DescriptionComprehensive and unique source integrates the material usually distributed among a half a dozen sources.
* Presents a unified approach to modeling of new designs and develops the skills for complex engineering analysis.
* Provides industrial insight to the applications of the basic theory developed.
1 Classification of Heat Exchangers.
1.2 Classification According to Transfer Processes.
1.3 Classification According to Number of Fluids.
1.4 Classification According to Surface Compactness.
1.5 Classification According to Construction Features.
1.6 Classification According to Flow Arrangements.
1.7 Classification According to Heat Transfer Mechanisms.
2 Overview of Heat Exchanger Design Methodology.
2.1 Heat Exchanger Design Methodology.
2.2 Interactions Among Design Considerations.
3 Basic Thermal Design Theory for Recuperators.
3.1 Formal Analogy between Thermal and Electrical Entities.
3.2 Heat Exchanger Variables and Thermal Circuit.
3.3 The ?(Epsilon)-NTU Method.
3.4 Effectiveness – Number of Transfer Unit Relationships.
3.5 The P-NTU Method.
3.6 P-N TU R elat ionships.
3.7 The Mean Temperature Difference Method.
3.8 F Factors for Various Flow Arrangements.
3.9 Comparison of the ?(Epsilon)-NTU, P-NTU, and MTD Methods.
3.10 The ?(Psi)-P and P1—P2 Methods.
3.11 Solution Methods for Determining Exchanger Effectiveness.
3.12 Heat Exchanger Design Problems.
4 Additional Considerations for Thermal Design of Recuperators.
4.1 Longitudinal Wall Heat Conduction Effects.
4.2 Nonuniform Overall Heat Transfer Coefficients.
4.3 Additional Considerations for Extended Surface Exchangers.
4.4 Additional Considerations for Shell-and-Tube Exchangers.
5 Thermal Design Theory for Regenerators.
5.1 Heat Transfer Analysis.
5.2 The ?(Epsilon)-NTUo Method.
5.3 The ?(Lambda)—?(Pi) Method.
5.4 Influence of Longitudinal Wall Heat Conduction.
5.5 Influence of Transverse Wall Heat Conduction.
5.6 Influence of Pressure and Carryover Leakages.
5.7 Influence of Matrix Material, Size, and Arrangement.
6 Heat Exchanger Pressure Drop Analysis.
6.2 Extended Surface Heat Exchanger Pressure Drop.
6.3 Regenerator Pressure Drop.
6.4 Tubular Heat Exchanger Pressure Drop.
6.5 Plate Heat Exchanger Pressure Drop.
6.6 Pressure Drop Associated with Fluid Distribution Elements.
6.7 Pressure Drop Presentation.
6.8 Pressure Drop Dependence on Geometry and Fluid Properties.
7 Surface Basic Heat Transfer and Flow Friction Characteristics.
7.1 Basic Concepts.
7.2 Dimensionless Groups.
7.3 Experimental Techniques for Determining Surface Characteristics.
7.4 Analytical and Semiempirical Heat Transfer and Friction Factor Correlations for Simple Geometries.
7.5 Experimental Heat Transfer and Friction Factor Correlations for Complex Geometries.
7.6 Influence of Temperature-Dependent Fluid Properties.
7.7 Influence of Superimposed Free Convection.
7.8 Influence of Superimposed Radiation.
8 Heat Exchanger Surface Geometrical Characteristics.
8.1 Tubular Heat Exchangers.
8.2 Tube-Fin Heat Exchangers.
8.3 Plate-Fin Heat Exchangers.
8.4 Regenerators with Continuous Cylindrical Passages.
8.5 Shell-and-Tube Exchangers with Segmental Baffles.
8.6 Gasketed Plate Heat Exchangers.
9 Heat Exchanger Design Procedures.
9.1 Fluid Mean Temperatures.
9.2 Plate-Fin Heat Exchangers.
9.3 Tube-Fin Heat Exchangers.
9.3.4 Core Mass Velocity Equation.
9.4 Plate Heat Exchangers.
9.5 Shell-and-Tube Heat Exchangers.
9.6 Heat Exchanger Optimization.
10 Selection of Heat Exchangers and Their Components.
10.1 Selection Criteria Based on Operating Parameters.
10.2 General Selection Guidelines for Major Exchanger Types.
10.3 Some Quantitative Considerations.
11 Thermodynamic Modeling and Analysis.
11.2 Modeling a Heat Exchanger Based on the First Law of Thermodynamics.
11.3 Irreversibilities in Heat Exchangers.
11.4 Thermodynamic Irreversibility and Temperature Cross Phenomena.
11.5 A Heuristic Approach to an Assessment of Heat Exchanger Effectiveness.
11.6 Energy, Exergy, and Cost Balances in the Analysis and Optimization of Heat Exchangers.
11.7 Performance Evaluation Criteria Based on the Second Law of Thermodynamics.
12 Flow Maldistribution and Header Design.
12.1 Geometry-Induced Flow Maldistribution.
12.2 Operating Condition–Induced Flow Maldistribution.
12.3 Mitigation of Flow Maldistribution.
12.4 Header and Manifold Design.
13 Fouling and Corrosion.
13.1 Fouling and its Effect on Exchanger Heat Transfer and Pressure Drop.
13.2 Phenomenological Considerations of Fouling.
13.3 Fouling Resistance Design Approach.
13.4 Prevention and Mitigation of Fouling.
13.5 Corrosion in Heat Exchangers.
Appendix A: Thermophysical Properties.
Appendix B: ?(Epsilon)-NTU Relationships for Liquid-Coupled Exchangers.
Appendix C: Two-Phase Heat Transfer and Pressure Drop Correlations.
C.1 Two-Phase Pressure Drop Correlations.
C.2 Heat Transfer Correlations for Condensation.
C.3 Heat Transfer Correlations for Boiling.
Appendix D: U and CUA Values for Various Heat Exchangers.
General References on or Related to Heat Exchangers.
- Comprehensive and unique source. The comprehensive coverage is a unique feature of the book that integrates the material usually distributed among a half a dozen sources.
- Integrated approach to thermal design and analysis. Presents a unified approach to modeling of new designs and develops the skills for complex engineering analysis.
- Practical value. Examples, problems and review questions in each chapter are based on real industrial problems and convey more than the theory development by providing industrial insight to the applications of the basic theory developed.
- Extensive coverage of thermal design theory for recuperators and surface basic heat transfer and flow friction characteristics. The chapters that cover this material integrate all basic results of a heat transfer analysis and the corresponding calculations required for heat exchanger thermal design.