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Beschreibung:
Cover; Title; Copyright; Dedication; Contents; Preface; Acknowledgments; Guide to Instructors and Students; 1 Introduction and Preliminaries; 1.1 Applications and History; 1.1.1 Heat Transfer; 1.1.2 Applications; 1.1.3 History, Frontiers, and Integration*; 1.2 Units and Normalization (Scaling); 1.2.1 Units; 1.2.2 Normalization (Scaling); 1.3 Thermal Systems; 1.3.1 Thermodynamic Properties; 1.3.2 Thermal Nonequilibrium; 1.3.3 Control Volume and Control Surface; 1.4 Principal Energy Carriers and Heat Flux Vector; 1.4.1 Macroscopic Heat Transfer Mechanisms
1.4.2 Atomic-Level Heat Carriers (Heat Transfer Physics)1.4.3 Net Heat Transfer Rate Q|A; 1.4.4 Magnitude and Representation of q; 1.5 Heat Transfer Materials and Heat Flux Tracking; 1.5.1 Three Phases of Matter: Intermolecular and Intramolecular Forces*; 1.5.2 Microscale Energies of Matter: Discrete and Continuous Energies*; 1.5.3 Multiphase Heat Transfer Medium: Composites; 1.5.4 Fluid Motion; 1.5.5 Intramedium and Intermedium Heat Transfer; 1.5.6 Heat Flux Vector Tracking in Various Phases; 1.6 Conservation of Energy; 1.7 Conservation of Mass, Species, and Momentum*
1.7.1 Conservation of Mass* 1.7.2 Conservation of Species* ; 1.7.3 Conservation of Momentum*; 1.7.4 Other Conserved Quantities*; 1.8 Scope; 1.9 Summary; 1.10 References*; 1.11 Problems; 1.11.1 Heat Flux Vector Tracking; 1.11.2 Integral-Volume Energy Equation; 2 Energy Equation; 2.1 Nonuniform Temperature Distribution Differential :(Infinitesimal)-Volume Energy Equation; 2.1.1 Physical Interpretation of Divergence of q; 2.1.2 Relation between Volumetric Differentiation and Surface Integration
2.2 Uniform Temperature in One or More Directions: Energy Equation for Volumes with One or More Finite Lengths2.2.1 Integral-Volume Energy Equation; 2.2.2 Combined Integral- and Differential-Length Energy Equation; 2.2.3 Discrete Temperature Nonuniformity: Finite-Small-Volume Energy Equation*; 2.2.4 Summary of Selection of Energy Equation Based on Uniformity or Nonuniformity of Temperature; 2.3 Thermal Energy Conversion Mechanisms ; 2.3.1 Chemical- or Physical-Bond Energy Conversion; 2.3.2 Electromagnetic Energy Conversion; 2.3.3 Mechanical Energy Conversion
2.3.4 Summary of Thermal Energy Conversion Mechanisms2.4 Bounding-Surface and Far-Field Thermal Conditions; 2.4.1 Continuity of Temperature across Bounding Surface*; 2.4.2 Bounding-Surface Energy Equation; 2.4.3 Prescribed Bounding-Surface Thermal Conditions* ; 2.4.4 Far-Field Thermal Conditions* ; 2.5 Heat Transfer Analysis*; 2.5.1 Integration of Differential-Volume Energy Equation*; 2.5.2 Single- and Multidimensional Heat Flow* ; 2.5.3 Time Dependence and Steady State* ; 2.5.4 Thermal Circuit Models* ; 2.5.5 Summary of Methodology for Heat Transfer Analysis*
2.5.6 Solution Format for End-of-Chapter Problems*
This is a modern, example-driven introductory textbook on heat transfer, with modern applications, written by a renowned scholar