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A High Conductive Composite Bipolar Plate with Conductive Network Constructed by Chemical Vapor Deposition

Wenkai Li, Haodong Zeng, Tao Peng, Ziteng Gao, Zhiyong Xie

2022Energies13 citationsDOIOpen Access PDF

Abstract

In this study, a highly conductive composite bipolar plate with an embedded conductive carbon nanofiber network was prepared by chemical vapor deposition, and a conductive network was constructed inside the composite bipolar plate. The latter network was then compared with a conductive network formed by directly adding carbon nanotubes more evenly distributed. The optimum preparation methods of vapor-grown carbon fibers and the fiber content were analyzed, and the specific surface area and porosity of the bipolar plates were measured and analyzed using a BET test. The results show that the carbon nanofibers prepared under the conditions of 700 °C and a content of 2% exhibited the best effect on improving the performance of the bipolar plates. The conductivity of the prepared bipolar plates could reach 255.2 S/cm, which is 22.1% higher than treatment with multi-walled carbon nanotubes. The bending strength of the prepared bipolar plates was 47.92 MPa, and the interface contact resistance was 6.24 mΩ·cm2. In conclusion, the bipolar plates modified with vapor-grown carbon fibers were a promising kind of material for proton exchange membrane fuel cells.

Topics & Concepts

Materials scienceElectrical conductorChemical vapor depositionComposite materialCarbon nanofiberComposite numberCarbon nanotubeCarbon fibersPorosityNanotechnologyFuel Cells and Related MaterialsSupercapacitor Materials and FabricationAdvanced Battery Technologies Research