Front Cover
Title Page
Copyright
Quotes on Ethics
About the Authors
Brief Contents
CONTENTS
Preface
Chapter 1: Introduction and Basic Concepts
1–1 Thermodynamics and Energy
Application Areas of Thermodynamics
1–2 Importance of Dimensions and Units
Some SI and English Units
Dimensional Homogeneity
Unity Conversion Ratios
1–3 Systems and Control Volumes
1–4 Properties of a System
Continuum
1–5 Density and Specific Gravity
1–6 State and Equilibrium
The State Postulate
1–7 Processes and Cycles
The Steady-Flow Process
1–8 Temperature and the Zeroth Law of Thermodynamics
Temperature Scales
The International Temperature Scale of 1990 (ITS-90)
1–9 Pressure
Variation of Pressure with Depth
1–10 Pressure Measurement Devices
The Barometer
The Manometer
Other Pressure Measurement Devices
1–11 Problem-Solving Technique
Step 1: Problem Statement
Step 2: Schematic
Step 3: Assumptions and Approximations
Step 4: Physical Laws
Step 5: Properties
Step 6: Calculations
Step 7: Reasoning, Verification, and Discussion
Engineering Software Packages
Engineering Equation Solver (EES)
A Remark on Significant Digits
Summary
References and Suggested Readings
Problems
Chapter 2: Energy, Energy Transfer, and General Energy Analysis
2–1 Introduction
2–2 Forms of Energy
Some Physical Insight to Internal Energy
More on Nuclear Energy
Mechanical Energy
2–3 Energy Transfer by Heat
Historical Background on Heat
2–4 Energy Transfer by Work
Electrical Work
2–5 Mechanical Forms of Work
Shaft Work
Spring Work
Work Done on Elastic Solid Bars
Work Associated with the Stretching of a Liquid Film
Work Done to Raise or to Accelerate a Body
Nonmechanical Forms of Work
2–6 The First Law of Thermodynamics
Energy Balance
Energy Change of a System, ΔEsystem
Mechanisms of Energy Transfer, Ein and Eout
2–7 Energy Conversion Efficiencies
Efficiencies of Mechanical and Electrical Devices
2–8 Energy and Environment
Ozone and Smog
Acid Rain
The Greenhouse Effect: Global Warming and Climate Change
Topic of Special Interest: Mechanisms of Heat Transfer
Summary
References and Suggested Readings
Problems
Chapter 3: Properties of Pure Substances
3–1 Pure Substance
3–2 Phases of a Pure Substance
3–3 Phase-Change Processes of Pure Substances
Compressed Liquid and Saturated Liquid
Saturated Vapor and Superheated Vapor
Saturation Temperature and Saturation Pressure
Some Consequences of Tsat and Psat Dependence
3–4 Property Diagrams for Phase-Change Processes
1 The T-v Diagram
2 The P-v Diagram
Extending the Diagrams to Include the Solid Phase
3 The P-T Diagram
The P-v-T Surface
3–5 Property Tables
Enthalpy—A Combination Property
1a Saturated Liquid and Saturated Vapor States
1b Saturated Liquid–Vapor Mixture
2 Superheated Vapor
3 Compressed Liquid
Reference State and Reference Values
3–6 The Ideal-Gas Equation of State
Is Water Vapor an Ideal Gas?
3–7 Compressibility Factor—A Measure of Deviation from Ideal-Gas Behavior
3–8 Other Equations of State
van der Waals Equation of State
Beattie-Bridgeman Equation of State
Benedict-Webb-Rubin Equation of State
Virial Equation of State
Topic of Special Interest: Vapor Pressure and Phase Equilibrium
Summary
References and Suggested Readings
Problems
Chapter 4: Energy Analysis of Closed Systems
4–1 Moving Boundary Work
Polytropic Process
4–2 Energy Balance for Closed Systems
4–3 Specific Heats
4–4 Internal Energy, Enthalpy, and Specific Heats of Ideal Gases
Specific Heat Relations of Ideal Gases
4–5 Internal Energy, Enthalpy, and Specific Heats of Solids and Liquids
Internal Energy Changes
Enthalpy Changes
Topic of Special Interest: Thermodynamic Aspects of Biological Systems
Summary
References and Suggested Readings
Problems
Chapter 5: Mass and Energy Analysis of Control Volumes
5–1 Conservation of Mass
Mass and Volume Flow Rates
Conservation of Mass Principle
Mass Balance for Steady-Flow Processes
Special Case: Incompressible Flow
5–2 Flow Work and the Energy of a Flowing Fluid
Total Energy of a Flowing Fluid
Energy Transport by Mass
5–3 Energy Analysis of Steady-Flow Systems
5–4 Some Steady-Flow Engineering Devices
1 Nozzles and Diffusers
2 Turbines and Compressors
3 Throttling Valves
4a Mixing Chambers
4b Heat Exchangers
5 Pipe and Duct Flow
5–5 Energy Analysis of Unsteady-Flow Processes
Topic of Special Interest: General Energy Equation
Summary
References and Suggested Readings
Problems
Chapter 6: The Second Law of Thermodynamics
6–1 Introduction to the Second Law
6–2 Thermal Energy Reservoirs
6–3 Heat Engines
Thermal Efficiency
Can We Save Qout?
