Genetic Algorithm as the Solution of Non-Linear Inverse Heat Conduction Problems: a Novel Sequential Approach

0 ENGINEERING, MECHANICAL
Dominic Allard, Hamidreza Najafi
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引用次数: 0

Abstract

Direct measurement of surface heat flux could be extremely challenging, or impossible, in numerous applications. In such cases, the use of temperature measurement data from sub-surface locations can facilitate the determination of surface heat flux and temperature through the solution of the inverse heat conduction problem (IHCP). Different techniques have been developed for solving IHCPs. Inspired by the filter coefficient approach, a novel method is presented in this paper for solving one-dimensional IHCPs in a domain with temperature-dependent material properties. A test case is developed in COMSOL Multiphysics where the front side of a slab is subject to known transient heat flux and the temperature distributions within the domain are calculated. The IHCP solution in the form of filter coefficients is defined and a genetic algorithm is used for the calculation of filter matrix. The number of significant filter coefficients required to evaluate surface heat flux at each time step is determined through trial and error and the optimal number is selected for evaluating the solution. The structure of the filter matrix is assessed and discussed. The resulting filter coefficients are used to evaluate the surface heat flux for several cases and the performance of the proposed approach is assessed in detail. The results showed that the presented approach is robust and can result in finding optimal filter coefficients to accurately estimate various types of surface heat flux profiles using temperature data from a limited number of time steps and in a near real-time fashion.
遗传算法作为非线性反热传导问题的解决方案:一种新颖的序列方法
在许多应用中,直接测量表面热通量可能极具挑战性,甚至是不可能的。在这种情况下,利用来自地下位置的温度测量数据,可以通过解决反热传导问题(IHCP)来确定表面热通量和温度。目前已开发出不同的 IHCP 求解技术。受过滤系数方法的启发,本文提出了一种新方法,用于求解具有温度相关材料特性的域中的一维 IHCP。在 COMSOL Multiphysics 中开发了一个测试案例,板的正面受到已知瞬态热通量的影响,并计算域内的温度分布。定义了滤波系数形式的 IHCP 解决方案,并使用遗传算法计算滤波矩阵。通过试验和误差来确定评估每个时间步长的表面热通量所需的重要滤波系数数量,并选择最佳数量来评估解决方案。对滤波矩阵的结构进行了评估和讨论。得出的滤波系数用于评估几种情况下的表面热通量,并详细评估了所提方法的性能。结果表明,所提出的方法是稳健的,能够找到最佳滤波系数,从而利用有限时间步数的温度数据,以接近实时的方式准确估算各种类型的表面热通量剖面。
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
CiteScore
4.20
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0.00%
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