金属热处理 ›› 2023, Vol. 48 ›› Issue (2): 242-246.DOI: 10.13251/j.issn.0254-6051.2023.02.038

• 数值模拟 • 上一篇    下一篇

42CrMo钢输出法兰感应淬火的数值模拟及验证

王伟, 张文, 赵建森, 朱百智, 米艳军, 江红兵, 胡成飞   

  1. 南京高速齿轮制造有限公司, 江苏 南京 211100
  • 收稿日期:2022-09-07 修回日期:2022-12-17 出版日期:2023-02-25 发布日期:2023-03-22
  • 通讯作者: 张 文,工程师,硕士,E-mail:1347476466@qq.com
  • 作者简介:王 伟(1982—),男,工程师,硕士,主要研究方向为热处理工艺技术,E-mail: wang.weiN880747@NGCtransmission.com。

Numerical simulation and experimental verification of induction quenching for output flange of 42CrMo steel

Wang Wei, Zhang Wen, Zhao Jiansen, Zhu Baizhi, Mi Yanjun, Jiang Hongbing, Hu Chengfei   

  1. Nanjing High Accurate Drive Equipment Manufacturing Co., Ltd., Nanjing Jiangsu 211100, China
  • Received:2022-09-07 Revised:2022-12-17 Online:2023-02-25 Published:2023-03-22

摘要: 基于电磁-热-组织-应力耦合模型,采用数值模拟研究了42CrMo钢输出法兰感应淬火过程中的温度、组织和应力的变化规律,同时采用硬化轮廓对比和硬度检测验证了模拟的可靠性。研究表明,在加热阶段,输出法兰圆弧过渡区的上、下尖角比中间位置先到达奥氏体化温度,感应区域温度到达材料居里点后加热效果逐渐减小;随着温度升高,法兰表面的组织由原始组织向奥氏体组织转变;法兰表面应力在加热阶段为压应力状态,加热开始阶段迅速增大,随着内部温度升高逐渐减小;在淬火阶段,温度迅速降低,表层奥氏体快速转变成马氏体,表层处应力经过短暂拉应力时刻,然后转变成压应力(轴向、径向和切向应力都为压应力),其中径向压应力最大,约为460 MPa。

关键词: 电磁-热-组织-应力耦合模型, 输出法兰, 温度场, 相变, 硬化层, 残余应力

Abstract: Based on the electromagnetic-thermal-microstructure-stress coupling model, the temperature, microstructure and stress variation laws of the 42CrMo steel output flange during induction quenching process were studied, and the reliability of the numerical simulation was experimentally verified by hardening profile comparison and hardness testing. The results show that in the heating stage, the upper and lower sharp corners of the arc transition zone reach the austenitizing temperature earlier than that of the middle position. The heating effect gradually decreases after the temperature of the induction zone reaches the Curie point of the material. The microstructure of flange surface changes from original microstructure to austenite with the increase of temperature. The surface stress of flange is compressive stress in the heating stage, which increases rapidly at the beginning of heating, and then decreases gradually with the increase of internal temperature. In the quenching stage, the temperature drops rapidly, and the surface austenite quickly transforms into martensite. The stress at the surface passes through a short period of tensile stress, and then transforms into compressive stress (axial, radial and tangential stresses are all compressive stresses), among which the radial compressive stress is the largest, about 460 MPa.

Key words: electromagnetic-thermal-microstructure-stress coupled field, output flange, temperature field, phase transformation, hardened layer, residual stress

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