该方法以测量的应变值为基础,由拟合的曲线方程计算接头载荷,并与试验时施加的总载荷对比。
In this method, based on the measured strain values, the joint load is calculated by the fitted curve equation and compared with the total load applied during test.
所得的载荷和延伸率都被转化成了真实应力-应变曲线。
Measured loads and elongations were converted to true stress-true strain curves.
数值例题给出了典型生物软组织的宏观载荷-位移曲线和应力应变曲线。
Numerical examples give the macroscopic load-deflection curves and the stress-strain curves of typical soft tissues.
主要观察指标:标本的最大载荷、最大应力、最大应变和应力-应变曲线。
MAIN OUTCOME MEASURES: The maximum load, maximum stress, maximum strain and stress-strain curve.
用三维有限元数值模拟软件DEFORM-3DTM进行了数值模拟研究,得到了锻造载荷-行程曲线以及整个成形过程的应力和应变分布等,并与传统的均匀加放余量法进行了比较。
At the same time, 3D-FEM simulation of the whole process was performed using DEFORM-3DTM software. And the load-stroke curve, effective stress and strain distribution, and so on were obtained.
试验的轴向应变-载荷曲线与计算的轴向应变-载荷曲线趋势基本一致。
The tested axial strain-load curve coincides well with the calculated axial strain-load curve.
管道的应变随着集中载荷的增大而增大,在一定载荷内,管道的应变曲线成正弦波形且周期无明显变化。
The strain of the pipeline increased with an increase of concentrated load. In a constant load, the strain curve of the pipeline was a cycle of sine wave with no significant changes in the cycle.
管道的应变随着集中载荷的增大而增大,在一定载荷内,管道的应变曲线成正弦波形且周期无明显变化。
The strain of the pipeline increased with an increase of concentrated load. In a constant load, the strain curve of the pipeline was a cycle of sine wave with no significant changes in the cycle.
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