Wiegerinck Harm T M, Kersten Reinder, Wood Jeffery A
Soft Matter, Fluidics and Interfaces, MESA+ Institute for Nanotechnology, University of Twente, 7500AE Enschede, The Netherlands.
Ind Eng Chem Res. 2023 Feb 7;62(7):3294-3306. doi: 10.1021/acs.iecr.2c03874. eCollection 2023 Feb 22.
In order to understand the ion transport in a continuous cross-flow shock electrodialysis process better, numerous theoretical studies have been carried out. One major assumption involved in these models has been that of a constant surface charge. In this work, we considered the influence of charge regulation, caused by changes in salt concentration, on the performance of a shock electrodialysis cell. Our results show that, by including charge regulation, much higher potentials need to be applied to reach the same degree of desalination, compared to the constant surface charge model. Furthermore, we found that operating at higher potentials could lead to substantial Joule heating and therefore temperature increases. Although somewhat lower potentials were required in the nonisothermal case versus the isothermal case with charge regulation, the required energy input for desalination is still much higher than the thermodynamic minimum. This works highlights the important role charge regulation can play in a shock electrodialysis process.
为了更好地理解连续错流冲击电渗析过程中的离子传输,人们进行了大量的理论研究。这些模型所涉及的一个主要假设是表面电荷恒定。在这项工作中,我们考虑了由盐浓度变化引起的电荷调节对冲击电渗析池性能的影响。我们的结果表明,与表面电荷恒定模型相比,考虑电荷调节时,需要施加更高的电势才能达到相同的脱盐程度。此外,我们发现,在较高电势下运行会导致大量的焦耳热,从而使温度升高。尽管在非等温情况下与考虑电荷调节的等温情况下相比所需电势略低,但脱盐所需的能量输入仍远高于热力学最小值。这项工作突出了电荷调节在冲击电渗析过程中可能发挥的重要作用。