Overview

The thermal camera has revolutionized our understanding of heat transfer across many fields. In particular, it has enabled the visualization of surface temperature fields, which were previously only accessible through point sensors. However, thermograms are often difficult to interpret and can only be obtained from existing scenes. To understand them and extrapolate their insights to projects that have not yet been realized, a digital twin is required. This book examines how the finite element method facilitates the creation of idealized thermograms that both explain and extend measured situations. Finite Element Thermography addresses steady-state and transient heat transfer, starting from diffusion equations. Their discretization leads to the classical formulation of the finite element method. This book then discusses thermal radiation, with the final chapter exploring the challenges of representing results and adapting them for the calculation of derived quantities, such as the mean radiant temperature.

Full Product Details

Author:   Benoit Beckers (Compiegne University of Technology, France) ,  Pierre Beckers (University of Liege, Belgium)
Publisher:   ISTE Ltd
Imprint:   ISTE Ltd
ISBN:  

9781836690788

ISBN 10:   1836690789
Pages:   192
Publication Date:   07 July 2026
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Forthcoming
Availability:   Awaiting stock  

Table of Contents

Preface ix Introduction xv Part 1. Thermal Diffusion 1 Chapter 1. Steady State 3 1.1. Partial differential equations of heat transfer in a solid 3 1.2. Variational method 6 1.3. Rayleigh–Ritz method 10 1.4. Finite element model 12 1.5. Finite element assembly 18 1.6. Convergence of the finite element method 20 1.7. Solution to the system of linear equations 24 1.8. Thermal bridge 24 Chapter 2. Boundary Conditions. 27 2.1. Dirichlet boundary conditions 27 2.2. Neumann boundary conditions 32 2.3. Convection 34 Chapter 3. Transient Response 49 3.1. General formulation 49 3.2. Temporal integration 51 3.3. The capacity matrix 53 3.4. Temperature evolution in a solid with adiabatic boundaries 54 3.5. Solid immersed in a fluid 56 Chapter 4. Isoparametric Elements 59 4.1. The concept of Coons patch 59 4.2. Trilinear hexahedron 61 4.3. Two-parameter surfaces or Coons patches 63 4.4. Three-dimensional isoparametric element 67 4.5. Using fins to cool a solid 71 Part 2. Thermal Radiation. 73 Chapter 5. Black Bodies 75 5.1. Planck's law 75 5.2. Stefan–Boltzmann law 78 5.3. Short waves and long waves 80 5.4. Kirchhoff's law 82 5.5. Solid angle 82 5.6. The solar constant 86 5.7. View factor 86 5.8. Calculation of the view factor using the ray tracing method 88 Chapter 6. The Sun and Short Waves 95 6.1. The ellipse and its anomalies 96 6.2. Keplerian orbits 100 6.3. The position of the Sun 103 6.4. Sidereal time and hour angle 106 6.5. Position of the Sun based on latitude and time 108 6.6. Attenuation of solar radiation by the atmosphere 110 6.7. Calculation of solar irradiance 112 6.8. Radiosity equations 120 6.9. Extended view factors 124 Chapter 7. The Earth and Long Waves 127 7.1. Longwave heat transfer 127 7.2. Three conventional surfaces 129 7.3. Cube section with a radiative cavity 131 7.4. Cube with a radiative cavity 133 Chapter 8. Mean Radiant Temperature 137 8.1. A cube and two spherical projections 137 8.2. Mollweide projection 138 8.3. Position of a point on the sphere in the Mollweide projection 140 8.4. Visualization of shortwave radiosities in the cube 142 8.5. Longwave radiation in a cube 143 8.6. Mollweide projections of the cube and cells of equal area 145 8.7. Use of the ray tracing technique 147 8.8. Cube with five cold sides and one hot side 151 Conclusion 153 References 155 Index 161

Reviews

Author Information

Benoit Beckers is a professor at the Université de Pau et des Pays de l’Adour, France. His research focuses on the perception of sound, light and thermal waves, in connection with the history of architecture and urban planning. Pierre Beckers is an emeritus professor at the Université de Liège, Belgium. His research focuses primarily on the finite element method, dual analysis, computer graphics and computer-aided design.

Tab Content 6

Author Website:  

Countries Available

All regions