José Luís Medeiros Thiesen, Bruno Klahr, Thiago André Carniel, Pablo Javier Blanco, Eduardo Alberto Fancello
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引用次数: 0
摘要
在有限应变运动学的背景下,提出了基于代表体积元素(RVE)概念的二阶多尺度理论,将 RVE 尺度的经典孔力学模型与宏观尺度的高阶孔力学模型联系起来。所提出的理论是从多尺度虚拟力原理(Principle of Multiscale Virtual Power)中精心推导出来的,而多尺度虚拟力原理是对希尔-曼德尔宏观均匀性原理(Hill-Mandel Principle of Macrohomogeneity)的概括。低尺度的耦合控制方程以及通量和应力类量的同质化规则是通过标准变分法论证得到的。主要理论结果是,与一阶理论不同,孔隙压力场的最小约束空间允许非零净流体流过 RVE 边界。这一发现的直接结果是,当宏观尺度运动学的演化导致低尺度(RVE 层)体积发生巨大变化(膨胀或收缩)时,本理论可以持续应用。本文介绍了均质化切线算子的公式开发和表达细节,供对模型计算实施感兴趣的人员参考。
A Second-Order Multiscale Model for Finite-Strain Poromechanics Based on the Method of Multiscale Virtual Power
A second-order multiscale theory based on the concept of a Representative Volume Element (RVE) is proposed to link a classical poromechanical model at the RVE scale to a high-order poromechanical model at the macro-scale in the context of finite-strain kinematics. The proposed theory is carefully derived from the Principle of Multiscale Virtual Power, which is a generalization of the Hill-Mandel Principle of Macrohomogeneity. The coupled governing equations of the low-scale and the homogenization rules for the flux and stress-like quantities are obtained by means of standard variational arguments. The main theoretical result is that the minimally constrained space for the pore pressure field allows for non-zero net fluid flow across the RVE boundaries, unlike first-order theories. The direct consequence of this finding is that the present theory can be consistently applied in cases where the low-scale (RVE level) exhibits substantial volume changes (swelling or shrinking) as a consequence of the evolution of the macro-scale kinematics. Details of formulation development and expression for the homogenized tangent operators are presented for those interested in the computational implementation of the model.
期刊介绍:
The Journal of Elasticity was founded in 1971 by Marvin Stippes (1922-1979), with its main purpose being to report original and significant discoveries in elasticity. The Journal has broadened in scope over the years to include original contributions in the physical and mathematical science of solids. The areas of rational mechanics, mechanics of materials, including theories of soft materials, biomechanics, and engineering sciences that contribute to fundamental advancements in understanding and predicting the complex behavior of solids are particularly welcomed. The role of elasticity in all such behavior is well recognized and reporting significant discoveries in elasticity remains important to the Journal, as is its relation to thermal and mass transport, electromagnetism, and chemical reactions. Fundamental research that applies the concepts of physics and elements of applied mathematical science is of particular interest. Original research contributions will appear as either full research papers or research notes. Well-documented historical essays and reviews also are welcomed. Materials that will prove effective in teaching will appear as classroom notes. Computational and/or experimental investigations that emphasize relationships to the modeling of the novel physical behavior of solids at all scales are of interest. Guidance principles for content are to be found in the current interests of the Editorial Board.