The Second Law of Thermodynamics: Kelvin–Planck Statement
6–4 Refrigerators and Heat Pumps
Coefficient of Performance
Heat Pumps
Performance of Refrigerators, Air-Conditioners, and Heat Pumps
The Second Law of Thermodynamics: Clausius Statement
Equivalence of the Two Statements
6–5 Perpetual-Motion Machines
6–6 Reversible and Irreversible Processes
Irreversibilities
Internally and Externally Reversible Processes
6–7 The Carnot Cycle
The Reversed Carnot Cycle
6–8 The Carnot Principles
6–9 The Thermodynamic Temperature Scale
6–10 The Carnot Heat Engine
The Quality of Energy
Quantity versus Quality in Daily Life
6–11 The Carnot Refrigerator and Heat Pump
Topic of Special Interest: Household Refrigerators
Summary
References and Suggested Readings
Problems
Chapter 7: Entropy
7–1 Entropy
A Special Case: Internally Reversible Isothermal Heat Transfer Processes
7–2 The Increase of Entropy Principle
Some Remarks about Entropy
7–3 Entropy Change of Pure Substances
7–4 Isentropic Processes
7–5 Property Diagrams Involving Entropy
7–6 What Is Entropy?
Entropy and Entropy Generation in Daily Life
7–7 The T ds Relations
7–8 Entropy Change of Liquids and Solids
7–9 The Entropy Change of Ideal Gases
Constant Specific Heats (Approximate Analysis)
Variable Specific Heats (Exact Analysis)
Isentropic Processes of Ideal Gases
Constant Specific Heats (Approximate Analysis)
Variable Specific Heats (Exact Analysis)
Relative Pressure and Relative Specific Volume
7–10 Reversible Steady-Flow Work
Proof that Steady-Flow Devices Deliver the Most and Consume the Least Work When the Process is Reversible
7–11 Minimizing the Compressor Work
Multistage Compression with Intercooling
7–12 Isentropic Efficiencies of Steady-Flow Devices
Isentropic Efficiency of Turbines
Isentropic Efficiencies of Compressors and Pumps
Isentropic Efficiency of Nozzles
7–13 Entropy Balance
Entropy Change of a System, ΔSsystem
Mechanisms of Entropy Transfer, Sin and Sout
1 Heat Transfer
2 Mass Flow
Entropy Generation, Sgen
Closed Systems
Control Volumes
Entropy Generation Associated with a Heat Transfer Process
Topic of Special Interest: Reducing the Cost of Compressed Air
Summary
References and Suggested Readings
Problems
Chapter 8: Exergy
8–1 Exergy: Work Potential of Energy
Exergy (Work Potential) Associated with Kinetic and Potential Energy
8–2 Reversible Work and Irreversibility
8–3 Second-Law Efficiency
8–4 Exergy Change of a System
Exergy of a Fixed Mass: Nonflow (or Closed System) Exergy
Exergy of a Flow Stream: Flow (or Stream) Exergy
8–5 Exergy Transfer by Heat, Work, and Mass
Exergy by Heat Transfer, Q
Exergy Transfer by Work, W
Exergy Transfer by Mass, m
8–6 The Decrease of Exergy Principle and Exergy Destruction
Exergy Destruction
8–7 Exergy Balance: Closed Systems
8–8 Exergy Balance: Control Volumes
Exergy Balance for Steady-Flow Systems
Reversible Work
Second-Law Efficiency of Steady-Flow Devices
Topic of Special Interest: Second-Law Aspects of Daily Life
Summary
References and Suggested Readings
Problems
Chapter 9: Gas Power Cycles
9–1 Basic Considerations in the Analysis of Power Cycles
9–2 The Carnot Cycle and its Value in Engineering
9–3 Air-Standard Assumptions
9–4 An Overview of Reciprocating Engines
9–5 Otto Cycle: The Ideal Cycle for Spark-Ignition Engines
9–6 Diesel Cycle: The Ideal Cycle for Compression-Ignition Engines
9–7 Stirling and Ericsson Cycles
9–8 Brayton Cycle: The Ideal Cycle for Gas-Turbine Engines
Development of Gas Turbines
Deviation of Actual Gas-Turbine Cycles from Idealized Ones
9–9 The Brayton Cycle with Regeneration
9–10 The Brayton Cycle with Intercooling, Reheating, and Regeneration
9–11 Ideal Jet-Propulsion Cycles
Modifications to Turbojet Engines
9–12 Second-Law Analysis of Gas Power Cycles
Topic of Special Interest: Saving Fuel and Money by Driving Sensibly
Summary
References and Suggested Readings
Problems
Chapter 10: Vapor and Combined Power Cycles
10–1 The Carnot Vapor Cycle
10–2 Rankine Cycle: The Ideal Cycle for Vapor Power Cycles
Energy Analysis of the Ideal Rankine Cycle
10–3 Deviation of Actual Vapor Power Cycles from Idealized Ones
10–4 How Can We Increase the Efficiency of the Rankine Cycle?
