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Temperature Effect on the Dust Filtration Performance of SiC Ceramic Membranes

High-temperature filtration is an energy-saving and efficient technology for treating high-temperature dusty exhaust, while most of the current studies focus on the design and preparation of high-temperature filtration materials and their application in room-temperature filtration. In this work, SiC...

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Bibliographic Details
Published in:Industrial & engineering chemistry research 2024-07, Vol.63 (26), p.11613-11625
Main Authors: Gan, Jinxin, Zhao, Lekai, Tan, Jiesong, Zeng, Yiqing, Qiao, Jiangxiao, Chen, Jiahao, Zhong, Zhaoxiang, Xing, Weihong
Format: Article
Language:English
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Summary:High-temperature filtration is an energy-saving and efficient technology for treating high-temperature dusty exhaust, while most of the current studies focus on the design and preparation of high-temperature filtration materials and their application in room-temperature filtration. In this work, SiC ceramic membranes were prepared as typical high-temperature filtration materials to systematically investigate the high-temperature filtration process at 25–400 °C. The experimental results show that the filtration temperature has a significant effect on both initial filtration and cake filtration processes. The increase of temperature results in an increase of gas viscosity, which contributes to the increase of the initial filtration pressure drop (ΔP 0). Meanwhile, temperature can affect the forces on dust in the pore of the SiC membrane, and a higher temperature leads to the easy penetration of dust (especially for the ultrafine particles) through the membrane layer into the support body layer at the initial filtration process. Moreover, the higher temperature can reduce the porosity of the dust cake, leading to an increase in the cake pressure drop (ΔP c). All above results were further proved during the experiments on studying the effect of the filtration velocity, dust concentration, and regeneration on the filtration performance of SiC membranes at 25 and 300 °C. Through this work, we expect to shed some light on the design and preparation of high-temperature filtration materials and on the understanding of the high-temperature filtration process.
ISSN:0888-5885
1520-5045
DOI:10.1021/acs.iecr.4c01382