Voltage control for membrane capacitive de-ionization cell for higher energy efficiency in salt removal

Alaa Ghamrawi, Maarouf Saad, Imad Mougharbel
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引用次数: 1

Abstract

Membrane Capacitive DeIonization (MCDI) cells have proven to be advantageous in water desalination and ions removal. Therefore, the time has come to introduce an alternative water purification technique to reduce the global water shortage. MCDI is known to be environmentally friendly, energy efficient and economical. Besides its reduced energy footprint, recent applications underline the regenerated energy during the desorption phase, which makes the MCDI as a potential cleaner energy source. Thus, a large number of scientific publications addressing problems and enhancing the performance of an MCDI have been published. In this paper, we have developed a simple and inexpensive method to control the adsorption voltage of the cells. So, the ion adsorption/desorption mechanisms of the MCDI will be controlled by a variable charging voltage applied to the cell.The entire response of controlled MCDI integrated model was created and he simulated results were compared with the experimental ones in order to validate the results. Accordingly, the controller parameters were tuned using the genetic algorithm optimization technique, based on the integral time absolute error criterion. Furthermore, the experimental results reveal that the control of the cell had increased the salt retention by 50%, the quantity of removed salt by the energy unit was improved by 10%, and the cell energy ratio from 28% to 32%.

提高除盐能效的膜电容式电离室电压控制
膜电容去电离(MCDI)电池已被证明在海水淡化和离子去除方面是有利的。因此,现在是时候引入一种替代性的水净化技术来减少全球水资源短缺了。众所周知,MCDI是环保、节能和经济的。除了减少能源足迹外,最近的应用强调了解吸阶段的再生能源,这使MCDI成为一种潜在的清洁能源。因此,已经出版了大量关于解决问题和提高MCDI性能的科学出版物。在本文中,我们开发了一种简单而廉价的方法来控制电池的吸附电压。因此,MCDI的离子吸附/解吸机制将由施加到电池的可变充电电压来控制。建立了受控MCDI集成模型的整体响应,并将模拟结果与实验结果进行了比较,以验证结果。因此,基于积分时间绝对误差准则,使用遗传算法优化技术对控制器参数进行了调整。此外,实验结果表明,对细胞的控制使盐保留率提高了50%,能量单元的除盐量提高了10%,细胞能量比从28%提高到32%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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