16Cr3NiWMoVNbE钢C型环真空低压渗碳及淬火有限元模拟

doi:10.13251/j.issn.0254-6051.2022.09.044

金属热处理 ›› 2022, Vol. 47 ›› Issue (9): 257-263.DOI: 10.13251/j.issn.0254-6051.2022.09.044

16Cr3NiWMoVNbE钢C型环真空低压渗碳及淬火有限元模拟

袁丽¹, 贺笃鹏², 何欣¹, 秦湘阁¹

1.佳木斯大学材料科学与工程学院, 黑龙江佳木斯 154007;
2.中国钢研科技集团有限公司, 北京 100081

收稿日期:2022-05-04 修回日期:2022-07-28 发布日期:2022-10-18
作者简介:袁丽(1996—), 女, 硕士研究生, 主要研究方向为材料工艺数值模拟, E-mail: 18715275645@qq.com。
基金资助:
黑龙江省教育厅基本科研业务费基础研究项目(2019-KYYWF-1371)

Finite element simulation of vacuum low pressure carburizing and quenching of 16Cr3NiWMoVNbE steel C-ring

Yuan Li¹, He Dupeng², He Xin¹, Qin Xiangge¹

1. School of Materials Science and Engineering, Jiamusi University, Jiamusi Heilongjiang 154007, China;
2. China Iron and Steel Research Institute Group, Beijing, 100081, China

Received:2022-05-04 Revised:2022-07-28 Published:2022-10-18

摘要/Abstract

摘要： 通过马氏体转变动力学和碳浓度的扩散系数有限元模型,对16Cr3NiWMoVNbE齿轮钢C型环进行真空低压渗碳淬火的温度场、浓度场、组织场、以及应力场的研究。结果表明,渗碳淬火后,得到碳浓度分布,可以很好地解释表层部分的最终马氏体分布情况,为预测齿轮钢渗碳淬火后碳浓度分布和马氏体分布提供了可靠依据。

关键词: 16Cr3NiWMoVNbE齿轮钢, 真空低压渗碳, C型环, 温度场

Abstract: Temperature field, concentration field, microstructure field and stress field of vacuumlow pressure carburizing and quenching of 16Cr3NiWMoVNbE gear steel C-ring were studied by using the finite element model of martensitic transformation kinetics and carbon concentration diffusion coefficient. The results show that the carbon concentration distribution obtained after carburizing quenching can well explain the final martensite distribution in the surface layer. A reliable basis is provided for predicting the carbon concentration distribution and martensite distribution of the gear steel after carburization and quenching.

Key words: 16Cr3NiWMoVNbE gear steel, vacuum low pressure carburising, C-ring, temperature field

中图分类号:

TG156

袁丽, 贺笃鹏, 何欣, 秦湘阁. 16Cr3NiWMoVNbE钢C型环真空低压渗碳及淬火有限元模拟[J]. 金属热处理, 2022, 47(9): 257-263.

Yuan Li, He Dupeng, He Xin, Qin Xiangge. Finite element simulation of vacuum low pressure carburizing and quenching of 16Cr3NiWMoVNbE steel C-ring[J]. Heat Treatment of Metals, 2022, 47(9): 257-263.

