Improvement in the desalination performance of membrane capacitive deionization with a bipolar electrode via an energy recovery process

[Display omitted] •Energy stored in bipolar MCDI is recovered via direct connection manner.•Direct connection of two bipolar MCDI induce their partial adsorption and desorption.•By using this phenomenon, operation with direct connection reduced energy up to 47%•Appropriate time combination can reduc...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2022-07, Vol.439, p.135603, Article 135603
Main Authors: Jeon, Sung-il, Kim, Nayeong, Jo, Kyusik, Ahn, Jaewuk, Joo, Hwajoo, Lee, Changha, Kim, Choonsoo, Yoon, Jeyong
Format: Article
Language:English
Subjects:
And direct process to process
Bipolar system
Energy recovery
Membrane capacitive deionization
Water treatment
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Summary:[Display omitted] •Energy stored in bipolar MCDI is recovered via direct connection manner.•Direct connection of two bipolar MCDI induce their partial adsorption and desorption.•By using this phenomenon, operation with direct connection reduced energy up to 47%•Appropriate time combination can reduce energy with the same desalination performance. In the practical implementation of capacitive deionization (CDI), membrane CDI with a bipolar electrode (bipolar MCDI) is emerging as one of the alternative CDI platforms due to its favorable cell configuration for scale-up and low current originating from the serial connection of electrodes. Nevertheless, one obstacle to practical use is that there are few studies about the energy recovery process for the high energy efficiency of bipolar MCDI, requiring further research. Therefore, in this study, we propose a bipolar MCDI process with energy recovery and assess its potential by analysis of a lab-scale module with a single stack and nine stacks of the bipolar electrode (i.e., 2.4 V and 12 V system, respectively) and a pilot-scale module with 250 stacks (i.e., 300 V system). As a result, the energy consumption of the bipolar MCDI systems was reduced by 43% and 41% in the lab-scale modules with 2.4 V and 12 V systems, respectively, via energy recovery. Furthermore, the energy recovery led to a 40% reduction in the energy consumption of bipolar MCDI, even in the pilot-scale modules of the 300 V system. The results suggest that energy recovery in bipolar MCDI can be one of the essential processes and it has a strong potential for implementation in real industrial and environmental applications.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2022.135603