考虑内力影响的应变梯度塑性理论

IF 0.7 Q4 MECHANICS
A. Borokinni, A. Akinola, O. Layeni
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引用次数: 3

摘要

本文建立了无塑性自旋时各向同性小变形体的应变梯度塑性理论。提出的理论是基于一个微应力系统,其中包括与微力平衡一致的微应力矢量;热力学第二定律的力学形式,包括在塑性流动中由微应力所做的功;本构理论允许自由能依赖于弹性应变Ee,塑性应变divEp的散度和Burgers张量g。将本构关系替换为微力平衡导致塑性应变中的非线性偏微分方程,称为流动规则,该方程捕获了由微应力矢量计算产生的额外能量长度尺度的存在。除流动规律外,还得到了非标准边界条件,并推导了流动规律的变分公式,以辅助有限元求解。得到了重力作用下一维粘塑性简单剪切问题的有限元解,结果表明,在一定的耗散长度尺度下,能量长度尺度的增大会导致塑性应变的减小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A theory of strain-gradient plasticity with effect of internal microforce
This paper develops a theory of strain gradient plasticity for isotropic bodies undergoing small deformation in the absence of plastic spin. The proposed theory is based on a system of microstresses which include a microstress vector consistent with microforce balance; the mechanical form of the second law of thermodynamics which includes work performed by the microstresses during plastic flow; and a constitutive theory that allows the free energy to depend on the elastic strain Ee, divergence of plastic strain divEp and the Burgers tensor G. Substitution of the constitutive relations into the microforce balance leads to a nonlinear partial differential equation in the plastic strain known as flow rule which captures the presence of an additional energetic length scale arising from the accounting of microstress vector. In addition to the flow rule, nonstandard boundary conditions are obtained, and as an aid to finite element solution a variational formulation of the flow rule is deduced. Finite element solution is obtained of one-dimensional problem of viscoplastic simple shearing under gravity force, where it is shown that for a fixed dissipative length scale, increase in the energetic length scales will result in decrease in the plastic strain.
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来源期刊
CiteScore
0.90
自引率
0.00%
发文量
4
审稿时长
32 weeks
期刊介绍: Theoretical and Applied Mechanics (TAM) invites submission of original scholarly work in all fields of theoretical and applied mechanics. TAM features selected high quality research articles that represent the broad spectrum of interest in mechanics.
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