№9|2012

POWER RESOURCES CONSERVATION

bbk 000000

UDC 628.3:658.26.004.18

Kofman V. Ya.

Improving the operating efficiency of the wastewater treatment facilities overseas (review)

Summary

The review of power efficient technologies of wastewater treatment used at the wastewater treatment facilities overseas is presented.

Key words

, , , , , ,

The further text is accessible on a paid subscription.
For authorisation enter the login/password.
Or subscribe

SPISOK LITERATURY

  1. McCarty P. L., Bae J., Kim J. Domestic wastewater treatment as a net energy producer – Can this be achieved? // Environmental Science & Technology. 2011. № 45.
  2. Danilovich D. A. Energosberezhenie i al'ternativnaia energetika na ochistnykh sooruzheniiakh kanalizatsii // Vodosnabzhnenie i san. tekhnika. 2011. № 1.
  3. Strous M., van Gerven E., Zheng P., et al. Ammonium removal from concentrated waste streams with the anaerobic ammonium oxidation (Anammox) process in different reactor configurations // Water Research. 1997. № 31 (8).
  4. Curtis T. P. Low-energy wastewater treatment: strategies and technologies. Environmental Microbiology, 2nd edition. – Wiley-Blackwell: Hoboken, NJ, 2010.
  5. Speece R. E. Anaerobic biotechnology and odor/corrosion control. – Nashville, TN, Archae Press, 2008.
  6. Opportunities for and benefits of combined heat and power at wastewater treatment facilities, EPA-430-R-07-003; Washington DC, 2007.
  7. Kulkarni P. Combined heat and power potential at California's wastewater treatment plants. IERP Workshop. Sacramento, CA. July 23, 2009.
  8. Proizvodstvo biogaza. Omega Prom Grupp, 2012. http://omegaprom.com/ru/techs/techs6.
  9. Lindtrom H. O. Experiences with a 3,3 MW heat pump using sewage water as heat sources // Journal of Heat Recovery Systems. 1985. № 5 (1).
  10. Weirich S. R., Silverstein J., Rajagopalan B. Effect of everage flow and capacity utilization on effluent water quality from US minicipal wastewater treatment facilities // Water Research. 2011. № 45 (14).
  11. Barsan N., Nedeff V., Lazar G. Current stage of domestic wastewater treatment in small plants // Journal of Engineering Studies and Research. 2011. № 7 (4).
  12. Foresti E. Anaerobic treatment of domestic sewage: established technologies and perspectives // Water Science and Technology. 2002. № 45 (10).
  13. Parawira W. Anaerobic treatment of agricultual residues and wastewater. Application of high-rate reactors. – Lund University, 2004.
  14. Van Haandel A. C., Kato M. T., Cavalcanti P. F. F., Florencio L. Anaerobic reactor design concepts for the treatment of domestic wastewater // Reviews in Environmental Science and Biotechnology. 2006. № 5.
  15. Leitao R. C., Silva-Filho J. A., Sanders W., et al. The effect of operational conditions on the performance of UASB reactors for domestric wastewater treatment // Water Science & Technology. 2005. № 52 (1–2).
  16. Cherniharo C. A. L. Post-treatment options for the anaerobic treatment of domestic wastewater // Reviews in Environmental Science and Biotechnology. 2006. № 5.
  17. Foresti E., Zaiat M., Vallero M. V. G. Anaerobic processes as the core technology for sustainable domestic wastewater treatment: Consolidated applications, new trends, perspectives and challenges // Reviews in Environmental Science and Biotechnology. 2006. № 5.
  18. Hu A. Y., Stuckey D. C. Treatment of diluted wastewater using a novel submerged anaerobic membrane bioreactor // Journal of Environmental Engineering. 2006. № 132 (2).
  19. Berube P. R., Hall E. R., Sutton P. M. Parameters govering permeate flux in an anaerobic membrane bioreactor treating low-strength municipal wastewaters: A literature review // Water Environmental Research. 2006. № 78 (8).
  20. Kim J., Kim K., Ye H., et al. Anaerobic fluidized bed membrane bioreactor for wastewater treatment // Environmental Science & Technology. 2011. № 45.
  21. Pant D., van Bogaert G., Diels L., Vanbroekhoven K. A review of the substrates used in microbial fuel cells (MFC) for sustainable energy production // Bioresource Technology. 2010. № 101 (6).
  22. Das S., Mangwani N. Recent developments in microbial fuel cells: A review // Journal of Scientific & Industrial Research. 2010. № 69.
  23. Rozental R. A., Hamelers H. V. M., Rabaey K., Keller J., Buisman C. J. N. Towards practical implementation of bioelectrochemical wastewater treatment // Trends in Biotechnology. 2008. № 26 (8).
  24. Nevin K .P., Richter H., Covalla S. F., et al. Power output and Coulumbic efficiency from biofilms of Geobacter sulfurreducens comparable to mixed community microibial fuel cells // Environmental Microbiology. 2008. № 10.
  25. Wang Y.-K., Sheng G.-P., Li W.-W., et al. Development of a novel bioelectrochemical membrane reactor for wastewater treatment // Environmental Science and Technology. 2011. № 45 (21).
  26. Tender L. M., Gray S. M., Groveman E., et al. The first demonstration of a microbial fuel cell as a viable power supply: Powering a meteorological buoy // Journal of Power Sources. 2008. № 179.
  27. Lettinga G., van Velsen A. F. M., Hobma S.W., et al. Use of the up-flow sludge blanket (USB) concept for biological waste water treatment, speciality for anaerobic treatment // Biotechnology and Bioengineering, 1980. № 22.

Журнал ВСТ включен в новый перечень ВАК

Шлафман В. В. Проектирование под заданную ценность, или достижимая эффективность технических решений – что это?

Banner Kofman 1

Авторизация

Внимание! Рекомендуется просматривать сайт максимально свежими версиями браузеров. Устаревшие версии не смогут корректно скачать материалы номеров журнала.