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Already one of the leading course texts on aerodynamics in the UK, the sixth edition welcomes a new US-based author team to keep the text current. The sixth edition has been re… Read more
LIMITED OFFER
Immediately download your ebook while waiting for your print delivery. No promo code needed.
Already one of the leading course texts on aerodynamics in the UK, the sixth edition welcomes a new US-based author team to keep the text current. The sixth edition has been revised to include the latest developments in compressible flow, computational fluid dynamics, and contemporary applications. Computational methods have been expanded and updated to reflect the modern approaches to aerodynamic design and research in the aeronautical industry and elsewhere, and new examples of ‘the aerodynamics around you’ have been added to link theory to practical understanding.
Undergraduate and postgraduate students in aeronautical engineering. Growing market for Aeronautical Engineers in both civilian and defense-related areas
Preface
Chapter 1. Basic Concepts and Definitions
1.1 Introduction
1.2 Units and Dimensions
1.3 Relevant Properties
1.4 Aeronautical Definitions
1.5 Dimensional Analysis
1.6 Basic Aerodynamics
1.7 Exercises
Chapter 2. Fundamental Equations of Fluid Mechanics
2.1 Introduction
2.2 One-Dimensional Flow: The Basic Equations
2.3 Measurement of Air Speed
2.4 Two-Dimensional Flow
2.5 Stream Function and Streamline
2.6 Momentum Equation
2.7 Rates of Strain, Rotational Flow, and Vorticity
2.8 Navier-Stokes Equations
2.9 Properties of the Navier-Stokes Equations
2.10 Exact Solutions of the Navier-Stokes Equations
2.11 Prandtl’s Boundary-Layer Equations
2.12 Boundary-Layer Equations
2.13 Exercises
Chapter 3. Potential Flow
3.1 Two-dimensional Flows
3.2 Standard Flows in Terms of ψ and ϕ
3.3 Axisymmetric Flows (Inviscid and Incompressible Flows)
3.4 Computational (Panel) Methods
3.5 Exercises
Chapter 4. Two-Dimensional Wing Theory
4.1 Introduction
4.2 The Development of Airfoil Theory
4.3 General Thin-Airfoil Theory
4.4 Solution to the General Equation
4.5 The Flapped Airfoil
4.6 The Jet Flap
4.7 Normal Force and Pitching Moment Derivatives Due to Pitching
4.8 Particular Camber Lines
4.9 The Thickness Problem for Thin-Airfoil Theory
4.10 Computational (Panel) Methods for Two-Dimensional Lifting Flows
4.11 Exercises
Chapter 5. Wing Theory
5.1 The Vortex System
5.2 Laws of Vortex Motion
5.3 The Wing as a Simplified Horseshoe Vortex
5.4 Vortex Sheets
5.5 Relationship between Spanwise Loading and Trailing Vorticity
5.6 Determination of Load Distribution on a Given Wing
5.7 Swept and Delta Wings
5.8 Computational (Panel) Methods for Wings
5.9 Exercises
Chapter 6. Compressible Flow
6.1 Introduction
6.2 Isentropic One-Dimensional Flow
6.3 One-Dimensional Flow: Weak Waves
6.4 One-Dimensional Flow: Plane Normal Shock Waves
6.5 Mach Waves and Shock Waves in Two-Dimensional Flow
6.6 Mach Waves
6.7 Shock Waves
6.8 Exercises
Chapter 7. Airfoils and Wings in Compressible Flow
7.1 Wings in Compressible Flow
7.2 Exercises
Chapter 8. Viscous Flow and Boundary Layers
8.1 Introduction
8.2 Boundary-Layer Theory
8.3 Boundary-Layer Separation
8.4 Flow Past Cylinders and Spheres
8.5 The Momentum-Integral Equation
8.6 Approximate Methods for a Boundary Layer on a Flat Plate with Zero Pressure Gradient
8.7 Additional Examples of the Momentum-Integral Equation
8.8 Laminar-Turbulent Transition
8.9 The Physics of Turbulent Boundary Layers
8.10 Computational Methods
8.11 Estimation of Profile Drag from the Velocity Profile in a Wake
8.12 Some Boundary-Layer Effects in Supersonic Flow
8.13 Exercises
Chapter 9. Flow Control and Wing Design
9.1 Introduction
9.2 Maximizing Lift for Single-Element Airfoils
9.3 Multi-Element Airfoils
9.4 Boundary Layer Control Prevention to Separation
9.5 Reduction of Skin-Friction Drag
9.6 Reduction of Form Drag
9.7 Reduction of Induced Drag
9.8 Reduction of Wave Drag
Chapter 10. Propulsion Devices
10.1 Froude’s Momentum Theory of Propulsion
10.2 Airscrew Coefficients
10.3 Airscrew Pitch
10.4 Blade-Element Theory
10.5 The Momentum Theory Applied to the Helicopter Rotor
10.6 The Rocket Motor
10.7 The Hovercraft
10.8 Exercises
Appendix A. Symbols and Notation
Subscripts
Primes and Superscripts
Appendix B
Appendix C. A Solution of Integrals of the Type of Glauert’s Integral
Appendix D. Conversion of Imperial Units to Systéme International (SI) Units
Bibliography
Index
SC
DV
PC