Effect of graphitization degree of fuel cell gas diffusion layers on their heat management: Modeling and experiments

Xiao-bo Wu; Piao-piao Yang; Ping-ping Gao; Chun-xuan Liu; Zhi-yong Xie; Qi-zhong Huang

doi:10.1007/s11771-022-4932-x

Journal of Central South University ›› 2022, Vol. 29 ›› Issue (1) : 80 -88. DOI: 10.1007/s11771-022-4932-x

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Effect of graphitization degree of fuel cell gas diffusion layers on their heat management: Modeling and experiments

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Abstract

Serving as gas diffusion layers (GDLs), the thermal conductivity of carbon paper (CP) plays a significant role in the heat transfer management in fuel cells. In the present study, the effect of graphitization degree of CP on its through-plane thermal conductivity and in-plane thermal conductivity is investigated. The relationship between heat treatment temperatures (1800, 2000, 2200, 2400 and 2500 °C) and graphitization degree is also investigated by SEM, XRD and Raman measurements. A model for CP under different graphitization degree is suggested considering the thermal conductivity difference of carbon fiber and matrix carbon. The experimental and simulation results are compared. The results show that the graphitization degree has a significant impact on the through-plane thermal conductivity and in-plane thermal conductivity.

Keywords

through-plane thermal conductivity / graphitization degree / heat transfer / carbon papers

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Xiao-bo Wu, Piao-piao Yang, Ping-ping Gao, Chun-xuan Liu, Zhi-yong Xie, Qi-zhong Huang. Effect of graphitization degree of fuel cell gas diffusion layers on their heat management: Modeling and experiments. Journal of Central South University, 2022, 29(1): 80-88 DOI:10.1007/s11771-022-4932-x

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References

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[1]	ShaoQ, Fernández-GonzálezR, MikdamA, et al.. Influence of heat transfer and fluid flow on crack growth in multilayered porous/dense materials using XFEM: Application to solid oxide fuel cell like material design [J]. International Journal of Solids and Structures, 2014, 51(2122): 3557-3569

[2]	BurheimO S, SuH-N, HaugeH H, et al.. Study of thermal conductivity of PEM fuel cell catalyst layers [J]. International Journal of Hydrogen Energy, 2014, 39(17): 9397-9408

[3]	DaiW, WangH-J, YuanX-Z, et al.. Measurement of water transport rates across the gas diffusion layer in a proton exchange membrane fuel cell, and the influence of polytetrafluoroethylene content and microporous layer [J]. Journal of Power Sources, 2009, 188(1): 122-126

[4]	KhandelwalM, MenchM M. An integrated modeling approach for temperature driven water transport in a polymer electrolyte fuel cell stack after shutdown [J]. Journal of Power Sources, 2010, 195(19): 6549-6558

[5]	KarimiG, LiX, TeertstraP. Measurement of through-plane effective thermal conductivity and contact resistance in PEM fuel cell diffusion media [J]. Electrochimica Acta, 2010, 55(5): 1619-1625

[6]	TeertstraP, KarimiG, LiX. Measurement of in-plane effective thermal conductivity in PEM fuel cell diffusion media [J]. Electrochimica Acta, 2011, 56(3): 1670-1675

[7]	BurheimO S, EllilaG, FairweatherJ D, et al.. Ageing and thermal conductivity of porous transport layers used for PEM fuel cells [J]. Journal of Power Sources, 2013, 221: 356-365

[8]	BaekJ, LeeH M, RohJ S, et al.. Studies on preparation and applications of polymeric precursor-based activated hard carbons: I. Activation mechanism and microstructure analyses [J]. Microporous and Mesoporous Materials, 2016, 219: 258-264

[9]	FengL, LiK-Z, SunJ-J, et al.. Influence of carbon nanotube extending length on pyrocarbon microstructure and mechanical behavior of carbon/carbon composites [J]. Applied Surface Science, 2015, 355: 1020-1027

[10]	IslamM A, AlamT, FarhatZ N, et al.. Effect of microstructure on the erosion behavior of carbon steel [J]. Wear, 2015, 332–333: 1080-1089

[11]	MoriM, YamanakaK, KuramotoK, et al.. Effect of carbon on the microstructure, mechanical properties and metal ion release of Ni-free Co-Cr-Mo alloys containing nitrogen [J]. Materials Science and Engineering C, 2015, 55: 145-154

[12]	ParveenS, RanaS, FangueiroR, et al.. Microstructure and mechanical properties of carbon nanotube reinforced cementitious composites developed using a novel dispersion technique [J]. Cement and Concrete Research, 2015, 73: 215-227

[13]	YaoH-W, SuiX-H, ZhaoZ-B, et al.. Optimization of interfacial microstructure and mechanical properties of carbon fiber/epoxy composites via carbon nanotube sizing [J]. Applied Surface Science, 2015, 347: 583-590

[14]	FitzerE, WeisenburgerS. Graphitization studies by in situ X-ray technique [J]. Carbon, 1974, 12(6): 657-666

[15]	GranoffB. Kinetics of graphitization of carbon-felt/carbon-matrix composites [J]. Carbon, 1974, 12(4): 405-416

[16]	SavageGCarbon-carbon composites [M], 1993, London, Chapman

[17]	ZamelN, LiX-G, ShenJ, et al.. Estimating effective thermal conductivity in carbon paper diffusion media [J]. Chemical Engineering Science, 2010, 65(13): 3994-4006

[18]	ZamelN, BeckerJ, WiegmannA. Estimating the thermal conductivity and diffusion coefficient of the microporous layer of polymer electrolyte membrane fuel cells [J]. Journal of Power Sources, 2012, 207: 70-80

[19]	ZamelN, LiX, ShenJ. Numerical estimation of the effective electrical conductivity in carbon paper diffusion media [J]. Applied Energy, 2012, 93: 39-44

[20]	EsseenC G. Fourier analysis of distribution functions. A mathematical study of the Laplace-Gaussian law [J]. Acta Mathematica, 1945, 77(1): 123-125

[21]	XieZ-Y, ChenG-F, YuX, et al.. Carbon nanotubes grown in situ on carbon paper as a microporous layer for proton exchange membrane fuel cells [J]. International Journal of Hydrogen Energy, 2015, 40(29): 8958-8965

[22]	XieZ-Y, TangX, YangP-P, et al.. Carboxyl-terminated butadiene-acrylonitrile-modified carbon paper for use of gas diffusion layer in PEM fuel cells [J]. International Journal of Hydrogen Energy, 2015, 40(41): 14345-14352

[23]	CaiX-K, MaR-Z, OzawaT C, et al.. Superlattice assembly of graphene oxide (GO) and titania nanosheets: Fabrication, in situ photocatalytic reduction of GO and highly improved carrier transport [J]. Nanoscale, 2014, 6(23): 14419-14427

[24]	FanZ-Q, TanR-X, HeK-J, et al.. Preparation and mechanical properties of carbon fibers with isotropic pyrolytic carbon core by chemical vapor deposition [J]. Chemical Engineering Journal, 2015, 272: 12-16

[25]	LiD-D, TanR-X, GaoJ-X, et al.. Comparison of pyrolytic graphite spheres from propylene with spheroidal graphite nodules in steel [J]. Carbon, 2017, 111: 428-438

[26]	ChenJ, XiongX, XiaoP. Thermal conductivity of unidirectional carbon/carbon composites with different carbon matrixes [J]. Materials & Design, 2009, 30(4): 1413-1416