Efficient simulation of single and poly-crystal plasticity based on the pencil glide mechanism

IF 1 4区 工程技术 Q4 MECHANICS
L. T. Le, K. Ammar, S. Forest
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引用次数: 4

Abstract

The present work demonstrates that the pencil glide mechanism is a physically reliable and a computationally efficient model to simulate the nonlinear behaviour of b.c.c. single and polycrystals. For that purpose, the pencil glide extension of Schmid’s criterion used by Gilormini [1] is incorporated in a single crystal model and in a homogenized polycrystal model accounting for large elastoviscoplastic deformations. The response of the pencil glide model in terms of stress-strain curves and lattice rotation is compared to the prediction based on the consideration of all ({110}〈111〉+ {112}〈111〉) slip systems. In the case of α-iron single crystals both approaches are shown to accurately reproduce recent experimental results [2, 3]. The comparison is extended to α-iron polycrystals behaviour under tension, compression, rolling and simple shear loading conditions. The evolution of crystallographic textures obtained either based on pencil glide or using the 24 slip systems is analyzed and compared to classical experimental results from the literature. Limitations of the approach, especially in the case of simple shear textures, are also pointed out. The pencil glide approach can be viewed as a reduced order model enhancing computational efficiency of crystal plasticity simulations involving many slip mechanisms.
基于铅笔滑动机制的单晶和多晶塑性高效仿真
本文的工作表明,铅笔滑动机制是一种物理上可靠的、计算上有效的模型,可以模拟b.c.c.单晶和多晶的非线性行为。为此,Gilormini[1]使用的Schmid准则的铅笔滑动扩展被纳入单晶模型和考虑大弹粘塑性变形的均匀化多晶模型中。将铅笔滑动模型在应力应变曲线和晶格旋转条件下的响应与考虑所有({110}< 111 > +{112}< 111 >)滑移体系的预测结果进行了比较。在α-铁单晶的情况下,这两种方法都被证明可以准确地再现最近的实验结果[2,3]。比较扩展到α-铁多晶在拉伸、压缩、轧制和简单剪切加载条件下的性能。分析了基于铅笔滑动或使用24滑动系统获得的晶体织构的演变,并与文献中的经典实验结果进行了比较。同时指出了该方法的局限性,特别是在简单剪切纹理的情况下。铅笔滑动方法可以看作是一种降阶模型,提高了涉及多种滑动机制的晶体塑性模拟的计算效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Comptes Rendus Mecanique
Comptes Rendus Mecanique 物理-力学
CiteScore
1.40
自引率
0.00%
发文量
0
审稿时长
12 months
期刊介绍: The Comptes rendus - Mécanique cover all fields of the discipline: Logic, Combinatorics, Number Theory, Group Theory, Mathematical Analysis, (Partial) Differential Equations, Geometry, Topology, Dynamical systems, Mathematical Physics, Mathematical Problems in Mechanics, Signal Theory, Mathematical Economics, … The journal publishes original and high-quality research articles. These can be in either in English or in French, with an abstract in both languages. An abridged version of the main text in the second language may also be included.
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