References

1. P. Asiedu-Boateng, S. Yamoah, F. Ameyaw, S. Dzide, K. Tuffour-Acheampong, Performance analysis of thermal vapour compression desalination system coupled to cogeneration nuclear power plant, Res. J. Appl. Sci. Eng. Technol., 4 (2012) 941–948.
2. S. Daneshmand, A. Mortaji, Z. Mortaji, Investigation and design seawater desalination with solar energy, Life Sci. J., 9 (2012) 770–773.
3. G. Fiorenza, V. Sharma, G. Braccio, Techno-economic evaluation of a solar powered water desalination plant, Energy Convers. Manage., 44 (2003) 2217–2240.
4. I.S. Al-Mutaz, I. Wazeer, Economic optimization of the number of effects for the multieffect desalination plant, Desal. Water Treat., 56 (2015) 2269–2275.
5. T. Mezher, H. Fath, Z. Abbas, A. Khaled, Techno-economic assessment and environmental impacts of desalination technologies, Desalination, 266 (2011) 263–273.
6. A. Alsairafi, I. Al-Shehaima, M. Darwish, Efficiency improvement and exergy destruction reduction by combining a power and a multi-effect boiling desalination plant, J. Eng. Res., 1 (2013) 289–315.
7. I.-S. Park, S.-M. Park, J.-S. Ha, Design and application of thermal vapor compressor for multi-effect desalination plant, Desalination, 182 (2005) 199–208.
8. H.M. Ettouney, H. El-Dessouky, A simulator for thermal desalination processes, Desalination, 125 (1999) 277–291.
9. P.A. Claisse, Transport Properties of Concrete: Measurements and Applications, Woodhead Publishing, Cambridge, 2014, pp. 1–16.
10. K.P. Lee, T.C. Arnot, D. Mattia, A review of reverse osmosis membrane materials for desalination—development to date and future potential, J. Membr. Sci., 370 (2011) 1–22.
11. N.M. Al-Bastaki, A. Abbas, Modeling an industrial reverse osmosis unit, Desalination, 126 (1999) 33–39.
12. T. Kaghazchi, M. Mehri, M.T. Ravanchi, A. Kargari, A mathematical modeling of two industrial seawater desalination plants in the Persian Gulf region, Desalination, 252 (2010) 135–142.
13. M.S. Atab, A. Smallbone, A. Roskilly, An operational and economic study of a reverse osmosis desalination system for potable water and land irrigation, Desalination, 397 (2016) 174–184.
14. M. Al-Sahali, S. Al-Qattan, Performance analysis of small capacity reverse osmosis desalination plants, Kuwait J. Sci. Eng., 39 (2012) 231–253.
15. K.A. Al-Shayji, Y. Liu, Predictive modeling of large-scale commercial water desalination plants: data-based neural network and model-based process simulation, Ind. Eng. Chem. Res., 41 (2002) 6460–6474.
16. A.M. Hassan, A. Abanmy, M. Al-Thobiety, T. Mani, T. Al-Luhibi, I. Al-Masudi, A.A. Al-Gherier, L. Bakheet, M.M. Amri, K. Atiya, Performance Evaluation of SWCC SWRO Plants Part II, in: Proceedings of IDA World Conference, International Desalination Association, Topsfield, MA, Washington, D.C., 1991, pp. 412−439.
17. O. Hamed, A. Moet, T. Abdelrahman, A. Zamamiri, Performance Analysis of Sea Water Reverse Osmosis Plants, in: IDA World Congress on “Desalination and Water Science” Abu Dhabi, 1995, pp. 13–23.
18. A.S. Al-Mobayed, F.M. Mubeen, S. Balaji, Comparison of the performance of hollow fine fiber and spiral-wound membranes in the Al-Jubail SWRO desalination plant, Desalination, 178 (2005) 273–286.
19. I.S. Al-Mutaz, B.A. Al-Sultan, Prediction performance of RO desalination plants, Desalination, 120 (1998) 153–160.
20. A. Jiang, Q. Ding, J. Wang, S. Jiangzhou, W. Cheng, C. Xing, Mathematical modeling and simulation of SWRO process based on simultaneous method, J. Appl. Math., 2014 (2014) 1–11.
21. M. Goosen, S. Sablani, M.D. Cin, M. Wilf, Effect of cyclic changes in temperature and pressure on permeation properties of composite polyamide seawater reverse osmosis membranes, Sep. Sci. Technol., 46 (2010) 14–26.
22. D. Ghernaout, Reverse osmosis process membranes modeling–a historical overview, J. Civil Construct. Environ. Eng. Civil, 2 (2017) 112–122.
23. T. Qiu, P. Davies, Concentration polarization model of spiralwound membrane modules with application to batch-mode RO desalination of brackish water, Desalination, 368 (2015) 36–47.
24. D.Y. Kim, M.H. Lee, B. Gu, J.H. Kim, S. Lee, D.R. Yang, Modeling of solute transport in multi-component solution for reverse osmosis membranes, Desal. Water Treat., 15 (2010) 20–28.
