Improving cathode cleaning and current efficiency by regulating loose scale deposition in scale inhibitor-containing water

[Display omitted] •Forming loose scale in anti-scale water and its promotion on descaling were studied.•High driving force at high current or low flow velocity induces loose deposits.•Loose scale acts as seeds promotes crystallization and enhances current efficiency.•Pre-deposition of fragile scale...

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Published in:Separation and purification technology 2023-10, Vol.323, p.124494, Article 124494
Main Authors: Zhu, Tianzhen, Wang, Meng, Yu, Deze, Wang, Ximin, He, Aizhen, Yao, Guangyuan, Xie, Chenxin, Tao, Lei, Guo, Zongbin, Xiao, Liguang, Chen, Jianxin
Format: Article
Language:English
Subjects:
Cleaning efficiency
Current efficiency
Interface electrochemistry
Loose scale deposition
Scale inhibitor
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Summary:[Display omitted] •Forming loose scale in anti-scale water and its promotion on descaling were studied.•High driving force at high current or low flow velocity induces loose deposits.•Loose scale acts as seeds promotes crystallization and enhances current efficiency.•Pre-deposition of fragile scale layer facilitates the cleaning of cathode. For electrochemical water softening in practical water containing scale inhibitor, unsatisfactory cathodic cleaning and low hardness removal effect greatly limit its wide large-scale application. An effective improvement is not only dependent on the performance of external mechanical cleaning, but also closely related to the scale structure itself. In this work, the deposition of loose scale layer in the presence of scale inhibitor and its promotion on current efficiency and cathode cleaning efficiency were investigated from interfacial electrochemical perspective. Results reveal that such scale formation is attributed to the relatively high enrichment degree of scaling ions at cathode-water interface. At a high current density or low flow velocity, a relatively high interfacial pH is obtained and the thickness of this alkaline interface is larger than that at lower current density or higher flow velocity. This leads to the increase of CO32− generated by the reaction of HCO3− with more OH−. Besides, due to the weak chelation ability of the scale inhibitor at the alkaline interface, more Ca2+ are released and interact with cathodically formed CO32–. Corresponding scaling driving force is higher than that at lower current density or higher flow velocity. This leads to the deposition of loose scale layer with less stable morphology and a higher specific surface area. This as-deposited scale layer not only acting as seeds accelerates the crystallization and enhances the current efficiency, but also acting as an fragile pre-deposition layer facilitates the cleaning of cathode and produces the highest cleaning efficiency over 95%. This is beneficial for the stable operation of hardness removal device.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2023.124494