References

  1. S. Sadri, M. Ameri, R.H. Khoshkhoo, Multi-objective optimization of MED-TVC-RO hybrid desalination system based on the irreversibility concept, Desalination, 402 (2017) 97–108.
  2. I.S. Al-Mutaz, I. Wazeer, Optimization of location of thermocompressor suction in MED-TVC desalination plants, Desal. Wat. Treat., 57 (2016) 26562–26576.
  3. A. Almutairi, P. Pilidis, N. Al-Mutawa, M. Al-Weshahi, Energetic and exergetic analysis of cogeneration power combined cycle and ME-TVC-MED water desalination plant: Part-1 operation and performance, Appl. Therm. Eng., 103 (2016) 77–91.
  4. K.M. Bataineh, Multi-effect desalination plant combined with thermal compressor driven by steam generated by solar energy, Desalination, 385 (2016) 39–52.
  5. B. Ortega-Delgado, P. Palenzuela, D.C. Alarón-Padilla, Parametric study of a multi-effect distillation plant with thermal vapor compression for its integration into a Rankine cycle power block, Desalination, 394 (2016) 18–29.
  6. S. Azimibavil, A.J. Dehkordi, Dynamic simulation of a multieffect distillation (MED) process, Desalination, 392 (2016) 91–101.
  7. A. Al Ghamdi, I. Mustafa, Exergy analysis of a MSF desalination plant in Yanbu, Saudi Arabia, Desalination, 399 (2016) 148–158.
  8. Y. Ghalavand, M.S. Hatamipour, A. Rahimi, Performance evaluation of humidification-compression desalination, Desal. Wat. Treat., 57 (2015) 15285–15292.
  9. M.T. Mazini, A. Yazdizadeh, M.H. Ramezani, Dynamic modeling of multi-effect desalination with thermal vapor compressor plant, Desalination, 353 (2014) 98–108.
  10. I.S. Al-Mutaz, I. Wazeer, Comparative performance evaluation of conventional multi-effect evaporation desalination processes, Appl. Therm. Eng., 73 (2014) 1194–1203.
  11. O. Samaké, N. Galanis, M. Sorin, Thermodynamic study of multi-effect thermal vapour-compression desalination systems, Energy, 72 (2014) 69–72.
  12. I.S. Al-Mutaz, I. Wazeer, Development of a steady-state mathematical model for MEE-TVC desalination plants, Desalination, 351 (2014) 9–18.
  13. B. Han, Z. Liu, H. Wu, Y. Li, Experimental study on a new method for improving the performance of thermal vapor compressors for multi-effect distillation desalination systems, Desalination, 344 (2014) 391–395.
  14. Y.D. Kim, K. Thu, A. Myat, K. Choon Ng, Numerical simulation of solar-assisted multi-effect distillation (SMED) desalination systems, Desal. Wat. Treat., 51 (2012) 1242–1253
  15. F. Hafdhi, T. Khir, A.B. Yahyia, A.B. Brahim, Energetic and exergetic analysis of a steam turbine power plant in an existing phosphoric acid factory, Energy Convers. Manage., 106 (2015) 1230–1241.
  16. G. Tsatsaronis, Definitions and nomenclature in exergy analysis and exergoeconomics, Energy, 32 (2007) 249–253.
  17. N. Shokati, F. Ranjbar, M. Yari, A comparative analysis of Rankine and absorption power cycles from exergoeconomic viewpoint, Energy Convers. Manage., 88 (2014) 657–668.
  18. H.T. El-Dessouky, H.M. Ettouney, Fundamentals of Salt Water, Desalination, Elsevier, Printed in the Netherlands, 2002.
  19. S.E. Shakib, M. Amidpour, C. Aghanajafi, Simulation and optimization of multi-effect desalination coupled to a gas turbine plant with HRSG consideration, Desalination, 285 (2012) 366–376.
  20. A.S. Nafey, H.E.S. Fath, A.A. Mabrouk, Thermoeconomic design of a multi-effect evaporation mechanical vapor compression (MEE-MVC) desalination process, Desalination, 230 (2008) 1–15.
  21. Entropie Corporation Catalog ENTC 2600, N/R A264/99393/DR, 09, 2000, p. 06.
  22. F.N. Alasfour, M.A. Darwish, A.O.B. Amer, Thermal analysis of ME-TVC+MEE desalination systems, Desalination, 174 (2005) 39–61.
  23. A.S. Nafey, H.E.S. Fath, A.A. Mabrouk, Exergy and thermoeconomic evaluation of MSF process using a new visual package, Desalination, 201 (2006) 224–240.