This is completed downloadable of Solution Manual for Fundamentals of Thermal Fluid Sciences 4th Edition by Cengel
Product Details:
- ISBN-10 : 9352601998
- ISBN-13 : 978-9352601998
- Author: CENGEL
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Table of Content:
- CHAPTER ONE INTRODUCTION AND OVERVIEW
- 1–1 Introduction to Thermal-Fluid Sciences
- 1–2 Thermodynamics
- 1–3 Heat Transfer
- 1–4 Fluid Mechanics
- 1–5 Importance of Dimensions and Units
- 1–6 Problem-Solving Technique
- Summary
- References and Suggested Readings
- Problems
- PART 1 THERMODYNAMICS
- CHAPTER TWO BASIC CONCEPTS OF THERMODYNAMICS
- 2–1 Systems and Control Volumes
- 2–2 Properties of a System
- 2–3 Density and Specific Gravity
- 2–4 State and Equilibrium
- 2–5 Processes and Cycles
- 2–6 Temperature and the Zeroth Law of Thermodynamics
- 2–7 Pressure
- 2–8 The Manometer
- 2–9 The Barometer and Atmospheric Pressure
- Summary
- References and Suggested Readings
- Problems
- CHAPTER THREE ENERGY, ENERGY TRANSFER, AND GENERAL ENERGY ANALYSIS
- 3–1 Introduction
- 3–2 Forms of Energy
- 3–3 Energy Transfer by Heat
- 3–4 Energy Transfer by Work
- 3–5 Mechanical Forms of Work
- 3–6 The First Law of Thermodynamics
- 3–7 Energy Conversion Efficiencies
- Summary
- References and Suggested Readings
- Problems
- CHAPTER FOUR PROPERTIES OF PURE SUBSTANCES
- 4–1 Pure Substance
- 4–2 Phases of a Pure Substance
- 4–3 Phase-Change Processes of Pure Substances
- 4–4 Property Diagrams for Phase-Change Processes
- 4–5 Property Tables
- 4–6 The Ideal-Gas Equation of State
- 4–7 Compressibility Factor—A Measure of Deviation from Ideal-Gas Behavior
- Summary
- References and Suggested Readings
- Problems
- CHAPTER FIVE ENERGY ANALYSIS OF CLOSED SYSTEMS
- 5–1 Moving Boundary Work
- 5–2 Energy Balance for Closed Systems
- 5–3 Specific Heats
- 5–4 Internal Energy, Enthalpy, and Specific Heats of Ideal Gases
- 5–5 Internal Energy, Enthalpy, and Specific Heats of Solids and Liquids
- Summary
- References and Suggested Readings
- Problems
- CHAPTER SIX MASS AND ENERGY ANALYSIS OF CONTROL VOLUMES
- 6–1 Conservation of Mass
- 6–2 Flow Work and the Energy of a Flowing Fluid
- 6–3 Energy Analysis of Steady-Flow Systems
- 6–4 Some Steady-Flow Engineering Devices
- 6–5 Energy Analysis of Unsteady-Flow Processes
- Summary
- References and Suggested Readings
- Problems
- CHAPTER SEVEN THE SECOND LAW OF THERMODYNAMICS
- 7–1 Introduction to the Second Law
- 7–2 Thermal Energy Reservoirs
- 7–3 Heat Engines
- 7–4 Refrigerators and Heat Pumps
- 7–5 Reversible and Irreversible Processes
- 7–6 The Carnot Cycle
- 7–7 The Carnot Principles
- 7–8 The Thermodynamic Temperature Scale
- 7–9 The Carnot Heat Engine
- 7–10 The Carnot Refrigerator and Heat Pump
- Summary
- References and Suggested Readings
- Problems
- CHAPTER EIGHT ENTROPY
- 8–1 Entropy
- 8–2 The Increase of Entropy Principle
- 8–3 Entropy Change of Pure Substances
- 8–4 Isentropic Processes
- 8–5 Property Diagrams Involving Entropy
- 8–6 What is Entropy?
- 8–7 The T ds Relations
- 8–8 Entropy Change of Liquids and Solids
- 8–9 The Entropy Change of Ideal Gases
- 8–10 Reversible Steady-Flow Work
- 8–11 Isentropic Efficiencies of Steady-Flow Devices
- 8–12 Entropy Balance
- Summary
- References and Suggested Readings
- Problems
- CHAPTER NINE POWER AND REFRIGERATION 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 Brayton Cycle: The Ideal Cycle for Gas-Turbine Engines
- 9–8 The Brayton Cycle with Regeneration
- 9–9 The Carnot Vapor Cycle
- 9–10 Rankine Cycle: The Ideal Cycle for Vapor Power Cycles
- 9–11 Deviation of Actual Vapor Power Cycles from Idealized Ones
- 9–12 How Can We Increase the Efficiency of the Rankine Cycle?