Lowering the Condenser Pressure (Lowers Tlow,avg)
Superheating the Steam to High Temperatures (Increases Thigh,avg)
Increasing the Boiler Pressure (Increases Thigh,avg)
10–5 The Ideal Reheat Rankine Cycle
10–6 The Ideal Regenerative Rankine Cycle
Open Feedwater Heaters
Closed Feedwater Heaters
10–7 Second-Law Analysis of Vapor Power Cycles
10–8 Cogeneration
10–9 Combined Gas–Vapor Power Cycles
Topic of Special Interest: Binary Vapor Cycles
Summary
References and Suggested Readings
Problems
Chapter 11: Refrigeration Cycles
11–1 Refrigerators and Heat Pumps
11–2 The Reversed Carnot Cycle
11–3 The Ideal Vapor-Compression Refrigeration Cycle
11–4 Actual Vapor-Compression Refrigeration Cycle
11–5 Second-Law Analysis of Vapor- Compression Refrigeration Cycle
11–6 Selecting the Right Refrigerant
11–7 Heat Pump Systems
11–8 Innovative Vapor-Compression Refrigeration Systems
Cascade Refrigeration Systems
Multistage Compression Refrigeration Systems
Multipurpose Refrigeration Systems with a Single Compressor
Liquefaction of Gases
11–9 Gas Refrigeration Cycles
11–10 Absorption Refrigeration Systems
Topic of Special Interest: Thermoelectric Power Generation and Refrigeration Systems
Summary
References and Suggested Readings
Problems
Chapter 12: Thermodynamic Property Relations
12–1 A Little Math—Partial Derivatives and Associated Relations
Partial Differentials
Partial Differential Relations
12–2 The Maxwell Relations
12–3 The Clapeyron Equation
12–4 General Relations For du, dh, ds, Cv, and Cp
Internal Energy Changes
Enthalpy Changes
Entropy Changes
Specific Heats Cv and Cp
12–5 The Joule-Thomson Coefficient
12–6 The Δh, Δu, and Δs of Real Gases
Enthalpy Changes of Real Gases
Internal Energy Changes of Real Gases
Entropy Changes of Real Gases
Summary
References and Suggested Readings
Problems
Chapter 13: Gas Mixtures
13–1 Composition of a Gas Mixture: Mass and Mole Fractions
13–2 P-v-T Behavior of Gas Mixtures: Ideal and Real Gases
Ideal-Gas Mixtures
Real-Gas Mixtures
13–3 Properties of Gas Mixtures: Ideal and Real Gases
Ideal-Gas Mixtures
Real-Gas Mixtures
Topic of Special Interest: Chemical Potential and the Separation Work of Mixtures
Summary
References and Suggested Readings
Problems
Chapter 14: Gas–Vapor Mixtures and Air-conditioning
14–1 Dry and Atmospheric Air
14–2 Specific and Relative Humidity of Air
14–3 Dew-Point Temperature
14–4 Adiabatic Saturation and Wet-Bulb Temperatures
14–5 The Psychrometric Chart
14–6 Human Comfort and Air-Conditioning
14–7 Air-Conditioning Processes
Simple Heating and Cooling (ω = constant)
Heating with Humidification
Cooling with Dehumidification
Evaporative Cooling
Adiabatic Mixing of Airstreams
Wet Cooling Towers
Summary
References and Suggested Readings
Problems
Chapter 15: Chemical Reactions
15–1 Fuels and Combustion
15–2 Theoretical and Actual Combustion Processes
15–3 Enthalpy of Formation and Enthalpy of Combustion
15–4 First-Law Analysis of Reacting Systems
Steady-Flow Systems
Closed Systems
15–5 Adiabatic Flame Temperature
15–6 Entropy Change of Reacting Systems
15–7 Second-Law Analysis of Reacting Systems
Topic of Special Interest: Fuel Cells
Summary
References and Suggested Readings
Problems
Chapter 16: Chemical and Phase Equilibrium
16–1 Criterion for Chemical Equilibrium
16–2 The Equilibrium Constant for Ideal-Gas Mixtures
16–3 Some Remarks about the Kp of Ideal-Gas Mixtures
16–4 Chemical Equilibrium for Simultaneous Reactions
16–5 Variation of Kp with Temperature
16–6 Phase Equilibrium
Phase Equilibrium for a Single-Component System
The Phase Rule
Phase Equilibrium for a Multicomponent System
Summary
References and Suggested Readings
Problems
Chapter 17: Compressible Flow
17–1 Stagnation Properties
17–2 Speed of Sound and Mach Number
