| Description |
1 online resource |
| Contents |
Cover; Half Title; Title Page; Copyright Page; Table of Contents; Authors; Preface; Acknowledgments; CHAPTER 1: Preliminary Concepts and Basic Equations; 1.1 REYNOLDS TRANSPORT THEOREM; 1.2 COMPRESSIBLE AND INCOMPRESSIBLE FLOWS; 1.3 ENERGY EQUATION USING SPECIFIC COORDINATE SYSTEM; 1.4 GENERALIZED APPROACH FOR DERIVATION OF ENERGY EQUATION; 1.5 IMPORTANT DIMENSIONLESS NUMBERS; 1.6 BOUNDARY LAYERS; 1.6.1 Velocity Boundary Layer; 1.6.2 Thermal Boundary Layer; 1.6.3 More about Velocity Boundary Layer and Thermal Boundary Layer; 1.6.4 Steady Flow over Flat Plate |
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2.8 MORE ABOUT SIMILARITY SOLUTION OF ENERGY EQUATION2.9 APPROXIMATE METHOD FOR BOUNDARY LAYER FLOWS OVER NON-ZERO PRESSURE GRADIENT SURFACES; 2.10 EFFECT OF PRESSURE GRADIENT ON EXTERNAL FLOWS; 2.11 DESCRIPTION OF FLOW PAST CIRCULAR CYLINDER; 2.12 EXPERIMENTAL RESULTS FOR CIRCULAR CYLINDER FLOW; 2.13 OTHER IMPORTANT CORRELATIONS; CHAPTER 3: Internal Flows; 3.1 ENTRY FLOW IN DUCT; 3.2 VELOCITY PROFILE IN FULLY DEVELOPED PIPE FLOW; 3.3 THERMAL CONSIDERATIONS DURING INTERNAL FLOWS; 3.3.1 Newton's Law of Cooling for Internal Flows; 3.3.2 Fully Developed Thermal Conditions |
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3.3.3 Energy Balance in Ducted Flows3.4 LAMINAR FLOW IN CIRCULAR TUBE; 3.4.1 Heat Transfer through Circular Tube for Hydrodynamically and Thermally Developed Flow with Uniform Wall Heat Flux (UHF) Condition; 3.4.2 Heat Transfer through Circular Tube for Thermally Fully Developed Laminar Slug Flow with Uniform Wall Temperature (UWT) Condition; 3.4.3 Heat Transfer in Circular Tube for Hydrodynamically and Thermally Developed Flow with Uniform Wall Temperature (UWT) Condition; 3.4.4 Calculation of Nusselt Number for UWT; 3.5 GRAETZ PROBLEM |
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3.6 SUMMARY OF SOLUTIONS FOR VARIOUS FLOW AND HEAT TRANSFER SITUATIONS IN PIPE FLOWS3.7 HEAT TRANSFER IN COUETTE FLOW; 3.8 CONVECTION CORRELATIONS FOR NON-CIRCULAR TUBES; CHAPTER 4: Solution of Complete Navier-Stokes and Energy Equations for Incompressible Internal Flows; 4.1 INTRODUCTION; 4.2 SOLUTION OF NAVIER STOKES EQUATIONS IN CARTESIAN COORDINATE; 4.2.1 Staggered Grid; 4.2.2 Introduction to MAC method; 4.3 SOLUTION OF ENERGY EQUATION IN CARTESIAN COORDINATE; 4.3.1 Solution Procedure; 4.3.2 Flow Chart; CHAPTER 5: Fluid Flow Solutions in Complex Geometry; 5.1 INTRODUCTION |
| Summary |
Thermal convection is often encountered by scientists and engineers while designing or analyzing flows involving exchange of energy. Fundamentals of Convective Heat Transfer is a unified text that captures the physical insight into convective heat transfer and thorough, analytical, and numerical treatments. It also focuses on the latest developments in the theory of convective energy and mass transport. Aimed at graduates, senior undergraduates, and engineers involved in research and development activities, the book provides new material on boiling, including nuances of physical processes. In all the derivations, step-by-step and systematic approaches have been followed |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Gautam Biswas is presently a professor of mechanical engineering at the Indian Institute of Technology (IIT) Kanpur. Previously, he was director of IIT Guwahati, and director of the CSIR-Central Mechanical Engineering Research Institute at Durgapur. He was the G.D. and V.M. Mehta Endowed Chair professor, and dean of academic affairs at IIT Kanpur. He served as a guest professor at the University of Erlangen-Nuremberg, Germany in 2002. Prof. Biswas was a Humboldt Fellow in Germany in 1987 and 1988 and an Invited Fellow by the Japan Society for the Promotion of Science in 1994. He is a fellow of the three major science academies in his country: the Indian National Science Academy, New Delhi, the Indian Academy of Sciences, Bangalore, and the National Academy of Sciences of India, Allahabad. He is a fellow of the Indian National Academy of Engineering, New Delhi and Institution of Engineers India, Kolkata. Prof. Biswas is a fellow of the American Society of Mechanical Engineers (ASME) and served as the associate editor of its Journal of Heat Transfer. He delivered the prestigious Prof. C.N.R. Rao Lecture in 2010. The Department of Science and Technology, India, awarded him the esteemed J.C. Bose National Fellowship in 2011. He is an associate editor of the journal Computers & Fluids. He has been conferred Honorary Doctorate by the Aristotle University of Thessaloniki, Greece in 2018. Amaresh Dalal is an associate professor in the Department of Mechanical Engineering at IIT Guwahati. He earned a PhD from IIT Kanpur in 2009 and served as a postdoctoral research associate at Purdue University, Indiana in 2008 and 2009. Dr. Dalal's research focuses on computational fluid dynamics and heat transfer, finite volume methods, unstructured grid techniques, and multiphase flows. He is presently developing a versatile and robust computational fluid dynamics solver over a hybrid unstructured grid. The programming paradigm is intended to solve a wide range of problems in the areas of real-life fluid flow, heat transfer, and transport phenomena involving complex geometries. Dr. Dalal won the Prof. K.N. Seetharamu Medal and Prize for the Best Young Researcher in Heat Transfer from the Indian Society of Heat and Mass Transfer in 2017. Vijay K. Dhir is a distinguished professor of mechanical and aerospace engineering and former dean of the Henry Samueli School of Engineering and Applied Science at the University of California Los Angeles (UCLA). Before being named dean, Prof. Dhir served as vice chair and chair of the Department of Mechanical and Aerospace Engineering. Dr. Dhir's efforts earned international recognition for the university's engineering school and made it a hub for interdisciplinary education and research. He leads the Boiling Heat Transfer Laboratory at UCLA. Its pioneering work in fundamental and applied sciences involving efficient heat removal through boiling gained international attention when NASA chose one of his research teams to conduct experiments on the International Space Station. They demonstrated the effects of microgravity on boiling. In 2006, Prof. Dhir earned one of the most prestigious honors for engineers. He was awarded membership in the National Academy of Engineering for his achievements in boiling heat transfer and nuclear reactor thermal hydraulics and safety. He received the Max Jakob Memorial Award; the American Society of Mechanical Engineers (ASME) Heat Transfer Memorial Award; the Donald Q. Kern Award of the American Institute of Chemical Engineers; and the Technical Achievement Award of the American Nuclear Society. Prof. Dhir has been a senior technical editor of ASME's Journal of Heat Transfer since 2000 and received its Best Paper Award twice. He serves on advisory boards of several other journals. His many areas of interest include two-phase heat transfer, boiling and condensation, thermal and hydrodynamic stability, thermal dynamics of nuclear reactors, and microgravity heat transfer. The Boiling Heat Transfer Laboratory is currently studying flow boiling, microgravity boiling, and thermal hydraulics of nuclear reactors |
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Restricted: Printing from this resource is governed by The Legal Deposit Libraries (Non-Print Works) Regulations (UK) and UK copyright law currently in force. WlAbNL |
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Online resource; title from PDF title page (EBSCO, viewed July 19, 2019) |
| Subject |
Heat -- Transmission.
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heat transmission.
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SCIENCE -- Mechanics -- Dynamics -- Thermodynamics.
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TECHNOLOGY -- Engineering -- Civil.
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TECHNOLOGY -- Engineering -- Mechanical.
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Heat -- Transmission
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| Form |
Electronic book
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| Author |
Dalal, Amaresh, author
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Dhir, V. K., author.
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| LC no. |
2021761856 |
| ISBN |
9780429198724 |
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0429198728 |
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9780429583797 |
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0429583796 |
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9780429581892 |
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0429581890 |
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9780429579677 |
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0429579675 |
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