Thermofluids
From Nature to Engineering
- 1st Edition - April 11, 2022
- Author: David Ting
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 0 6 2 6 - 5
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 1 4 5 5 - 0
Thermofluids: From Nature to Engineering presents the fundamentals of thermofluids in an accessible and student-friendly way. Author David Ting applies his 23 years of teaching… Read more
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Request a sales quoteThermofluids: From Nature to Engineering presents the fundamentals of thermofluids in an accessible and student-friendly way. Author David Ting applies his 23 years of teaching to this practical reference which works to clarify phenomena, concepts and processes via nature-inspired examples, giving the readers a well-rounded understanding of the topic. It introduces the fundamentals of thermodynamics, heat transfer and fluid mechanics which underpin most engineering systems, providing the reader with a solid basis to transfer and apply to other engineering disciplines.
With a strong focus on ecology and sustainability, this book will benefit students in various engineering disciplines including thermal energy, mechanical and chemical, and will also appeal to those coming to the topic from another discipline.
- Presents abstract and complex concepts in a tangible, accessible way
- Promotes the future of thermofluid systems with a focus on sustainability
- Guides the reader through the fundamentals of thermofluids which is essential for further study.
Undergraduate and graduate engineering students, particularly those in energy, mechanical and chemical engineering. Graduates and early career researchers/engineers from adjacent fields
- Cover Image
- Title Page
- Copyright
- Dedication
- Table of Contents
- Textbook Cover Photo
- List of figures
- List of tables
- Preface
- Acknowledgments
- Part 1 Introduction
- Chapter 1 Thermofluids
- Chapter Objectives
- Nomenclature
- Greek and other symbols
- 1.1 What is Thermofluids?
- 1.2 Thermodynamics, fluid mechanics, and heat transfer
- 1.3 Dimensions and units
- 1.4 Organization of the book
- Problems
- References
- Chapter 2 Energy and thermodynamics
- Chapter Objecives
- Nomenclature
- 2.1 The study of energy
- 2.2 The conservation of energy
- 2.3 The quality of energy
- 2.4 Thermodynamic systems
- 2.5 Thermodynamic state, equilibrium, and properties
- Problems
- References
- Chapter 3 Moving fluids
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 3.1 What is a fluid?
- 3.2 The continuum fluid
- 3.3 Nature thrives in moving fluids
- 3.4 What is viscosity?
- 3.5 Newtonian fluids
- 3.6 A classification of fluid motions
- 3.7 Fluid mechanics textbooks
- Problems
- References
- Chapter 4 The transfer of thermal energy
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 4.1 What is thermal energy?
- 4.2 Specific heats
- 4.3 Heat transfer versus thermodynamics
- 4.4 The three heat transfer mechanisms
- Problems
- References
- Part 2 An Ecological View on Engineering Thermodynamics
- Chapter 5 The four laws of ecology
- Chapter Objecives
- Nomenclature
- 5.1 What is ecology?
- 5.2 The four laws of ecology
- 5.3 Animal thermoregulation
- 5.4 Learning from intelligent designs
- Problems
- References
- Chapter 6 The first law of thermodynamics
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 6.1 Energy
- 6.2 Thermodynamic systems
- 6.3 Heat and work transfer
- 6.4 Conservation of energy
- 6.5 Moving boundary work
- 6.6 Enthalpy
- 6.7 Thermodynamic cycle
- Problems
- References
- Chapter 7 The second law of thermodynamics
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 7.1 Introduction
- 7.2 One-way energy flow
- 7.3 Entropy
- 7.4 Heat source and sink
- 7.5 Heat engine
- 7.6 Reverse heat engines
- Problems
- References
- Part 3 Environmental and Engineering Fluid Mechanics
- Chapter 8 Fluid statics
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 8.1 What is pressure?
