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碳质微滤膜对小分子有机化合物基于臭氧氧化的催化效率及其在水溶液中的碱性缓冲作用

Catalytic Efficiency of Carbon-Cementitious Microfiltration Membrane on the Ozonation-Based Oxidation of Small Molecule Organic Compounds and Its Alkaline Buffering Effect in Aqueous Solution.

作者信息

Sun Jingyi, Chen Zhonglin, Liu Shan, Kang Jing, Guo Yuhao, Cai Liming, Shen Jimin, Wang Binyuan, Zhao Shengxin, Song Zilong

机构信息

State Key Laboratory of Urban Water Resource and Environment, School of Environment, Harbin Institute of Technology, Harbin 150090, China.

Beijing Key Lab for Source Control Technology of Water Pollution, College of Environmental Science and Engineering, Beijing Forestry University, Beijing 100083, China.

出版信息

Membranes (Basel). 2021 Aug 7;11(8):601. doi: 10.3390/membranes11080601.

DOI:10.3390/membranes11080601
PMID:34436364
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8399918/
Abstract

In this study, powdered activated carbon (PAC) was added to replace the silica in a cementitious microfiltration membrane (CM) to solve the problems of the low mechanical strength and short lifetime of CMs. The carbon-cementitious microfiltration membrane (CCM) was fabricated by the dry pressing method and cured at room temperature. The bending strength of CCM was 12.69 MPa, which was about three times more than that of CM. The average pore size was 0.129 μm, and was reduced by about 80% compared to that of CM. The addition of PAC did not reduce the degradation efficiency of membrane catalytic ozonation. Because of the strong alkaline buffering ability of CCM, the CCM-ozone coupling process could eliminate the effect of the pH value of the solution. The strong alkaline environment inside the membrane pores effectively accelerated the ozone decomposition and produced oxidizing radicals, which accelerated the reaction rate and improved the utilization rate of ozone. The CCM-catalytic ozonation reaction of organic compounds occurred within the pores and membrane surface, resulting in the pH of the solution belonging to the neutral range. The addition of PAC accelerated the mass transfer and made the pollutants and oxidant react in the membrane pores and on the membrane surface. The reuse experiments of the CCM-ozone coupling process for removing nitrobenzene demonstrated that CCM has good catalytic activity and reuse stability. It broadens the application scope of CCM in the field of drinking water and provides theoretical support for the practical application of CCM.

摘要

在本研究中,添加粉末活性炭(PAC)以替代水泥基微滤膜(CM)中的二氧化硅,以解决CM机械强度低和寿命短的问题。通过干压法制备碳水泥基微滤膜(CCM)并在室温下固化。CCM的抗弯强度为12.69MPa,约为CM的三倍。平均孔径为0.129μm,与CM相比减小了约80%。PAC的添加并未降低膜催化臭氧化的降解效率。由于CCM具有较强的碱性缓冲能力,CCM-臭氧耦合过程可以消除溶液pH值的影响。膜孔内的强碱性环境有效地加速了臭氧分解并产生氧化自由基,从而加快了反应速率并提高了臭氧利用率。有机化合物的CCM催化臭氧化反应发生在孔内和膜表面,导致溶液的pH值处于中性范围。PAC的添加加速了传质,使污染物和氧化剂在膜孔内和膜表面发生反应。CCM-臭氧耦合过程去除硝基苯的重复使用实验表明,CCM具有良好的催化活性和重复使用稳定性。它拓宽了CCM在饮用水领域的应用范围,并为CCM的实际应用提供了理论支持。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4cbe/8399918/a70fb47d4b04/membranes-11-00601-g011.jpg
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