English

Heat transfer process with solid-solid interface: Analytical and numerical solutions

Analysis of PDEs 2021-10-28 v1

Abstract

This work is aimed at the study and analysis of the heat transport on a metal bar of length LL with a solid-solid interface. The process is assumed to be developed along one direction, across two homogeneous and isotropic materials. Analytical and numerical solutions are obtained under continuity conditions at the interface, that is a perfect assembly. The lateral side is assumed to be isolated and a constant thermal source is located at the left-boundary while the right-end stays free allowing the heat to transfer to the surrounding fluid by a convective process. The differences between the analytic solution and temperature measurements at any point on the right would indicate the presence of discontinuities. The greater these differences, the greater the discontinuity in the interface due to thermal resistances, providing a measure of its propagation from the interface and they could be modeled as temperature perturbations. The problem of interest may be described by a parabolic equation with initial, interface and boundary conditions, where the thermal properties, the conductivity and diffusivity coefficients, are piecewise constant functions. The analytic solution is derived by using Fourier methods. Special attention is given to the Sturm-Liouville problem that arises when deriving the solution, since a complicated eigenvalue equation must to be solved. Numerical simulations are conducted by using finite difference schemes where its convergence and stability properties are discussed along with physical interpretations of the results.

Keywords

Cite

@article{arxiv.2110.14542,
  title  = {Heat transfer process with solid-solid interface: Analytical and numerical solutions},
  author = {Diana Rubio and Domingo A. Tarzia and Guillermo F. Umbricht},
  journal= {arXiv preprint arXiv:2110.14542},
  year   = {2021}
}

Comments

10 Pages, 8 Figures, 3 Tables

R2 v1 2026-06-24T07:14:20.167Z