- 8.2 Fluid statics
- 8.3 Hydrostatic pressure
- 8.4 Measuring pressure
- 8.5 Hydrostatic force on a surface
- 8.6 Buoyancy
- Problems
- References
- Chapter 9 Bernoulli flow
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 9.1 Streamline, streakline, and pathline
- 9.2 Streamline, streamtube, and Bernoulli's Wig
- 9.3 The Bernoulli equation
- 9.4 Bernoulli's pressures
- 9.5 Flow rate measurements
- 9.6 Energy line and hydraulic grade line
- Problems
- References
- Chapter 10 Dimensional analysis
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 10.1 Dimensional homogeneity
- 10.2 Scaling and dimensional analysis
- 10.3 Buckingham Pi theorem
- 10.4 Prevailing nondimensional parameters in fluid mechanics
- 10.5 Some remarks on dimensional analysis
- Problems
- References
- Chapter 11 Internal flow
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 11.1 Flow in a channel
- 11.2 The Reynolds number and the type of pipe flow
- 11.3 Developing pipe flow
- 11.4 Fully developed horizontal pipe flow
- 11.5 Fully developed inclined pipe flow
- 11.6 Energy conservation and head loss in pipe flow
- 11.7 Major and minor losses in pipe flow
- Problems
- References
- Chapter 12 External flow
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 12.1 Everyday external flow
- 12.2 Lift and drag
- 12.3 Boundary layer
- 12.4 Flat plate boundary layer development
- 12.5 Bluff body aerodynamics
- Problems
- References
- Part 4 Ecophysiology-flavored Engineering Heat Transfer
- Chapter 13 Steady conduction of thermal energy
- Chapter Objecives
- Nomenclature
- 13.1 Fourier's law of heat conduction
- 13.2 From electric resistance to thermal resistance
- 13.3 One-dimensional heat conduction in cylindrical coordinates
- 13.4 Heat conduction radially through a sphere
- 13.5 Steady conduction through multilayered walls
- 13.6 Multilayered inhomogeneous walls
- Problems
- References
- Chapter 14 Transient conduction of thermal energy
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 14.1 A lumped system with homogeneous temperature
- 14.2 Biot number
- 14.3 One-dimensional transient problems
- 14.4 Semi-infinite solid
- Problems
- References
- Chapter 15 Natural convection
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 15.1 Natural convection and thermals
- 15.2 Thermal expansion and buoyancy force
- 15.3 Nondimensional parameters in natural convection
- 15.4 The classical Rayleigh–Bernard convection
- 15.5 Continuous thermal plumes and buoyant jets
- 15.6 Free convection along a vertical plate
- 15.7 Other free convection cases
- Problems
- References
- Chapter 16 Forced convection
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 16.1 What is the force behind forced convection?
- 16.2 The convection heat transfer coefficient
- 16.3 Forcing heat to convect from a flat surface
- 16.4 Primary parameters in forced convection
- 16.5 Nusselt number, Reynolds number, and Prandtl number
- 16.6 Nu–Re–Pr relationships
- 16.7 Relating heat convection with flow shear at the wall
- 16.8 Forced convection around a circular cylinder
- 16.9 Other nondimensional parameters of forced convection
- 16.10 Internal forced convection
- Problems
- References
- Chapter 17 Thermal radiation
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 17.1 The radiating Sun
- 17.2 All bodies above absolute zero radiate heat
- 17.3 Absorptivity, transmissivity, and reflectivity
- 17.4 View or shape factors
- 17.5 Further reading on thermal radiation
- Problems
- References
- Chapter 18 Heat exchangers
- Chapter Objecives
- Nomenclature
- Greek and other symbols
- 18.1 Nature thrives by exploiting effective heat exchangers
- 18.2 Counter-flow, parallel-flow, and crossflow heat exchangers
- 18.3 Moving along a constant-temperature passage
- 18.4 Heat exchange between a hot stream and a cold stream
- 18.5 Log mean temperature difference
- 18.6 Heat exchanger effectiveness and number of transfer units
- Problems
- References
- Index
- No. of pages: 434
- Language: English
- Edition: 1
- Published: April 11, 2022
- Imprint: Academic Press
- Paperback ISBN: 9780323906265
- eBook ISBN: 9780323914550
DT
David Ting
Dr. Ting has tangled with engineering flow turbulence for 25 years, starting with turbulent flame propagation in his graduate years, followed by grid turbulence, turbulent heat convection, turbulent flow induced vibrations, and turbulence and wind energy. He has taught a graduate course on turbulent flow seven times. He has also co-authored over 55 papers on turbulence and since 2012 has been on the editorial board for the Elsevier journal, Sustainable Energy Technologies and Assessments.
Affiliations and expertise
Professor, Department of Mechanical, Automotive & Materials Engineering, University of Windsor, Windsor, ON, CanadaRead Thermofluids on ScienceDirect