Numerical simulation on shape coefficient for tubular workpiece during heat treatment

doi:10.13251/j.issn.0254-6051.2024.03.046

Abstract

Abstract: For the problem of long tubular shape coefficient in the current heat treatment standard, a standard sample library consisting of 21 simulated temperature curves with Ø20-Ø40 mm diameter of the rod was established by using the Heat Transfer analysis module provided by ABAQUS simulation software and by uniform adopting environmental radiation heat transfer. Using simulation and data analysis technology, the “thickness comparison method under equivalent circular rod diameter condition” is proposed. The results show that the short tube shape coefficient is 2, and the long tube shape coefficient is 2+2R_inside/R_outside.

Key words: numerical simulation, tubular workpiece, shape coefficient, conditional thickness

CLC Number:

TG162.83

Liu Gang, Liu Yanmei, Zhang Zengguang, Kang Chong, Wang Xinyu, Liao Qiyu. Numerical simulation on shape coefficient for tubular workpiece during heat treatment[J]. Heat Treatment of Metals, 2024, 49(3): 279-285.

References

[1]Yang Shiming. Improvement of the basic correlating equations and transition criteria of natural convection heat transfer[J]. Heat Transerasian Research, 2001, 30(4): 293.
[2]杨志勇, 刘振宝, 梁剑雄, 等. 马氏体时效不锈钢的发展[J]. 材料热处理学报, 2008, 29(4): 1-7.
Yang Zhiyong, Liu Zhenbao, Liang Jianxiong, et al. Development of maraging stainless steel[J]. Transactions of Materials and Heat Treatment, 2008, 29(4): 1-7.
[3]颜如皋, 吴学仁, 朱知寿. 航空材料技术的发展现状与展望[J]. 航空制造技术, 2003, 46(12): 19-25.
Yan Ruhao, Wu Xueren, Zhu Zhishou. Recent progress and prospects for aeronautical material technologies[J]. Aeronautical Manufacturing Technology, 2003, 46(12): 19-25.
[4]Eckert E R G, Drake R M. Heat and Mass Transfer[M]. New York: McGraw-Hill Book Company, 1959.
[5]樊东黎, 徐跃明, 佟晓辉. 热处理工程师手册[M]. 北京: 机械工业出版社, 2005.
[6]刘晓菲. 热处理淬火过程计算机模拟的现状与展望[J]. 工业加热, 2008, 37(3): 61-63.
Liu Xiaofei. The status and perspective of computer simulation in heat treatment quenching process[J]. Industrial Heating, 2008, 37(3): 61-63.
[7]刘庄, 吴肇基, 吴景之, 等. 热处理过程的数值模拟[M]. 北京: 科学出版社, 1996.
[8]陶文铨. 传热学[M]. 西安: 西北工业大学出版社, 2006.
[9]过曾元. 对流换热的物理机制及其控制: 速度场与热流场的协同[J]. 科学通报, 2000, 45(19): 2118-2120.
[10]Rose H, Rademacher R, Marzo M D. Horizontal flow boilling of pure and mixed refrigerants[J]. International Journal of Heat and Mass Transfer, 1987, 30(5): 979.
[11]张李强, 王婧, 骆晓萌, 等. 热处理过程流场-温度场-组织场-应力场耦合模拟研究[J]. 金属热处理, 2017, 42(8): 181-186.
Zhang Liqiang, Wang Jing, Luo Xiaomeng, et al. Coupled numerical simulation of flow field, temperature field, microstructure field and stress field on heat treatment process[J]. Heat Treatment of Metals, 2017, 42(8): 181-186.
[12]陈乃录, 潘健生, 廖波. 用冷却曲线估测动态条件下淬火油的淬火烈度[J]. 金属热处理, 2002, 27(12): 46-48.
Chen Nailu, Pan Jiansheng, Liao Bo. Estimating quench severity of quenching oil at various flow rates with cooling curves[J]. Heat Treatment of Metals, 2002, 27(12): 46-48.

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