Process and challenges of stainless steel based bipolar plates for proton exchange membrane fuel cells

Gaoyang Liu; Faguo Hou; Shanlong Peng; Xindong Wang; Baizeng Fang

doi:10.1007/s12613-022-2485-5

International Journal of Minerals, Metallurgy, and Materials ›› 2022, Vol. 29 ›› Issue (5) : 1099 -1119. DOI: 10.1007/s12613-022-2485-5

Invited Review

Process and challenges of stainless steel based bipolar plates for proton exchange membrane fuel cells

Gaoyang Liu ¹^,²^,^a
, Faguo Hou ¹^,²
, Shanlong Peng ¹^,²
, Xindong Wang ¹^,²
, Baizeng Fang ³^,^e

Author information +

History +

PDF

Abstract

Proton exchange membrane fuel cell (PEMFC) powered automobiles have been recognized to be the ultimate solution to replace traditional fuel automobiles because of their advantages of PEMFCs such as no pollution, low temperature start-up, high energy density, and low noise. As one of the core components, the bipolar plates (BPs) play an important role in the PEMFC stack. Traditional graphite BPs and composite BPs have been criticized for their shortcomings such as low strength, high brittleness, and high processing cost. In contrast, stainless steel BPs (SSBPs) have recently attracted much attention of domestic and foreign researchers because of their excellent comprehensive performance, low cost, and diverse options for automobile applications. However, the SSBPs are prone to corrosion and passivation in the PEMFC working environment, which lead to reduced output power or premature failure. This review is aimed to summarize the corrosion and passivation mechanisms, characterizations and evaluation, and the surface modification technologies in the current SSBPs research. The non-coating and coating technical routes of SSBPs are demonstrated, such as substrate component regulation, thermal nitriding, electroplating, ion plating, chemical vapor deposition, and physical vapor deposition, etc. Alternative coating materials for SSBPs are metal coatings, metal nitride coatings, conductive polymer coatings, and polymer/carbon coatings, etc. Both the surface modification technologies can solve the corrosion resistance problem of stainless steel without affecting the contact resistance, however still facing restraints such as long-time stability, feasibility of low-cost, and mass production process. This paper is believed to enrich the knowledge of high-performance and long-life BPs applied for PEMFC automobiles.

Keywords

automobile application / proton exchange membrane fuel cell / stainless steel bipolar plates / corrosion resistance / contact resistance

Cite this article

Download citation ▾

Gaoyang Liu, Faguo Hou, Shanlong Peng, Xindong Wang, Baizeng Fang. Process and challenges of stainless steel based bipolar plates for proton exchange membrane fuel cells. International Journal of Minerals, Metallurgy, and Materials, 2022, 29(5): 1099-1119 DOI:10.1007/s12613-022-2485-5

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Y. Wang, H. Yuan, A. Martinez, P. Hong, H. Xu, and F.R. Bockmiller, Polymer electrolyte membrane fuel cell and hydrogen station networks for automobiles: Status, technology, and perspectives, Adv. Appl. Energy, 2(2021), art. No. 100011.

[2]	Rodríguez-Varela J, Alonso-Lemus IL, Savadogo O, Palaniswamy K. Overview: Current trends in green electrochemical energy conversion and storage. J. Mater. Res., 2021, 36(20): 4071.

[3]	Y. Luo, Y.H. Wu, B. Li, T.D. Mo, Y. Li, S.P. Feng, J.K. Qu, and P.K. Chu, Development and application of fuel cells in the automobile industry, J. Energy Storage, 42(2021), art. No. 103124.

[4]	Debe MK. Electrocatalyst approaches and challenges for automotive fuel cells. Nature, 2012, 486(7401): 43.

[5]	Mazumder V, Lee Y, Sun SH. Recent development of active nanoparticle catalysts for fuel cell reactions. Adv. Funct. Mater., 2010, 20(8): 1224.

[6]	Smitha B, Sridhar S, Khan AA. Solid polymer electrolyte membranes for fuel cell applications—A review. J. Membr. Sci., 2005, 259(1–2): 10.

[7]	Wu SD, Yang WM, Yan H, Zuo XH, Cao ZB, Li HY, Shi MN, Chen HB. A review of modified metal bipolar plates for proton exchange membrane fuel cells. Int. J. Hydrogen Energy, 2021, 46(12): 8672.

[8]	Bi J, Yang JM, Liu XX, Wang DD, Yang ZY, Liu GY, Wang XD. Development and evaluation of nitride coated titanium bipolar plates for PEM fuel cells. Int. J. Hydrogen Energy, 2021, 46(1): 1144.

