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Direct potable reuse--an untapped resource






Water and sewage works 127(11): 14

Direct potable reuse--an untapped resource



Accession: 015516857



Related references

Adelman, B., 2015: Concerns about direct potable reuse. Environmental Health Perspectives 123(6): A146-A146

Arnold, R.G.; Saez, A.E.; Snyder, S.; Maeng, S.Kyu.; Lee, C.; Woods, G.J.; Li, X.; Choi, H., 2013: Direct potable reuse of reclaimed wastewater: it is time for a rational discussion. Water shortage arising from rapid population growth and relocation has produced an unprecedented degree of stress on regional water resources. Engineered solutions to relieve water stress are frequently based on the use of water of impaired initia...

Cooper R.C.; Danielson R.E.; Olivieri A.W.; Eisenberg D.M.; Rudnicki R., 1989: Direct potable reuse of reclaimed wastewater preliminary results of a five year study. Abstracts of the Annual Meeting of the American Society for Microbiology 89: 333

Van-Rensburg, J.; Theron, S.; Hassett, A.; Van-Rossum, P., 1982: Organic micropollution of potable water supplies: indirect versus direct reuse. Water science and technology4(4-5): 365-380

Anonymous, 1982: Organic micro pollution of potable water supplies indirect vs direct reuse

Guo, T.; Englehardt, J.D., 2015: Principles for scaling of distributed direct potable water reuse systems: a modeling study. Scaling of direct potable water reuse (DPR) systems involves tradeoffs of treatment facility economy-of-scale, versus cost and energy of conveyance including energy for upgradient distribution of treated water, and retention of wastewater thermal...

Wu, T.; Englehardt, J.D., 2015: Peroxone mineralization of chemical oxygen demand for direct potable water reuse: Kinetics and process control. Mineralization of organics in secondary effluent by the peroxone process was studied at a direct potable water reuse research treatment system serving an occupied four-bedroom, four bath university residence hall apartment. Organic concentrations...

Barker, S.Fiona.; Packer, M.; Scales, P.J.; Gray, S.; Snape, I.; Hamilton, A.J., 2014: Pathogen reduction requirements for direct potable reuse in Antarctica: evaluating human health risks in small communities. Small, remote communities often have limited access to energy and water. Direct potable reuse of treated wastewater has recently gained attention as a potential solution for water-stressed regions, but requires further evaluation specific to small...

Linstedt, K.; Rothberg, M., 1982: Potable water reuse. Water reuse edited by E Joe Middlebrooks: 212

Rogers S.E.; Lauer W.C., 1986: Disinfection for potable reuse. Potable reuse requires a multiple barrier approach to control pathogens from a grossly contaminated source. The primary multiple pathogen barriers used at the Denver [Colorado, USA] Potable Water Reuse Demonstration Plant are excess lime treatment...