嵌入弹性基质中的交联纤维网络
Cross-Linked Fiber Network Embedded in Elastic Matrix.
作者信息
Zhang L, Lake S P, Barocas V H, Shephard M S, Picu R C
机构信息
Scientific Computation Research Center, Rensselaer Polytechnic Institute, Troy, NY 12180.
出版信息
Soft Matter. 2013 Jul 28;9(28):6398-6405. doi: 10.1039/C3SM50838B.
Abstract
The mechanical behavior of a three-dimensional cross-linked fiber network embedded in matrix is studied in this work. The network is composed from linear elastic fibers which store energy only in the axial deformation mode, while the matrix is also isotropic and linear elastic. Such systems are encountered in a broad range of applications, from tissue to consumer products. As the matrix modulus increases, the network is constrained to deform more affinely. This leads to internal forces acting between the network and the matrix, which produce strong stress concentration at the network cross-links. This interaction increases the apparent modulus of the network and decreases the apparent modulus of the matrix. A model is developed to predict the effective modulus of the composite and its predictions are compared with numerical data for a variety of networks.
摘要
本文研究了嵌入基体中的三维交联纤维网络的力学行为。该网络由仅在轴向变形模式下储存能量的线性弹性纤维组成,而基体也是各向同性且线性弹性的。从组织到消费品,这类系统在广泛的应用中都会遇到。随着基体模量的增加,网络被迫更均匀地变形。这导致网络与基体之间产生内力,从而在网络交联处产生强烈的应力集中。这种相互作用增加了网络的表观模量,降低了基体的表观模量。建立了一个模型来预测复合材料的有效模量,并将其预测结果与各种网络的数值数据进行了比较。
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