[9]	T. Stein and Y. Ein-Eli, Challenges and perspectives of metal-based proton exchange membrane’s bipolar plates: Exploring durability and longevity, Energy Technol., 8(2020), No. 6, art. No. 2000007.

[10]	R. Stroebel, DOE Bipolar Plates Workshop Approach to Provide a Metallic Bipolar Plate Module to the Industry, DOE bipolar plate workshop, Michigan [2017-02-14]. https://www.energy.gov/sites/prod/files/2017/05/f34/fcto_biploar_plates_wkshp_stroebel.pdf

[11]	Hermann A, Chaudhuri T, Spagnol P. Bipolar plates for PEM fuel cells: A review. Int. J. Hydrogen Energy, 2005, 30(12): 1297.

[12]	Yi PY, Peng LF, Zhou T, Huang JQ, Lai XM. Composition optimization of multilayered chromium-nitride-carbon film on 316L stainless steel as bipolar plates for proton exchange membrane fuel cells. J. Power Sources, 2013, 236, 47.

[13]	Shen CH, Pan M, Yuan Q, Yuan RZ. Studies on preparation and performance of sodium silicate/graphite conductive composites. J. Compos. Mater., 2006, 40(9): 839.

[14]	Kuan HC, Ma CCM, Chen KH, Chen SM. Preparation, electrical, mechanical and thermal properties of composite bipolar plate for a fuel cell. J. Power Sources, 2004, 134(1): 7.

[15]	Wind J, Späh R, Kaiser W, Böhm G. Metallic bipolar plates for PEM fuel cells. J. Power Sources, 2002, 105(2): 256.

[16]	Yoon W, Huang XY, Fazzino P, Reifsnider KL, Akkaoui MA. Evaluation of coated metallic bipolar plates for polymer electrolyte membrane fuel cells. J. Power Sources, 2008, 179(1): 265.

[17]	Fu Y, Hou M, Lin GQ, Hou JB, Shao ZG, Yi BL. Coated 316L stainless steel with Cr_xN film as bipolar plate for PEMFC prepared by pulsed bias arc ion plating. J. Power Sources, 2008, 176(1): 282.

[18]	Xiong YM, Zhu SL, Wang FH. Synergistic corrosion behavior of coated Ti60 alloys with NaCl deposit in moist air at elevated temperature. Corros. Sci., 2008, 50(1): 15.

[19]	Yang LJ, Yu HJ, Jiang LJ, Zhu L, Jian XY, Wang Z. Graphite-polypyrrole coated 316L stainless steel as bipolar plates for proton exchange membrane fuel cells. Int. J. Miner. Metall. Mater., 2011, 18(1): 53.

[20]	Mehta V, Cooper JS. Review and analysis of PEM fuel cell design and manufacturing. J. Power Sources, 2003, 114(1): 32.

[21]	Brady MP, Wang H, Yang B, Turner JA, Bordignon M, Molins R, Elhamid MA, Lipp L, Walker LR. Growth of Cr-Nitrides on commercial Ni—Cr and Fe—Cr base alloys to protect PEMFC bipolar plates. Int. J. Hydrogen Energy, 2007, 32(16): 3778.

[22]	Y. Wang, C.M. Wu, W. Li, H.Y. Li, Y.C. Li, X.Y. Zhang, and L.L. Sun, Effect of bionic hydrophobic structures on the corrosion performance of Fe-based amorphous metallic coatings, Surf. Coat. Technol., 416(2021), art. No. 127176.

[23]	Antunes RA, Oliveira MCL, Ett G, Ett V. Corrosion of metal bipolar plates for PEM fuel cells: A review. Int. J. Hydrogen Energy, 2010, 35(8): 3632.

[24]	Lee SJ, Huang CH, Lai JJ, Chen YP. Corrosion-resistant component for PEM fuel cells. J. Power Sources, 2004, 131(1–2): 162.

[25]	Li Q, Lin X, Luo Q, Chen YA, Wang JF, Jiang B, Pan FS. Kinetics of the hydrogen absorption and desorption processes of hydrogen storage alloys: A review. Int. J. Miner. Metall. Mater., 2022, 29(1): 32.

[26]	Y. Li, W.J. Meng, S. Swathirajan, S.J. Harris, and G.L. Doll, Corrosion Resistant Pem Fuel Cell, United States Patent, Appl. 5624769, 1997.

[27]	Jirarungsatian C, Prateepasen A. Pitting and uniform corrosion source recognition using acoustic emission parameters. Corros. Sci., 2010, 52(1): 187.

