奥氏体不锈钢双极板的低温超饱和气体渗碳表面改性

doi:10.16183/j.cnki.jsjtu.2019.02.017

上海交通大学学报（自然版） ›› 2019, Vol. 53 ›› Issue (2): 247-252.doi: 10.16183/j.cnki.jsjtu.2019.02.017

• 学报（中文） • 上一篇

奥氏体不锈钢双极板的低温超饱和气体渗碳表面改性

姜勇，李洋，周阳，巩建鸣

南京工业大学机械与动力工程学院；极端承压装备设计与制造重点实验室，南京 211816

出版日期:2019-02-28 发布日期:2019-02-28
作者简介:姜勇(1974-)，男，山东省乳山市人，副教授，主要研究方向为金属材料表面改性和性能分析. 电话(Tel.)：025-58139362；E-mail: jiangyong@njtech.edu.cn.
基金资助:
国家自然科学基金(51475224)，江苏省高校自然科学研究重大项目(14KJA470002)，江苏省普通高校研究生创新计划(CXZZ11_0420)

Surface Modification of Austenitic Stainless Steel Bipolar Plates by Low Temperature Colossal Supersaturation Gaseous Carburization

JIANG Yong,LI Yang,ZHOU Yang,GONG Jianming

College of Mechanical and Power Engineering; Key Laboratory of Design and Manufacture of Extreme Pressure Equipment, Nanjing Tech University, Nanjing 211816, China

Online:2019-02-28 Published:2019-02-28

摘要/Abstract

摘要： 通过低温超饱和气体渗碳(LTCSGC)处理，在316L不锈钢双极板表面形成了一层厚度约30 μm的渗碳层，研究了从基体沿渗碳层深度方向的碳的质量分数、残余应力、硬度分布和相结构，测量了渗碳后316L不锈钢双极板的接触电阻，分析了渗碳后316L不锈钢双极板在模拟质子交换膜燃料电池(PEMFC)环境中的耐腐蚀性能.结果表明：渗碳层是由膨胀奥氏体相组成的梯度材料，从渗碳层表面到基体的碳的质量分数、残余应力和硬度逐渐降低；经过LTCSGC处理后，316L不锈钢双极板的接触电阻降低了34%；在模拟PEMFC的阳极环境中，其自腐蚀电位升到 -79mV，高于工作电位 -0.1V，获得了阴极保护；在模拟PEMFC的阴极环境中，其自腐蚀电位提高了260mV，抗腐蚀性能显著提高，恒电位极化腐蚀电流密度降低了75%.

关键词: 质子交换膜燃料电池, 奥氏体不锈钢, 双极板, 低温超饱和气体渗碳, 抗腐蚀性能

Abstract: By the means of low temperature colossal supersaturation gaseous carburization (LTCSGC) technique, a carburizing layer of 30 μm was formed on the surface of 316L austenitic stainless steel bipolar plate. The carbon concentration, compressive residual stress, nano-hardness and the phase structure along cross-sectional depth direction of the specimens were investigated, respectively. Besides, the contact resistance of carburized 316L stainless steel bipolar plates was measured and the corrosion resistance of the samples in simulated proton exchange membrane fuel cell (PEMFC) environment was analyzed. Results demonstrate that the LTCSGC layer was a functionally gradient material which was composed of expanded austenite. Moreover, its carbon concentration, residual stress and hardness decline continuously along cross-sectional depth direction from surface to substrate. Compared with 316L stainless steel bipolar plates, the contact resistance of carburized samples after LTCSGC treatment was reduced by 34%. The self-corrosion potential in PEMFC anode environment was improved to -79mV, which was higher than the PEMFC work potential (-0.1V). Therefore, it was protected by cathode. In PEMFC simulated cathode environment, the self-corrosion potential was increased by 260mV and the corrosion resistance was remarkably improved. Meanwhile, the potentiostatic polarization etching current density was reduced by 75%.

Key words: proton exchange membrane fuel cell (PEMFC), austenitic stainless steel, bipolar plate, low temperature colossal supersaturation gaseous carburization (LTCSGC), corrosion resistance

中图分类号:

TG 156

姜勇，李洋，周阳，巩建鸣. 奥氏体不锈钢双极板的低温超饱和气体渗碳表面改性[J]. 上海交通大学学报（自然版）, 2019, 53(2): 247-252.

JIANG Yong,LI Yang,ZHOU Yang,GONG Jianming. Surface Modification of Austenitic Stainless Steel Bipolar Plates by Low Temperature Colossal Supersaturation Gaseous Carburization[J]. Journal of Shanghai Jiaotong University, 2019, 53(2): 247-252.

