Numerical Analysis of Surface Temperature in Grind-Hardening Based on Time Variation Heat Flux

被引:2
作者
Zhang, Y. [1 ]
Ge, P. Q. [1 ]
Zhang, L. [1 ]
机构
[1] Shandong Univ, Sch Mech Engn, Jinan 250061, Peoples R China
来源
ADVANCES IN MATERIALS MANUFACTURING SCIENCE AND TECHNOLOGY XIV | 2012年 / 697-698卷
关键词
Grind-hardening; Grinding force; Grinding temperature;
D O I
10.4028/www.scientific.net/MSF.697-698.34
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The invariable heat flux is always loaded in temperature simulation for grind-hardening. The heat flux is time-variant in actual process. The paper uses experiment result of grinding force to calculate out the time variation heat flux. The grinding temperature is simulated based on time variation heat flux by ANSYS software. The variation tendencies for the grinding force and the simulated surface top temperature will be discussed.
引用
收藏
页码:34 / 38
页数:5
相关论文
共 38 条
[21]   Analysis of the distortion and compensation potential in grind-hardening of linear guides [J].
Soelter, J. ;
Eckebrecht, J. ;
Kolkwitz, B. ;
Heinzel, C. .
MATERIALWISSENSCHAFT UND WERKSTOFFTECHNIK, 2016, 47 (08) :726-734
[22]   Mechanism investigation of hardening layer hardness uniformity based on grind-hardening process [J].
Liu, Minghe ;
Zhang, Ke ;
Xiu, Shichao .
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2017, 88 (9-12) :3185-3194
[23]   Multi-Objective Optimization of Surface Integrity in the Grind-Hardening Process [J].
Wang, Chunyan ;
Wang, Guicheng ;
Shen, Chungen ;
Dai, Xinyu .
COATINGS, 2024, 14 (07)
[24]   Experimental and numerical identification of process parameters of grind-hardening and resulting part distortions [J].
Zäh M.F. ;
Brinksmeier E. ;
Heinzel C. ;
Huntemann J.-W. ;
Föckerer T. .
Production Engineering, 2009, 3 (03) :271-279
[25]   Study on External Grind-hardening Experiments and the Analysis of Hardening Effects for 40Cr Steel [J].
Yang, Gang ;
Han, Zhengtong ;
Du, Changlong .
ADVANCE MATERIALS DEVELOPMENT AND APPLIED MECHANICS, 2014, 597 :223-+
[26]   Residual stress distribution at grind-hardening layer surface of the 40Cr workpiece [J].
Zou, J. F. ;
Pei, H. J. ;
Hua, C. L. ;
Jiao, B. ;
Wang, G. C. .
MATERIALS RESEARCH INNOVATIONS, 2015, 19 :580-584
[27]   Research on grind-hardening layer and residual stresses based on variable grinding forces [J].
Xiangming Huang ;
Yinghui Ren ;
Wei Wu ;
Tong Li .
The International Journal of Advanced Manufacturing Technology, 2019, 103 :1045-1055
[28]   Investigation on simulation for grind-hardening temperature field of non-quenched and tempered steel [J].
Li, Shusheng ;
Xiao, Bing ;
Qin, Songxiang ;
Song, Zhenghe ;
Su, Honghua ;
Gong, Huan .
ADVANCES IN MACHINING AND MANUFACTURING TECHNOLOGY IX, 2008, 375-376 :520-+
[29]   Research on grind-hardening layer and residual stresses based on variable grinding forces [J].
Huang, Xiangming ;
Ren, Yinghui ;
Wu, Wei ;
Li, Tong .
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2019, 103 (1-4) :1045-1055
[30]   Experiment research on grind-hardening of AISI5140 steel based on thermal compensation [J].
Xiangming Huang ;
Yinghui Ren ;
Bo Zheng ;
Zhaohui Deng ;
Zhixiong Zhou .
Journal of Mechanical Science and Technology, 2016, 30 :3819-3827
1234