Description

Book Synopsis


Table of Contents

1 Introduction

Learning Objectives

1.1 Some Characteristics of Fluids

1.2 Dimensions, Dimensional Homogeneity, and Units

1.2.1 Systems of Units

1.3 Analysis of Fluid Behavior

1.4 Measures of Fluid Mass and Weight

1.4.1 Density

1.4.2 Specific Weight

1.4.3 Specific Gravity

1.5 Ideal Gas Law

1.6 Viscosity

1.7 Compressibility of Fluids

1.7.1 Bulk Modulus

1.7.2 Compression and Expansion of Gases

1.7.3 Speed of Sound

1.8 Vapor Pressure

1.9 Surface Tension

1.10 A Brief Look Back in History

Chapter Summary

Key Equations

References

Questions and Problems

2 Fluid Statics

Learning Objectives

2.1 Pressure at a Point

2.2 Basic Equation for Pressure Field

2.3 Pressure Variation in a Fluid at Rest

2.3.1 Incompressible Fluid

2.3.2 Compressible Fluid

2.4 Standard Atmosphere

2.5 Measurement of Pressure

2.6 Manometry

2.6.1 Piezometer Tube

2.6.2 U-Tube Manometer

2.6.3 Inclined-Tube Manometer

2.7 Mechanical and Electronic Pressure-Measuring Devices

2.8 Hydrostatic Force on a Plane Surface and Pressure Diagram

2.8.1 Hydrostatic Force

2.8.2 Pressure Diagram

2.9 Hydrostatic Force on a Curved Surface

2.10 Buoyancy, Flotation, and Stability

2.10.1 Archimedes’ Principle

2.10.2 The Stability of Bodies in Fluids

2.11 Pressure Variation in a Fluid with Rigid-Body Motion

2.12 Equilibrium of Moving Fluids

(Special Case of Fluid Statics)

