基于热力学耦合的硬质合金砧硬质合金层厚度优化

IF 0.6 4区工程技术 Q4 MECHANICS

Mechanika Pub Date : 2022-10-21 DOI:10.5755/j02.mech.30808

G. Xie, Tao Wang, Liangwen Wang, Xiaoyun Gong, Shixin Zhang, Zeheng Zhi, Ziye Zhao, Xiaojun Yang

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引用次数: 0

摘要

基于热力学耦合分析，对硬质合金砧的硬质合金层厚度进行了优化。在我们的方法中，首先将通过SolidWorks建立的硬质合金砧座系统导入有限元软件中。分析了硬质合金砧座系统的温度场和热-机械耦合场。从模拟结果可以发现，在温度载荷下，钢圈的接触应力比没有温度载荷时增加了17.9%。因此，硬质合金砧在温度负载下的使用寿命低于没有温度负载时的使用寿命。此外，由于剪切应力集中的现象，砧座的四个边缘容易产生疲劳裂纹。这与硬质合金砧座的实际裂纹位置一致，验证了热机械耦合模拟的准确性和合理性。基于热力学耦合对硬质合金层的厚度进行了优化。优化结果表明，当尺寸在1.8cm至2.2cm之间时，1.8cm的厚度最好。最大接触应力、最大剪切应力和温度分别降低了387.5MPa、110.55MPa和10.11℃。

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Cemented Carbide Layer Thickness Optimization of Carbide Anvil Based on Thermodynamic Coupling

This paper presents cemented carbide layer thickness optimization of a carbide anvil based on thermodynamic coupling analysis. In our method, the established carbide anvil system through SolidWorks is firstly imported into the finite element software. The temperature field and thermal-mechanical coupling field of the carbide anvil system are analyzed. From the simulation results, it can be found that the contact stress of steel ring under temperature load is increased by 17.9% compared with that without temperature load. Thus, the service life of carbide anvil under temperature load is lower than that without temperature load. In addition, the four edges of anvil are prone to fatigue cracks due to the phenomenon of shear stress concentration. This is consistent with the actual crack location of cemented carbide anvil, which verifies the accuracy and rationality of thermal-mechanical coupling simulation. The thickness of cemented carbide layer is optimized based on thermodynamic coupling. The optimization results show that the thickness of 1.8cm is the best when size ranges from 1.8cm to 2.2cm. The maximum contact stress, the maximum shear stress, the temperature are all reduced by 387.5MPa, 110.55MPa, and 10.11℃, respectively.

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来源期刊

Mechanika 物理-力学

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： The journal is publishing scientific papers dealing with the following problems: Mechanics of Solid Bodies; Mechanics of Fluids and Gases; Dynamics of Mechanical Systems; Design and Optimization of Mechanical Systems; Mechanical Technologies.