815.
  • Von Sperling M. Wastewater characteristics, treatment and disposal. London: IWA Publishing; 2007.
  • Akpor OB, et al. Microbial roles and dynamics in wastewater treatment systems: An overview. Int J Pure Appl Bioscience. 2014;2(1):156–168.
  • Shannon KE, et al. Application of real-time quantitative PCR for the detection of selected bacterial pathogens during municipal wastewater treatment. Sci Total Environ. 2007;382(1):121–129.
  • Tree JA, Adams MR, Lees DN. Chlorination of indicator bacteria and viruses in primary sewage effluent. Appl Environ Microbiol. 2003;69(4):2038–2043.
  • McMinn BR, Ashbolt NJ, Korajkic A. Bacteriophages as indicators of faecal pollution and enteric virus removal. Lett Appl Microbiol. 2017;65(1):11–26.
  • Weinbauer MG. Ecology of prokaryotic viruses. FEMS Microbiol Rev. 2004;28(2):127–181.
  • Pinheiro MDO, et al. Inactivation of the bacteriophage MS2 by the ciliated protozoan, tetrahymena thermophila. Water Qual Res J Can. 2008;43(1):7.
  • Berg G, et al. Validity of fecal coliforms, total coliforms, and fecal streptococci as indicators of viruses in chlorinated primary sewage effluents. Appl Environ Microbiol. 1978;36(6):880–884.
  • Sims A, et al. Toward the development of microbial indicators for wetland assessment. Water Res. 2013;47(5):1711–1725.

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