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Drinking Water Sources and Storage ENVR 890 Mark D. Sobsey Spring, 2007 WHO Risk-based Framework Water Sources and Water Treatment • Drinking water should be essentially free of disease-causing microbes, but often this is not the case. – A large proportion of the world’s population drinks microbially contaminated water, especially in developing countries • Using the best possible source of water for potable water supply and protecting it from microbial and chemical contamination is the goal – In many places an adequate supply of pristine water or water that can be protected from contamination is not available • The burden of providing microbially safe drinking water supplies from contaminated natural waters rests upon water treatment processes – The efficiency of removal or inactivation of enteric microbes and other pathogenic microbes in specific water treatment processes has been determined for some microbes but not others. – The ability of water treatment processes and systems to reduce waterborne disease has been determined in epidemiological studies Source Water Protection: Water Resources Management • Integral to the preventive management of drinking-water quality. • Preventing microbial and chemical contamination of source water is the first barrier against drinking-water contamination of public healthconcern. • Water resource management and potentially polluting human activity in catchments and aquifers influence water quality. • This impacts treatment steps required to ensure safe water • Preventive action may be preferableto upgrading treatment. Influence of Land Use on Water Quality • Assess land use influence on water quality • Not normally undertaken by health authorities or drinkingwater supply agencies alone • Establish close collaboration between public health authority, water supplier and resource management agency – may include other sectors, .e.g., agriculture, traffic, tourism or urban development. • National authorities must interact with other sectors to formulate national policy for integrated water resource management • Set up regional and local structures to implement policy – National authorities need to guide regional and local authorities by providing tools Land Uses to Consider that Influence Water Quality • • • • • • • • • land cover modification extraction activities construction/modification of waterways application of fertilizers, herbicides, pesticides and other chemicals livestock density and application of manure road construction, maintenance and use various forms of recreation urban or rural residential development – Pay particular attention to excreta disposal, sanitation, landfill and waste disposal other potentially polluting human activities, such as industry, military sites, Drinking Water Sources • • • • • • Ground Water Surface water Rainwater Condensed water from the atmosphere Reclaimed wastewater Other? Groundwater • Water table or surficial aquifer – First water encountered through the soil or subsurface – Often subject to contamination from the land surface • Confined aquifer – Water found below a confining subsurface later of clay, rock or other impervious material – Often protected from contamination lan surface • Both may contain geological chemical contaminants – Arsenic and fluoride are probably of most health risk • Confined aquifer water is often better protected from surface contamination Surface Waters • Lakes, ponds and other and “confined” bodies of water • Rivers, streams, creeks and other flowing bodies of water • All are subject to direct contamination from wastewater and excreta discharges • All are subject to contamination from land runoff • Surface water should be assumed to be contaminated unless proven otherwise by direct and indirect evidence from observations and analysis Rainwater • Rainwater as it falls from the sky is essentially free of pathogens and toxic chemicals • Airborne contaminants can cause low level contamination with microbes and chemicals • Rainwater is collected primarily on roofs or other impervious collectors – Contamination from roof/impervious surface chemicals and microbes is possible • Rainwater is often stored in barrels, cisterns and other surface and subsurface collectors or impoundments – Contamination is very likely unless special precautions are taken to protect the collected water from fecal and other sources of contamination Condensed water from the atmosphere • Atmospheric water as clouds, fod and airborne mist can be harvested at it impacts impervious surfaces. • Solar Stills – Water evaporated from standing water also can be condensed and harvested – Solar condensers collect evaporated water – Solar energy can supply heat Reclaimed Water • Water can be purified from sewage and other wastewater • Reuse for non-potable purposes in encouraged • Reuse for potable purposes is discouraged – Indirect reuse is considered feasible and of less risk by recharging aquifers or reservoirs and allowing addition die-off and further treatment • WHO and countries have regulations for nonpotable and