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Handbook for Transversely Finned Tube Heat Exchanger Design
- 1st Edition - May 6, 2016
- Authors: Eugene Pis’mennyi, Georgiy Polupan, Ignacio Carvajal-Mariscal, Florencio Sanchez-Silva, Igor Pioro
- Language: English
- Paperback ISBN:9 7 8 - 0 - 1 2 - 8 0 4 3 9 7 - 4
- eBook ISBN:9 7 8 - 0 - 1 2 - 8 0 4 4 1 6 - 2
Handbook for Transversely Finned Tubes Heat Exchangers Design contains detailed experimental data, correlations, and design methods for designing and improving the performan… Read more
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contains detailed experimental data, correlations, and design methods for designing and improving the performance of finned tube heat exchangers. It covers the three main types, circular finned, square finned, and helical finned tube bundles.Based on extensive experimental studies and tested at leading design and research institutions, this handbook provides an extensive set of materials for calculating and designing convective surfaces from transversely finned tubes, with a particular emphasis on power plant applications.
- Provides a design manual for calculating heat transfer and aerodynamic resistance of convective heating surfaces fabricated in the form of tube bundles with transverse circular, square and helical fins
- Presents calculations for finned surfaces operating under conditions of clean and dust-laden flows alike, including finned convective heating surfaces of boilers
- Includes a fully solved exercise at the end of the book, illustrating the top-down approach specially oriented to power plant heat exchangers
design engineers, researchers, and students of power engineering and power machine construction specialties
- About the Authors
- Foreword
- Preface
- Nomenclature
- Chapter 1. General Statements
- 1.1. Geometric Characteristics
- Chapter 2. Heat-Transfer Calculations
- 2.1. Basic Equations
- 2.2. Overall Heat-Transfer Coefficient
- 2.3. Reduced Convective Heat-Transfer Coefficient h1rdc
- 2.4. Convective Heat-Transfer Coefficient (hc)
- 2.5. Heat-Transfer Coefficient From Wall to Internal Medium (h2)
- 2.6. Contamination Factor and Thermal Efficiency
- 2.7. Average Temperature Difference
- Chapter 3. Calculation of Aerodynamic Resistance
- 3.1. Aerodynamic Resistance Calculation
- Chapter 4. Calculation of Hydraulic Resistance
- 4.1. Definition of Quantities that Characterize Flow
- 4.2. Calculation of Total Hydraulic Resistance of Tube Element
- 4.3. Calculation of Hydraulic Friction and Local Resistances of Heat-Transfer Surface
- 4.4. Friction Resistance
- 4.5. Local Resistance in Tube Elements
- 4.6. Pressure Variation in Collectors
- Chapter 5. Calculation of Temperature Mode of Finned Tubes
- 5.1. Definition
- 5.2. Calculation of Temperature of Fin Base
- 5.3. Temperature at Fin Tip
- 5.4. Mean Integral Temperature of Fin
- 5.5. Temperature of the Inside Surface of Tube
- 5.6. Thickness Average Temperature of the Tube Wall in the Region of Maximum Heat Flux
- Chapter 6. Strength Design
- 6.1. Basic Concepts
- 6.2. Design Pressure
- 6.3. Design Temperature
- 6.4. Allowable Stress
- 6.5. Calculation of Allowable Wall Thickness of Finning-Carrying Tube
- Chapter 7. Examples of Calculations
- 7.1. Calculation Assignment
- 7.2. Heat Balance
- 7.3. Structural Features of WAHE
- 7.4. Area of Heat-Transfer Surface
- 7.5. Calculation of Aerodynamic Resistance
- 7.6. Calculation of Hydraulic Resistance of WAHE
- Appendix A. Units Conversion
- Appendix B. Recommended Thermophysical Properties Software for Gases and Liquids
- Appendix C. Tables of Properties of Substances
- References
- Index
- No. of pages: 188
- Language: English
- Edition: 1
- Published: May 6, 2016
- Imprint: Academic Press
- Paperback ISBN: 9780128043974
- eBook ISBN: 9780128044162
EP
Eugene Pis’mennyi
GP
Georgiy Polupan
His major area of study is thermal processes in steam generators, thermo physics, and efficient use of energy. He is an author of more than 300 publications, including three technical books, two patents, and 67 papers in refereed journals.
G. Polupan was a researcher at the Thermal Physics Department from 1972 to 1985 and a professor of the Thermal Engineering Faculty of the National Technical University of Ukraine, Kyiv Polytechnic Institute from 1985 to 1999. Since 1999, he has been a full professor at the National Polytechnic Institute of Mexico, Superior School of Mechanical and Electrical Engineering, Thermal Engineering and Applied Hydraulic Laboratory.
IC
Ignacio Carvajal-Mariscal
Currently, Dr. Carvajal-Mariscal is a full professor at the National Polytechnic Institute of Mexico. His research interests are heat-transfer enhancement, experimental fluid dynamics and heat-exchanger design. Dr. Carvajal-Mariscal is an ASME member since 2008.
FS
Florencio Sanchez-Silva
Currently, he is a full professor at the National Polytechnic Institute of Mexico. His research interests are two-phase flow dynamics, heat pipes, energy saving and, development and analysis of thermal energy systems.
Up to now, Dr. Sánchez-Silva has 38 refereed journal publications, 250 refereed papers in conference proceedings, 15 technical reports, 2 technical books, 3 chapters in technical books. He has supervised 3 PhD, 44 Master in Science and 31 bachelor thesis on two-phase flow, heat transfer, fluid mechanics, metrology and thermal systems topics.
Dr. Sanchez-Silva is a Fellow of the Societé des Ingenieurs et Scientifiques de France, Mexican Section (since l987) and a member of the Mexican Academy of Sciences since 2004.
IP