References

  1. F. Mansour, S.Y. Alnouri, M. Al-Hindi, F. Azizi, P, Linke. Screening and cost assessment strategies for end-of-pipe zero liquid discharge systems, J. Cleaner Prod., 179 (2018) 460–477.
  2. Z. Liu, Y. Zhang, X. Lu, X. Wang, X. Zhao, Study of the bubble membrane crystallization process for zero-brine discharge, J. Membr. Sci., 563 (2018) 584–591.
  3. G.U. Semblante, J.Z. Lee, L.Y. Lee, S.L. Ong, H.Y. Ng, Brine pre-treatment technologies for zero liquid discharge systems, Desalination, 441 (2018) 96–111.
  4. B. Chen, C. Jiang, Y. Wang, R. Fu, Z. Liu, T. Xu, Selectrodialysis with bipolar membrane for the reclamation of concentrated brine from RO plant, Desalination, 442 (2018) 8–15.
  5. W.L. Luyben, Dynamic simulation of multi-effect evaporators, Chem. Eng. Process. - Process Intens., 131 (2018) 106–115.
  6. D. Han, Study on zero-emission desalination system based on mechanical vapor recompression technology, Energy Procedia, 75 (2015) 1436–1444.
  7. Z. Ye, Y. Hong, S. Pan, Z. Huang, S. Chen, W. Wang, Full-scale treatment of landfill leachate by using the mechanical vapor recompression combined with coagulation pretreatment, Waste Manage., 66 (2017) 88–96.
  8. Y.S. Jeong, J. Jung, U. Lee, C. Yang, Techno-economic analysis of mechanical vapor recompression for process integration of post-combustion CO2 capture with downstream compression, Chem. Eng. Res. Design, 104 (2015) 247–255.
  9. M.A. Jamil, S.M. Zubair, On thermoeconomic analysis of a single-effect mechanical vapor compression desalination system, Desalination, 420 (2017) 292–307.
  10. M.A. Jamil, S.M. Zubair, Design and analysis of a forward feed multi-effect mechanical vapor compression desalination system: an exergo-economic approach, Energy, 140 (2017) 1107–1120.
  11. M.L. Elsayed, O. Mesalhy, R.H. Mohammed, L.C. Chow, Transient and thermo-economic analysis of MED-MVC desalination system, Energy, 167 (2019) 283–296.
  12. M.L. Elsayed, O. Mesalhy, R.H. Mohammed, L.C. Chow, Performance modeling of MED-MVC systems: exergy-economic analysis, Energy, 166 (2019) 552–568.
  13. S. Ai, B. Wang, X. Li, Numerical analysis on the performance of mechanical vapor recompression system for strong sodium chloride solution enrichment, Appl. Thermal Eng., 137 (2018) 386–394.
  14. Y. Zhou, C. Shi, G. Dong, Analysis of a mechanical vapor recompression wastewater distillation system, Desalination, 353 (2014) 91–97.
  15. A. Karameldin, A. Lotfy. S. Mekhemar, The Red Sea area winddriven mechanical vapor compression desalination system, Desalination, 153 (2002) 47–53.
  16. A.M. Helal, S.A. Al-Malek, Design of a solar-assisted mechanical vapor compression (MVC) desalination unit for remote areas in the UAE, Desalination, 197 (2006) 273–300.
  17. D. Zejli, A. Ouammi, R. Sacile, H. Dagdougui, A. Elmidaoui, An optimization model for a mechanical vapor compression desalination plant driven by a wind/PV hybrid system, Appl. Energy, 88 (2011) 4042–4054.
  18. X. Gao, Q. Gu, J. Ma, Y. Zeng, MVR heat pump distillation coupled with ORC process for separating a benzene-toluene mixture, Energy, 143 (2018) 658–665.