1) Strain Rate Strengthening
应变率硬化
2) stain-hardening rate
应变硬化率
1.
The stain-hardening rate could be obtained from true stress-true strain curves,the plots of θ-σ,-(θ/σ)-σ and -lnθ-σ under the different compression conditions were obtained through the agency of this study.
从真应力-真应变曲线上得到了应变硬化率(θ),分别绘制了在不同压缩条件下的θ-σ,-(θ/σ)-σ和lnθ-σ。
2.
The stain-hardening rate can be obtained from true stress-true strain curves,the plots of θ-σ, -((?)θ/(?)σ)-σand Inθ-σ in the different compression condition are obtained by the further study.
从真应力-真应变曲线上得到了应变硬化率(θ),分别得到了在不同压缩条件下的θ-σ、-((?)θ/■σ)-σ和 lnθ-σ。
3) work hardening rate strain(θ ε) curve
硬化率-应变图
4) strain hardening rate
应变硬化速率
1.
The strain hardening rate of g.
研究了粒状贝氏体组织的形变历史、断裂过程与组织内部应力分布关系,结果表明粒状贝氏体组织的主要断裂机制为微孔洞形成、长大和连接,尽管早期的变形历史中就产生了微裂纹,但在随后的形变过程中,由于组织变形微裂纹沿拉伸方向排列,使其不可能成为重要的断裂方式,粒状贝氏体组织在形变过程中应变硬化速率存在一个极小值,在此前后的变形历史和断裂过程中,材料内部的应力分布和微观断裂机制不同。
2.
For the steel containing high content martensite,strain hardening exponent n and strain hardening rate significantly increase in the stage of uniform deformation with the increase of martensite.
利用扫描电子显微镜对不同马氏体含量的试样的断口和断口侧面分析,发现在高马氏体含量下,双相钢变形和断裂与马氏体含量和组织形态有关,且其均匀变形阶段的应变硬化指数n值及应变硬化速率也会随着马氏体含量的增加而显著升高。
5) strain hardening
应变硬化
1.
Tensile strain hardening behaviours of nitrogen strengthening high manganese austenitic cryogenic steel;
氮强化高锰奥氏体低温钢的拉伸应变硬化行为
2.
Effect of moisture content on PVA-SHCC fracture energy and strain hardening;
水分含量对PVA-SHCC断裂能及应变硬化的影响
3.
Tensile strain hardening behavior of TRIP/TWIP steel with 18.8%manganese
18.8%MnTRIP/TWIP钢拉伸应变硬化行为
6) strain-hardening
应变硬化
1.
An autofrettage model considering the material strain-hardening relationship and the Baus-chinger effect was proposed based on the actual tensile-compressive stress-strain curve of material and modified yield criterion.
提出了一种以材料的实际拉-压应力应变曲线为基础,考虑材料应变硬化行为和包辛格效应的厚壁管自增强理论模型。
2.
TiNi alloy is an excellent tribo-material compared to conventional wear-resistant materials, which is closely related to its superelasticity originating from stress-induced matensite transformation, along with rapid strain-hardening, erosion-resistance and fatigue-resistance.
TiNi合金是一种新型的性能优异的摩擦学材料,其摩擦学特性主要与相变超弹性有关,快速应变硬化、耐腐蚀及抗疲劳等特性也对合金的耐磨性能有很大帮助。
3.
There are some different autofrettage models based on different simplified material strain-hardening behaviors,such as linear strain-hardening model, power strain-hardening model, and the combination of these strain-hardening relationship models.
基于对材料应变硬化行为的不同简化得到不同的自增强理论模型 ,如理想弹塑性模型、线性应变硬化模型、幂硬化模型以及这些简化的应变硬化模型的组合模型等。
补充资料:应变硬化率
strainhardeningrate:表示应变硬化的程度,即表示塑性变形阻力(继续塑性变形所需外应力)随塑性变形量的增大而增加的现象的程度。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条