[28]	Chen ZG, Zhang GF, Bobaru F. The Influence of passive film damage on pitting corrosion. J. Electrochem. Soc., 2016, 163(2): C19.

[29]	H.Y. Tian, L. Fan, Y.Z. Li, K. Pang, F.Z. Chu, X. Wang, and Z.Y. Cui, Effect of NH₄ ⁺ on the pitting corrosion behavior of 316 stainless steel in the chloride environment, J. Electroanal. Chem., 894(2021), art. No. 115368.

[30]	Huang NB, Liang CH, Yi BL. Corrosion resistance of PANi-coated steel in simulated PEMFC anodic environment. Mater. Corros., 2008, 59(1): 21.

[31]	Jiang JC, Liu SJ, Ma ZY, Wang LY, Wu K. Butler-Volmer equation-based model and its implementation on state of power prediction of high-power lithium titanate batteries considering temperature effects. Energy, 2016, 117, 58.

[32]	Hinds G, Brightman E. In situ mapping of electrode potential in a PEM fuel cell. Electrochem. Commun., 2012, 17, 26.

[33]	Hinds G, Brightman E. Towards more representative test methods for corrosion resistance of PEMFC metallic bipolar plates. Int. J. Hydrogen Energy, 2015, 40(6): 2785.

[34]	Healy J, Hayden C, Xie T, Olson K, Waldo R, Brundage M, Gasteiger H, Abbott J. Aspects of the chemical degradation of PFSA ionomers used in PEM fuel cells. Fuel Cells, 2005, 5(2): 302.

[35]	Abdullah AM, Mohammad AM, Okajima T, Kitamura F, Ohsaka T. Effect of load, temperature and humidity on the pH of the water drained out from H₂/air polymer electrolyte membrane fuel cells. J. Power Sources, 2009, 190(2): 264.

[36]	Hou KH, Lin CH, Ger MD, Shiah SW, Chou HM. Analysis of the characterization of water produced from proton exchange membrane fuel cell (PEMFC) under different operating thermal conditions. Int. J. Hydrogen Energy, 2012, 37(4): 3890.

[37]	X.Z. Wang, C.P. Ye, D.D. Shi, H.Q. Fan, and Q. Li, Potential polarization accelerated degradation of interfacial electrical conductivity for Au/TiN coated 316L SS bipolar plates used in polymer electrolyte membrane fuel cells, Corros. Sci., 189(2021), art. No. 109624.

[38]	Liu M, Xu HF, Fu J, Tian Y. Conductive and corrosion behaviors of silver-doped carbon-coated stainless steel as PEMFC bipolar plates. Int. J. Miner. Metall. Mater., 2016, 23(7): 844.

[39]	Fan HQ, Shi DD, Wang XZ, Luo JL, Zhang JY, Li Q. Enhancing through-plane electrical conductivity by introducing Au microdots onto TiN coated metal bipolar plates of PEMFCs. Int. J. Hydrogen Energy, 2020, 45(53): 29442.

[40]	DeBerry DW. Modification of the electrochemical and corrosion behavior of stainless steels with an electroactive coating. J. Electrochem. Soc., 1985, 132(5): 1022.

[41]	Hermas AA, Morad MS. A comparative study on the corrosion behaviour of 304 austenitic stainless steel in sulfamic and sulfuric acid solutions. Corros. Sci., 2008, 50(9): 2710.

[42]	Kim JS, Peelen WHA, Hemmes K, Makkus RC. Effect of alloying elements on the contact resistance and the passivation behaviour of stainless steels. Corros. Sci., 2002, 44(4): 635.

[43]	Hornung R, Kappelt G. Bipolar plate materials development using Fe-based alloys for solid polymer fuel cells. J. Power Sources, 1998, 72(1): 20.

[44]	Yuan XW, Wang X, Cao Y, Yang HY. Natural passivation behavior and its influence on chloride-induced corrosion resistance of stainless steel in simulated concrete pore solution. J. Mater. Res. Technol., 2020, 9(6): 12378.

[45]	Hamada E, Yamada K, Nagoshi M, Makiishi N, Sato K, Ishii T, Fukuda K, Ishikawa S, Ujiro T. Direct imaging of native passive film on stainless steel by aberration corrected STEM. Corros. Sci., 2010, 52(12): 3851.

[46]	Wang XY, Wu YS, Zhang L, Ding BF. Passivationm echanism of 316L stainless steel in oxidizing acid solution. J. Univ. Sci. Technol. Beijing, 2000, 7(3): 204

[47]	Zhang CY, Wei YH, Yang J, Emori W, Li J. Effects of nitric acid passivation on the corrosion behavior of ZG₀₆Cr₁₃Ni₄Mo stainless steel in simulated marine atmosphere. Mater. Corros., 2020, 71(9): 1576.

