Defect size analysis approach combined with silicate gel/ceramic particles for defect repair of Pd composite membranes

Pd composite membranes show great potential in several important fields, such as high-purity H2 separation and production, due to unique permeability to hydrogen and its isotopes. However, the significant defect formation on palladium membranes and following decline in H2 selectivity resulted from e...

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Bibliographic Details
Published in:International journal of hydrogen energy 2016-11, Vol.41 (41), p.18522-18532
Main Authors: Zheng, Lei, Li, Hui, Xu, Tianying, Bao, Feng, Xu, Hengyong
Format: Article
Language:English
Subjects:
Defect distribution analysis
Durability
Guidance for the selection of particle sizes
Palladium composite membranes
Strong adhesion
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Summary:Pd composite membranes show great potential in several important fields, such as high-purity H2 separation and production, due to unique permeability to hydrogen and its isotopes. However, the significant defect formation on palladium membranes and following decline in H2 selectivity resulted from either preparation process or thermal/chemical stability issues exist as a great challenge for their commercial applications. The currently existing techniques for defect repair of Pd composite membranes show either high complexity or limited effect thus limiting their practical applications. In this study, we presented a novel approach, i.e., strongly adhesive and high temperature resistant silicate gel (HTRSG)/ceramic particles, in combination with home-developed “modified” liquid–liquid displacement porometry (MLLDP) for defect size distribution analysis, where the latter can provide important guidance for the selection of appropriate particles sizes. The experimental results with thin Pd membranes indicated significant improvement in H2 permselectivity without decreasing H2 permeance after defect repair treatment. Moreover, silicate gel exhibits great durability under high temperature conditions. This approach features high simplicity, effectiveness and low cost, and is especially suitable for on-site repair of spent membranes in future applications. In addition, it is universal for defect repair of other inorganic membranes, and can also be used for the sealing of membrane modules. •Defect size analysis combined with silicate gel/ceramic particles for defect repair.•The defect size information provides guidance for proper selection of particle sizes.•Silicate gel exhibits strong adhesion towards ceramic particles and metal membranes.•H2 permselectivity was significantly improved after two cycles of treatment.•Silicate gel exhibits great durability under high temperature conditions.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2016.08.169