Heat exchangers : types, design, and applications /
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| Author / Creator: | Branson, Spencer T. |
|---|---|
| Imprint: | Hauppauge, N.Y. : Nova Science Publishers, c2011. |
| Description: | 1 online resource. |
| Language: | English |
| Series: | Energy science, engineering and technology Energy science, engineering and technology series. |
| Subject: | |
| Format: | E-Resource Book |
| URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/11131882 |
Table of Contents:
- HEAT EXCHANGERS: TYPES, DESIGN, AND APPLICATIONS; HEAT EXCHANGERS: TYPES, DESIGN, AND APPLICATIONS ; CONTENTS ; PREFACE ; LIGHTWEIGHT COMPACT HEAT EXCHANGERS WITH OPEN-CELL METAL FOAMS ; ABSTRACT ; 1. INTRODUCTION ; 2. TOPOLOGIES OF OPEN-CELL METAL FOAMS ; 2.1. Macro/Micro Topologies ; 2.2. Fabrication Methods of Metal Foams ; 3. SINGLE PHASE FORCED CONVECTION IN OPEN-CELL METAL FOAMS ; 3.1. Pressure Drop (Loss) ; 3.1.1. Overall Pressure drop Behavior; 3.1.2. Empirical Correlations for Homogeneous Isotropic Foams with Open Cells.
- 3.1.3. Contribution of Overall Foam Shape and Size to Pressure Drop 3.1.4. Effect of Porosity on Pressure Drop ; 3.1.5. Effect of Pore Density (Pore Size) on Pressure Drop ; 3.2. Heat Transfer ; 3.2.1. Forced Convection Heat Transfer in Open-Cell Metal Foams ; 3.2.2. Analytical Modeling of Heat Transfer ; 3.2.3. Effect of Porosity (<U+0066>) ; 3.2.4. Effect of Pore Size (Dp) and Pore Density (PPI) ; 3.2.5. Effect of Thermal Conductivity ; 3.3. Comparison of Overall Performance for Different Types of Heat Dissipation Medium ; 4. IMPINGING JETS ON OPEN-CELL METAL FOAMS ; 4.1. Impinging Round Jet.
- 4.2. Single Jet Flow Structures 4.3. Heat Transfer Enhancement ; 4.4. Effects of Topological Parameters ; 4.4.1. Effect of Porosity ; 4.4.2. Effect of Pore Density (Pore Size) ; 4.4.3. Effect of Foam Height ; 4.4.4. Effect of Foam Width ; 4.4.5. Effect of Nozzle-to-Foam Tip Distance ; 4.5. Impinging Annular Jet ; 4.5.1. Exit Flow Structures ; 4.5.2. Heat Transfer Enhancement ; 5. OPEN-CELL METAL FOAMS FOR ELECTRONICS COOLING ; 5.1. Background ; 5.2. Conventional Heat Sink (Exchanger) for Electronics Cooling ; 5.3. Open-Cell Metal Foam Heat Sink: Flow Field and Overall Thermal Performance.
- 5.5. Lightweight Compact Heat Sinks Acknowledgments ; APPENDIX A ; NOMENCLATURE ; Greek Symbols ; Abbreviations ; REFERENCES ; THE NTU-EFFECTIVENESS METHOD ; ABSTRACT ; 1. INTRODUCTION ; 2. THE PARALLEL FLOW HEAT EXCHANGER; 3. THE COUNTER FLOW HEAT EXCHANGER; 4. THE 1-2 HEAT EXCHANGER; 4.1. First Configuration (Inlets on the Same Side); 4.2. Second Configuration (Inlets on Opposite Sides); 5. THE 1-2N HEAT EXCHANGER ; 6. THE CROSS FLOW HEAT EXCHANGERS; 6.1. Unmixed-Mixed Configuration; 6.2. Mixed-Mixed Configuration; 6.1. Unmixed-Unmixed Configuration; 7. HEAT EXCHANGER NETWORKS.
- 7.1. Heat Exchangers Globally in a Counter Flow Configuration 7.2. Heat Exchangers Globally in a Parallel Flow Configuration ; 7.3. Heat Exchangers in Paralle/Serial Flow Configuration ; 8. EXAMPLES ; 8.1. Comparison of Counter Flow and Parallel Flow Heat Exchangers ; 8.2. Counter Flow Heat Exchanger (Variable Properties); 8.3. Cross Flow Heat Exchanger; 8.4. Coupled Heat Exchangers (Identical Effectiveness); 8.5. Coupled Heat Exchangers (Identical Heat Exchangers); 8.6. Determination of the Heat Exchanger Type and of the Overall Heat Transfer Coefficient.