[48]	Lu ZJ, Macdonald DD. Transient growth and thinning of the barrier oxide layer on iron measured by real-time spectroscopic ellipsometry. Electrochim. Acta, 2008, 53(26): 7696.

[49]	Habibzadeh S, Li L, Shum-Tim D, Davis EC, Omanovic S. Electrochemical polishing as a 316L stainless steel surface treatment method: Towards the improvement of biocompatibility. Corros. Sci., 2014, 87, 89.

[50]	Han W, Fang FZ. Fundamental aspects and recent developments in electropolishing. Int. J. Mach. Tools Manuf., 2019, 139, 1.

[51]	Richards J, Cremers C, Fischer P, Schmidt K. Corrosion studies on electro polished stainless steels for the use as metallic bipolar plates in PEMFC applications. Energy Procedia, 2012, 20, 324.

[52]	Lee SJ, Lai JJ. The effects of electropolishing (EP) process parameters on corrosion resistance of 316L stainless steel. J. Mater. Process. Technol., 2003, 140(1–3): 206.

[53]	W. Han and F.Z. Fang, Two-step electropolishing of 316L stainless steel in a sulfuric acid-free electrolyte, J. Mater. Process. Technol., 279(2020), art. No. 116558.

[54]	Kumar A, Ricketts M, Hirano S. Ex situ evaluation of nanometer range gold coating on stainless steel substrate for automotive polymer electrolyte membrane fuel cell bipolar plate. J. Power Sources, 2010, 195(5): 1401.

[55]	Wang SH, Peng J, Lui WB, Zhang JS. Performance of the gold-plated titanium bipolar plates for the light weight PEM fuel cells. J. Power Sources, 2006, 162(1): 486.

[56]	Yan XJ, Zhuang JB, Huang NB, Liang CH, Wang HT, Xu LS. Corrosion behavior of SAMs modified silver-coated 316LSS as PEMFC bipolar plates. Key Eng. Mater., 2015, 645–646, 1233.

[57]	Wang HL, Turner JA. Electrochemical nitridation of a stainless steel for PEMFC bipolar plates. Int. J. Hydrogen Energy, 2011, 36(20): 13008.

[58]	Pugal Mani S, Rajendran N. Corrosion and interfacial contact resistance behavior of electrochemically nitrided 316L SS bipolar plates for proton exchange membrane fuel cells. Energy, 2017, 133, 1050.

[59]	Mattox DM. Physical vapor deposition (PVD) processes. Met. Finish., 2001, 99, 409.

[60]	Aliofkhazraei M, Ali N. PVD technology in fabrication of micro- and nanostructured coatings. Comprehensive Materials Processing, 2014, Amsterdam, Elsevier, 49.

[61]	N.S. Mansoor, A. Fattah-Alhosseini, H. Elmkhah, and A. Shishehian, Comparison of the mechanical properties and electrochemical behavior of TiN and CrN single-layer and CrN/TiN multi-layer coatings deposited by PVD method on a dental alloy, Mater. Res. Express, 6(2020), No. 12, art. No. 126433.

[62]	S.H. Song, B.K. Min, M.H. Hong, and T.Y. Kwon, Application of a novel CVD TiN coating on a biomedical Co—Cr alloy: An evaluation of coating layer and substrate characteristics, Materials, 13(2020), No. 5, art. No. 1145.

[63]	Wang JL, Sun JC, Li S, Wen ZS, Ji SJ. Surface diffusion modification AISI 304SS stainless steel as bipolar plate material for proton exchange membrane fuel cell. Int. J. Hydrogen Energy, 2012, 37(1): 1140.

[64]	Nam DG, Lee HC. Thermal nitridation of chromium electroplated AISI316L stainless steel for polymer electrolyte membrane fuel cell bipolar plate. J. Power Sources, 2007, 170(2): 268.

[65]	Hung Y, Tawfik H, Mahajan D. Durability and characterization studies of polymer electrolyte membrane fuel cell’s coated aluminum bipolar plates and membrane electrode assembly. J. Power Sources, 2009, 186(1): 123.

[66]	A. Gago, A. Ansar, N. Wagner, J. Arnold, and K. Friedrich, Titanium coatings deposited by thermal spraying for bipolar plates of PEM electrolysers, [in] The 64th Annual Meeting of the International Society of Electrochemistry, Queretaro, 2013, p. 7.

[67]	El-Khatib KM, Abou Helal MO, El-Moneim AA, Tawfik H. Corrosion stability of SUS316L HVOF sprayed coatings as lightweight bipolar plate materials in PEM fuel cells. Anti-Corros. Methods Mater., 2004, 51(2): 136.

