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Dr Stuart Khan School of Civil & Environmental Engineering, University of New South Wales

Drinking Water Through Recycling The benefits and costs of supplying direct to the distribution system. Dr Stuart Khan School of Civil & Environmental Engineering, University of New South Wales. Project aim.

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Dr Stuart Khan School of Civil & Environmental Engineering, University of New South Wales

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  1. Drinking Water Through RecyclingThe benefits and costs of supplying direct to the distribution system Dr Stuart Khan School of Civil & Environmental Engineering, University of New South Wales

  2. Project aim “To define in objective scientific, economic and social terms, the potential place of recycling directly to the drinking water distribution system, in the spectrum of available water supply options” Target audience “The report will be directed towards policy makers, regulators, researchers, the water industry at large and the consuming public”

  3. Indirect potable reuse Water treatment plant

  4. Indirect potable reuse Water treatment plant

  5. Role of the ‘environmental buffer’ • Opinions of 80 Australian stakeholders: • To provide an additional treatment barrier for pathogenic and/or trace chemical substances • To provide dilution of contaminants in recycled water • To stabilise/equilibrate highly purified reverse osmosis permeates • To provide ‘time to respond’ to treatment malfunctions or unacceptable water quality • Bufferingthe production and use of recycled water / storage • Maintenance of aquifer integrity and/or groundwater quality • To provide a ‘perception’ of increased water quality or safety / public confidence • To provide a perception of a disconnection between treated effluent and raw drinking water / To reduce the “yuck factor”

  6. Goreangab Water Reclamation Plant, Windhoek, Namibia • Pioneer DPR Project (since 1968) • GoreangabWTP converted to not only treat water from Goreangab Dam, but also reclaimed effluent • New plant completed in 2002 (NGWRP) • Capacity: 7.5 GL/year (~20 ML/day) • Provides 35% of total supply • Can do 50% in severe drought conditions

  7. Cloudcroft, New Mexico, USA • Small, high altitude skiing village • Permanent population <1000, but more than doubles on weekends and holidays • Potable water from springs and wells, but during drought has been tankered in on weekends • DPR system began operation in 2011 • Operating license requires slightly greater fraction (51%) of surface or groundwater to be used. • DPR capacity: 0.1 ML/day

  8. Big Spring, West Texas, USA • Permian Basin city of around 30,000 population • Severe drought during much of last 15 years • Surface water (from Colorado River) and available groundwater insufficient for future needs • IPR considered but: • Current raw water sources are distant and lower in elevation • High evaporative losses • High dissolved solids in current surface water (and in available effluent sources) • DPR began operation April 2013. Capacity: 10 ML/day • Contributes up to 15% of blended raw water in the pipeline • Treatment energy costs offset by energy savings from avoided raw water and effluent pumping

  9. Beaufort West Municipality, South Africa • Situated in Central Karoo, one of the driest areas in South Africa • Population: ~40,000 (spread across three towns) • Severe drought in 2010/2011 led to daily water trucking to >8000 homes • Increased water demand forecast in coming years • DPR plant commissioned in January 2011 • Design capacity: 2 ML/day • Contributes 20% of blended raw water in the pipeline (will increase to 25%)

  10. Health risk assessment and risk management • Broad range of harmful substances in untreated sewage • Pathogens (viruses, bacteria, protozoa) • Chemicals (carcinogenic, endocrine disrupting, other toxicities) • Objectives • Reduce concentrations to levels of acceptable risk (treatment) • Ensure that the above is achieved (monitoring) • Engineer system reliability • Hazard Analysis and Critical Control Points (HACCP) • Multiple-barrier approach • Probabilistic reliability analysis • Foster operator reliability • High levels of expertise and training within the Australian water industry • Supported by mechanisms to ensure compliance with requirements to only use appropriately skilled operators and managers

  11. Cost, energy and GHG emissions • Illustrative hypothetical case study • Undertaken by GHD • Four scenarios based on alternative water supply options for a hypothetical coastal Australian city: • Seawater desalination • Indirect potable reuse • Direct potable reuse • Dual-pipe systems • Model (including uncertainty): • Financial (capital and operating) costs • Potential environmental impacts

  12. Cost, energy and GHG emissions

  13. Power consumption

  14. Greenhouse gas emissions

  15. Social acceptance of DPR • A significant challenge • Numerous important factors • Trust in organisations involved • Protection of public health is clear • The ‘Yuck factor’ • Participation in planning • Timing of information • Religion? • Prior knowledge and understanding of urban water cycles • But some interesting recent research on DPR • Context and language • Effect of Prior Knowledge of Unplanned Potable Reuse on the Acceptance of Planned Potable Reuse

  16. Report findings • DPR can safely supply drinking water directly into the water distribution system, but needs to be designed correctly and operated effectively with appropriate oversight. • Current Australian regulatory arrangements can already accommodate soundly designed and operated DPR systems. • Australian Guidelines for Water Recycling provide an appropriate framework for managing community safety and for guiding responsible decision-making. • High levels of expertise and workforce training within the Australian water industry are critical. • These must be supported by mechanisms to ensure provider compliance with requirements to use appropriately skilled operators and managers in their water treatment facilities. • Planning, decision-making and post-implementation management processes should acknowledge and respond to community concerns. • Public access to information and decision-making processes needs to be facilitated.

  17. Report findings (cont). • The relative merits of water supply options should be based on quantifiableor evidence-based factors • Public safety, cost, GHG emissions and other environmental impacts, as well as public attitudes. • There is little value in distinguishing DPR from other water supply options, unless specific proposals are compared using these criteria. • ATSE considers there can be considerable environmental, economic, and community benefits of DPR in suitable circumstances. • ATSE concludes that DPR should be considered on its merits –among the range of available water supply options for Australian towns and cities. • Governments, community leaders, water utilities, scientists, engineers and other experts will need to take leadership roles to foster the implementation and acceptance of any DPR proposal in Australia.

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