Description

Book Synopsis


Table of Contents

1 Fundamental Concepts

1-1. Introduction

1-2. Characteristics of Matter

1-3. The International System of Units

1-4. Calculations

1-5. Problem Solving

1-6. Basic Fluid Properties

1-7. Viscosity

1-8. Viscosity Measurement

1-9. Vapor Pressure

1-10. Surface Tension and Capillarity

2 Fluid Statics

2-1. Pressure

2-2. Absolute and Gage Pressure

2-3. Static Pressure Variation

2-4. Pressure Variation for Incompressible

2-5. Pressure Variation for Compressible Fluids

2-6. Measurement of Static Pressure

2-7. Hydrostatic Forces on Plane Surfaces

2-8. Hydrostatic Forces on an Incline Plane or Curved Surface Determined by Projection

2-9. Buoyancy

2-10. Stability

2-11. Constant Accelerated Translation of a Liquid

2-12. Steady Rotation of a Liquid

3 Kinematics of Fluid Motion

3-1. Types of Flow Description

3-2. Types of Fluid Flow

3-3. Graphical Descriptions of Fluid Flow

3-4. Fluid Acceleration

3-5. Streamline Coordinates

3-6. The Reynolds Transport Theorem

4 Conservation of Mass

4-1. Rate of Flow and Average Velocity

4-2. Continuity Equation

5 Energy of Moving Fluids

5-1. Euler’s Equations of Motion

5-2. The Bernoulli Equation

5-3. Applications of Bernoulli’s Equation

5-4. Energy and the Hydraulic Gradient

5-5. The Energy Equation

6 Fluid Momentum

6-1. The Linear Momentum Equation

6-2. The Angular Momentum Equation

6-3. Propellers

6-4. Applications for Control Volumes Having Rectilinear Accelerated Motion

6-5. Turbojets

6-6. Rockets

7 Differential Fluid Flow

7-1. Differential Analysis

7-2. Kinematics of Differential Fluid Elements

7-3. Circulation and Vorticity

7-4. Conservation of Mass

7-5. Equations of Motion of a Fluid Particle

7-6. The Euler and Bernoulli Equations

7-7. The Stream Function

7-8. The Potential Function

7-9. Basic Two-Dimensional Flows

7-10. Superposition of Flows

7-11. The Navier-Stokes Equations

7-12. Computational Fluid Dynamics

8 Dimensional Analysis and Similitude

8-1. Dimensional Analysis

8-2. Important Dimensionless Numbers

8-3. The Buckingham Pi Theorem

8-4. Similitude

9 Viscous Flow Within Enclosed Surfaces

9-1. Steady Laminar Flow between Parallel Plates

9-2. Navier-Stokes Solution for Steady Laminar Flow Between Parallel Plates

9-3. Steady Laminar Flow Within A Smooth Pipe

9-3. Laminar and Turbulent Shear Stress Within a Smooth Pipe

9-4. Navier-Stokes Solution for Steady Laminar Flow Within a Smooth Pipe

9-5. The Reynolds Number

9-6. Laminar and Turbulent Shear Stress Within a Smooth Pipe

9-7. Fully Developed Flow From an Entrance

9-8. Turbulent Flow Within a Smooth Pipe

10 Analysis and Design for Pipe Flow

10-1. Resistance to Flow in Rough Pipes

10-2. Losses Occurring From Pipe Fittings And Transitions

10-3. Single Pipeline Flow

10-4. Pipe Systems

10-5. Flow Measurement

11 Viscous Flow Over External Surfaces

11-1. The Concept of the Boundary Layer

11-2. Laminar Boundary Layers

11-3. The Momentum Integral Equation

11-4. Turbulent Boundary Layers

11-5. Laminar and Turbulent Boundary Layers

11-6. Drag and Lift

11-7. Pressure Gradient Effects

11-8. The Drag Coefficient

11-9. Methods for Reducing Drag

11-10. Lift and Drag on an Airfoil

12 Turbomachine

Fluid Mechanics in SI Units

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    Description

    Book Synopsis


    Table of Contents

    1 Fundamental Concepts

    1-1. Introduction

    1-2. Characteristics of Matter

    1-3. The International System of Units

