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Issue
Korean Journal of Chemical Engineering,
Vol.31, No.1, 155-161, 2014
Utilization of solar energy for direct contact membrane distillation process: An experimental study for desalination of real seawater
Palanisami N, He K, Moon IS
Membrane distillation (MD), a non-isothermal membrane separation process, is based on the phenomenon that pure water in its vapor state can be extracted from aqueous solutions by passing vapor through a hydrophobic microporous membrane when a temperature difference is established across it. We used three commercially available hydrophobic microporous membranes (C02, C07 and C12; based on the pore size 0.2, 0.7 and 1.2 μm respectively) for desalination via direct contact MD (DCMD). The effects of operating parameters on permeation flux were studied. In addition, the desalination of seawater by solar assisted DCMD process was experimentally investigated. First, using solar power only short-term (one day), successful desalination of real seawater was achieved without temperature control under the following conditions: feed inlet temperature 65.0 ℃, permeate inlet temperature 25.0 ℃, and a flow rate of 2.5 L/min. The developed system also worked well in the long-term (150 days) for seawater desalination using both solar and electric power. Long-term test flux was reduced from 28.48 to only 26.50 L/m2hr, indicating system feasibility.
Keywords: Direct Contact Membrane Distillation; Solar Energy; Permeation Flux; Salt Rejection
[References]
  1. Ettouney HM, El-Dessouky HT, Faibish RS, Gowin PJ, Chem. Eng. Progr., 98, 32, 2002
  2. Kerr RA, Science, 281(5380), 1128, 1998
  3. Thomson M, Miranda MS, Infield D, Desalination., 153, 229, 2002
  4. Ortiz JM, Exposito E, Gallud F, Garcia-Garcia V, Montiel V, Aldaz A, J. Membr. Sci., 274(1-2), 138, 2006
  5. Banat F, Jwaied N, Desalination, 230(1-3), 27, 2008
  6. Koschikowski J, Wieghaus M, Rommel M, Ortin VS, Suarez BP, Rodriguez JRB, Desalination, 248(1-3), 125, 2009
  7. Fath HES, Desalination, 116(1), 45, 1998
  8. Mulder M, Basic principles of membrane technology, 2nd Ed., Kluwer Academic Publishers, Netherlands, 1996
  9. Imdakm AO, Matsuura T, J. Membr. Sci., 262(1-2), 117, 2005
  10. Greenlee LF, Lawler DF, Freeman BD, Marrot B, Moulin P, Water Res., 43, 2317, 2009
  11. Calabro V, Jiao BL, Drioli E, Ind. Eng. Chem. Res., 33(7), 1803, 1994
  12. Cath TY, Adams VD, Childress AE, J. Membr. Sci., 228(1), 5, 2004
  13. Lawson KW, Lloyd DR, J. Membr. Sci., 124(1), 1, 1997
  14. Li B, Sirkar KK, Ind. Eng. Chem. Res., 43(17), 5300, 2004
  15. El-Bourawi MS, Ding Z, Ma R, Khayet M, J. Membr. Sci., 285(1-2), 4, 2006
  16. Banat FA, Simandl J, Sep. Sci. Technol., 33(2), 201, 1998
  17. Charcosset C, Desalination, 245(1-3), 214, 2009
  18. Burgoyne A, Vahdati MM, Sep. Sci. Technol., 35(8), 1257, 2000
  19. Alklaibi AM, Lior N, Desalination., 171, 111, 2004
  20. Zhu B, Kim JH, Na YH, Moon IS, Connor G, Maeda S, Morris G, Gray S, Duke M, Membranes., 3, 155, 2013
  21. Zhang J, Gray S, Li JD, Desalination., 323, 142, 2013
  22. Yoo CK, Kim DS, Cho JH, Choi SW, Lee IB, Korean J. Chem. Eng., 18(4), 408, 2001
  23. Hwang ST, Korean J. Chem. Eng., 28(1), 1, 2011
  24. Manickam M, Kwon TO, Kim JW, Duke M, Gray S, Moon IS, Desalination Water Treat., 13, 362, 2010
  25. He K, Hwang HJ, Moon IS, Korean J. Chem. Eng., 28(3), 770, 2011
  26. He K, Hwang HJ, Woo MW, Moon IS, J. Ind. Eng. Chem., 17(1), 41, 2011
  27. Hwang HJ, He K, Gray S, Zhang JH, Moon IS, J. Membr. Sci., 371(1-2), 90, 2011
  28. Curcio E, Drioli E, Sep. Purif. Rev., 34, 35, 2005
  29. Al-Obaidani S, Curcio E, Macedonio F, Di Profio G, Ai-Hinai H, Drioli E, J. Membr. Sci., 323(1), 85, 2008
  30. Gryta M, Tomaszewska M, J. Membr. Sci., 144(1-2), 211, 1998
  31. Kalogirou SA, Prog. Energy Combust. Sci., 30, 231, 2004
  32. Khayet M, Godino MP, Mengual JI, Int. J. Nuclear Desalination., 1, 30, 2003
  33. Martinez-Diez L, Florido-Diaz FJ, Vazquez-Gonzalez MI, Desalination, 126(1-3), 193, 1999
  34. Avlonitis SA, Kouroumbas K, Vlachakis N, Desalination, 157(1-3), 151, 2003
  35. Camacho LM, Dumee L, Zhang J, Li JD, Duke M, Gomez J, Gray S, Water., 5, 94, 2013
  36. Lawson KW, Lloyd DR, J. Membr. Sci., 124(1), 1, 1997
  37. Banat F, Jumah R, Garaibeh M, Renew. Energy., 25, 293, 2002
  38. Hogan PA, Sudjito FAG, Morrison GL, Desalination., 81, 81, 1991
  39. Chen TC, Ho CD, J. Membr. Sci., 358(1-2), 122, 2010
  40. Galvez JB, Garcia-Rodriguez L, Martin-Mateos I, Desalination, 246(1-3), 567, 2009
  41. Jonsson AS, Wimmerstedt R, Harrysson AC, Desalination., 56, 237, 1985
  42. Liu GL, Zhu C, Cheung CS, Leung CW, Heat Mass Transfer., 34, 329, 1998
  43. Abu Al-Rub FA, Banat F, Bani-Melhem K, Sep. Sci. Technol., 38(15), 3645, 2003
  44. Shirazi MMA, Kargari A, Javad M, Shirazi A, Desalination Water Treat., 49, 368, 2012
  45. Khayet M, Adv. Colloid Interface Sci., 164, 56, 2011
  46. Alklaibi AM, Lior N, Desalination., 171, 111, 2004
  47. Drioli E, Calabrd V, Wu Y, Pure Appl. Chem., 58, 1657, 1986
  48. Saffarini RB, Summers EK, Arafat HA, Lienhard JH, Desalination., 286, 332, 2012
  49. Kang JD, Heack KY, J. Korean Sol. Energy Soc., 27, 11, 2007
[Cited By]
  1. Jang DJ, Kim YH, Korean Journal of Chemical Engineering, 32(11), 2181, 2015
  2. Esfahani IJ, Rashidi J, Ifaei P, Yoo CK, Korean Journal of Chemical Engineering, 33(2), 351, 2016
  3. Moradi R, Monfared SM, Amini Y, Dastbaz A, Korean Journal of Chemical Engineering, 33(7), 2160, 2016
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