Chapter Summary

Key Equations

References

Questions and Problems

3 Fluid Kinematics

Learning Objectives

3.1 The Velocity Field

3.1.1 Eulerian and Lagrangian Flow Descriptions

3.1.2 One-, Two-, and Three- Dimensional Flows

3.1.3 Steady and Unsteady Flows

3.1.4 F low Patterns: Streamlines, Streaklines, and Pathlines

3.2 The Acceleration Field

3.2.1 Acceleration and the Material Derivative

3.2.2 Unsteady Effects

3.2.3 Convective Effects

3.2.4 Streamline Coordinates

3.3 Control Volume and System Representations

3.4 The Reynolds Transport Theorem

3.4.1 Derivation of the Reynolds Transport Theorem

3.4.2 Selection of a Control Volume

Chapter Summary

Key Equations

References

Questions and Problems

4 Elementary Fluid Dynamics—The Bernoulli Equation

Learning Objectives

4.1 Newton’s Second Law

4.2 F = ma along a Streamline

4.3 F = ma Normal to a Streamline

4.4 Physical Interpretations and Alternate Forms of the Bernoulli Equation

4.5 Static, Stagnation, Dynamic, and Total Pressure

4.6 Applications of the Bernoulli Equation

4.6.1 Free Jets

4.6.2 Confined Flows

4.6.3 Flowrate Measurement

4.7 The Energy Line and the Hydraulic Grade Line

4.8 Restrictions on Use of the Bernoulli Equation

Chapter Summary

Key Equations

References

Questions and Problems

5 Finite Control Volume Analysis

Learning Objectives

5.1 Conservation of Mass—The Continuity Equation

5.1.1 Derivation of the Continuity Equation

5.1.2 Fixed, Nondeforming Control Volume

5.1.3 Moving, Nondeforming Control Volume

5.2 Newton’s Second Law—The Linear Momentum and Moment-of-Momentum Equations

5.2.1 Derivation of the Linear Momentum Equation

5.2.2 Application of the Linear Momentum Equation

5.2.3 Derivation of the Moment-of-Momentum Equation

5.2.4 Application of the Moment-of-Momentum Equation

5.3 First Law of Thermodynamics—The Energy Equation

5.3.1 Derivation of the Energy Equation

5.3.2 Application of the Energy Equation

5.3.3 The Mechanical Energy Equation and the Bernoulli Equation

5.3.4 Application of the Energy Equation to Nonuniform Flows

5.3.5 Comparison of Various Forms of the Energy Equation

Chapter Summary

Key Equations

References

Questions and Problems

6 Differential Analysis of Fluid Flow

Learning Objectives

6.1 Fluid Element Kinematics

6.1.1 Velocity and Acceleration Revisited

6.1.2 Linear Motion and Deformation

6.1.3 Angular Motion and Deformation

6.2 Conservation of Mass

6.2.1 Differential Form of Continuity Equation

6.2.2 Cylindrical Polar Coordinates

6.2.3 The Stream Function

6.3 The Linear Momentum Equation

6.3.1 Description of Forces Acting Differential Element

6.3.2 Equations of Motion

6.4 Inviscid Flow

6.4.1 Euler’s Equations of Motion

6.4.2 The Bernoulli Equation

6.4.3 Irrotational Flow

6.4.4 The Bernoulli Equation Irrotational Flow

6.4.5 The Velocity Potential

6.5 Some Basic, Plane Potential Flows

6.5.1 Uniform Flow

6.5.2 Source and Sink

6.5.3 Vortex

6.5.4 Doublet

6.6 Superposition of Basic, Plane

6.6.1 Source in a Uniform Stream—Half Body

6.6.2 Flow Around a Circular Cylinder

6.7 Other Aspects of Potential Flow

6.8 Viscous Flow

6.8.1 Stress–Deformation Relationships

6.8.2 The Navier–Stokes Equations

6.9 Some Simple Solutions for Laminar, Viscous, Incompressible Flows

6.9.1 Steady, Laminar Flow Fixed Parallel Plates

6.9.2 Couette Flow

6.9.3 Steady, Laminar Flow in

6.10 Other Aspects of Differential Analysis

Chapter Summary

Key Equations

References

Questions and Problems

7 Dimensional Analysis, Similitude, and Modeling

Learning Objectives

7.1 The Need for Dimensional Analysis

7.2 Buckingham Pi Theorem

7.3 Determination of Pi Terms

7.4 Some Directions about Dimensional

7.4.1 Selection of Variables

7.4.2 Determination of Reference Dimensions

7.4.3 Uniqueness of Pi Terms

7.5 Determination of Pi Terms by Inspection

7.6 Common Dimensionless Groups in Fluid Mechanics

7.7 Correlation of Experimental Data

7.7.1 Problems with One Pi Term

7.7.2 Problems with Two or More Pi Terms

7.8 Modeling and Similitude

7.8.1 Theory of Models

7.8.2 Model Scales

7.8.3 Practical Aspects of Using Models

7.9 Typical Model Studies

7.9.1 Flow Through Closed Conduits

7.9.2 Flow Around Immersed Bodies

7.9.3 Flow with a Free Surface

Chapter Summary

Key Equations

References

Questions and Problems

8 Viscous Flow in Pipes

Learning Objectives

8.1 General Characteristics of Pipe Flow

8.1.1 Laminar or Turbulent Flow

8.1.2 Entrance Region and Fully Developed Flow

8.2 Fully Developed Laminar Flow

8.2.1 From F = ma Applied Directly to a Fluid Element

8.2.2 From the Navier–Stokes Equations

8.3 Fully Developed Turbulent Flow

8.3.1 T ransition from Laminar to Turbulent Flow

