变形对钨合金微观组织性能及绝热剪切敏感性的影响

李淑华; 王富耻; 谭成文; 许保才

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变形对钨合金微观组织性能及绝热剪切敏感性的影响
Effects of Deformation on Microstructure Performance and Adiabatic Shearing Sensitivity of Tungsten Heavy Alloy
2005年第11期
纸质出版日期： 2005 ，
DOI：

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[1]李淑华,王富耻,谭成文,许保才.变形对钨合金微观组织性能及绝热剪切敏感性的影响[J].特种铸造及有色合金,2005(11):31-33+5.

Li Shuhua 1, 2 Wang Fuchi 1 Tan Chengwen 1 Xu Baocai 2. Effects of Deformation on Microstructure Performance and Adiabatic Shearing Sensitivity of Tungsten Heavy Alloy[J]. Special Casting & Nonferrous Alloys, 2005,(11).
[1]李淑华,王富耻,谭成文,许保才.变形对钨合金微观组织性能及绝热剪切敏感性的影响[J].特种铸造及有色合金,2005(11):31-33+5. DOI：

Li Shuhua 1, 2 Wang Fuchi 1 Tan Chengwen 1 Xu Baocai 2. Effects of Deformation on Microstructure Performance and Adiabatic Shearing Sensitivity of Tungsten Heavy Alloy[J]. Special Casting & Nonferrous Alloys, 2005,(11). DOI：

摘要

含有两相且质量分数为90%～97%的钨合金具有高密度、高强度和较高的延展性。钨合金的显微组织、力学状态对绝热剪切行为有很大影响。综述了前人的研究工作

得到如下结论:随着钨颗粒变形程度增加

钨合金强度增加。纤维化程度越高

各向异性越明显

在径向动态压缩时容易产生绝热剪切。预扭转试样钨颗粒呈椭球状

椭球状钨颗粒长轴方向与最大剪应力方向一致时

绝热剪切易于发生

“自锐”现象明显

侵彻能力较强。变形方法、变形量及材料变形后的晶粒取向的研究

将有助于材料绝热剪切机理的研究。

Abstract

Tungsten heavy alloy （WHA） containing 90%～97% W two-phase composites possesses high density and strength and relatively high ductility. The microstructure and mechanical properties has a remarkable effect on the adiabatic shearing sensitivity of the WHA. The former researches were reviewed. The results show that the relative intensity of tungsten heavy alloy is improved with varying tungsten particles figure. The higher the fibre degree is

the more obvious the crystal anisotropy is

and the easier advent the adiabatic shearingis in the model of drawing

extrusion

radial smithing. Tungsten particles become ellipse after torsion. Adiabatic shearing is easily formed and self-sharpness in evidence and capability of penetration is stronger when the elongated axial orientation consistent with orientation of the strongest shearing stress. The deformation mode

deformation quantity and crystal tropism will be helpful to understanding the mechanism of adiabatic shearing of the materials.