Several calorimetric techniques are available for the sequential estimation of thermal conductivities of composites by conducting heat balance successively along the principal directions. Such methods are time consuming and require three samples for estimating the properties. The hollow core, in combination with rigid face sheets, helps in achieving a high strength to-weight ratio, as demanded by its application. Because the manufacturing process of composites inevitably gives rise to a joint resistance between the face sheets and the core, due to the presence of an adhesive, its effect becomes detrimental in the estimation of effective thermal transport properties. A combination of several values of tridimensional effective thermal conductivities may lead to same temperature distribution; hence, the problem is ill posed in nature and requires regularization prior, an engineering intuition, or a combination of both.

C. Balaji

Department of Mechanical Engineering

Condensed Matter Physics

Heat transfer

ANISOTROPIC COMPOSITES

Calorimetric techniques

Effective thermal conductivity

Manufacturing Process

Principal directions

REGULARIZATION PRIORS

SEQUENTIAL ESTIMATION

THERMAL TRANSPORT PROPERTIES

Thermal conductivity

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

It currently offers undergraduate, postgraduate and research degrees across 16 disciplines in Engineering, Sciences, Humanities and Management. About 596 faculty belonging to science and engineering departments and centres of the Institute are engaged in teaching, research and industrial consultancy.

IIT Madras

Joint Conductance Effects on Estimation of Effective Thermal Conductivities of Anisotropic Composites

Journal of Thermophysics and Heat Transfer

Composite materials are novel inventions of material science which are often used as viable solutions in many technologically challenging situations like aero-space and satellite applications, because of their well known superior mechanical properties. The challenge which these materials always pose to the thermal designers, is knowledge of their thermal properties, effective directional thermal conductivity being one of them as this is critical in the design of systems employing these materials. The present work aims at developing a novel experimental technique for the simultaneous estimation of principal thermal conductivities of a layered honeycomb composite widely used in aerospace structures. A new standard test material exhibiting structural anisotropy with respect to thermal transport is first conceptualised, designed and fabricated. A full scale direct numerical simulation is performed on the standard test material to understand the thermal transport process in it and determine its principal thermal conductivities. Following this, carefully designed experiments are performed on the standard test material in simulated space environment (inside a vacuum chamber) and its principal thermal conductivities are estimated using the developed inverse methodology based on a synergistic combination of artificial neural network (ANN) and genetic algorithm (GA). Experimentally obtained thermal conductivities are compared with those obtained from full scale numerical simulations. A close agreement between the experimentally and numerically estimated thermal conductivities is observed, validating the technique and establishing the possibility of use of a full scale numerical model as an alternate and standalone approach for estimation of thermal conductivities of structured integral composites. Finally, a layered honeycomb composite having carbon fiber reinforced plastic (CFRP) facesheet and aluminium core actually used in satellite applications is tested and its principal thermal conductivities are estimated. Problems related to interface thermal contact conductance in case of honeycomb composites are also brought out and addressed. © 2016 Elsevier Masson SAS

International Journal of Thermal Sciences

Estimation of principal thermal conductivities of layered honeycomb composites using ANN–GA based inverse technique

This paper reports the results of an experimental study to determine the principal thermal conductivities (k x, k y, and k z) of an anisotropic composite medium using an inverse heat transfer analysis. The direct problem consists of solving the three dimensional heat conduction equation in an orthotropic composite medium with the finite difference method to generate the required temperature distribution for known thermal conductivities. The measurement technique involves dissipating a known heat flux at the central region of a square sample and allowing it to conductively transfer the heat to an aluminium cold plate sink via a square copper ring. At steady state, temperatures at 28 (19 are used for retrievals due to symmetry) discrete locations are logged and used for parameter estimation. The entire measurement process is conducted in a vacuum environment. The inverse heat conduction problem (IHCP) for retrieving the orthotropic thermal conductivity tensor(parameter estimation) is then solved using a two layer feed forward back propagation artificial neural network (ANN) trained using the Levenberg-Marquardt algorithm (LMA), with temperatures as input and thermal conductivity values k x, k y, and k z as the output. The method is first validated against a stainless steel(SS-304) sample of known thermal properties followed by the determination of the orthotropic conductivities of the honeycomb composite material. © 2013 American Society of Mechanical Engineers.

Journal of Heat Transfer

Simultaneous estimation of principal thermal conductivities of an anisotropic composite medium: An inverse analysis

Inverse Heat Transfer Problems (IHTP) are characterized by estimation of unknown quantities by utilizing any given information of the system. In this study, the inverse problem of estimation of boundary heat flux for a given temperature distribution on the walls of a two dimensional square cavity with a finite wall thickness is considered. A non-iterative method is applied utilizing Artificial Neural Network (ANN) and Principal Component Analysis (PCA) to estimate the parameters that define the boundary heat flux. The forward model is numerically solved with Fluent 6.3 for known values of a linearly varying boundary heat flux and the temperature distribution thus obtained is utilized to train the ANN for the inverse model. A parametric study is carried out to determine the effect of the thermal conductivity of the top and bottom walls on the flow and temperature distribution in the cavity. PCA analysis is carried out to reduce the dimensions of the input data set for the inverse model. These reduced dimensions are used to train the network and due to low dimensionality of the input, the effort required to train the network is considerably less. The trained networks are finally used to estimate boundary heat flux for any desired temperature distribution on the top and bottom walls. Additionally, covariance analysis is carried out in order to estimate the required number of temperatures during an experiment, on the top and bottom walls for the prediction of heat flux with a reasonable accuracy. The inverse model with covariance analysis is compared with the inverse model with PCA and both the methods are found to be equally potent. © 2010 Elsevier Ltd.

International Journal of Heat and Mass Transfer

A Principal Component Analysis and neural network based non-iterative method for inverse conjugate natural convection

Choice Reviews Online

Genetic algorithms in search, optimization, and machine learning

An experimental device for the simultaneous estimation of the thermal conductivity 3-D tensor and the specific heat of orthotropic composite materials

Applying neural networks to the solution of forward and inverse heat conduction problems

Joint conductance effects on estimation of effective thermal conductivities of anisotropic composites

Journal	Data powered by TypesetJournal of Thermophysics and Heat Transfer
Publisher	Data powered by TypesetAmerican Institute of Aeronautics and Astronautics Inc.
ISSN	08878722
Impact Factor	1.868
Open Access	No
Citation Style	unsrt
Sherpa RoMEO Archiving Policy	Green