The theory underlying heat transfer is described, and the principal results and formulae are presented. Available techniques for obtaining rapid, approximate solutions to complicated problems are also considered. This book is comprised of 12 chapters and begins with a brief account of some of the concepts, methods, nomenclature, and other relevant information about heat transfer. The reader is then introduced to radiation, conduction, convection, and boiling and condensation. Problems involving more than one mode of heat transfer are presented.
Some of the factors influencing the selection of heat exchangers are also discussed. The remaining chapters focus on mass transfer and its simultaneous occurrence with heat transfer; the air-water vapor system, with emphasis on humidity and enthalpy as well as wet-bulb temperature, adiabatic saturation temperature, cooling by evaporation, drying, and condensation; and physical properties and other information that must be taken into account before any generalized formula for heat or mass transfer can be applied to a specific problem.
This monograph will be of value to mechanical engineers, physicists, and mathematicians. Introduction to heat and mass transfer for advanced undergraduate and graduate engineering students, used in classrooms for over 38 years and updated regularly. Topics include conduction, convection, radiation, and phase-change. Heat Transfer Engineering: Fundamentals and Techniques reviews the core mechanisms of heat transfer and provides modern methods to solve practical problems encountered by working practitioners, with a particular focus on developing engagement and motivation.
The book reviews fundamental concepts in conduction, forced convection, free convection, boiling, condensation, heat exchangers and mass transfer succinctly and without unnecessary exposition. Throughout, copious examples drawn from current industrial practice are examined with an emphasis on problem-solving for interest and insight rather than the procedural approaches often adopted in courses. The book contains numerous important solved and unsolved problems, utilizing modern tools and computational sources wherever relevant.
A subsection on common issues and recent advances is presented in each chapter, encouraging the reader to explore a greater diversity of problems. Reveals physical solutions alongside their application in practical problems, with an aim of generating interest from reality rather than dry exposition Reviews pertinent, contemporary computational tools, including emerging topics such as machine learning Describes the complexity of modern heat transfer in an engaging and conversational style, greatly adding to the uniqueness and accessibility of the book.
A student-oriented approach in which basic ideas and assumptions are stressed and discussed in detail and full developments of all important analyses are provided. The book contains many worked examples that illustrate the methods of analysis discussed. The book also contains a comprehensive set of problems and a Solutions Manual, written by the text authors. Heat Transfer Principles and Applications is a welcome change from more encyclopedic volumes exploring heat transfer.
This shorter text fully explains the fundamentals of heat transfer, including heat conduction, convection, radiation and heat exchangers. The fundamentals are then applied to a variety of engineering examples, including topics of special and current interest like solar collectors, cooling of electronic equipment, and energy conservation in buildings.
Each chapter has several example problems and a large, but not overwhelming, number of end-of-chapter problems. This text provides balanced coverage of the basic concepts of thermodynamics and heat transfer. Together with the illustrations, student-friendly writing style, and accessible math, this is an ideal text for an introductory thermal science course for non-mechanical engineering majors. This highly recommended book on transport phenomena shows readers how to develop mathematical representations models of physical phenomena.
The key elements in model development involve assumptions about the physics, the application of basic physical principles, the exploration of the implications of the resulting model, and the evaluation of the degree to which the model mimics reality. This book also expose readers to the wide range of technologies where their skills may be applied.
Designed for engineering graduate students who will later be required to work in industrial or environmental settings where latent heat transfer is important. The book provides a fundamental treatment of such topics as boiling, condensation, melting and solidification. Skip to content. Introduction to Heat Transfer. Author : Theodore L. Bergman,Frank P. Incropera,Adrienne S. Lavine,David P. Introduction to Heat Transfer Book Review:. Introduction To Heat Transfer.
Author : Frank P. Incropera,David P. Author : S. Author : Vedat S. Author : John H. Introduction to Thermal Systems Engineering. Author : Michael J. Moran,Howard N. Shapiro,Bruce R. Munson,David P. Author : J. The examples in the book are ubiquitous, not trivial "textbook" exercises.
They are rather complex and timely real-world problems that are inherently interesting. ISBN Your tags:. Send-to-Kindle or Email Please login to your account first Need help?
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