Sequential Inverse Heat Conduction Problem in OpenFOAM

OpenFOAM® Journal Pub Date : 2021-10-21 DOI:10.51560/ofj.v1.33

J. Bohácek, J. Kominek, A. Vakhrushev, E. Karimi-Sibaki, Taewoo Lee

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引用次数: 3

Abstract

The solution of the inverse heat conduction problem (IHCP) is commonly found with the sequential algorithm known as the function specification method with explicit updating formulas and sensitivity coefficients of heat flux. This paper presents a different approach namely a direct mathematical optimization of minimizing the least squares norm between experimental data and simulation. A CFD open-source code OpenFOAM is used together with NLOPT and DLIB optimization libraries. To guarantee credibility of the simulation tool developed herein, real experimental data is used from spray cooling of a fast-moving hot steel plate. As the IHCP is inherently an ill-posed problem, the proposed sequential algorithm is stabilized using future time stepping and thereof the optimal number is explained. An assumption about the profile of thermal boundary condition during future steps must be made. It is shown that assuming a linear change of the heat transfer coefficient during each sequence of future time steps yields more accurate results than setting a constant value. For the problem size considered with less than 10k cells, the preconditioned conjugate gradient (FDIC) linear solver converges faster than the multigrid solver (GAMG). However, the latter performs better as the accuracy is concerned. Concerning the best choice of minimizer, the BOBYQA algorithm (quadratic approximation) is found superior to other methods. The proposed IHCP solver is compared with the well-established one.

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OpenFOAM的序贯逆热传导问题

反热传导问题的求解通常采用具有显式更新公式和热流敏感系数的序列算法，即函数规范法。本文提出了一种不同的方法，即在实验数据和模拟数据之间最小化最小二乘范数的直接数学优化。CFD开源代码OpenFOAM与NLOPT和DLIB优化库一起使用。为了保证所开发的模拟工具的可靠性，采用了快速运动热钢板喷雾冷却的真实实验数据。由于IHCP本质上是一个不适定问题，所提出的序列算法使用未来时间步进来稳定，并解释了最优数。必须对今后步骤的热边界条件剖面作一个假设。结果表明，假设传热系数在未来每一个时间步长序列中呈线性变化，比设定一个恒定值产生更准确的结果。对于小于10k单元的问题，预条件共轭梯度(FDIC)线性求解器比多网格求解器(GAMG)收敛得更快。然而，后者在准确性方面表现得更好。对于最小化器的最佳选择，发现BOBYQA算法(二次逼近)优于其他方法。将所提出的求解器与已有的求解器进行了比较。

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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OpenFOAM® Journal

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