Amazon cover image
Image from Amazon.com

Encyclopedia of thermal packaging. Set 1, Thermal packaging techniques / edited-in-chief, Avram Bar-Cohen.

Contributor(s): Material type: TextTextPublication details: Singapore : World Scientific, ©2013.Description: 1 online resourceContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9789814313797
  • 9814313793
  • 9781283971713
  • 1283971712
Subject(s): Genre/Form: Additional physical formats: Print version:: Encyclopedia of thermal packaging. Set 1, Thermal packaging techniques.DDC classification:
  • 621.381046 23
LOC classification:
  • TK7870.15 .E49 2013eb
Online resources:
Contents:
Vol. 1. Microchannel heat sinks for electronics cooling / Suresh V. Garimella, Tannaz Harirchian -- v. 2. Air- and liquid-cooled cold plates / Allan Kraus -- v. 3. Dielectric liquid cooling of immersed components / Karl J.L. Geisler. Avram Bar-Cohen -- v. 4. Thermoelectric microcoolers / Bao Yang, Peng Wang -- v. 5. Energy efficienct solid state lighting / Mehmet Arik, Anant Setlur, Stanton E. Weaver Jr., Joseph J. Shiang -- v. 6. Experimental thermofluid characterization of electronic components / Gary L. Solbrekken.
Foreword to the Encyclopedia of Thermal Packaging by Wataru Nakayama; Preface; Contents; Chapter 1 Introduction; 1.1. Physics and Applications of Microchannels; 1.2. Use of Microchannels in Electronics Cooling; References; Chapter 2 Design and Optimization of Single-Phase Microchannel Heat Sinks; 2.1. Prediction of Heat Transfer Coefficient; 2.1.1. Experiments and comparison to correlations; 2.1.2. Numerical analyses; 2.1.3. Correlations; 2.2. Prediction of Pressure Drop; 2.3. Optimization of Heat Transfer Performance; 2.4. Importance of Inlet Manifold Design; 2.5. Hot-Spot Thermal Management.
2.6. System-Level Design and OptimizationReferences; Chapter 3 Two-Phase Operation of Microchannel Heat Sinks; 3.1. Fundamentals of Two-Phase Transport in Microchannels; 3.2. Macroscale versus Microscale Boiling; 3.3. Flow Regime Maps; References; Chapter 4 Boiling Heat Transfer at Small Scales; 4.1. Saturated Boiling in Microchannels; 4.2. Heat Transfer in Boiling and Two-Phase Flow; 4.3. Effect of Geometrical and Flow Parameters; 4.3.1. Effect of channel dimensions; 4.3.2. Effect of mass flow rate; 4.3.3. Effect of surface roughness; 4.4. Empirical Predictions of Thermal Performance.
4.4.1. Subcooled boiling regime4.4.2. Saturated boiling regime; 4.4.3. Saturated flow boiling correlation; 4.5. Physics-Based Modeling of Boiling Heat Transfer; 4.5.1. Annular flow; 4.5.1.1. Solution procedure; 4.5.1.2. Model assessment; 4.5.2. Annular/Wispy-annular flow; 4.5.3. Slug flow; References; Chapter 5 Pressure Drop in Two-Phase Flow; 5.1. Two-Phase Flow Pressure Drop; 5.2. Empirical Prediction of Two-Phase Pressure Drop; 5.3. Regime-Based Modeling of Two-Phase Pressure Drop; 5.3.1. Confined flow; 5.3.2. Unconfined flow; 5.3.3. Model assessment; References.
Chapter 6 Micropumps and Pumping Requirements6.1. Microscale Pumping Technologies; 6.2. Mechanical Displacement Micropumping Techniques; 6.2.1. Diaphragm displacement pumps; 6.2.2. Fluid displacement pumps; 6.2.3. Rotary pumps; 6.3. Electro- and Magneto-Kinetic Micropumping Techniques; 6.3.1. Electrohydrodynamic pumps; 6.3.1.1. Induction-type EHD; 6.3.1.2. Injection-type EHD; 6.3.1.3. Polarization-type EHD; 6.3.1.4. Ion-drag; 6.3.2. Electroosmotic pumps; 6.3.2.1. DC electroosmotic; 6.3.2.2. AC electroosmotic; 6.3.3. Magnetohydrodynamic pumps; 6.3.4. Electrowetting pumps; 6.3.5. Other.
6.4. Pump Selection6.4.1. Materials and construction; 6.4.2. Selection guidelines; References; Chapter 7 Challenges in Implementation; 7.1. Effect of Dissolved Air on System Performance; 7.1.1. Degassing scheme; 7.2. System Instabilities for Boiling in Microchannels; 7.3. Critical Heat Flux; References; Chapter 8 Measurement Techniques; 8.1. Conventional Techniques; 8.2. Microscale Temperature Measurement; 8.3. Optical Flow Measurements; 8.4. Micro-PIV and IR Micro-PIV; 8.5. Laser-Induced Fluorescence Thermometry; References; Author Index; Subject Index; About the Authors.
Summary: Please click here for information on Set 2: Thermal Packaging ToolsThermal and mechanical packaging - the enabling technologies for the physical implementation of electronic systems - are responsible for much of the progress in miniaturization, reliability, and functional density achieved by electronic, microelectronic, and nanoelectronic products during the past 50 years. The inherent inefficiency of electronic devices and their sensitivity to heat have placed thermal packaging on the critical path of nearly every product development effort in traditional, as well as emerging, electronic prod.
Item type:
Tags from this library: No tags from this library for this title. Log in to add tags.
Star ratings
    Average rating: 0.0 (0 votes)
Holdings
Item type Home library Collection Call number Materials specified Status Date due Barcode
Electronic-Books Electronic-Books OPJGU Sonepat- Campus E-Books EBSCO Available

Includes bibliographical references and indexes.