17–3 One-Dimensional Isentropic Flow
Variation of Fluid Velocity with Flow Area
Property Relations for Isentropic Flow of Ideal Gases
17–4 Isentropic Flow Through Nozzles
Converging Nozzles
Converging–Diverging Nozzles
17–5 Shock Waves and Expansion Waves
Normal Shocks
Oblique Shocks
Prandtl–Meyer Expansion Waves
17–6 Duct Flow with Heat Transfer and Negligible Friction (Rayleigh Flow)
Property Relations for Rayleigh Flow
Choked Rayleigh Flow
17–7 Steam Nozzles
Summary
References and Suggested Readings
Problems
Appendix 1: Property Tables and Charts (SI Units)
Table A–1 Molar mass, gas constant, and critical-point properties
Table A–2 Ideal-gas specific heats of various common gases
Table A–3 Properties of common liquids, solids, and foods
Table A–4 Saturated water—Temperature table
Table A–5 Saturated water—Pressure table
Table A–6 Superheated water
Table A–7 Compressed liquid water
Table A–8 Saturated ice–water vapor
Figure A–9 T-s diagram for water
Figure A–10 Mollier diagram for water
Table A–11 Saturated refrigerant-134a—Temperature table
Table A–12 Saturated refrigerant-134a—Pressure table
Table A–13 Superheated refrigerant-134a
Figure A–14 P-h diagram for refrigerant-134a
Figure A–15 Nelson–Obert generalized compressibility chart
Table A–16 Properties of the atmosphere at high altitude
Table A–17 Ideal-gas properties of air
Table A–18 Ideal-gas properties of nitrogen, N₂
Table A–19 Ideal-gas properties of oxygen, O₂
Table A–20 Ideal-gas properties of carbon dioxide, CO₂
Table A–21 Ideal-gas properties of carbon monoxide, CO
Table A–22 Ideal-gas properties of hydrogen, H₂
Table A–23 Ideal-gas properties of water vapor, H₂O
Table A–24 Ideal-gas properties of monatomic oxygen, O
Table A–25 Ideal-gas properties of hydroxyl, OH
Table A–26 Enthalpy of formation, Gibbs function of formation, and absolute entropy at 258°C, 1 atm
Table A–27 Properties of some common fuels and hydrocarbons
Table A–28 Natural logarithms of the equilibrium constant Kp
Figure A–29 Generalized enthalpy departure chart
Figure A–30 Generalized entropy departure chart
Figure A–31 Psychrometric chart at 1 atm total pressure
Table A–32 One-dimensional isentropic compressible-flow functions for an ideal gas with k = 1.4
Table A–33 One-dimensional normal-shock functions for an ideal gas with k = 1.4
Table A–34 Rayleigh flow functions for an ideal gas with k = 1.4
Appendix 2: Property Tables and Charts (English Units)
Table A–1E Molar mass, gas constant, and critical-point properties
Table A–2E Ideal-gas specific heats of various common gases
Table A–3E Properties of common liquids, solids, and foods
Table A–4E Saturated water—Temperature table
Table A–5E Saturated water—Pressure table
Table A–6E Superheated water
Table A–7E Compressed liquid water
Table A–8E Saturated ice–water vapor
Figure A–9E T-s diagram for water
Figure A–10E Mollier diagram for water
Table A–11E Saturated refrigerant-134a—Temperature table
Table A–12E Saturated refrigerant-134a—Pressure table
Table A–13E Superheated refrigerant-134a
Figure A–14E P-h diagram for refrigerant-134a
Table A–16E Properties of the atmosphere at high altitude
Table A–17E Ideal-gas properties of air
Table A–18E Ideal-gas properties of nitrogen, N₂
Table A–19E Ideal-gas properties of oxygen, O₂
Table A–20E Ideal-gas properties of carbon dioxide, CO₂
Table A–21E Ideal-gas properties of carbon monoxide, CO
Table A–22E Ideal-gas properties of hydrogen, H₂
Table A–23E Ideal-gas properties of water vapor, H₂O
Table A–26E Enthalpy of formation, Gibbs function of formation, and absolute entropy at 778°C, 1 atm
Table A–27E Properties of some common fuels and hydrocarbons
Figure A–31E Psychrometric chart at 1 atm total pressure
INDEX
A
B
C
D
E
F
G
H
I
J
K
L
M
N
O
P
Q
R
S
T
U
V
W
Z