References

  1. New Seawater Plants Fuel, Third Year of Growth for Desalination Market, IDA Yearbook 2016–2017, 2016.
  2. K. Wangnick, IDA Worldwide Desalting Plants Inventory, Report No. 18, Wangnick Consulting, Gnarrenburg, 2004.
  3. I.G. Wenten, Khoiruddin, Reverse osmosis applications: prospect and challenges, Desalination, 391 (2016) 112–125.
  4. Z. Aihua, P. Christofides, Y. Cohen, Minimization of energy consumption for a two-pass membrane desalination: effect of energy recovery, membrane rejection and retentate recycling, J. Membr. Sci., 330 (2009) 126–137.
  5. M. Wilf, K. Klinko, Optimization of seawater RO system design, Desalination, 138 (2005) 299–306.
  6. M. Wilf, C. Bartels, Optimization of seawater RO system design, Desalination, 173 (2005) 1–12.
  7. S. Meyer-Steele, A.V. Gottberg, J.L. Talavera, Seawater Reverse Osmosis Plants in the Caribbean Recover Energy and Brine and Refuse Costs, GE Power and Water, Water and Process Technologies Technical Paper TP1029EN.doc, 2008.
  8. Dow Water and Process Solutions WAVE (Water Application Value Engine) https://www.dow.com/en-us/water-andprocessolutions/resources/design-software, Dow Chemicals website WAVE design software.
  9. A. Karameldin, RO System Design Rehabilitation. Part 1: Sizzling feed intake management, 9th International Water Technology Conference, IWTC9, Sharm El-Sheikh, Egypt, 2005.
  10. A. Farooque, A. Jamaluddin, A. Al-Reweli, P. Jalaluddin, A. Al-Marwani, A. Al-Mobayed, A. Qasim, Comparative Study of Various Energy Recovery Devices Used in SWRO Process, KSA, SWCC, Technical Report No. TR.3807/EVP 02005, 2004.
  11. V. Frenkel, Energy for Desalination: Are We Looking in the Right Place, The International Desalination Association World Congress on Desalination and Water Reuse, Tianjin, China, 2013.
  12. J.P. MacHarg, The evolution of SWRO energy recovery systems, Desal. Water Reuse, 11 (2001) 49–53.
  13. S. Abdul-Ghafour, Optimization of Reverse Osmosis Design, Master’s Thesis, Alexandria University, Egypt, 2009.
  14. L. Littrell, J. Pinto, Energy recovery in desalination: returning alternative water supplies to consideration, Florida Water Resour. J. (2015) 40–46.
  15. Energy Recovery Company, Desalination Products Catalog, May 2016 , http://www.energyrecovery.com/wpcontent/uploads/2014/12/0916_ER_desalProducts_brochure_interactive_v3.pdf.
  16. K. Moftah, Quick analysis of energy recovery in brackish water RO systems, Clearbakk Energy Services, Ltd, https://www.owwa.ca/wp-content/uploads/2014/06/6.-Energy-Recoveryin-RO-Systems-Technical-and-Economic-Analyses-Extended-Abstract.pdf.
  17. N. Voutchkov, Latest Developments in Pumps and Energy Recovery, AMTA/ADC Pre-Conference Workshop Desalination Technology Developments & Improvements, Austin, TX, 2009.
  18. T. Manth, M. Gabor, E. Oklejas, Minimizing RO energy consumption under variable conditions of operation, Desalination, 157 (2003) 9–21.
  19. B. Liberman, The Importance of Energy Recovery Devices in Reverse Osmosis Desalination, The Future of Desalination in Texas, Chap. 2b, Vol. 2, Technical Papers, Case Studies, and Desalination Technology Resources, Report 363, 2004.
  20. T. Qiu, P.A. Davies, Comparison of configurations for highrecovery inland desalination systems, Water, 4 (2012) 690–706.
  21. J. MacHarg, S. McClellan, Pressure exchanger helps reduce energy costs in brackish water RO system, J. AWWA, 96 (2004) 44–48.
  22. ROSA System Design Software ROSA 9.1 http://www.dow.com/en-us/water-and-process-solutions/resources/design-software/rosa-software, Dow Chemicals website ROSA 9.1 Design software.
  23. A. Contreras, An Energy Recovery Device for Small-Scale Seawater Reverse Osmosis Desalination, Ph.D. Thesis, Loughborough University, London, 2009.
  24. A. Zhu, Energy and Cost Optimization of Reverse Osmosis Desalination, Ph.D. Thesis, California University, LA, USA, 2012.