Vol. 1. Microchannel heat sinks for electronics cooling / Suresh V. Garimella, Tannaz Harirchian -- v. 2. Air- and liquid-cooled cold plates / Allan Kraus -- v. 3. Dielectric liquid cooling of immersed components / Karl J.L. Geisler. Avram Bar-Cohen -- v. 4. Thermoelectric microcoolers / Bao Yang, Peng Wang -- v. 5. Energy efficienct solid state lighting / Mehmet Arik, Anant Setlur, Stanton E. Weaver Jr., Joseph J. Shiang -- v. 6. Experimental thermofluid characterization of electronic components / Gary L. Solbrekken.

Foreword to the Encyclopedia of Thermal Packaging by Wataru Nakayama; Preface; Contents; Chapter 1 Introduction; 1.1. Physics and Applications of Microchannels; 1.2. Use of Microchannels in Electronics Cooling; References; Chapter 2 Design and Optimization of Single-Phase Microchannel Heat Sinks; 2.1. Prediction of Heat Transfer Coefficient; 2.1.1. Experiments and comparison to correlations; 2.1.2. Numerical analyses; 2.1.3. Correlations; 2.2. Prediction of Pressure Drop; 2.3. Optimization of Heat Transfer Performance; 2.4. Importance of Inlet Manifold Design; 2.5. Hot-Spot Thermal Management.

2.6. System-Level Design and OptimizationReferences; Chapter 3 Two-Phase Operation of Microchannel Heat Sinks; 3.1. Fundamentals of Two-Phase Transport in Microchannels; 3.2. Macroscale versus Microscale Boiling; 3.3. Flow Regime Maps; References; Chapter 4 Boiling Heat Transfer at Small Scales; 4.1. Saturated Boiling in Microchannels; 4.2. Heat Transfer in Boiling and Two-Phase Flow; 4.3. Effect of Geometrical and Flow Parameters; 4.3.1. Effect of channel dimensions; 4.3.2. Effect of mass flow rate; 4.3.3. Effect of surface roughness; 4.4. Empirical Predictions of Thermal Performance.

4.4.1. Subcooled boiling regime4.4.2. Saturated boiling regime; 4.4.3. Saturated flow boiling correlation; 4.5. Physics-Based Modeling of Boiling Heat Transfer; 4.5.1. Annular flow; 4.5.1.1. Solution procedure; 4.5.1.2. Model assessment; 4.5.2. Annular/Wispy-annular flow; 4.5.3. Slug flow; References; Chapter 5 Pressure Drop in Two-Phase Flow; 5.1. Two-Phase Flow Pressure Drop; 5.2. Empirical Prediction of Two-Phase Pressure Drop; 5.3. Regime-Based Modeling of Two-Phase Pressure Drop; 5.3.1. Confined flow; 5.3.2. Unconfined flow; 5.3.3. Model assessment; References.

Chapter 6 Micropumps and Pumping Requirements6.1. Microscale Pumping Technologies; 6.2. Mechanical Displacement Micropumping Techniques; 6.2.1. Diaphragm displacement pumps; 6.2.2. Fluid displacement pumps; 6.2.3. Rotary pumps; 6.3. Electro- and Magneto-Kinetic Micropumping Techniques; 6.3.1. Electrohydrodynamic pumps; 6.3.1.1. Induction-type EHD; 6.3.1.2. Injection-type EHD; 6.3.1.3. Polarization-type EHD; 6.3.1.4. Ion-drag; 6.3.2. Electroosmotic pumps; 6.3.2.1. DC electroosmotic; 6.3.2.2. AC electroosmotic; 6.3.3. Magnetohydrodynamic pumps; 6.3.4. Electrowetting pumps; 6.3.5. Other.

6.4. Pump Selection6.4.1. Materials and construction; 6.4.2. Selection guidelines; References; Chapter 7 Challenges in Implementation; 7.1. Effect of Dissolved Air on System Performance; 7.1.1. Degassing scheme; 7.2. System Instabilities for Boiling in Microchannels; 7.3. Critical Heat Flux; References; Chapter 8 Measurement Techniques; 8.1. Conventional Techniques; 8.2. Microscale Temperature Measurement; 8.3. Optical Flow Measurements; 8.4. Micro-PIV and IR Micro-PIV; 8.5. Laser-Induced Fluorescence Thermometry; References; Author Index; Subject Index; About the Authors.

Please click here for information on Set 2: Thermal Packaging ToolsThermal and mechanical packaging - the enabling technologies for the physical implementation of electronic systems - are responsible for much of the progress in miniaturization, reliability, and functional density achieved by electronic, microelectronic, and nanoelectronic products during the past 50 years. The inherent inefficiency of electronic devices and their sensitivity to heat have placed thermal packaging on the critical path of nearly every product development effort in traditional, as well as emerging, electronic prod.

eBooks on EBSCOhost EBSCO eBook Subscription Academic Collection - Worldwide

There are no comments on this title.

to post a comment.

O.P. Jindal Global University, Sonepat-Narela Road, Sonepat, Haryana (India) - 131001

Send your feedback to glus@jgu.edu.in

Hosted, Implemented & Customized by: BestBookBuddies   |   Maintained by: Global Library