Heterogeneous directions of orthotropy in three-dimensional structures: finite element description based on diffusion equations

IF 1 Q4 MECHANICS

Mathematics and Mechanics of Complex Systems Pub Date : 2018-10-01 DOI:10.2140/MEMOCS.2018.6.339

R. Allena, C. Cluzel

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引用次数: 16

Abstract

Heterogeneous materials such as bone or woven composites show mesostruc-tures whose constitutive elements are all oriented locally in the same direction and channel the stress ﬂow throughout the mechanical structure. The interfaces between such constitutive elements and the matrix are regions of potential degra-dations. Then, when building a numerical model, one has to take into account the local systems of orthotropic coordinates in order to properly describe the damage behavior of such materials. This can be a difﬁcult task if the orthotropic directions constantly change across the complex three-dimensional geometry as is the case for bone structures or woven composites. In the present paper, we propose a ﬁnite element technique to estimate the continuum ﬁeld of orthotropic directions based on the main hypothesis that they are mainly triggered by the external surface of the structure itself and the boundary conditions. We employ two diffusion equations, with speciﬁc boundary conditions, to build the radial and the initial longitudinal unit vectors. Then, to ensure the orthonormality of the basis, we compute the longitudinal, the circumferential, and the radial vectors via a series of vector products. To validate the numerical results, a comparison with the average directions of the experimentally observed Haversian canals is used. Our method is applied here to a human femur.

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三维结构中正交异性的非均匀方向:基于扩散方程的有限元描述

非均质材料如骨或编织复合材料显示出细观结构，其本构元素都在局部方向相同，并引导应力流贯穿整个机械结构。这种本构元素和矩阵之间的界面是潜在退化的区域。因此，在建立数值模型时，必须考虑正交各向异性坐标系的局部系统，才能正确地描述这类材料的损伤行为。如果骨结构或编织复合材料的正交异性方向在复杂的三维几何结构中不断变化，这可能是一项艰巨的任务。本文在假定正交各向异性场主要由结构本身的外表面和边界条件触发的基础上，提出了一种估计正交各向异性连续场的有限元方法。我们采用两个扩散方程，具有特定的边界条件，以建立径向和初始纵向单位矢量。然后，为了保证基的正交性，我们通过一系列向量积来计算纵向向量、圆周向量和径向向量。为了验证数值结果，采用了与实验观测到的哈弗斯运河平均方向的比较。我们的方法在这里应用于人类股骨。

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

Mathematics and Mechanics of Complex Systems MECHANICS-

CiteScore

3.00

自引率

5.30%

发文量

期刊介绍： MEMOCS is a publication of the International Research Center for the Mathematics and Mechanics of Complex Systems. It publishes articles from diverse scientific fields with a specific emphasis on mechanics. Articles must rely on the application or development of rigorous mathematical methods. The journal intends to foster a multidisciplinary approach to knowledge firmly based on mathematical foundations. It will serve as a forum where scientists from different disciplines meet to share a common, rational vision of science and technology. It intends to support and divulge research whose primary goal is to develop mathematical methods and tools for the study of complexity. The journal will also foster and publish original research in related areas of mathematics of proven applicability, such as variational methods, numerical methods, and optimization techniques. Besides their intrinsic interest, such treatments can become heuristic and epistemological tools for further investigations, and provide methods for deriving predictions from postulated theories. Papers focusing on and clarifying aspects of the history of mathematics and science are also welcome. All methodologies and points of view, if rigorously applied, will be considered.