Fundamentals of heat transfer : an interdisciplinary analytical approach

This book demonstrates the analytical solution of fundamental problems in heat transfer which covers conduction, convection, and radiation heat transfer. The analytical solution of heat transfer problems is described in a simple way which is easy to understand. This book also provides competence of solving fundamental heat transfer problems by analytical method which is particularly important to gain a strong background on heat transfer. The book is an interdisciplinary heat transfer book which is useful for all academicians and students from different disciplines with different levels of mathematical knowledge. The book can be used as a core or supplementary textbook in undergraduate and graduate bridge courses. Furthermore, it is suitable for professional and vocational coursework for technology and engineering professionals.

Chapter 1: Basics mathematics for Heat Transfer Chapter 2: Basics of heat transfer (classification of heat transfer, governing laws (Fourier laws, Newton's cooling law, Stefan Boltzmann low, Newton viscosity law, Newton's second law, etc.) initial and boundary conditions) Chapter 3: Conduction heat transfer 3.1 Heat conduction equation (governing equation, assumptions of this book, initial and boundary conditions) 3.2 One dimensional heat conduction in space or time 3.3 One dimensional unsteady heat conduction in Cartesian coordinate (solution by using Separation of variables method) 3.4 Two dimensional steady heat conduction in Cartesian coordinate (solution by using Separation of variables method) 3.5 One dimensional unsteady heat conduction in cylindrical coordinate (solution by using Separation of variables method, Bessel functions) 3.6 One dimensional unsteady heat conduction in spherical coordinate (solution by using Separation of variables method, Legendre functions) 3.7 Solution for further dimensions (Description of heat conduction problems for two and three dimensions and presenting just their solution) 3.8 Problems Chapter 4: Convection Heat Transfer 4.1 Basics of convection heat transfer and governing equations (governing equations (continuity, momentum and energy equations), assumptions of this book, initial and boundary conditions) 4.2 External flow: heat and fluid flow over a flat plate (Boundary layer theory, simplification of governing equations, velocity and temperature profiles, friction coefficient and Nusselt number) 4.3 Internal flow: heat and fluid flow in a channel and a tube (Developing and fully developed regions, simplification of equations, velocity and temperature equations) 4.4 Internal Flow: Heat transfer in a channel with slug flow (Solution by using separation of variables) 4.5 Natural convection over a vertical flat plate (governing equations, boundary layer theory, velocity and temperature profiles) 4.6 Further details in convection heat transfer problems (Gratz problem, natural convection in cavities by presenting correlations and equations) 4.7 Problems Chapter 5: Radiation Heat Transfer 5.1 Basics of radiation heat transfer and related equations (Plank distribution, Weins displacement laws, Stefan Boltzmann low, 5.2 Coupled radiation and conduction problems (heat conduction equation with Surface radiation, heat conduction equation with participating medium) 5.3 Coupled radiation and convection problems (Convection with participating medium) 5.4 Problems References