1. Y. Lu, Y.Y. Zhao, G.X. Bu, P.C. Shu, The integration of water vane pump and hydraulic vane motor for a small desalination system, Desalination, 276 (2011) 60–65.
  2. H.Y. Yang, M. Pan, Engineering research in fluid power: a review, J. Zhejiang Univ. Sci., A, 16 (6) (2015) 427–442.
  3. L.S. Drabløs, Testing of Danfoss APP1.0-2.2 with APP pumps as water hydraulic motors for energy recovery, Desalination, 183 (2005) 41–54.
  4. A. Farooque, A. Jamaluddin, A.R. Al-Reweli, P. Jalaluddin, S. Al-Marwani, A. Al-Mobayed, A. Qasim, Comparative study of various energy recovery devices used in swro process, Saline Water Desalination Research Institute, Saline Water Conversion Corporation (SWCC), 2004.
  5. N. Liu, Z.L. Liu, Y.X. Li, L.X. Sang, Studies on leakage characteristics and efficiency of a fully-rotary valve energy recovery device by CFD simulation, Desalination, 415 (2017) 40–48.
  6. N. Liu, Z.L. Liu, Y.X. Li, L.X. Sang, Development and experimental studies on a fully-rotary valve energy recovery device for SWRO desalination system, Desalination, 397 (2016) 67–74.
  7. F.H. Ye, J.Q. Deng, K. Liu, Z. Cao, Performance study of a rotary vane pressure exchanger for SWRO, Desal. Water Treat., 89 (2017) 36–46.
  8. I.B. Cameron, R.B. Clemente, SWRO with ERI’s PX pressure exchanger device - a global survey, Desalination, 221 (2008) 136–142.
  9. R.L. Stover, Seawater reverse osmosis with isobaric energy recovery devices, Desalination, 203 (2007) 168–175.
  10. Y. Zhou, X. Ding, M. Ju, Y. Chang, Numerical simulation on a dynamic mixing process in ducts of a rotary pressure exchanger for SWRO, Desal. Water Treat., 1 (2009) 107–113.
  11. Y. Liu, Y.H. Zhou, M.S. Bi, 3D numerical simulation on mixing process in ducts of rotary pressure exchanger, Desal. Water Treat., 42 (2012) 269–273.
  12. F. Zhao, Z.M. Feng, L. Jiao, C.J. Wu, Z.X. Zhang, C.P. Zhao, S.B. Yao, The analysis of pressure fluctuation frequency with rotor rotation speed in pressure exchanger, J. Eng. Therm., 35 (2014) 74–77.
  13. W.J. Yuan, J.Q. Deng, Z. Cao, Dynamic length research on the pulsating mixing of rotary pressure exchanger, J. Eng. Therm., 36 (2015) 766–769.
  14. Y. Wang, L.Y. Wu, B. Li, W.T. Zhang, Y.D. Hu, Numerical simulation and analysis of the mixing process of rotary pressure exchangers with different sizes and structures, J. Chem. Eng. Jpn., 49 (2016) 573–578.
  15. Z. Cao, J.Q. Deng, W.J. Yuan, Z.H. Chen, Integration of CFD and RTD analysis in flow pattern and mixing behavior of rotary pressure exchanger with extended angle, Desal. Water Treat., 57 (2016) 15265–15275.
  16. E. Xu, Y. Wang, L. Wu, S. Xu, Y. Wang, S. Wang, Computational fluid dynamics simulation of brine-seawater mixing in a rotary energy recovery device, Ind. Eng. Chem. Res., 53 (2014) 18304–18310.
  17. E. Xu, Y. Wang, J. Wu, S. Xu, S. Wang, Investigations on the applicability of hydrostatic bearing technology in a rotary energy recovery device through CFD simulation and validating experiment, Desalination, 383 (2016) 60–67.
  18. Y. Wang, Y.W. Duan, J. Zhou, S.C. Xu, S.C. Wang, Introducing pre-pressurization/depressurization grooves to diminish flow fluctuations of a rotary energy recovery device: Numerical simulation and validating experiment, Desalination, 413 (2017) 1–9.
  19. E. Xu, Y. Wang, J. Zhou, S.C. Xu, S.C. Wang, Theoretical investigations on rotor speed of the self-driven rotary energy recovery device through CFD simulation, Desalination, 398 (2016) 189–197.
  20. R.L. Stover, Development of a fourth generation energy recovery device. A ‘CTO’s notebook’, Desalination, 165 (2004) 313– 321.
  21. D.Z. Wu, J. Wu, F. Zhao, T.C. Miao, C.J. Wu, L.Q. Wang, The research on internal leakage and lubrication property of gap in rotary pressure exchanger, J. Chem. Eng. Chin. Univ., 28 (2014) 1204–1209.
  22. L.M. Wu, Y. Wang, E.L. Xu, J.N. Wu, S.C. Xu, Employing groove-textured surface to improve operational performance of rotary energy recovery device in membrane desalination system, Desalination, 369 (2015) 91–96.
  23. J.N. Wu, Q. Jin, Y. Wang, P. Tandon, Theoretical analysis and auxiliary experiment of the optimization of energy recovery efficiency of a rotary energy recovery device, Desalination, 415 (2017) 1–7.
  24. R.L. Stover, B. Andrews, Isobaric energy-recovery devices: past, present, and future, J. Water Reuse Desal., 4 (2012) 38–43.
  25. V. Pikalov, S. Arrieta, A.T. Jones, J.L. Mamo, Demonstration of an energy recovery device well suited for modular community- based seawater desalination systems: Result of Danfoss iSAVE 21 testing, Desal. Water Treat., 51(22–24) (2013) 4694– 4698.
  26. D.F. Wu, Y.S. Liu, D.L. Li, X.F. Zhao, C. Li, Effect of materials on the noise of a water hydraulic pump used in submersible, Ocean Eng., 131 (2017) 107–113.
  27. F.L. Yin, S.L. Nie, H. Ji, Y.Q. Huang, Non-probabilistic reliability analysis and design optimization for valve-port plate pair of seawater hydraulic pump for underwater apparatus, Ocean Eng., 163 (2018) 337–347.
  28. F.L. Yin, S.L. Nie, W. Hou, S.H. Xiao, Effect analysis of silencing grooves on pressure and vibration characteristics of seawater axial piston pump, P. I. Mech. Eng. C-J.Mec., 231 (8) (2017) 1390– 1409.
  29. J.M. Bergada, S. Kumar, D.L. Davies, J. Watton, A complete analysis of axial piston pump leakage and output flow ripples, Appl. Math Model., 36 (2012) 1731–1751.
  30. H. Ding, F.C. Visser, Y. Jiang, M. Furmanczyk, Demonstration and validation of a 3D CFD simulation tool predicting pump performance and cavitation for industrial applications, ASME J. Fluids Eng., 133 (2011) 011101.
  31. S.G. Ye, J.H. Zhang, B. Xu, W. Song, L. Chen, H.Y. Shi, S.Q. Zhu, Experimental and numerical studies on erosion damage in damping holes on the valve plate of an axial piston pump. J Mech Sci Technol., 31(2017) 4285–4295.
  32. N.D. Manring, Y.H. Zhang, The improved volumetric-efficiency of an axial piston pump utilizing a trapped-volume design, ASME J. Dyn. Syst., Meas., Control, 123 (2001) 479–487.