Numerical-experimental study on the thickness distribution of metallic bipolar plates for PEM fuel cells

Document Type : Research Paper

Authors

1 Faculty of Mechanical Engineering, University of Kashan, Kashan, Iran

2 Northern Research Center for Science and Technology, Malek Ashtar University of Technology, Iran

3 Faculty of Mechanical Engineering, Tarbiat Modares University, Iran

Abstract

In this study, the plastic deformation of a metallic bipolar plate with a serpentine flow field was investigated during the stamping process. The strain path and thickness distribution in 304 stainless steel bipolar plates with a thickness of 0.1 mm were determined. To achieve this purpose, the process was simulated by the ABAQUS commercial finite element code, and the validity of the results was evaluated by experimental tests under simple and lubricated conditions. According to the results, the flow of material has a significant effect on the thickness distribution of the central and lateral channels, and the thickness reduction percentage of the central channel in the longitudinal, diagonal, and transverse directions is higher than the lateral one. The maximum thickness reduction in the central channels is observed in the longitudinal direction, while the diagonal direction is considered as a critical direction for lateral channels. Due to the existence of the equibiaxial tension strain path in the diagonal direction, significant thickness reduction is observed in both the side and the rib zone of the channels. However, using lubricant led to a decrease in the thickness reduction percentage by improving the flow of material into the die cavity. Moreover, under lubricated conditions, the critical area is transferred from the side area of the channel in the longitudinal direction to the rib area in the diagonal direction

Keywords

Main Subjects

References

[1] Chubbock S, Clague R. Comparative analysis of internal combustion engine and fuel cell range extender. SAE International Journal of Alternative Powertrains. 2016;5:175-82.
[2] Barzegari MM, Rahgoshay SM, Mohammadpour L, Toghraie D. Performance prediction and analysis of a dead-end PEMFC stack using data-driven dynamic model. Energy. 2019;188:116049.
[3] Alizadeh E, Ghadimi M, Barzegari M, Momenifar M, Saadat S. Development of contact pressure distribution of PEM fuel cell's MEA using novel clamping mechanism. Energy. 2017;131:92-7.
[4] Barzegari MM, Dardel M, Alizadeh E, Ramiar A. Dynamic modeling and validation studies of dead-end cascade H2/O2 PEM fuel cell stack with integrated humidifier and separator. Applied energy. 2016;177:298-308.
[5] Silva R, Franchi D, Leone A, Pilloni L, Masci A, Pozio A. Surface conductivity and stability of metallic bipolar plate materials for polymer electrolyte fuel cells. Electrochimica Acta. 2006;51:3592-8.
[6] Yan X, Hou M, Zhang H, Jing F, Ming P, Yi B. Performance of PEMFC stack using expanded graphite bipolar plates. Journal of Power Sources. 2006;160:252-7.
[7] Minke C, Hickmann T, dos Santos AR, Kunz U, Turek T. Cost and performance prospects for composite bipolar plates in fuel cells and redox flow batteries. Journal of Power Sources. 2016;305:182-90.
[8] Hung J-C, Chang D-H, Chuang Y. The fabrication of high-aspect-ratio micro-flow channels on metallic bipolar plates using die-sinking micro-electrical discharge machining. Journal of Power Sources. 2012;198:158-63.
[9] Hung J-C, Yang T-C, Li K-c. Studies on the fabrication of metallic bipolar plates—Using micro electrical discharge machining milling. Journal of Power Sources. 2011;196:2070-4.
[10] Lim S, Kim Y, Kang C. Fabrication of aluminum 1050 micro-channel proton exchange membrane fuel cell bipolar plate using rubber-pad-forming process. The International Journal of Advanced Manufacturing Technology. 2013;65:231-8.
[11] Modanloo V, Talebi-Ghadikolaee H, Alimirzaloo V, Elyasi M. Fracture prediction in the stamping of titanium bipolar plate for PEM fuel cells. International Journal of Hydrogen Energy. 2021; 46: 5729-5739.‏
[12] Lee S-J, Lai J-J, Huang C-H. Stainless steel bipolar plates. Journal of Power Sources. 2005;145:362-8.
[13] Kahraman H, Orhan MF. Flow field bipolar plates in a proton exchange membrane fuel cell: Analysis & modeling. Energy Conversion and Management. 2017;133:363-84.
[14] Karimi S, Fraser N, Roberts B, Foulkes FR. A review of metallic bipolar plates for proton exchange membrane fuel cells: materials and fabrication methods. Advances in Materials Science and Engineering. 2012;2012.
[15] Yang G, Mo J, Kang Z, List III FA, Green Jr JB, Babu SS, et al. Additive manufactured bipolar plate for high-efficiency hydrogen production in proton exchange membrane electrolyzer cells. international journal of hydrogen energy. 2017;42:14734-40.
[16] Mohammadtabar N, Bakhshi-Jooybari M, Hosseinipour SJ, Gorji A. Study of effective parameters inhydroforming of fuel cell metallic bipolar plates with parallel serpentine flow field. Modares Mechanical Engineering. 2014;14.
[17] Elyasi M, Talebi Ghadikolaee H, Hosseinzadeh M. Fabrication of metallic bipolar plates in PEM fuel cell using semi-stamp rubber forming process. The International Journal of Advanced Manufacturing Technology. 2017;92:765-76.
[18] Talebi-Ghadikolaee H, Elyasi M, Mirnia MJ. Investigation of failure during rubber pad forming of metallic bipolar plates. Thin-Walled Structures. 2020;150:106671.
[19] Abeyrathna B, Zhang P, Pereira MP, Wilkosz D, Weiss M. Micro-roll forming of stainless steel bipolar plates for fuel cells. International Journal of Hydrogen Energy. 2019;44:3861-75.
[20] Barzegari MM, Khatir FA. Study of thickness distribution and dimensional accuracy of stamped metallic bipolar plates. International Journal of Hydrogen Energy. 2019;44:31360-71.
[21] Hu Q, Zhang D, Fu H, Huang K. Investigation of stamping process of metallic bipolar plates in PEM fuel cell—Numerical simulation and experiments. International Journal of Hydrogen Energy. 2014;39:13770-6.
[22] Bong HJ, Lee J, Kim J-H, Barlat F, Lee M-G. Two-stage forming approach for manufacturing ferritic stainless steel bipolar plates in PEM fuel cell: Experiments and numerical simulations. International Journal of Hydrogen Energy. 2017;42:6965-77.
[23] Choi S-W, Park SH, Jeong H-S, Cho J, Park S, Ha MY. Improvement of formability for fabricating thin continuously corrugated structures in sheet metal forming process. Journal of mechanical science and technology. 2012;26:2397-403.
[24] Jin CK, Koo JY, Kang CG. Fabrication of stainless steel bipolar plates for fuel cells using dynamic loads for the stamping process and performance evaluation of a single cell. International Journal of Hydrogen Energy. 2014;39:21461-9.
[25] Neto DM, Oliveira MC, Alves JL, Menezes LF. Numerical study on the formability of metallic bipolar plates for proton exchange membrane (PEM) fuel cells. Metals. 2019; 9: 810.‏
[26] Ahmadi Khatir F, Barzegari MM, Talebi-Ghadikolaee H, Seddighi S. Integration of design of experiment and finite element method for the study of geometrical parameters in metallic bipolar plates for PEMFCs. International Journal of Hydrogen Energy. 2021; 46: 39469-39482.‏
Hydrogen, Fuel Cell & Energy Storage
Volume 9, Issue 1
January 2022
Pages 1-18

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