25. M. Khanarmuei, H. Ahmadisedigh, I. Ebrahimi, L. Gosselin, H. Mokhtari, Comparative design of plug and recirculation RO systems; thermoeconomic: case study, Energy, 121 (2017) 205–219.
26. J.G. Wijmans, R.W. Baker, The solution-diffusion model: a review, J. Membr. Sci., 107 (1995) 1–21.
27. S. Lee, R.M. Lueptow, Membrane rejection of nitrogen compounds, Environ. Sci. Technol., 35 (2001) 3008–3018.
28. R. Rautenbach, F. Helmus, Some considerations on masstransfer resistances in solution—diffusion-type membrane processes, J. Membr. Sci., 87 (1994) 171–180.
29. R.V. Linares, Z. Li, S. Sarp, S.S. Bucs, G. Amy, J.S. Vrouwenvelder, Forward osmosis niches in seawater desalination and wastewater reuse, Water Res., 66 (2014) 122–139.
30. G. Schock, A. Miquel, Mass transfer and pressure loss in spiral wound modules, Desalination, 64 (1987) 339–352.
31. M. Sekino, Performance data analysis for hollow-fiber reverseosmosis modules in seawater desalination plants, Kagaku kōgaku ronbunshū, 20 (1994) 574–579.
32. M. Taniguchi, S. Kimura, Estimation of transport parameters of RO membranes for seawater desalination, AIChE J., 46 (2000) 1967–1973.
33. M. Taniguchi, M. Kurihara, S. Kimura, Behavior of a reverse osmosis plant adopting a brine conversion two-stage process and its computer simulation, J. Membr. Sci., 183 (2001) 249–257.
34. C. Chen, H. Qin, A mathematical modeling of the reverse osmosis concentration process of a glucose solution, Processes, 7 (2019) 271.
35. J.A. Howell, V. Sanchez, R.W. Field, Membranes in Bioprocessing: Theory and Applications, Springer Netherlands, 2012, pp. 55–112.
36. H.T. El-Dessouky, H.M. Ettouney, Fundamentals of Salt Water Desalination, Elsevier Science, New York, 2002, pp. 409–437.
37. G. Amy, N. Ghaffour, Z. Li, L. Francis, R.V. Linares, T. Missimer, S. Lattemann, Membrane-based seawater desalination: present and future prospects, Desalination, 401 (2017) 16–21.
38. J. Kim, K. Park, D.R. Yang, S. Hong, A comprehensive review of energy consumption of seawater reverse osmosis desalination plants, Appl. Energy, 254 (2019) 113652.
39. J. Kim, K. Park, S. Hong, Optimization of two-stage seawater reverse osmosis membrane processes with practical design aspects for improving energy efficiency, J. Membr. Sci., 601 (2020) 117889.
40. A.H. Gulamhusein, A.S. Al Sheikh Khalil, I.A. Fatah, R. Boda, S. Rybar, IMS SWRO Kindasa—Two years of operational experience, Desal. Water Treat., 10 (2009) 245–254.
41. R. de Morales, Planta desaladora de agua de mar con capacidad para producir 60,000 m³/día de agua apta para riego, Infoenviro, (2016) 35–50.
42. S. Meyer-Steele, A. von Gottberg, J.L. Talavera, seawater reverse osmosis plants in the Caribbean recover energy and brine and reduce costs, (2005).
43. R. Lemes, R. Falcon, R. Arocha, J. Curbelo, V. Platas, L.D. Lorenzo, Different designs in energy savings of SWRO Plant of Las Palmas III, Desal. Water Treat., 51 (2013) 749–758.
44. T. Hamano, Operation of Fukuoka sea water desalination plant, Bull. Soc. Sea Water Sci. Jpn., 60 (2006) 415–421.
45. F. Rezazadeh, W.F. Gale, M. Akram, K.J. Hughes, M. Pourkashanian, Performance evaluation and optimisation of post combustion CO₂ capture processes for natural gas applications at pilot scale via a verified rate-based model, Int. J. Greenhouse Gas Control, 53 (2016) 243–253.
46. F. Mahmoudi, A. Akbarzadeh, Sustainable Desalination by Permeate Gap Membrane Distillation Technology, in: Emerging Technologies for Sustainable Desalination Handbook, Elsevier, Oxford, 2018, pp. 157–204.
47. A. Schäfer, A. Broeckmann, B. Richards, Membranes and renewable energy—a new era of sustainable development for developing countries, Membr. Technol., 2005 (2005) 6–10.
48. S. Sourirajan, The science of reverse osmosis-mechanisms, membranes, transport and applications, Pure Appl. Chem., 50 (1978) 593–615.
49. S. Sourirajan, The Science of Reverse Osmosis-Mechanisms, Membranes, Transport and Applications, in: Chemistry for the Welfare of Mankind, Elsevier, Great Britain, 1979, pp. 593–615.
50. Z. Triki, M. Bouaziz, M. Boumaza, Techno-economic feasibility of wind-powered reverse osmosis brackish water desalination systems in southern Algeria, Desal. Water Treat., 52 (2014) 1745–1760.