采用宏观电化学试验和浸泡试验研究25Cr2Ni2MoV汽轮机转子堆焊焊接接头在80 ℃,3.5% Cl−环境下的电偶腐蚀行为. 电化学试验结果表明,焊缝为腐蚀薄弱区,腐蚀电位从高到低依次为热影响区、母材、焊缝. 浸泡试验结果表明,随着母材面积的增大,焊缝平均腐蚀厚度逐渐加深. 进一步利用宏观电化学测试所获的电化学参量建立焊接接头电偶腐蚀有限元模型对比浸泡试验结果. 结果表明,有限元仿真结果能有效模拟堆焊焊接接头的电偶腐蚀行为,为实际生产提供电偶腐蚀速率预测.
The galvanic corrosion behavior of 25Cr2Ni2MoV overlaying welded nuclear steam turbine rotor was investigated by macro-electrochemical tests and immersion tests in chloride solution at 80 ℃. The results of electrochemical experiments show that the weld metal is the weak corrosion zone, and the corrosion potential from low to high is the heat-affected zone, the base metal, and the weld metal. The results of the immersion tests show that as the area of the BM increases, the average corrosion thickness of the WM gradually increases Furthermore, the galvanic corrosion finite element model of welded joint was established by using the electrochemical parameters obtained from macro electrochemical test. The results show that the finite element simulation results can effectively simulate the galvanic corrosion behavior of overlaying welding joint and provide galvanic corrosion rate prediction for actual production.
[1] Mazur Z, Hernandez-Rossette A. Steam turbine rotor discs failure evaluation and repair process implementation[J]. Engineering Failure Analysis, 2015, 56: 545 ? 554.
[2] 温建锋, 轩福贞, 涂善东. 高温构件蠕变损伤与裂纹扩展预测研究新进展[J]. 压力容器, 2019, 36(2): 38 ? 50
Wen Jianfeng, Xuan Fuzhen, Tu Shantung. Advances in predictions of creep damage and crack growth in components under high temperatures[J]. Pressure Vessel Technology, 2019, 36(2): 38 ? 50
[3] Mitchell K C. Weld repair of steam turbine rotors[D]. Swansea: Swansea University, 1999.
[4] Mazur-Czerwiec Z, Kubiak J, Hernández A. Welding repair of steam and gas turbine rotors made of Cr-Mo-V steel[J]. Welding International, 2000, 14: 203 ? 210.
[5] Li S, Dong H, Wang X, et al. Effect of repair welding on microstructure and mechanical properties of 7N01 aluminum alloy MIG welded joint[J]. Journal of Manufacturing Processes, 2020, 54: 80 ? 88.
[6] Dak G, Pandey C. A critical review on dissimilar welds joint between martensitic and austenitic steel for power plant application[J]. Journal of Manufacturing Processes, 2020, 58(4): 377 ? 406.
[7] Lin Y J, Lin C S. Galvanic corrosion behavior of friction stir welded AZ31B magnesium alloy and 6N01 aluminum alloy dissimilar joints[J]. Corrosion Science, 2021, 180: 1 ? 5.
[8] Wang S, Ding J, Ming H, et al. Characterization of low alloy ferritic steel–Ni base alloy dissimilar metal weld interface by SPM techniques, SEM/EDS, TEM/EDS and SVET[J]. Materials Characterization, 2015, 100: 50 ? 60.
[9] Dhanapal A, Rajendra Boopathy S, Balasubramanian V. Corrosion behaviour of friction stir welded AZ61A magnesium alloy welds immersed in NaCl solutions[J]. Transactions of Nonferrous Metals Society of China, 2012, 22(4): 793 ? 802.
[10] Zhu J, Xu L, Feng Z, et al. Galvanic corrosion of a welded joint in 3Cr low alloy pipeline steel[J]. Corrosion Science, 2016, 111: 391 ? 403.
[11] Weng S, Huang Y, Xuan F Z, et al. Correlation between microstructure, hardness and corrosion of welded joints of disc rotors[J]. Procedia Engineering, 2015, 130: 1761 ? 1769.
[12] 周鲁军, 董毅, 杨善武. E550钢埋弧焊接接头在模拟海洋大气环境中的腐蚀行为[J]. 材料热处理学报, 2020, 41(4): 173 ? 180
Zhou Lujun, Dong yi, Yang Shanwu. Corrosion behavior of submerged arc welded joint of E550 steel in simulated marine atmospheric environment[J]. Transactions of Materials and Heat Treatment, 2020, 41(4): 173 ? 180
[13] 欧阳玉清, 黄毓晖, 翁硕, 等. 核电汽轮机焊接转子接头在氯离子环境中的电偶腐蚀行为[J]. 焊接学报, 2019, 40(6): 153 ? 160
Ouyang Yuqing, Huang Yuhui, Weng Shuo, et al. Galvanic corrosion behavior of nuclear steam turbine welded joint in chloride environment[J]. Transactions of the China Welding Institution, 2019, 40(6): 153 ? 160
[14] Oh S, Kim Y, Jung K, et al. Effects of temperature and operation parameters on the galvanic corrosion of Cu coupled to Au in organic solderability preservatives process[J]. Metals and Materials International, 2017, 23(2): 290 ? 297.
[15] Deshpande K B. Validated numerical modelling of galvanic corrosion for couples: Magnesium alloy (AE44)–mild steel and AE44–aluminium alloy (AA6063) in brine solution[J]. Corrosion Science, 2010, 52(10): 3514 ? 3522.
[16] Snihirova D, H?che D, Lamaka S, et al. Galvanic corrosion of Ti6Al4V -AA2024 joints in aircraft environment: Modelling and experimental validation[J]. Corrosion Science, 2019, 157: 70 ? 78.
[17] Yin L, Jin Y, Leygraf C, et al. A FEM model for investigation of micro-galvanic corrosion of Al alloys and effects of deposition of corrosion products[J]. Electrochimica Acta, 2016, 192: 310 ? 318.
[18] Shi L, Song Y, Zhao P, et al. Variations of galvanic currents and corrosion forms of 2024/Q235/304 tri-metallic couple with multivariable cathode/anode area ratios: Experiments and modeling[J]. Electrochimica Acta, 2020, 359: 1 ? 10.
[19] 曹楚南. 腐蚀电化学原理[M]. 北京: 化学工业出版社, 2008.
Cao Chunan. Principles of electrochemistry of corrosion[M]. Beijing: Chemical Industry Press, 2008.