    1-4. Calculations

    1-5. Problem Solving

    1-6. Basic Fluid Properties

    1-7. Viscosity

    1-8. Viscosity Measurement

    1-9. Vapor Pressure

    1-10. Surface Tension and Capillarity

    2 Fluid Statics

    2-1. Pressure

    2-2. Absolute and Gage Pressure

    2-3. Static Pressure Variation

    2-4. Pressure Variation for Incompressible

    2-5. Pressure Variation for Compressible Fluids

    2-6. Measurement of Static Pressure

    2-7. Hydrostatic Forces on Plane Surfaces

    2-8. Hydrostatic Forces on an Incline Plane or Curved Surface Determined by Projection

    2-9. Buoyancy

    2-10. Stability

    2-11. Constant Accelerated Translation of a Liquid

    2-12. Steady Rotation of a Liquid

    3 Kinematics of Fluid Motion

    3-1. Types of Flow Description

    3-2. Types of Fluid Flow

    3-3. Graphical Descriptions of Fluid Flow

    3-4. Fluid Acceleration

    3-5. Streamline Coordinates

    3-6. The Reynolds Transport Theorem

    4 Conservation of Mass

    4-1. Rate of Flow and Average Velocity

    4-2. Continuity Equation

    5 Energy of Moving Fluids

    5-1. Euler’s Equations of Motion

    5-2. The Bernoulli Equation

    5-3. Applications of Bernoulli’s Equation

    5-4. Energy and the Hydraulic Gradient

    5-5. The Energy Equation

    6 Fluid Momentum

    6-1. The Linear Momentum Equation

    6-2. The Angular Momentum Equation

    6-3. Propellers

    6-4. Applications for Control Volumes Having Rectilinear Accelerated Motion

    6-5. Turbojets

    6-6. Rockets

    7 Differential Fluid Flow

    7-1. Differential Analysis

    7-2. Kinematics of Differential Fluid Elements

    7-3. Circulation and Vorticity

    7-4. Conservation of Mass

    7-5. Equations of Motion of a Fluid Particle

    7-6. The Euler and Bernoulli Equations

    7-7. The Stream Function

    7-8. The Potential Function

    7-9. Basic Two-Dimensional Flows

    7-10. Superposition of Flows

    7-11. The Navier-Stokes Equations

    7-12. Computational Fluid Dynamics

    8 Dimensional Analysis and Similitude

    8-1. Dimensional Analysis

    8-2. Important Dimensionless Numbers

    8-3. The Buckingham Pi Theorem

    8-4. Similitude

    9 Viscous Flow Within Enclosed Surfaces

    9-1. Steady Laminar Flow between Parallel Plates

    9-2. Navier-Stokes Solution for Steady Laminar Flow Between Parallel Plates

    9-3. Steady Laminar Flow Within A Smooth Pipe

    9-3. Laminar and Turbulent Shear Stress Within a Smooth Pipe

    9-4. Navier-Stokes Solution for Steady Laminar Flow Within a Smooth Pipe

    9-5. The Reynolds Number

    9-6. Laminar and Turbulent Shear Stress Within a Smooth Pipe

    9-7. Fully Developed Flow From an Entrance

    9-8. Turbulent Flow Within a Smooth Pipe

    10 Analysis and Design for Pipe Flow

    10-1. Resistance to Flow in Rough Pipes

    10-2. Losses Occurring From Pipe Fittings And Transitions

    10-3. Single Pipeline Flow

    10-4. Pipe Systems

    10-5. Flow Measurement

    11 Viscous Flow Over External Surfaces

    11-1. The Concept of the Boundary Layer

    11-2. Laminar Boundary Layers

    11-3. The Momentum Integral Equation

    11-4. Turbulent Boundary Layers

    11-5. Laminar and Turbulent Boundary Layers

    11-6. Drag and Lift

    11-7. Pressure Gradient Effects

    11-8. The Drag Coefficient

    11-9. Methods for Reducing Drag

    11-10. Lift and Drag on an Airfoil

    12 Turbomachine

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