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1)  compressive yield strength
压缩屈服强度
1.
Based on the compression and tension curves of spherical pores Al foam,the densification starting point,energy absorption,compressive yield strength,and tension properties are investigated.
采用Gibson-Ashby的模型来分析球形孔泡沫纯铝的压缩屈服强度和抗拉强度,吻合效果良好。
2.
Based on compression curves of spherical pores Al foam measured,compressive yield strength and energy absorption were investigated.
在获得球形孔泡沫纯铝压缩应力-应变曲线基础上,研究了泡沫纯铝的压缩屈服强度、吸能能力。
3.
Based on compression curves of spherical pores Al foam, compressive yield strength and energy absorption had been investigated.
采用Gibson-Ashby的模型来分析球形孔泡沫纯铝的压缩屈服强度,吻合良好。
2)  compressive yield strength at elevated temperature
高温压缩屈服强度
3)  internal yield pressure strength
内压屈服强度
4)  compressive yielding
压缩屈服
1.
Numerical simulation on compressive yielding behavior of closed-cell metal foam with low density
低密度闭孔金属泡沫压缩屈服行为的数值模拟
5)  yield strength
屈服强度
1.
Effect of phosphorus on the yield strength of as-quenched GH761 alloy;
磷对GH761合金固溶水淬组织屈服强度的影响
2.
Study of influence factors of yield strength of oil and gas pipeline;
油气管道屈服强度影响因素的研究
3.
A modeling study of the yield strength of HRB335 hot rolled ribbed bar;
HRB335热轧带肋钢筋屈服强度模型研究
6)  yield stress
屈服强度
1.
Based on the plain carbon steel with the chemical composition of 200MPa class steel the products of the yield stress of 400~500 MPa class and high-quality mechanical properties can be produced using the technology of chemistry tightly-tuning and controlled rolling - controlled cooling.
以屈服强度为 2 0 0MPa级的普碳钢为基本成分 ,采用成分微调与控轧控冷工艺相结合的技术路线 ,可将屈服强度提高到 4 0 0~ 5 0 0MPa,同时保证良好的综合性能。
2.
From the tests, a two-stage linear relation has been found between yield stress(σ_s) and strain rate(ε),σ_s=σ_0+klgε.
对4种金属材料进行了应变率为10~(-4)—10~3s~(-1)的拉伸试验,结果表明,屈服强度随应变率的升高分两阶段线性升高。
补充资料:屈服强度
分子式:
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性质:是材料屈服的临界应力值。(1)对于屈服现象明显的材料,刷子服强度就是在屈服点在应力(屈服值);(2)对于屈服现象不明显的材料,与应力-应变的直线关系的极限偏差达到规定值(通常为0.2%的永久形变)时的应力。通常用作固体材料力学机械性能的评价指标,是材料的实际使用极限。因为材料屈服后产生颈缩,应变增大,使材料失去了原有功能。

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