破碎锤活塞失效分析及活塞用SNCM616钢的优化

doi:10.13251/j.issn.0254-6051.2025.06.049

金属热处理 ›› 2025, Vol. 50 ›› Issue (6): 314-319.DOI: 10.13251/j.issn.0254-6051.2025.06.049

破碎锤活塞失效分析及活塞用SNCM616钢的优化

杜正龙^1,2, 李波^1,2, 张光鸿^1,2, 彭峰^1,2, 王占忠^1,2, 郭士北^1,2

1.大冶特殊钢有限公司技术中心, 湖北黄石 435001;
2.高品质特殊钢湖北省重点实验室, 湖北黄石 435001

收稿日期:2025-01-27 修回日期:2025-04-24 出版日期:2025-06-25 发布日期:2025-07-08
作者简介:杜正龙(1985—),男,工程师,学士,主要研究方向为工程用钢的开发,E-mail: duzhenglong@citicsteel.com

Failure analysis of piston of breaking hammer and optimization of piston steel SNCM616

Du Zhenglong^1,2, Li Bo^1,2, Zhang Guanghong^1,2, Peng Feng^1,2, Wang Zhanzhong^1,2, Guo Shibei^1,2

1. Technology Center, Daye Special Steel Co., Ltd., Huangshi Hubei 435001, China;
2. Hubei Key Laboratory of High Quality Special Steel, Huangshi Hubei 435001, China

Received:2025-01-27 Revised:2025-04-24 Online:2025-06-25 Published:2025-07-08

摘要/Abstract

摘要： 采用直读光谱仪、金相显微镜和扫描电镜对用户提供的失效破碎锤活塞断口进行了成分测试及组织观察,分析活塞断裂原因,并按用户要求对活塞用SNCM616钢进行了成分与热处理工艺优化。结果表明,活塞断裂原因为表面渗碳层及附近区域粗晶、碳化物异常析出以及使用时发热烧蚀共同作用导致裂纹在渗碳层萌生,之后在交变应力作用下疲劳扩展直至断裂。在JIS G 4053:2016标准基础上,采用低P、低S及添加微量V元素的设计思路,制备了P、S含量仅0.005%、V含量0.12%的SNCM616钢。在原热处理工艺基础上,对热处理工艺进行了改进,即在渗碳后增加正火工序(860 ℃保温2 h,空冷),并在低温回火后增加深冷工序(－140 ℃深冷14 h)。经机加工及改进工艺热处理后,新开发SNCM616钢试制活塞的渗碳层及心部组织晶粒较细,不低于5级,渗碳层无异常碳化物析出,硬度满足用户要求。

关键词: SNCM616钢, 活塞, 断口, 热处理, 晶粒度, 碳化物, 性能

Abstract: Composition and microstructure of the fracture surface of a curshing hammer piston provided by the user were studied by means of direct reading spectrometer, metallographic microscope and scanning electron microscope, and the cause of the piston fracture was analyzed, and then the chemical composition and heat treatment process of the SNCM616 steel for pistons were optimized according to the user requirements. The results indicate that the fracture of the piston is caused by the combined effect of coarse grains and abnormal precipitation of carbides in the surface carburized layer and its nearby zones, as well as thermal ablation during use, resulting in crack initiation in the carburized layer, followed by fatigue propagation under alternating stress until fracture. Based on the JIS G 4053:2016 standard, SNCM616 steel with P and S content of only 0.005% and V content of 0.12% is prepared by the design concept of low P, low S and addition of trace V element. On the basis of the original heat treatment process, the heat treatment process is improved by adding normalizing process (860 ℃ for 2 h, air cooling) after carburizing and cryogenic process (-140 ℃ for 14 h) after low-temperature tempering. After machining and improved heat treatment, the grain size of the carburized layer and at core of the piston trial-produced by the newly developed SNCM616 steel is relatively fine, not less than grade 5, no abnormal carbide precipitates in the carburized layer, and the hardness meets user requirements.

Key words: SNCM616 steel, piston, fracture, heat treatment, grain size, carbides, properties

中图分类号:

TG142.1

杜正龙, 李波, 张光鸿, 彭峰, 王占忠, 郭士北. 破碎锤活塞失效分析及活塞用SNCM616钢的优化[J]. 金属热处理, 2025, 50(6): 314-319.

Du Zhenglong, Li Bo, Zhang Guanghong, Peng Feng, Wang Zhanzhong, Guo Shibei. Failure analysis of piston of breaking hammer and optimization of piston steel SNCM616[J]. Heat Treatment of Metals, 2025, 50(6): 314-319.

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破碎锤活塞失效分析及活塞用SNCM616钢的优化

Failure analysis of piston of breaking hammer and optimization of piston steel SNCM616

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