8.3.2 Turbulent Shear Stress

8.3.3 Turbulent Velocity Profile

8.4 Pipe Flow Losses via Dimensional Analysis

8.4.1 Major Losses

8.4.2 Minor Losses

8.4.3 Noncircular Conduits

8.5 Pipe Flow Examples

8.5.1 Single Pipes

8.5.2 Multiple Pipe Systems

8.6 Pipe Flowrate Measurement

Chapter Summary

Key Equations

References

Questions and Problems

9 Flow over Immersed Bodies

Learning Objectives

9.1 General External Flow Characteristics

9.1.1 Lift and Drag Concepts

9.1.2 Characteristics of Flow Past an Object

9.2 Boundary Layer Characteristics

9.2.1 Boundary Layer Structure and Thickness on a Flat Plate

9.2.2 Prandtl / Blasius Boundary Layer Solution

9.2.3 Momentum Integral Boundary Layer Equation for a Flat Plate

9.2.4 Transition from Laminar to Turbulent Flow

9.2.5 Turbulent Boundary Layer Flow

9.2.6 Effects of Pressure Gradient

9.3 Drag

9.3.1 Friction Drag

9.3.2 Pressure Drag

9.3.3 Drag Coefficient Data and Examples

9.4 Lift

9.4.1 Surface Pressure Distribution

9.4.2 Circulation

Chapter Summary

Key Equations

References

Questions and Problems

10 Open-Channel Flow

Learning Objectives

10.1 General Characteristics of Open-Channel Flow

10.2 Surface Waves

10.2.1 Wave Speed

10.2.2 Froude Number Effects

10.3 Energy Considerations

10.3.1 Energy Balance

10.3.2 Specific Energy

10.4 Uniform Flow

10.4.1 Uniform Flow Approximations

10.4.2 The Chezy and Manning Equations

10.4.3 Uniform Flow Examples

10.5 Most Efficient Channel Section

10.5.1 Trapezoidal Channel Section

10.5.2 Triangular Channel Section

10.6 Gradually Varied Flow

10.7 Rapidly Varied Flow

10.7.1 The Hydraulic Jump

10.7.2 Sharp-Crested Weirs

10.7.3 Broad-Crested Weirs

10.7.4 Underflow (Sluice) Gates

Chapter Summary

Key Equations

References

Questions and Problems

11 Turbomachines

Learning Objectives

11.1 Introduction

11.2 Basic Energy Considerations

11.3 Angular Momentum Considerations

11.4 The Centrifugal Pump

11.4.1 Theoretical Considerations

11.4.2 Pump Performance Characteristics

11.4.3 System Characteristics, Pump-System Matching, and Pump Selection

11.5 Dimensionless Parameters and Similarity Laws

11.5.1 Specific Speed

11.6 Axial-Flow and Mixed-Flow Pumps

11.7 Turbines

11.7.1 Impulse Turbines

11.7.2 Reaction Turbines

11.8 Fans

11.9 Compressible Flow Turbomachines

Chapter Summary

Key Equations

References

Questions and Problems

APPENDIX A Computational Fluid Dynamics

APPENDIX B Physical Properties of Fluids

APPENDIX C Properties of the U.S. Standard Atmosphere

APPENDIX D Comprehensive Table of Conversion Factors

INDEX

Young Munson and Okiishis A Brief Introduction to

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    A Paperback / softback by John I. Hochstein, Andrew L. Gerhart

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      Publisher: John Wiley & Sons Inc
      Publication Date: 24/09/2021
      ISBN13: 9781119702771, 978-1119702771
      ISBN10: 1119702771
      Also in:
      Engineering: Mechanics of fluids

      Description

      Book Synopsis


      Table of Contents

      1 Introduction

      Learning Objectives

      1.1 Some Characteristics of Fluids

      1.2 Dimensions, Dimensional Homogeneity, and Units

      1.2.1 Systems of Units

      1.3 Analysis of Fluid Behavior

      1.4 Measures of Fluid Mass and Weight

      1.4.1 Density

      1.4.2 Specific Weight

      1.4.3 Specific Gravity

      1.5 Ideal Gas Law

      1.6 Viscosity

      1.7 Compressibility of Fluids

      1.7.1 Bulk Modulus

      1.7.2 Compression and Expansion of Gases

      1.7.3 Speed of Sound

      1.8 Vapor Pressure

      1.9 Surface Tension

      1.10 A Brief Look Back in History

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      2 Fluid Statics

      Learning Objectives

      2.1 Pressure at a Point

      2.2 Basic Equation for Pressure Field

      2.3 Pressure Variation in a Fluid at Rest

      2.3.1 Incompressible Fluid

      2.3.2 Compressible Fluid

      2.4 Standard Atmosphere

      2.5 Measurement of Pressure

      2.6 Manometry

      2.6.1 Piezometer Tube

      2.6.2 U-Tube Manometer

      2.6.3 Inclined-Tube Manometer

      2.7 Mechanical and Electronic Pressure-Measuring Devices

      2.8 Hydrostatic Force on a Plane Surface and Pressure Diagram

      2.8.1 Hydrostatic Force

      2.8.2 Pressure Diagram

      2.9 Hydrostatic Force on a Curved Surface

      2.10 Buoyancy, Flotation, and Stability

      2.10.1 Archimedes’ Principle

      2.10.2 The Stability of Bodies in Fluids

      2.11 Pressure Variation in a Fluid with Rigid-Body Motion

      2.12 Equilibrium of Moving Fluids

      (Special Case of Fluid Statics)