potable reuse Water Treatment Processes: Storage Reservoirs, aquifers & other systems: – store water – protect it from contamination • Factors influencing microbe reductions (site-specific) – detention time – temperature – microbial activity – water quality: particulates, dissolved solids, salinity – sunlight – sedimentation – land use – precipitation – runoff or infiltration Larger Scale Water Storage • Reservoir impoundments and other water storage diversions • Tanks and other fabricated vessels – Above and below ground cisterns, reservoirs and tanks Household Water Containers for Safe Storage: • Material: Depends on Rx; easy to clean; lightweight, durable, impact- and oxidationresistant, heat-resistant (if thermal Rx) – High-density polyethylene (HDPE) for chemical Rx – Transparent beverage bottles for solar-UV + heat (PET) – Black or opaque for solar-heat only • Can adapt traditional vessels to safer storage – Add cover – Add spout or spigot Characteristics of Preferred HH Water Storage Vessels • Appropriate material, size, shape, dimensions, – Depends on collection, Rx method, use conditions & user • Volume: usually 10 and 30 liters (not too heavy) – smaller volumes (1-1.5 L) for solar Rx; multiples • Handles to facilitate lifting and carrying • Stable base to prevent overturning • Uniform size for standard chemical dosing • Opening: large enough to fill and clean; small enough to discourage hands, cups or other dip utensils. – Inlet: fitted with a lid • Durable spigot or spout for pouring Household Water Containers for Safe Storage Plastic vessels are commonly used – many have safe features Properties Composition Volume (L) Durability Cleaning Ease Lid Faucet Inside Cleaning Chemical Dosing Ease Cost Distribution Cost CDC Vessel Plastic (HDPE) 20 Good Yes Yes Yes Yes Very easy Med.-High High Jerry Can Plastic Oxfam Plastic Varies Acceptable Good Yes, qualified Yes No No, usually Easy (may be variable) Low Low, if local 14 Traditional vessels, such as pots, urns and bowls can be made safe by covering and providing a dispenser (spigot or spout) Yes Yes Yes Yes Very easy Med.-High High Household Water Storage: Disease Risks and Containers for Improved Protection • Inadequate storage results in microbial contamination and waterborne disease • Improved storage vessels reduce microbial contamination and disease risks • Improved storage can be coupled with household treatment to further improve microbial quality and reduce disease risks • Best implemented and sustained if supported with behavior modification, education, motivation and social marketing Increased Microbial Contamination (Decreased Microbial Quality) and Infectious Disease Risks from Inadequately Stored Household Water Location Storage Vessel Storage Times Rural Bangladesh Water jars 1-2 days Calcutta, India Widemouth vs. narrownecked Clay jars ("zeers") in homes, etc. Not reported Not measured 2 days to 1 month Rural Malawi Stored HH water; others South Sudan Rangoon, Burma Not reported Buckets Khartoum, Sudan Microbial Quality Impact? Increased V. cholerae Disease Impact? Reference Incr. (~10X higher) cholera rates 4X higher cholera infections w/ wide-mouth Spira et al., 1980 Not Measured Hammad and Dirar, 1982 Not reported Incr. Fecal indicators w/ time, summer, w/ dust events Higher fecal coliforms Not measured Not reported Up to 2 days Increased fecal bacteria levels Higher FC than source Not Measured Lindskog and Lindskog, 1988 Mascher et al., 1988 Han et al., 1989 Not Measured Deb et al., 1982 Increased Microbial Contamination (Decreased Microbial Quality) and Infectious Disease Risks from Inadequately Stored Household Water Location Storage Vessel Urban slum and rural villages, Liberia Kurunegala, Sri Lanka Storage Times Large containers, open or closed Earthen pots and others Rural Africa Traditional & metal jars Rural Various Malaysia containers "A long time" Trujillo, Peru Not reported Widemouth containers Not reported 24 hours or more Not reported Microbial Quality Impact? Higher enterobacters in stored than source water Higher FC in stored unboiled water Higher TC and FC Higher FC in unboiled than boiled water Higher FC in stored than source waters Disease Impact? Reference Not Measured Molbak et al., 1989 Not Measured Mertens et al., 1990 Not Measured Empereur et al., 1992 Knight et al., 1992 Higher diarrhea risks stored in wide-necked than narrow-necked Increased cholera Swerdlow et risks al., 1992 Reservoir Water Storage and Microbial Reductions • Microbe levels reduced over time by natural antimicrobial processes and microbial death/die-off • Human enteric viruses in surface water reduced 4001,000-fold when stored 6-7 months (The Netherlands) – Indicator bacteria reductions were less extensive, probably due to recontamination by waterfowl. • Protozoan cyst reductions (log10) by storage were 1.6 for Cryptosporidium and 1.9 for Giardia after about 5 months (The Netherlands; G.J Medema, Ph.D. diss.) – Recent ICR data indicates lower protozoan levels in reservoir or lake sources than in river sources; suggests declines in Giardia & Cryptosporidium by storage