References

  1. J. Schewe, J. Heinke, D. Gerten, I. Haddeland, N.W. Arnell, D.B. Clark, R. Dankers, S. Eisner, B.M. Fekete, F.J. Colon-Gonzalez, S.N. Gosling, H. Kim, X. Liu, Y. Masaki, F.T. Portmann, Y. Satoh, T. Stacke, Q. Tang, Y. Wada, D. Wisser, T. Albrecht, K. Frieler, F. Piontek, L. Wars-zawski, P. Kabat, Multimodel assessment of water scarcity under climate change, Proc. Natl. Acad. Sci. U.S.A., 111 (2014) 3245–3250.
  2. H. Shemer, R. Semiat, Sustainable RO desalination - energy demand and environmental impact, Desalination, 424 (2017) 10–16.
  3. A.D. Khawaji, I.K. Kutubkhanah, J.M. Wie, Advances in seawater desalination technologies, Desalination, 221 (2008) 47–69.
  4. N. Liu, Z. Liu, Y. Li, L. Sang, Studies on leakage characteristics and efficiency of a fully-rotary valve energy recovery device by CFD simulation, Desalination, 415 (2017) 40–48.
  5. T.A. El-Sayed, A.A. Abdel Fatah, Performance of hydraulic turbocharger integrated with hydraulic energy management in SWRO desalination plants, Desalination, 379 (2016) 85–92.
  6. N. Melián-Martel, J.J. Sadhwani Alonso, S.O. Pérez Báez, Reuse and management of brine in sustainable SWRO desalination plants, Desal. Wat. Treat., 51 (2013) 560–566.
  7. A.S. Stillwell, M.E. Webber, Predicting the specific energy consumption of reverse osmosis desalination, Water, 8 (2016) 601.
  8. E.S. Mohamed, G. Papadakis, E. Mathioulakis, V. Belessiotis, An experimental comparative study of the technical and economic performance of a small reverse osmosis desalination system equipped with an hydraulic energy recovery unit, Desalination, 194 (2006) 239–250.
  9. V.G. Gude, Energy consumption and recovery in reverse osmosis, Desal. Wat. Treat., 36 (2011) 239–260.
  10. Danfoss, Energy Recovery Devices for Reverse Osmosis Applications, Available at: https://www.danfoss.com/en/products/energy-recovery-devices/dcs/energy-recovery-devices-forreverse- osmosis-applications/#/ (Accessed 18 March 2019).
  11. M. Thomson, D. Infield, Laboratory demonstration of a photovoltaic-powered seawater reverse-osmosis system without batteries, Desalination, 183 (2005) 105–111.
  12. M. Thomson, M.S. Miranda, D. Infield, A small-scale seawater reverse-osmosis system with excellent energy efficiency over a wide operating range, Desalination, 153 (2003) 229–236.
  13. V. Pikalov, S. Arrieta, A.T. Jones, J. Mamo, Demonstration of an energy recovery device well suited for modular communitybased seawater desalination systems: result of Danfoss iSAVE 21 testing, Desal. Wat. Treat., 51 (2013) 4694–4698.
  14. E.S. Mohamed, G. Papadakis, E. Mathioulakis, V. Belessiotis, The effect of hydraulic energy recovery in a small sea water reverse osmosis desalination system; experimental and economical evaluation, Desalination, 184 (2005) 241–246.
  15. B. Schneider, Selection, operation and control of a work exchanger energy recovery system based on the Singapore project, Desalination, 184 (2005) 197–210.
  16. M.J. Guirguis, Energy Recovery Devices in Seawater Reverse Osmosis Desalination Plants with Emphasis on Efficiency and Economical Analysis of Isobaric versus Centrifugal Devices, University of South Florida, 2011.
  17. B. Schneider, Design Enhancements, IDA World Congress/Perth Convention and Exhibition Centre (PCEC), 2011.
  18. S. Mirza, Reduction of energy consumption in process plants using nanofiltration and reverse osmosis, Desalination, 224 (2008) 132–142.
  19. S. Bross, W. Kochanowski, SWRO core hydraulic module – the right concept decides in terms of energy consumption and reliability Part II. Advanced pressure exchanger design, Desalination, 165 (2004) 351–361.
  20. S. Bross, W. Kochanowski, SWRO core hydraulic system: Extension of the SalTec DT to higher flows and lower energy consumption, Desalination, 203 (2007) 160–167.
  21. Z. Wang, Y. Wang, Y. Zhang, B. Qi, S. Xu, S. Wang, Pilot tests of fluid-switcher energy recovery device for seawater reverse osmosis desalination system, Desal. Wat. Treat., 48 (2012) 310–314.
  22. D. Song, Y. Wang, S. Xu, Z. Wang, H. Liu, S. Wang, Control logic and strategy for emergency condition of piston type energy recovery device, Desalination, 348 (2014) 1–7.
  23. D. Song, Y. Wang, N. Lu, H. Liu, E. Xu, S. Xu, Development and stand tests of reciprocating-switcher energy recovery device for SWRO desalination system, Desal. Wat. Treat., 54 (2015) 1519–1525.
  24. D. Song, Y. Wang, S. Xu, J. Gao, Y. Ren, S. Wang, Analysis, experiment and application of a power-saving actuator applied in the piston type energy recovery device, Desalination, 361 (2015) 65–71.
  25. J.J. Kolle, K. Theimer, T. Theimer, R. Cox, S.R. Scherschel, Coiled Tubing Jet Drilling with a Downhole Pressure Intensifier, SPE/ ICoTA Coiled Tubing and Well Intervention Conference and Exhibition, Woodlands, Texas, USA, 2008.
  26. J. Zhou, Y. Wang, Y. Duan, J. Tian, S. Xu, Capacity flexibility evaluation of a reciprocating-switcher energy recovery device for SWRO desalination system, Desalination, 416 (2017) 45–53.
  27. D. Michas, Design of an Energy Recovery Concept for a Smallscale Renewable-driven Reverse Osmosis Desalination System, Delft University of Technology, 2013.
  28. Wikipedia, Purified Water, Available at: https://en.wikipedia. org/wiki/Purified_water (Accessed 18 March 2019).
  29. Wikipedia, Conductivity (Electrolytic), Available at: https://en.wikipedia.org/wiki/Conductivity_(electrolytic) (Accessed 18 March 2019).
  30. A.S. Bermude, An Energy Recovery Device for Small-Scale Seawater Reverse Osmosis Desalination, Loughborough University, 2010.