Document Type : Research Paper
Authors
Faculty of Renewable and Natural Resources, Kwame Nkrumah University of Science and Technology, Kumasi.
Abstract
The problems of shortages and quality deterioration of water, have led to an increased interest in the reuse of treated grey water in many parts of the world. This study examined the suitability of locally available materials (beach sand, oyster shells, and charcoal) to treat grey water samples collected weekly from three halls of residence (Unity Hall, Africa Hall, and Independence Hall) on Kwame Nkrumah University of Science and Technology (KNUST) campus for irrigation. Beach sand, oyster shells, and charcoal were employed in the construction of three vertical flow-through filter systems, each consisting of PVC pipes of height 100 cm and internal diameter 5.08 cm. The grey water samples were filtered and the levels of physicochemical parameters (pH, conductivity, TDS and salinity), nutrient and microbial counts determined over a three-week period. Results indicate that the measured physico-chemical parameters treated grey water were within the permissible limits for irrigation water. Also filtration process is effective in reducing phosphate, the total and faecal coliform levels in grey water from the halls of residence. These observations suggest that treated grey water from KNUST campus would support production when used as irrigation water.
Keywords
Bauder T.A., Colorado State University extension water quality specialist; Waskom R.M., director, Colorado Water Institute; Sutherland, P.L., USDA/NRCS area resource conservationist; and Davis, J.G., Extension soils specialist and professor, Soil and Crop Sciences (2011).
Bhumbla D.K., Agriculture Practices and Nitrate Pollution of Water, West Virginia University Extension Service (1999). Available at: http://www.caf.wvu.edu/wforage/-nitratepollution/nitrate.html, (Accessed October 2, 2012).
Brown R.R., Davies P., Understanding community receptivity to water re-use: Ku-ring-gai Council case study, Water Science and Technology 55 (2007) 283–290.
Dixon A., Butler D., Fewkes A., Robinson M., Measurement and modeling of quality changes in stored untreated grey water, Urban Water 1 (2000) 293-306.
Domenech L., Sauri D., Socio-technical transitions in water scarcity contexts: Public acceptance of grey water reuse technologies in the Metropolitan Area of Barcelona, Resources, Conservation and Recycling. (2010).
FAO, Water quality for agriculture. Irrigation and Drainage paper 29 Rev. 1. Food and Agriculture Organization of the United Nations, Rome, (1985), pp. 174.
Finley S., Barrington S., Lyew D., Reuse of domestic grey water for the irrigation of food crops, Water, Air, & Soil Pollution 199 (2009) 235-245.
Friedler E., Quality of individual domestic grey water streams and its implication for on-site treatment and reuse possibilities. Environmental Technology, 25 (2004) 997-1008.
Gross A., Kaplan D., Baker K., Removal of chemical and microbiological contaminants from domestic grey water using a recycled vertical flow bioreactor (RVFB), Ecological Engineering 31 (2007) 107–114.
Health considerations, Available at: http://www.emro .who.int/ceha/pdf/Greywter% 20English%202006.pdf. (Accessed: October 11, 2012).
James (Mudor) T., Accra. Reviewed paper, 33th WEDC International Conference. Access to sanitation and safe water: global partnerships and local actions (2008) 20-26.
Jefferson B., Palmer A., Jeffrey P., Stuetz R., Judd S., Grey water characterization and its impact on the selection and operation of technologies for urban reuse. Water Science & Technology 50 (2004) 157-164.
Keraita B., Drechsel P., Amoah P., Influence of Urban Wastewater on Stream Water Quality and Agriculture in and around Kumasi, Ghana, Environment and Urbanization, 15 (2003) 171-178.
Khalaphallah R., Grey water treatment for reuse by sand filtration: study of pathogenic microorganisms and phage survival (2012).
Morel A., Diener S., Grey water management in low and middle-income countries, review of different treatment systems for households or neighbourhoods-Sandec Report No. 14/06. Sandec (Water and Sanitation in Developing Countries) at Eawag (Swiss Federal Institute of Aquatic Science and Technology), Dübendorf, Switzerland (2006).
Protection Agency and U.S. Agency for International development, Washington D.C. World Health Organization, Overview of grey water management: Health considerations, (2006). Available at: http://www.emro.who.int/ceha/pdf/Greywter%20English%202006.pdf. (Accessed: October 11, 2012)
Rowe D.R., Abdel-Magid I.M., Handbook of Wastewater Reclamation and Reuse. CRC Press, Inc (1995), p. 550.
Toze S., Reuse of effluent water – benefits and risks. CSIRO Land and Water, CSIRO Centre for Environment and Life Sciences (2006). (Accessed: November 8, 2012).
USEPA, Guidelines for water reuse, U.S. Environmental Protection Agency, Washington DC, (2004).
USEPA, Manual Guideline for water reuse (1995), EPA/625/R- 92/004, U.S. Environment
USEPA, Water: Monitoring and Assessment (2012), Conductivity. Available at: www.water.epa.gov. (Accessed: April 19, 2013).
WHO, Guidelines for the safe use of wastewater, excreta and grey water (2006). Available at: http://www.who.int/water_sanitation health/-wastewater/gsuww/en/index, (Accessed: September 18, 2012)
WHO, Regional Office for the Eastern Mediterranean Overview of grey water management: Health considerations (2006). Available at: http://www.emro.who.int/ceha/pdf/Greywter%20English%202006.pdf. (Accessed: October 11, 2012).