Estimation of spatially varying heat transfer coefficient from a flat plate with flush mounted heat sources using Bayesian inference
01 Sep 2016-Vol. 745, Iss: 3, pp 032094
TL;DR: In this article, the authors employed the Bayesian based Metropolis Hasting - Markov Chain Monte Carlo algorithm to solve inverse heat transfer problem of determining the spatially varying heat transfer coefficient from a flat plate with flush mounted discrete heat sources with measured temperatures at the bottom of the plate.
Abstract: This paper employs the Bayesian based Metropolis Hasting - Markov Chain Monte Carlo algorithm to solve inverse heat transfer problem of determining the spatially varying heat transfer coefficient from a flat plate with flush mounted discrete heat sources with measured temperatures at the bottom of the plate. The Nusselt number is assumed to be of the form Nu = aReb(x/l)c . To input reasonable values of 'a' and 'b' into the inverse problem, first limited two dimensional conjugate convection simulations were done with Comsol. Based on the guidance from this different values of 'a' and 'b' are input to a computationally less complex problem of conjugate conduction in the flat plate (15mm thickness) and temperature distributions at the bottom of the plate which is a more convenient location for measuring the temperatures without disturbing the flow were obtained. Since the goal of this work is to demonstrate the eficiacy of the Bayesian approach to accurately retrieve 'a' and 'b', numerically generated temperatures with known values of 'a' and 'b' are treated as 'surrogate' experimental data. The inverse problem is then solved by repeatedly using the forward solutions together with the MH-MCMC aprroach. To speed up the estimation, the forward model is replaced by an artificial neural network. The mean, maximum-a-posteriori and standard deviation of the estimated parameters 'a' and 'b' are reported. The robustness of the proposed method is examined, by synthetically adding noise to the temperatures.
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TL;DR: In this paper , an Artificial Neural Networks (ANN) and Genetic Algorithm (GA)-based inverse technique is proposed to estimate linearly varying heat flux constants using space-time temperature response.
Abstract: AbstractThe present work concerns the application of Artificial Neural Networks (ANN) and Genetic Algorithm (GA)-based inverse technique on a transient heat transfer problem. The proposed methodology has been demonstrated on a two-dimensional heat slab to estimate linearly varying heat flux constants using space–time temperature response. Initial temperatures and thermophysical properties are assigned. Different heat flux is specified at the right and bottom surfaces of the slab. The input–output (heat flux-temperature) data set of the slab is obtained using MATLAB [1]. This is used to train the ANN network, which acts as a proxy model. The synthetic experimental temperature data set are generated from the analytical method. In the inverse problem, the GA is employed to generate the samples and minimize the objective function to estimate the constants (S1 and S2) of the heat flux function Q = S(t). The robustness of the methodology is examined for different noise levels.
References
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TL;DR: In this article, the authors considered the problem of conjugate heat transfer from discrete heat sources mounted on one wall of a channel and exposed to fully-developed laminar flow.
76 citations
TL;DR: In this article, the effect of a priori model on the performance of the algorithm at different noise levels in the measured data was analyzed and the results showed that the mean and maximum a posteriori estimates for thermal conductivity and the convection heat transfer coefficient were insensitive to the a priora model at all the considered noise levels for the single-parameter estimation problem.
56 citations
TL;DR: A composite model for area-average Nusselt number for forced, laminar e ow parallel to a e nite, isothermal rectangular plate for a wide range of Reynolds numbers is proposed in this article.
Abstract: A composite model for area-average Nusselt number for forced, laminar e ow parallel to a e nite, isothermal rectangular plate for a wide range of Reynolds numbers is proposed. The correlation equation is based on the superposition of the dimensionless shape factor and a modie ed laminar e ow boundary-layer asymptote with an empirically determined interpolation parameter. The Nusselt and Reynolds numbers and the dimensionless shape factor are based on either the rectangle side dimension parallel to the e ow direction or the square root of the heat transferarea.Theproposedcorrelation equationsareapplicableto rectangleswith sidedimensionratiosina range from 1 to 10. Extensive numerical results were used to e nd the optimal values of the interpolation parameter to provide close agreement between the correlation equation predictions and the numerical values. Nomenclature A = plate surface area, ´L £ W, m 2 C;CT = boundary-layer solution coefe cients F.Pr/ = Prandtl number function, Eq. (14) h = convective coefe cient, W/m 2 K
7 citations