Coupled thermal and mechanical analysis of composite cross sections using mathematical optimization strategies

Engineering Structures and Technologies Pub Date : 2017-03-27 DOI:10.3846/2029882X.2017.1299965

C. Taube, Hans-Georg Timmler, M. Helmrich, G. Morgenthal

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引用次数: 2

Abstract

In the present article an alternative approach for the coupled thermal and mechanical analysis of composite cross sections under temperature effects is introduced, which uses the mathematical optimization as a consistent methodical base. By applying the principle of the virtual source energy for the thermal and the principle of the minimum of the total potential energy for the mechanical analysis, an accurate determination of temperature fields as well as residual strain and stress distributions is possible. The coupling is enabled by the thermal strains, which are determined based on the temperature field and passed to the nonlinear mechanical analysis as tension free pre-strains. The energy functional of the heat conduction problem is derived and implemented. The resulting optimization task is strictly convex and represents an implicit formulation, which does not impose any stability criteria. The performance of the introduced method is demonstrated on a principle example and an outlook is given on possible further extensions and applications.

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基于数学优化策略的复合材料截面热力学耦合分析

本文介绍了一种在温度效应下进行复合材料截面热力学耦合分析的替代方法，该方法将数学优化作为一致的系统基础。通过应用热的虚拟源能量原理和机械分析的总势能最小原理，可以准确地确定温度场以及残余应变和应力分布。耦合是由热应变实现的，热应变是基于温度场确定的，并作为无张力预应变传递给非线性力学分析。导出并实现了热传导问题的能量泛函。由此产生的优化任务是严格凸的，并且表示一个隐式公式，该公式不强加任何稳定性标准。通过一个原理实例验证了该方法的性能，并对可能的进一步扩展和应用进行了展望。

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

Engineering Structures and Technologies

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审稿时长

15 weeks