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      3 Fluid Kinematics

      Learning Objectives

      3.1 The Velocity Field

      3.1.1 Eulerian and Lagrangian Flow Descriptions

      3.1.2 One-, Two-, and Three- Dimensional Flows

      3.1.3 Steady and Unsteady Flows

      3.1.4 F low Patterns: Streamlines, Streaklines, and Pathlines

      3.2 The Acceleration Field

      3.2.1 Acceleration and the Material Derivative

      3.2.2 Unsteady Effects

      3.2.3 Convective Effects

      3.2.4 Streamline Coordinates

      3.3 Control Volume and System Representations

      3.4 The Reynolds Transport Theorem

      3.4.1 Derivation of the Reynolds Transport Theorem

      3.4.2 Selection of a Control Volume

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      4 Elementary Fluid Dynamics—The Bernoulli Equation

      Learning Objectives

      4.1 Newton’s Second Law

      4.2 F = ma along a Streamline

      4.3 F = ma Normal to a Streamline

      4.4 Physical Interpretations and Alternate Forms of the Bernoulli Equation

      4.5 Static, Stagnation, Dynamic, and Total Pressure

      4.6 Applications of the Bernoulli Equation

      4.6.1 Free Jets

      4.6.2 Confined Flows

      4.6.3 Flowrate Measurement

      4.7 The Energy Line and the Hydraulic Grade Line

      4.8 Restrictions on Use of the Bernoulli Equation

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      5 Finite Control Volume Analysis

      Learning Objectives

      5.1 Conservation of Mass—The Continuity Equation

      5.1.1 Derivation of the Continuity Equation

      5.1.2 Fixed, Nondeforming Control Volume

      5.1.3 Moving, Nondeforming Control Volume

      5.2 Newton’s Second Law—The Linear Momentum and Moment-of-Momentum Equations

      5.2.1 Derivation of the Linear Momentum Equation

      5.2.2 Application of the Linear Momentum Equation

      5.2.3 Derivation of the Moment-of-Momentum Equation

      5.2.4 Application of the Moment-of-Momentum Equation

      5.3 First Law of Thermodynamics—The Energy Equation

      5.3.1 Derivation of the Energy Equation

      5.3.2 Application of the Energy Equation

      5.3.3 The Mechanical Energy Equation and the Bernoulli Equation

      5.3.4 Application of the Energy Equation to Nonuniform Flows

      5.3.5 Comparison of Various Forms of the Energy Equation

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      6 Differential Analysis of Fluid Flow

      Learning Objectives

      6.1 Fluid Element Kinematics

      6.1.1 Velocity and Acceleration Revisited

      6.1.2 Linear Motion and Deformation

      6.1.3 Angular Motion and Deformation

      6.2 Conservation of Mass

      6.2.1 Differential Form of Continuity Equation

      6.2.2 Cylindrical Polar Coordinates

      6.2.3 The Stream Function

      6.3 The Linear Momentum Equation

      6.3.1 Description of Forces Acting Differential Element

      6.3.2 Equations of Motion

      6.4 Inviscid Flow

      6.4.1 Euler’s Equations of Motion

      6.4.2 The Bernoulli Equation

      6.4.3 Irrotational Flow

      6.4.4 The Bernoulli Equation Irrotational Flow

      6.4.5 The Velocity Potential

      6.5 Some Basic, Plane Potential Flows

      6.5.1 Uniform Flow

      6.5.2 Source and Sink

      6.5.3 Vortex

      6.5.4 Doublet

      6.6 Superposition of Basic, Plane

      6.6.1 Source in a Uniform Stream—Half Body

      6.6.2 Flow Around a Circular Cylinder

      6.7 Other Aspects of Potential Flow

      6.8 Viscous Flow

      6.8.1 Stress–Deformation Relationships

      6.8.2 The Navier–Stokes Equations

      6.9 Some Simple Solutions for Laminar, Viscous, Incompressible Flows

      6.9.1 Steady, Laminar Flow Fixed Parallel Plates

      6.9.2 Couette Flow

      6.9.3 Steady, Laminar Flow in

      6.10 Other Aspects of Differential Analysis

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      7 Dimensional Analysis, Similitude, and Modeling