- 9–13 The Ideal Reheat Rankine Cycle
- 9–14 Refrigerators and Heat Pumps
- 9–15 The Reversed Carnot Cycle
- 9–16 The Ideal Vapor-Compression Refrigeration Cycle
- 9–17 Actual Vapor-Compression Refrigeration Cycle
- Summary
- References and Suggested Readings
- Problems
- PART 2 FLUID MECHANICS
- CHAPTER TEN INTRODUCTION AND PROPERTIES OF FLUIDS
- 10–1 The No-Slip Condition
- 10–2 Classification of Fluid Flows
- 10–3 Vapor Pressure and Cavitation
- 10–4 Viscosity
- 10–5 Surface Tension and Capillary Effect
- Summary
- References and Suggested Readings
- Problems
- CHAPTER ELEVEN FLUID STATICS
- 11–1 Introduction to Fluid Statics
- 11–2 Hydrostatic Forces on Submerged Plane Surfaces
- 11–3 Hydrostatic Forces on Submerged Curved Surfaces
- 11–4 Buoyancy and Stability
- Summary
- References and Suggested Readings
- Problems
- CHAPTER TWELVE BERNOULLI AND ENERGY EQUATIONS
- 12–1 The Bernoulli Equation
- 12–2 General Energy Equation
- 12–3 Energy Analysis of Steady Flows
- Summary
- References and Suggested Readings
- Problems
- CHAPTER THIRTEEN MOMENTUM ANALYSIS OF FLOW SYSTEMS
- 13–1 Newton’s Laws
- 13–2 Choosing a Control Volume
- 13–3 Forces Acting on a Control Volume
- 13–4 The Reynolds Transport Theorem
- 13–5 The Linear Momentum Equation
- Summary
- References and Suggested Readings
- Problems
- CHAPTER FOURTEEN INTERNAL FLOW
- 14–1 Introduction
- 14–2 Laminar and Turbulent Flows
- 14–3 The Entrance Region
- 14–4 Laminar Flow in Pipes
- 14–5 Turbulent Flow in Pipes
- 14–6 Minor Losses
- 14–7 Piping Networks and Pump Selection
- Summary
- References and Suggested Readings
- Problems
- CHAPTER FIFTEEN EXTERNAL FLOW: DRAG AND LIFT
- 15–1 Introduction
- 15–2 Drag and Lift
- 15–3 Friction and Pressure Drag
- 15–4 Drag Coefficients of Common Geometries
- 15–5 Parallel Flow over Flat Plates
- 15–6 Flow over Cylinders and Spheres
- 15–7 Lift
- Summary
- References and Suggested Readings
- Problems
- PART 3 HEAT TRANSFER
- CHAPTER SIXTEEN MECHANISMS OF HEAT TRANSFER
- 16–1 Introduction
- 16–2 Conduction
- 16–3 Convection
- 16–4 Radiation
- 16–5 Simultaneous Heat Transfer Mechanisms
- Summary
- References and Suggested Readings
- Problems
- CHAPTER SEVENTEEN STEADY HEAT CONDUCTION
- 17–1 Steady Heat Conduction in Plane Walls
- 17–2 Thermal Contact Resistance
- 17–3 Generalized Thermal Resistance Networks
- 17–4 Heat Conduction in Cylinders and Spheres
- 17–5 Critical Radius of Insulation
- 17–6 Heat Transfer from Finned Surfaces
- Summary
- References and Suggested Readings
- Problems
- CHAPTER EIGHTEEN TRANSIENT HEAT CONDUCTION
- 18–1 Lumped System Analysis
- 18–2 Transient Heat Conduction in Large Plane Walls, Long Cylinders, and Spheres with Spatial Effe
- 18–3 Transient Heat Conduction in Semi-Infinite Solids
- 18–4 Transient Heat Conduction in Multidimensional Systems
- Summary
- References and Suggested Readings
- Problems
- CHAPTER NINETEEN FORCED CONVECTION
- 19–1 Physical Mechanism of Convection
- 19–2 Thermal Boundary Layer
- 19–3 Parallel Flow over Flat Plates
- 19–4 Flow across Cylinders and Spheres
- 19–5 General Considerations for Pipe Flow
- 19–6 General Thermal Analysis
- 19–7 Laminar Flow in Tubes
- 19–8 Turbulent Flow in Tubes
- Summary
- References and Suggested Readings
- Problems
- CHAPTER TWENTY NATURAL CONVECTION
- 20–1 Physical Mechanism of Natural Convection
- 20–2 Equation of Motion and the Grashof Number
- 20–3 Natural Convection over Surfaces
- 20–4 Natural Convection Inside Enclosures
- Summary
- References and Suggested Readings
- Problems
- CHAPTER TWENTY-ONE RADIATION HEAT TRANSFER
- 21–1 Introduction
- 21–2 Thermal Radiation
- 21–3 Blackbody Radiation
- 21–4 Radiative Properties
- 21–5 The View Factor
- 21–6 Radiation Heat Transfer: Black Surfaces
- 21–7 Radiation Heat Transfer: Diffuse, Gray Surfaces
- Summary
- References and Suggested Readings
- Problems
- CHAPTER TWENTY-TWO HEAT EXCHANGERS
- 22–1 Types of Heat Exchangers
- 22–2 The Overall Heat Transfer Coefficient
- 22–3 Analysis of Heat Exchangers
- 22–4 The Log Mean Temperature Difference Method
- 22–5 The Effectiveness–NTU Method
- Summary
- References and Suggested Readings
- Problems
- APPENDIX PROPERTY TABLES AND CHARTS
- 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–9T-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–14P-h diagram for refrigerant-134a
- Table A–15 Properties of saturated water
- Table A–16 Properties of saturated refrigerant-134a
- Table A–17 Properties of saturated ammonia
- Table A–18 Properties of saturated propane
- Table A–19 Properties of liquids
- Table A–20 Properties of liquid metals
- Table A–21 Ideal-gas properties of air
- Table A–22 Properties of air at 1 atm pressure
- Table A–23 Properties of gases at 1 atm pressure
- Table A–24 Properties of solid metals
- Table A–25 Properties of solid nonmetals
- Table A–26 Emissivities of surfaces
- Figure A–27 The Moody chart
- Figure A–28 Nelson–Obert generalized compressibility chart
- Index
- Nomenclature
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