[68]	Zhang HB, Lin GQ, Hou M, Hu L, Han ZY, Fu Y, Shao ZG, Yi BL. CrN/Cr multilayer coating on 316L stainless steel as bipolar plates for proton exchange membrane fuel cells. J. Power Sources, 2012, 198, 176.

[69]	Ren YJ, Zhang CR, Liu GM, Ceng CL. A review on corrosion and protection of metallic bipolar plates for proton exchange membrane fuel cell. Corros. Sci. Protetion Technol., 2009, 21, 388

[70]	Fu Y, Lin GQ, Hou M, Wu B, Shao ZG, Yi BL. Carbon-based films coated 316L stainless steel as bipolar plate for proton exchange membrane fuel cells. Int. J. Hydrogen Energy, 2009, 34(1): 405.

[71]	Feng K, Shen Y, Sun HL, Liu DA, An QZ, Cai X, Chu PK. Conductive amorphous carbon-coated 316L stainless steel as bipolar plates in polymer electrolyte membrane fuel cells. Int. J. Hydrogen Energy, 2009, 34(16): 6771.

[72]	Lee SH, Pukha VE, Vinogradov VE, Kakati N, Jee SH, Cho SB, Yoon YS. Nanocomposite-carbon coated at low-temperature: A new coating material for metallic bipolar plates of polymer electrolyte membrane fuel cells. Int. J. Hydrogen Energy, 2013, 38(33): 14284.

[73]	Wang LX, Sun JC, Li PB, Jing B, Li S, Wen ZS, Ji SJ. Niobized AISI 304 stainless steel bipolar plate for proton exchange membrane fuel cell. J. Power Sources, 2012, 208, 397.

[74]	Weil KS, Xia G, Yang ZG, Kim JY. Development of a niobium clad PEM fuel cell bipolar plate material. Int. J. Hydrogen Energy, 2007, 32(16): 3724.

[75]	Feng K, Li ZG, Cai X, Chu PK. Corrosion behavior and electrical conductivity of niobium implanted 316L stainless steel used as bipolar plates in polymer electrolyte membrane fuel cells. Surf. Coat. Technol., 2010, 205(1): 85.

[76]	Feng K, Shen Y, Mai JM, Liu DA, Cai X. An investigation into nickel implanted 316L stainless steel as a bipolar plate for PEM fuel cell. J. Power Sources, 2008, 182(1): 145.

[77]	Li MC, Luo SZ, Zeng CL, Shen JN, Lin HC, Cao CN. Corrosion behavior of TiN coated type 316 stainless steel in simulated PEMFC environments. Corros. Sci., 2004, 46(6): 1369.

[78]	Cho EA, Jeon US, Hong SA, Oh IH, Kang SG. Performance of a 1 kW-class PEMFC stack using TiN-coated 316 stainless steel bipolar plates. J. Power Sources, 2005, 142(1–2): 177.

[79]	Wang Y, Northwood DO. An investigation into TiN-coated 316L stainless steel as a bipolar plate material for PEM fuel cells. J. Power Sources, 2007, 165(1): 293.

[80]	You QB, Xiong J, Yang TN, Hua T, Huo YL, Liu JB. Effect of cermet substrate characteristics on the microstructure and properties of TiAlN coatings. Int. J. Miner. Metall. Mater., 2022, 29(3): 547.

[81]	Zhao Y, Wei L, Yi PY, Peng LF. Influence of Cr—C film composition on electrical and corrosion properties of 316L stainless steel as bipolar plates for PEMFCs. Int. J. Hydrogen Energy, 2016, 41(2): 1142.

[82]	Zhang T, Zeng CL. Corrosion protection of 1Cr18Ni9Ti stainless steel by polypyrrole coatings in HCl aqueous solution. Electrochim. Acta, 2005, 50(24): 4721.

[83]	Joseph S, McClure JC, Chianelli R, Pich P, Sebastian PJ. Conducting polymer-coated stainless steel bipolar plates for proton exchange membrane fuel cells (PEMFC). Int. J. Hydrogen Energy, 2005, 30(12): 1339.

[84]	García MAL, Smit MA. Study of electrodeposited polypyrrole coatings for the corrosion protection of stainless steel bipolar plates for the PEM fuel cell. J. Power Sources, 2006, 158(1): 397.

[85]	Wang Y, Northwood DO. An investigation into polypyrrole-coated 316L stainless steel as a bipolar plate material for PEM fuel cells. J. Power Sources, 2006, 163(1): 500.