      Learning Objectives

      7.1 The Need for Dimensional Analysis

      7.2 Buckingham Pi Theorem

      7.3 Determination of Pi Terms

      7.4 Some Directions about Dimensional

      7.4.1 Selection of Variables

      7.4.2 Determination of Reference Dimensions

      7.4.3 Uniqueness of Pi Terms

      7.5 Determination of Pi Terms by Inspection

      7.6 Common Dimensionless Groups in Fluid Mechanics

      7.7 Correlation of Experimental Data

      7.7.1 Problems with One Pi Term

      7.7.2 Problems with Two or More Pi Terms

      7.8 Modeling and Similitude

      7.8.1 Theory of Models

      7.8.2 Model Scales

      7.8.3 Practical Aspects of Using Models

      7.9 Typical Model Studies

      7.9.1 Flow Through Closed Conduits

      7.9.2 Flow Around Immersed Bodies

      7.9.3 Flow with a Free Surface

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      8 Viscous Flow in Pipes

      Learning Objectives

      8.1 General Characteristics of Pipe Flow

      8.1.1 Laminar or Turbulent Flow

      8.1.2 Entrance Region and Fully Developed Flow

      8.2 Fully Developed Laminar Flow

      8.2.1 From F = ma Applied Directly to a Fluid Element

      8.2.2 From the Navier–Stokes Equations

      8.3 Fully Developed Turbulent Flow

      8.3.1 T ransition from Laminar to Turbulent Flow

      8.3.2 Turbulent Shear Stress

      8.3.3 Turbulent Velocity Profile

      8.4 Pipe Flow Losses via Dimensional Analysis

      8.4.1 Major Losses

      8.4.2 Minor Losses

      8.4.3 Noncircular Conduits

      8.5 Pipe Flow Examples

      8.5.1 Single Pipes

      8.5.2 Multiple Pipe Systems

      8.6 Pipe Flowrate Measurement

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      9 Flow over Immersed Bodies

      Learning Objectives

      9.1 General External Flow Characteristics

      9.1.1 Lift and Drag Concepts

      9.1.2 Characteristics of Flow Past an Object

      9.2 Boundary Layer Characteristics

      9.2.1 Boundary Layer Structure and Thickness on a Flat Plate

      9.2.2 Prandtl / Blasius Boundary Layer Solution

      9.2.3 Momentum Integral Boundary Layer Equation for a Flat Plate

      9.2.4 Transition from Laminar to Turbulent Flow

      9.2.5 Turbulent Boundary Layer Flow

      9.2.6 Effects of Pressure Gradient

      9.3 Drag

      9.3.1 Friction Drag

      9.3.2 Pressure Drag

      9.3.3 Drag Coefficient Data and Examples

      9.4 Lift

      9.4.1 Surface Pressure Distribution

      9.4.2 Circulation

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      10 Open-Channel Flow

      Learning Objectives

      10.1 General Characteristics of Open-Channel Flow

      10.2 Surface Waves

      10.2.1 Wave Speed

      10.2.2 Froude Number Effects

      10.3 Energy Considerations

      10.3.1 Energy Balance

      10.3.2 Specific Energy

      10.4 Uniform Flow

      10.4.1 Uniform Flow Approximations

      10.4.2 The Chezy and Manning Equations

      10.4.3 Uniform Flow Examples

      10.5 Most Efficient Channel Section

      10.5.1 Trapezoidal Channel Section

      10.5.2 Triangular Channel Section

      10.6 Gradually Varied Flow

      10.7 Rapidly Varied Flow

      10.7.1 The Hydraulic Jump

      10.7.2 Sharp-Crested Weirs

      10.7.3 Broad-Crested Weirs

      10.7.4 Underflow (Sluice) Gates

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      11 Turbomachines

      Learning Objectives

      11.1 Introduction

      11.2 Basic Energy Considerations

      11.3 Angular Momentum Considerations

      11.4 The Centrifugal Pump

      11.4.1 Theoretical Considerations

      11.4.2 Pump Performance Characteristics

      11.4.3 System Characteristics, Pump-System Matching, and Pump Selection

      11.5 Dimensionless Parameters and Similarity Laws

      11.5.1 Specific Speed

      11.6 Axial-Flow and Mixed-Flow Pumps

      11.7 Turbines

      11.7.1 Impulse Turbines

      11.7.2 Reaction Turbines

      11.8 Fans

      11.9 Compressible Flow Turbomachines

      Chapter Summary

      Key Equations

      References

      Questions and Problems

      APPENDIX A Computational Fluid Dynamics

      APPENDIX B Physical Properties of Fluids

      APPENDIX C Properties of the U.S. Standard Atmosphere

      APPENDIX D Comprehensive Table of Conversion Factors

      INDEX

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