Study on Creep Rupture Strength and Fracture Behavior of Super304H/T92Austenitic Heat-resistant Steel Friction Welding Joints
ZHANG Jianlong1,2, XUE He1, LU Yuan2
1 School of Mechanical Engineering, Xi’an University of Science and Technology, Xi’an 710054 2 Xi’an Special Equipment Inspection Institute, Xi'an 710065
Abstract: In this paper, the isotherm method was used to extrapolate the results of the creep rupture strength test of the Super304H/T92 friction welding joint at 625 ℃. Service life prediction curves indicated that Super304H/T92 weld joints could ensure safe service for duration of 105 h at 625 ℃, which is in according with the ultra-supercritical units steam conditions. The rupture process of the specimens is normal, and the fracture location is on the T92 heat affected zone. When the stress is higher, the rupture mode belongs to transcrystalline fracture, and results in forming dimples. When the stress is lower, the rupture mode belongs to creep rupture, and results in cleavage rupture. With the decrease of stress load and the extension of the fracture time, the number of dimples reduced significantly, the cleavage surface increased gradually, and plastic rupture transformed into cleavage rupture. This research provides the theoretical basis and experimental support for the further engineering application of the Super304H/T92 friction welding technology.
1 Zhao Q X, Zhu L H. Research on heat-resistant steel for supercritical boi-ler, China Machine Press, China, 2010 (in Chinese). 赵钦新, 朱丽慧. 超临界锅炉耐热钢研究, 机械工业出版社, 2010. 2 Lou Y M, Zheng H H. Zhe Jiang Electric Power, 2015(5), 39 (in Chinese). 楼玉民, 郑宏晔. 浙江电力, 2015(5), 39. 3 Zhang Q, Wang J Q, Chen G H. The Chinese Journal of Nonferrous Me-tals, 2013, 23(2), 396 (in Chinese). 张祺, 王家庆, 陈国宏. 中国有色金属学报, 2013, 23(2), 396. 4 Zhang Z W, Li X M, Zou Y. Hot Working Technology, 2011, 40(23), 17 (in Chinese). 张忠文, 李新梅, 邹勇. 热加工工艺, 2011, 40(23), 17. 5 Wu W, Deng F. Journal of Chongqing University of Technology (Natural Science), 2017, 31(12),72 (in Chinese). 吴玮, 邓发. 重庆理工大学学报(自然科学), 2017, 31(12),72. 6 Li P, Li J, Li X, et al. Journal of Adhesion Science and Technology, 2015, 29(12), 1246. 7 Li X, Li J, Liao Z, et al. Journal of Adhesion Science and Technology, 2018, 32(18), 1987. 8 Li X, Li J, Liao Z, et al. Materials & Design, 2016, 99, 26. 9 Wang S B, Wu C L, Yuan M. Journal of Nanjing University, 2009, 43(2), 269(in Chinese). 王双宝, 伍翠兰, 元敏. 南京大学学报, 2009, 43(2), 2694. 10Wang Y F, Zheng K Y, Wu Z Y. Journal of Chinese Society of Power Engineering, 2010, 30(4), 245(in Chinese). 王延峰, 郑开云, 吾之英. 动力工程学报, 2010, 30(4), 245. 11Song Y M. Studies on high-temperature microstructures and mechanical properties of the T92/HR3C dissimilar steel weld joints. Master’s Thesis, Hefei University of Technology, China, 2012 (in Chinese). 宋有明. T92/HR3C接头的髙温组织结构与力学性能的研究. 硕士学位论文, 合肥工业大学, 2012. 12Hao M M, Peng B C, Wang Q J. Materials for Mechanical Engineering, 2011, 35(10), 32(in Chinese). 郝曼曼, 彭碧草, 王起江. 机械工程材料, 2011, 35(10), 32. 13Cao J, Gong Y, Yang Z G, et al. International Journal of Pressure Vessels and Piping, 2011, 88, 94. 14Cao J, Gong Y, Yang Z G. Materials Science and Engineering A, 2011, 528, 6103. 15Wang L, Liu Z D, Chen P. Press Vessel Technology, 2008, 25(3), 1 (in Chinese). 王亮, 刘宗德, 陈鹏. 压力容器, 2008, 25(3), 1. 16Wang S B. High-temperature resistant property and microstructure characterization of T92 boiler steel. Master’s Thesis, Hunan University, China, 2009 (in Chinese). 王双宝. T92 锅炉钢抗高温性能及其微观组织表征, 硕士学位论文, 湖南大学, 2009.