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Energy efficiency of membrane distillation up to high salinity: Evaluating critical system size and optimal membrane thickness

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  • Swaminathan, Jaichander
  • Chung, Hyung Won
  • Warsinger, David M.
  • Lienhard V, John H.

Abstract

This study presents a comprehensive analytical framework to design efficient single-stage membrane distillation (MD) systems for the desalination of feed streams up to high salinity. MD performance is quantified in terms of energy efficiency (represented as a gained output ratio, or GOR) and vapor flux, both of which together affect the specific cost of pure water production. Irrespective of the feed salinity, permeate or conductive gap MD (P/CGMD) perform better than direct contact MD (DCMD) when the heat transfer resistance of the gap (in P/CGMD) is lower than that of the external heat exchanger in DCMD. Air gap MD’s (AGMD) better performance relative to the other configurations at high salinity and large system area can be explained in terms of its thicker ‘effective membrane’, which includes the air-gap region. CGMD and DCMD employing a thick membrane are also resilient to high salinity, similar to AGMD, while not being susceptible to the gap flooding that can harm AGMD’s performance. A method is described to simultaneously determine the cost-optimal membrane thickness and system size as a function of the ratio of specific costs of heat energy and module area. At low salinity and small system size, GOR rises and flux declines with an increase in membrane area. For salty feed solutions, there exists a critical system size beyond which GOR also begins to decline. Since both GOR and flux are lower, no economic rationale favors operation above this critical size, irrespective of the costs of thermal energy and system area. A closed-form analytical expression for this critical system area is derived as a function of the feed salinity and two dimensionless ratios of heat transfer resistances within the MD module.

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  • Swaminathan, Jaichander & Chung, Hyung Won & Warsinger, David M. & Lienhard V, John H., 2018. "Energy efficiency of membrane distillation up to high salinity: Evaluating critical system size and optimal membrane thickness," Applied Energy, Elsevier, vol. 211(C), pages 715-734.
    • Handle: RePEc:eee:appene:v:211:y:2018:i:c:p:715-734
    DOI: 10.1016/j.apenergy.2017.11.043
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    1. McGovern, Ronan K. & Thiel, Gregory P. & Prakash Narayan, G. & Zubair, Syed M. & Lienhard, John H., 2013. "Performance limits of zero and single extraction humidification-dehumidification desalination systems," Applied Energy, Elsevier, vol. 102(C), pages 1081-1090.
    2. Ghaffour, Noreddine & Lattemann, Sabine & Missimer, Thomas & Ng, Kim Choon & Sinha, Shahnawaz & Amy, Gary, 2014. "Renewable energy-driven innovative energy-efficient desalination technologies," Applied Energy, Elsevier, vol. 136(C), pages 1155-1165.
    3. Sarbatly, Rosalam & Chiam, Chel-Ken, 2013. "Evaluation of geothermal energy in desalination by vacuum membrane distillation," Applied Energy, Elsevier, vol. 112(C), pages 737-746.
    4. Baghbanzadeh, Mohammadali & Rana, Dipak & Lan, Christopher Q. & Matsuura, Takeshi, 2017. "Zero thermal input membrane distillation, a zero-waste and sustainable solution for freshwater shortage," Applied Energy, Elsevier, vol. 187(C), pages 910-928.
    5. Zaragoza, G. & Ruiz-Aguirre, A. & Guillén-Burrieza, E., 2014. "Efficiency in the use of solar thermal energy of small membrane desalination systems for decentralized water production," Applied Energy, Elsevier, vol. 130(C), pages 491-499.
    6. Swaminathan, Jaichander & Chung, Hyung Won & Warsinger, David M. & Lienhard V, John H., 2016. "Membrane distillation model based on heat exchanger theory and configuration comparison," Applied Energy, Elsevier, vol. 184(C), pages 491-505.
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