参考文献［16］

［1］	STEELE B C H, HEINZEL A. Materials for fuel-cell technologies［J］. Nature, 2001, 414: 345-352.
［2］	ASRI N F, HUSAINI T, SULONG A B, et al. Coating of stainless steel and titanium bipolar plates for anticorrosion in PEMFC: A review［J］. International Journal of Hydrogen Energy, 2017, 42(14): 9135-9148.
［3］	SILVA R F, POZIO A. Corrosion study on different types of metallic bipolar plates for polymer electrolyte membrane fuel cells［J］. Journal of Fuel Cell Science and Technology, 2007, 4(2): 116-122.
［4］	AYERS K E, CAPUANO C, ANDERSON E B. Recent advances in cell cost and efficiency for PEM-based water electrolysis［C］//ECS Transactions. Boston, USA: ECS, 2012, 41(10): 15-22.
［5］	LEE S H, KAKATI N, MAITI J, et al. Corrosion and electrical properties of CrN-and TiN-coated 316L stainless steel used as bipolar plates for polymer electrolyte membrane fuel cells［J］. Thin Solid Films, 2013, 529: 374-379.
［6］	YANG G, MO J, KANG Z, et al. Additive manufactured bipolar plate for high-efficiency hydrogen production in proton exchange membrane electrolyzer cells［J］. International Journal of Hydrogen Energy, 2017, 42(21): 14734-14740.
［7］	荣冬松, 姜勇, 巩建鸣. 奥氏体不锈钢低温超饱和渗碳实验及热动力学模拟研究［J］. 金属学报, 2015, 51(12): 1516-1522.
	RONG Dongsong, JIANG Yong, GONG Jianming. Experimental research and thermodynamic simulation of low temperature colossal carburization of austenitic stainless steel［J］. Acta Metallurgica Sinica, 2015, 51(12): 1516-1522.
［8］	TRIWIYANTO A, HUSAIN P, HARUMAN E, et al. Low temperature thermochemical treatments of austenitic stainless steel without impairing its corrosion resistance［EB/OL］.［2017-07-20］.http://www.doc88.com/p-274339490502.html.
［9］	HOEFT D, LATELLA B A, SHORT K T. Residual stress and cracking in expanded austenite layers［J］. Journal of Physics: Condensed Matter, 2005, 17(23): 3547-3558.
［10］	荣冬松, 巩建鸣, 姜勇, 等. 奥氏体金属低温超饱和气体渗碳表面强化试验装置: CN103323355A ［P］. 2013-09-05［2017-02-09］.
	RONG Dongsong, GONG Jianming, JIANG Yong, et al. Test device for austenitic metal low temperature supersaturated gas carburizing surface strengthening: CN103323355A ［P］. 2013-09-05［2017-02-09］.
［11］	周上祺. X射线衍射分析原理、方法、应用［M］. 重庆: 重庆大学出版社, 1991.
	ZHOU Shangqi. X ray diffraction analysis principle, method and application ［M］. Chongqing: Chongqing University Press, 1991.
［12］	AVASARALA B, HALDAR P. Effect of surface roughness of composite bipolar plates on the contact resistance of a proton exchange membrane fuel cell［J］. Journal of Power Sources, 2009, 188(1): 225-229.
［13］	PENG Y W, GONG J M, JIANG Y, et al. The effect of plastic pre-strain on low-temperature surface carburization of AISI 304 austenitic stainless steel［J］. Surface and Coatings Technology, 2016, 304: 16-22.
［14］	DAVIES D P, ADCOCK P L, TURPIN M, et al. Bipolar plate materials for solid polymer fuel cells［J］. Journal of Applied Electrochemistry, 2000, 30(1): 101-105.
［15］	HEUER A H, KAHN H, NATISHAN P M, et al. Electrostrictive stresses and breakdown of thin passive films on stainless steel［J］. Electrochimica Acta, 2011, 58: 157-160.
［16］	HEUER A H, KAHN H, ERNST F, et al. Enhanced corrosion resistance of interstitially hardened stainless steel: Implications of a critical passive layer thickness for breakdown［J］. Acta Materialia, 2012, 60(2): 716-725.

[1]	刘克, 郝亮, 耿珺, 陈洵, 陆维. 质子交换膜燃料电池仿真模型并行计算与优化[J]. 上海交通大学学报, 2025, 59(11): 1754-1762.
[2]	陈敏学, 邱殿凯, 彭林法. 基于反应状态原位测试的空冷型燃料电池运行参数分析[J]. 上海交通大学学报, 2024, 58(3): 253-262.
[3]	杨博, 曾春源, 陈义军, 束洪春, 曹璞璘. 极限学习机及其在质子交换膜燃料电池参数辨识中的应用[J]. 上海交通大学学报, 2023, 57(4): 482-494.
[4]	刘贵吉, 甘志云, 李江, 王旭, 张洪飞. 超声相控阵检测技术在奥氏体不锈钢[J]. 海洋工程装备与技术, 2018, 5(增刊): 248-252.
[5]	周苏，姜缜，DE LILE J R. 基于密度泛函理论的过渡金属酞菁配合物氧还原反应催化能力[J]. 上海交通大学学报, 2017, 51(12): 1422-1427.
[6]	沈朝, 汪家梅, 张乐福. 铁素体/马氏体钢和奥氏体不锈钢在超临界水中的腐蚀行为[J]. 上海交通大学学报, 2015, 49(12): 1768-1777.
[7]	潘向烽1，段振刚1，张乐福1，王力1，徐雪莲2，石秀强2. 锌对316L奥氏体不锈钢氧化膜影响的XPS分析[J]. 上海交通大学学报（自然版）, 2014, 48(03): 417-421.

奥氏体不锈钢双极板的低温超饱和气体渗碳表面改性

Surface Modification of Austenitic Stainless Steel Bipolar Plates by Low Temperature Colossal Supersaturation Gaseous Carburization

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献［16］

相关文章 7

编辑推荐

Metrics

本文评价

奥氏体不锈钢双极板的低温超饱和气体渗碳表面改性

Surface Modification of Austenitic Stainless Steel Bipolar Plates by Low Temperature Colossal Supersaturation Gaseous Carburization

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献 ［16］

相关文章 7

编辑推荐

Metrics

本文评价

参考文献［16］