参考文献

[1]张文帅, 周贤良, 李晖榕, 等. 新型16Cr3NiWMoVNbE齿轮钢渗碳工艺与性能研究[J]. 热加工工艺, 2010, 39(24): 216-218.
Zhang Wenshuai, Zhou Xianliang, Li Huirong, et al. Study on carburizing process for new-type 16Cr3NiWMoVNbE gear steel and its properties[J]. Hot Working Technology, 2010, 39(24): 216-218.
[2]温冠云, 杜晨, 麻瑜梁, 等. 12CrNi3斜齿轮渗碳淬火工艺有限元仿真关键技术研究[J]. 新技术新工艺, 2019(6): 20-26.
Wen Guanyun, Du Chen, Ma Yuliang, et al. Research on the key technology of finite element simulation of 12CrNi3 helical gear carburizing and quenching process[J]. New Technology and New Process, 2019(6): 20-26.
[3]Wołowiec K E. Modeling methods for gas quenching, low-pressure carburizing and low-pressure nitriding[J]. Engineering Structures, 2018, 177: 489-505.
[4]张建国, 丛培武. 真空渗碳技术国内外概况及发展[J]. 金属热处理, 2003, 28(10): 52-55.
Zhang Jianguo, Cong Peiwu. Development of vacuum carburizing technology at home and abroad[J]. Heat Treatment of Metals, 2003, 28(10): 52-55.
[5]Wołowiec E, Kula P. The application of artificial neural networks in optimization of heat treatment processes of steel[J]. Journal of Applied Computer Science, 2011, 19(1): 161-169.
[6]Zajusz M, Tkacz M K, Danielews K M. Modeling of vacuum pulse carburizing of steel[J]. Surface and Coatings Technology, 2014, 258: 646-651.
[7]张星, 唐进元. 17CrNiMo6钢内齿圈渗碳仿真关键技术研究[J]. 金属热处理, 2015, 40(3): 185-189.
Zhang Xing, Tang Jinyuan. Key technology in carburizing process simulation for 17CrNiMo6 steel annular gear[J]. Heat Treatment of Metals, 2015, 40(3): 185-189.
[8]王硕彬, 丛培武, 陈旭阳, 等. 20CrMoH钢的真空低压渗碳工艺模拟及优化[J]. 金属热处理, 2022, 47(5): 189-193.
Wang Shuobin, Cong Peiwu, Chen Xuyang, et al. Simulation and optimization of low-pressure carburizing process for 20CrMoH steel[J]. Heat Treatment of Metals, 2022, 47(5): 189-193.
[9]王志新, 施建军, 梅俊歌, 等. 20CrNi2Mo钢真空渗碳工艺及数值模拟[J]. 金属热处理, 2017, 42(11): 117-122.
Wang Zhixin, Shi Jianjun, Mei Junge, et al. Numerical simulation on vacuum carburization of 20CrNi2Mo steel[J]. Heat Treatment of Metals, 2017, 42(11): 117-122.
[10]韩妙玲, 王静, 张国峰, 等. 精密齿轮件的真空低压渗碳高压气淬热处理[J]. 金属热处理, 2019, 44(6): 184-186.
Han Miaoling, Wang Jing, Zhang Guofeng, et al. Vacuum low pressure carburizing and high-pressure gas quenching heat treatment of precision gear[J]. Heat Treatment of Metals, 2019, 44(6): 184-186.
[11]Kim D W, Cho Y G, Cho H H, et al. A numerical model for vacuum carburization of an automotive gear ring[J]. Metals and Materials International, 2011, 17(6): 885-890.
[12]Yan Y M, Xue Y J, Yu W C, et al. Predictions and experiments on the distortion of the 20Cr2Ni4A C-ring during carburizing and quenching process[J]. Materials, 2022, 15(12): 4345-4345.
[13]Wang J G, Yang S, Li J H, et al. Mathematical simulation and experimental verification of carburizing quenching process based on multi-field coupling[J]. Coatings, 2021, 11(9): 1132-1132.
[14]Guo J Y, Deng X H, Wang L Y, et al. Modeling and simulation of vacuum low pressure carburizing process in gear steel[J]. Coatings, 2021, 11(8): 1003-1003.
[15]谢成, 朱戈阳, 寻丹, 等. 16Cr3NiWMoVNbE 渗碳淬火组织与热物理力学性能的数值模拟[[J]. 湖南科技大学学报(自然科学版), 2018, 33(1): 78-83.
Xie Cheng, Zhu Geyang, Xun Dan, et al. Simulation of carburizing quenched microstructure and thermo-physical mechanical properties for 16Cr3NiWMoVNbE steel[J]. Journal of Hunan University of Science and Technology (Natural Science Edition), 2018, 33(1): 78-83.
[16]Saunders N, Guo U K Z, Li X, et al. Using JMatPro to model materials properties and behavior[J]. JOM, 2003, 55(12): 60-65.
[17]Yu H X, Yang M, Sisson R D. Application of C-ring specimen for controlling the distortion of parts during quenching[J]. Metal Science and Heat Treatment, 2021(63): 220-228.
[18]贺笃鹏, 张国强, 王毛球, 等. 18CrNiMo7-6齿轮钢高温渗碳淬火变形数值模拟[J]. 金属功能材料, 2021, 28(5): 13-20.
He Dupeng, Zhang Guoqiang, Wang Maoqiu, et al. Simulation analysis of high temperature carburizing and quenching deformation of gear steel 18CrNiMo7-6[J]. Metallic Functional Materials, 2021, 28(5): 13-20.
[19]Wang H J, Wang B, Wang Z D, et al. Optimizing the low-pressure carburizing process of 16Cr3NiWMoVNbE gear steel[J]. Journal of Materials Science and Technology, 2019, 35(7): 1218-1227.
[20]陈旭阳, 陆文林, 杜春辉, 等. 大长径比零件高压气淬温度场数值模拟[J]. 金属热处理, 2021, 46(10): 242-247.
Chen Xuyang, Lu Wenlin, Du Chunhui, et al. Numerical simulation of temperature field of parts with large aspect ratio during high pressure gas quenching process[J]. Heat Treatment of Metals, 2021, 46(10): 242-247.

16Cr3NiWMoVNbE钢C型环真空低压渗碳及淬火有限元模拟

Finite element simulation of vacuum low pressure carburizing and quenching of 16Cr3NiWMoVNbE steel C-ring

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