Introduction to Heat TransferIntroduction to Heat Transfer, 6th Edition is the gold standard of heat transfer pedagogy for more than 30 years. With examples and problems that reveal the richness and beauty of this discipline, this text teaches students how to become efficient problem-solvers through the use of the rigorous and systematic problem-solving methodology pioneered by the authors. Fundamental concepts have received further emphasis in this new edition, making the text even more accessible while providing a bridge from those ideas to critical applications in areas such as energy and the environment. |
Contents
Introduction to Conduction | 68 |
OneDimensional SteadyState Conduction | 111 |
TwoDimensional SteadyState Conduction | 229 |
The Graphical Method | W-1 |
Problems W10 CHAPTER 5 Transient Conduction | 279 |
Graphical Representation of OneDimensional Transient Conduction in | W-12 |
Introduction to Convection | 377 |
Derivation of the Convection Transfer Equations W25 | W-25 |
650 | 650 |
656 | 656 |
Heat Exchangers | 672 |
Log Mean Temperature Difference Method for Multipass | W-38 |
Processes and Properties | 733 |
Radiation Exchange Between Surfaces | 827 |
APPENDIX A Thermophysical Properties of Matter 897 | 916 |
APPENDIX B Mathematical Relations and Functions | 927 |
External Flow | 415 |
Internal Flow | 489 |
Free Convection | 561 |
Free Convection 561 9 1 Physical Considerations | 562 |
Boiling and Condensation | 619 |
626 | 626 |
635 | 635 |
641 | 641 |
Thermal Conditions Associated with Uniform Energy | 932 |
Generation in OneDimensional SteadyState Systems | 933 |
The GaussSeidel Method | 939 |
APPENDIX E The Convection Transfer Equations | 941 |
APPENDIX F Boundary Layer Equations for Turbulent Flow | 945 |
APPENDIX G An Integral Laminar Boundary Layer Solution | 949 |
| 953 | |
Other editions - View all
Introduction to Heat Transfer, Binder Ready Version Frank P. Incropera,David P. DeWitt No preview available - 2011 |
Common terms and phrases
aluminum ambient analysis applied approximation associated assumed average base boundary layer Calculate Chapter chip Consider constant convection coefficient convection heat transfer cooling corresponding cylinder depends determine diameter difference effect electrical engine Equation evaluated example exposed expression Figure finite-difference flow fluid follows forces function geometry heat flux heat loss heat rate heat transfer heat transfer coefficient heat transfer rate heater Hence increasing initial inner insulation known length liquid maintained material maximum measured medium method node obtained occurs one-dimensional operating outer surface plane wall plate plot Problem properties provides radiation reduce resistance respectively shown side sketch solid solution solved space sphere steady-state conditions steel surface temperature surroundings Table tempera temperature distribution thermal conductivity thermal energy thickness tion transient tube ture unit velocity W/mK wall