Advanced Heat Transfer 3rd Edition by Greg Naterer 1032072474 9781032072470

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ISBN 10: 1032072474 
ISBN 13: 9781032072470
Author: Greg F. Naterer

The book provides a valuable source of technical content for the prediction and analysis of advanced heat transfer problems, including conduction, convection, radiation, phase change, and chemically reactive modes of heat transfer. With more than 20 new sections, case studies, and examples, the Third Edition broadens the scope of thermal engineering applications, including but not limited to biomedical, micro- and nanotechnology, and machine learning. The book features a chapter devoted to each mode of multiphase heat transfer. FEATURES Covers the analysis and design of advanced thermal engineering systems Presents solution methods that can be applied to complex systems such as semi-analytical, machine learning, and numerical methods Includes a chapter devoted to each mode of multiphase heat transfer, including boiling, condensation, solidification, and melting Explains processes and governing equations of multiphase flows with droplets and particles Applies entropy and the second law of thermodynamics for the design and optimization of thermal engineering systems Advanced Heat Transfer, Third Edition, offers a comprehensive source for single and multiphase systems of heat transfer for senior undergraduate and graduate students taking courses in advanced heat transfer, multiphase fluid mechanics, and advanced thermodynamics. A solutions manual is provided to adopting instructors.

Advanced Heat Transfer 3rd Table of contents:

1 Introduction

1.1 Fundamental Concepts and Definitions

1.2 Conservation of Energy

1.3 Thermophysical Properties

1.3.1 Thermodynamic Properties

1.3.2 Transport Properties

1.4 Heat Conduction

1.5 Convection

1.6 Thermal Radiation

1.7 Phase Change Heat Transfer

1.8 Mass Transfer

References

Problems

2 Heat Conduction

2.1 Introduction

2.2 One-dimensional Heat Conduction

2.2.1 Heat Conduction Equation

2.2.2 Steady Conduction in a Plane Layer

2.3 Thermal Resistance and Shape Factor

2.4 Fins and Extended Surfaces

2.5 Multidimensional Conduction

2.5.1 Cartesian Coordinates

2.5.2 Orthogonal Curvilinear Coordinates

2.5.3 Cylindrical and Spherical Coordinates

2.6 Method of Separation of Variables

2.7 Nonhomogeneous Systems

2.8 Conformal Mapping

2.9 Transient Heat Conduction

2.9.1 Lumped Capacitance Method

2.9.2 Semi-Infinite Solid

2.9.3 Finite Regions

2.10 Time-Dependent Boundary Conditions

2.11 Conduction in Porous Media

2.12 Heat Transfer in Living Tissue

2.13 Microscale Conduction

References

Problems

3 Convection

3.1 Introduction

3.2 Governing Equations

3.2.1 Conservation of Mass (Continuity Equation)

3.2.2 Conservation of Momentum (Navier–Stokes Equations)

3.2.3 Total Energy (First Law of Thermodynamics)

3.2.4 Mechanical Energy Equation

3.2.5 Internal Energy Equation

3.3 Nondimensional Form of Equations

3.3.1 Dimensionless Variables

3.3.2 Buckingham–Pi Theorem

3.4 Convection Boundary Layer

3.4.1 Boundary Layer Equations

3.4.2 Heat and Momentum Analogies

3.5 Evaporative Cooling

3.6 Flat Plate Boundary Layer

3.6.1 Scaling Analysis

3.6.2 Integral Solution

3.6.3 Similarity Solution

3.7 Flow Past a Wedge

3.8 Cylinder in Cross Flow

3.9 Other External Flow Configurations

3.9.1 Sphere

3.9.2 Tube Bundles

3.10 Internal Flow

3.10.1 Poiseuille Flow in Tubes

3.10.2 Non-Circular Ducts

3.11 Free Convection

3.11.1 Vertical Flat Plate

3.11.2 Body Gravity Function Method

3.11.3 Spherical Geometries

3.12 Introduction to Turbulence

3.12.1 Turbulence Spectrum

3.12.2 Reynolds Averaged Navier–Stokes Equations

3.12.3 Eddy Viscosity

3.12.4 Mixing Length

3.12.5 Near-Wall Flow

3.12.6 One- and Two-Equation Closure Models

3.13 Entropy and the Second Law

3.13.1 Formulation of Entropy Production

3.13.2 Apparent Entropy Production Difference

3.13.3 Dimensionless Entropy Production Number

References

Problems

4 Thermal Radiation

4.1 Introduction

4.2 Fundamentals of Radiation

4.2.1 Electromagnetic Spectrum

4.2.2 Radiation Intensity

4.2.3 Blackbody Radiation

4.3 Radiative Surface Properties

4.4 Radiation Exchange between Surfaces

4.5 Thermal Radiation in Enclosures

4.5.1 Radiation Exchange at a Surface

4.5.2 Radiation Exchange Between Surfaces

4.5.3 Two-Surface Enclosures

4.6 Radiation in Participating Media

4.6.1 Attenuation by Absorption and Scattering

4.6.2 Scattering from Other Directions

4.6.3 Enhancement of Intensity by Emission

4.7 Equations of Energy Transfer for Participating Media

4.7.1 General Equation of Transfer

4.7.2 Radiative Flux Vector

4.7.3 Conservation of Energy

4.8 Approximate Solutions of the Equation of Transfer

4.8.1 Transparent Gas Approximation

4.8.2 Emission Approximation

4.8.3 Rosseland Approximation

4.9 Coupled Radiation and Convection

4.10 Solar Radiation

4.10.1 Components of Solar Radiation

4.10.2 Solar Angles

4.10.3 Incident Solar Radiation

4.11 Solar Collectors

4.11.1 Collector Efficiency and Heat Losses

4.11.2 Temperature Distribution

4.11.3 Heat Removal Factor

References

Problems

5 Gas–Liquid Two-Phase Flows

5.1 Introduction

5.2 Pool Boiling

5.2.1 Physical Processes

5.2.2 Nucleate Pool Boiling

5.2.3 Film Pool Boiling

5.3 Forced Convection Boiling in External Flow

5.3.1 Over a Flat Plate

5.3.2 Outside a Horizontal Tube

5.3.3 Other Surface Configurations

5.4 Two-phase Flow in Vertical Tubes

5.4.1 Vertical Flow Regimes

5.4.2 Formation of Bubbles

5.4.3 Models of Annular Flow and Heat Transfer

5.5 Internal Horizontal Two-phase Flows

5.5.1 Flow Regimes in Horizontal Tubes

5.5.2 Dispersed Bubble Flow

5.5.3 One-dimensional Model of Stratified Flow

5.5.4 Plug and Annular Flow Correlations

5.5.5 Multi–Regime Nusselt Number Correlations

5.6 Turbulence Modeling of Two-phase Flows

5.7 Laminar Film Condensation

5.7.1 Axisymmetric Bodies

5.7.2 Other Configurations

5.8 Turbulent Film Condensation

5.8.1 Over a Vertical Plate

5.8.2 Outside a Sphere

5.9 Forced Convection Condensation

5.9.1 Internal Flow in Tubes

5.9.2 Outside a Horizontal Tube

5.9.3 Finned Tubes

5.10 Thermosyphons and Heat Pipes

5.10.1 Transport Processes

5.10.2 Operational Limitations

References

Problems

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