In recent years, more efforts have been made to improve new and more efficient nonmembrane-based methods for water desalination. Capacitive deionization (CDI), a novel technique for water desalination using an electric field to adsorb ions from a solution to a high-porous media, has the capability to recover a fraction of the energy consumed for the desalination during the regeneration process, which happens to be its most prominent characteristic among other desalination methods. This paper introduces a new desalination method that aims at improving the performance of traditional CDI systems. The proposed process consists of an array of CDI cells connected in series with buffer containers in between them. Each buffer serves two purposes: (1) averaging the outlet solution from the preceding cell and (2) securing a continuous water supply to the following cell. Initial evaluation of the proposed CDI system architecture was made by comparing a two-cell-one-buffer assembly with a two cascaded cells array. Concentration of the intermediate solution buffer was the minimum averaged concentration attained at the outlet of the first CDI cell, under a steady-state condition. The obtained results show that the proposed CDI system with intermediate solution had better performance in terms of desalination percentage. This publication opens new opportunities to improve the performance of CDI systems and implement this technology on industrial applications.
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Performance Characterization of a Capacitive Deionization Water Desalination System With an Intermediate Solution and Low Salinity Water
Yasamin Salamat,
Yasamin Salamat
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: s.salamat@neu.edu
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: s.salamat@neu.edu
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Carlos A. Rios Perez,
Carlos A. Rios Perez
Mem. ASME
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: c.riosperez@neu.edu
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: c.riosperez@neu.edu
Search for other works by this author on:
Carlos Hidrovo
Carlos Hidrovo
Mem. ASME
Mechanical and Industrial Engineering Department,
Northeastern University,
207 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: hidrovo@neu.edu
Mechanical and Industrial Engineering Department,
Northeastern University,
207 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: hidrovo@neu.edu
Search for other works by this author on:
Yasamin Salamat
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: s.salamat@neu.edu
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: s.salamat@neu.edu
Carlos A. Rios Perez
Mem. ASME
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: c.riosperez@neu.edu
Mechanical and Industrial Engineering Department,
Northeastern University,
334 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: c.riosperez@neu.edu
Carlos Hidrovo
Mem. ASME
Mechanical and Industrial Engineering Department,
Northeastern University,
207 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: hidrovo@neu.edu
Mechanical and Industrial Engineering Department,
Northeastern University,
207 Snell Engineering Center,
360 Huntington Avenue,
Boston, MA 02115
e-mail: hidrovo@neu.edu
1Corresponding author.
Contributed by the Advanced Energy Systems Division of ASME for publication in the JOURNAL OF ENERGY RESOURCES TECHNOLOGY. Manuscript received December 18, 2015; final manuscript received December 23, 2015; published online January 18, 2016. Editor: Hameed Metghalchi.
J. Energy Resour. Technol. May 2016, 138(3): 032003 (5 pages)
Published Online: January 18, 2016
Article history
Received:
December 18, 2015
Revised:
December 23, 2015
Citation
Salamat, Y., Rios Perez, C. A., and Hidrovo, C. (January 18, 2016). "Performance Characterization of a Capacitive Deionization Water Desalination System With an Intermediate Solution and Low Salinity Water." ASME. J. Energy Resour. Technol. May 2016; 138(3): 032003. https://doi.org/10.1115/1.4032427
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