Experiment and Simulation Prediction of Grinding Burn of Gear Steel 18Cr2Ni4WA

被引：0

作者：

Liang Z.-Q. ^{[1
]}

Huang D.-Q. ^{[1
]}

Zhou T.-F. ^{[1
]}

Li H.-W. ^{[1
,2
]}

Qiao Z. ^{[1
]}

Wang X.-B. ^{[1
]}

Liu X.-L. ^{[2
]}

机构：

[1] Key Laboratory of Fundamental Science for Advanced Machining, Beijing Institute of Technology, Beijing

[2] Beijing North Vehicle Group Corporation, Beijing

来源：

Binggong Xuebao/Acta Armamentarii | 2017年 / 38卷 / 10期

关键词：

Finite element analysis; Gear steel; Grinding burn; Microhardness; Surface and interface of materials;

D O I：

10.3969/j.issn.1000-1093.2017.10.016

中图分类号：

学科分类号：

摘要：

18Cr2Ni4WA steel has been widely used to manufacture the heavy-duty gears, such as spiral bevel gear, which is characterized by high toughness and high strength. Grinding burn easily occurs due to the high temperature during grinding, which makes the grinding precision and surface quality difficult to meet the requirements. The surface hardness, hardness gradient and surface morphology of workpiece are analyzed through single factor experiment, and the degree of grinding burn is simulated using the finite element analysis software. The results show that, with the increase in grinding depth, the degree of grinding burn is aggravated, the color of oxide layer is changed from faint yellow to brown, and finally becomes cyan, and the surface morphology is changed from clear texture to heavily coated. The hardness of surface layer decreases and a tempered sorbite is produced due to tempering burn. The measured and simulated values of grinding burn depth are basically identical, which shows that the degree of grinding burn can be predicted by the finite element simulation. © 2017, Editorial Board of Acta Armamentarii. All right reserved.

引用

页码：1995 / 2001

页数：6

共 16 条

[1] Xu Z.-J., Wei S.-P., Zhou P., Et al., Optimization of heat treatment process after vacuum carburizing of 18Cr2Ni4WA steel, Heat Treatment of Metals, 39, 9, pp. 32-35, (2014)
[2] Qiao Z., Liang Z.-Q., Zhao W.-X., Et al., Grinding hardening of 30CrMnTi gear steel, China Surface Engineering, 30, 1, pp. 26-32, (2017)
[3] Huang X.-C., Zhang D.-H., Yao C.-F., Et al., Research on the grinding burn of the ultrahigh strength steel AerMet100, Journal of Mechanical Engineering, 51, 9, pp. 184-190, (2015)
[4] Zhang H.-X., Chen W.-Y., Chen Z.-T., Grinding burn mechanism of titanium alloys with SG wheels, Journal of Beijing University of Aeronautics and Astronautics, 34, 1, pp. 22-26, (2008)
[5] Ming X.-Z., Li F., Zhou J., Modeling simulation and experimental validation of grinding surface burn of spiral bevel gear, Journal of Mechanical Transmission, 38, 5, pp. 15-20, (2014)
[6] Dai C., Ding W., Xu J., Et al., Effects of undeformed chip thickness on grinding temperature and burn-out in high-efficiency deep grinding of Inconel718 superalloys, International Journal of Advanced Manufacturing Technology, 89, 4, pp. 1841-1852, (2017)
[7] Ding W., Linke B., Zhu Y., Et al., Review on monolayer CBN superabrasive wheels for grinding metallic materials, Chinese Journal of Aeronautics, 30, 1, pp. 109-134, (2017)
[8] Ding W.F., Xu J.H., Chen Z.Z., Et al., Fabrication and performance of porous metal-bonded CBN grinding wheels using alumina bubble particles as pore-forming agents, The International Journal of Advanced Manufacturing Technology, 67, 5, pp. 1309-1315, (2013)
[9] Guo L., Sheng X.-M., Li B., Experimental study on surface burn of ultra high speed deep grinding, Precise Manufacturing & Automation, 4, pp. 6-8, (2012)
[10] Guan H.-B., Chen L., Zhang X.-M., Et al., Surface micro-structure damage of 40Cr samples in pre-stressed dry grinding process, China Surface Engineering, 29, 2, pp. 117-122, (2016)

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