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Theory and practice of aircraft performance /
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
[Place of publication not identified] :
Wiley,
[2016]
|
| Colección: | Aerospace series (Chichester, England)
|
| Temas: | |
| Acceso en línea: | Texto completo (Requiere registro previo con correo institucional) |
Tabla de Contenidos:
- Title Page
- Copyright Page
- Contents
- Preface
- Series Preface
- Road Map of the Book
- Acknowledgements
- Nomenclature
- Chapter 1 Introduction
- 1.1 Overview
- 1.2 Brief Historical Background
- 1.2.1 Flight in Mythology
- 1.2.2 Fifteenth to Nineteenth Centuries
- 1.2.3 From 1900 to World War I (1914)
- 1.2.4 World War I (1914-1918)
- 1.2.5 The Inter-War Period: the Golden Age (1918-1939)
- 1.2.6 World War II (1939-1945)
- 1.2.7 Post World War II
- 1.3 Current Aircraft Design Status
- 1.3.1 Current Civil Aircraft Trends
- 1.3.2 Current Military Aircraft Trends
- 1.4 Future Trends
- 1.4.1 Trends in Civil Aircraft
- 1.4.2 Trends in Military Aircraft
- 1.4.3 Forces and Drivers
- 1.5 Airworthiness Requirements
- 1.6 Current Aircraft Performance Analyses Levels
- 1.7 Market Survey
- 1.8 Typical Design Process
- 1.8.1 Four Phases of Aircraft Design
- 1.9 Classroom Learning Process
- 1.10 Cost Implications
- 1.11 Units and Dimensions
- 1.12 Use of Semi empirical Relations and Graphs
- 1.13 How Do Aircraft Fly?
- 1.13.1 Classification of Flight Mechanics
- 1.14 Anatomy of Aircraft
- 1.14.1 Comparison between Civil and Military Design Requirements
- 1.15 Aircraft Motion and Forces
- 1.15.1 Motion
- Kinematics
- 1.15.2 Forces
- Kinetics
- 1.15.3 Aerodynamic Parameters
- Lift, Drag and Pitching Moment
- 1.15.4 Basic Controls
- Sign Convention
- References
- Chapter 2 Aerodynamic and Aircraft Design Considerations
- 2.1 Overview
- 2.2 Introduction
- 2.3 Atmosphere
- 2.3.1 Hydrostatic Equations and Standard Atmosphere
- 2.3.2 Non-standard/Off-standard Atmosphere
- 2.3.3 Altitude Definitions
- Density Altitude (Off standard)
- 2.3.4 Humidity Effects
- 2.3.5 Greenhouse Gases Effect
- 2.4 Airflow Behaviour: Laminar and Turbulent
- 2.4.1 Flow Past an Aerofoil
- 2.5 Aerofoil
- 2.5.1 Subsonic Aerofoil.
- 2.5.2 Supersonic Aerofoil
- 2.6 Generation of Lift
- 2.6.1 Centre of Pressure and Aerodynamic Centre
- 2.6.2 Relation between Centre of Pressure and Aerodynamic Centre
- 2.7 Types of Stall
- 2.7.1 Buffet
- 2.8 Comparison of Three NACA Aerofoils
- 2.9 High-Lift Devices
- 2.10 Transonic Effects
- Area Rule
- 2.10.1 Compressibility Correction
- 2.11 Wing Aerodynamics
- 2.11.1 Induced Drag and Total Aircraft Drag
- 2.12 Aspect Ratio Correction of 2D-Aerofoil Characteristics for 3D-Finite Wing
- 2.13 Wing Definitions
- 2.13.1 Planform Area, SW
- 2.13.2 Wing Aspect Ratio
- 2.13.3 Wing-Sweep Angle
- 2.13.4 Wing Root (croot) and Tip (ctip) Chords
- 2.13.5 Wing-Taper Ratio, n
- 2.13.6 Wing Twist
- 2.13.7 High/Low Wing
- 2.13.8 Dihedral/Anhedral Angles
- 2.14 Mean Aerodynamic Chord
- 2.15 Compressibility Effect: Wing Sweep
- 2.16 Wing-Stall Pattern and Wing Twist
- 2.17 Influence of Wing Area and Span on Aerodynamics
- 2.17.1 The Square-Cube Law
- 2.17.2 Aircraft Wetted Area (AW) versus Wing Planform Area (SW)
- 2.17.3 Additional Wing Surface Vortex Lift
- Strake/Canard
- 2.17.4 Additional Surfaces on Wing
- Flaps/Slats and High Lift Devices
- 2.17.5 Other Additional Surfaces on Wing
- 2.18 Empennage
- 2.18.1 Tail-arm
- 2.18.2 Horizontal Tail (H-Tail)
- 2.18.3 Vertical Tail (V-Tail)
- 2.18.4 Tail-Volume Coefficients
- 2.19 Fuselage
- 2.19.1 Fuselage Axis/Zero-Reference Plane
- 2.19.2 Fuselage Length, Lfus
- 2.19.3 Fineness Ratio, FR
- 2.19.4 Fuselage Upsweep Angle
- 2.19.5 Fuselage Closure Angle
- 2.19.6 Front Fuselage Closure Length, Lf
- 2.19.7 Aft Fuselage Closure Length, La
- 2.19.8 Mid-Fuselage Constant Cross-Section Length, Lm
- 2.19.9 Fuselage Height, H
- 2.19.10 Fuselage Width, W
- 2.19.11 Average Diameter, Dave
- 2.20 Nacelle and Intake.
- 2.20.1 Large Commercial/Military Logistic and Old Bombers Nacelle Group
- 2.20.2 Small Civil Aircraft Nacelle Position
- 2.20.3 Intake/Nacelle Group (Military Aircraft)
- 2.20.4 Futuristic Aircraft Nacelle Positions
- 2.21 Speed Brakes and Dive Brakes
- References
- Chapter 3 Air Data Measuring Instruments, Systems and Parameters
- 3.1 Overview
- 3.2 Introduction
- 3.3 Aircraft Speed
- 3.3.1 Definitions Related to Aircraft Velocity
- 3.3.2 Theory Related to Computing Aircraft Velocity
- 3.3.3 Aircraft Speed in Flight Deck Instruments
- 3.3.4 Atmosphere with Wind Speed (Non-zero Wind)
- 3.3.5 Calibrated Airspeed
- 3.3.6 Compressibility Correction (EVc)
- 3.3.7 Other Position Error Corrections
- 3.4 Air Data Instruments
- 3.4.1 Altitude Measurement
- Altimeter
- 3.4.2 Airspeed Measuring Instrument
- Pitot-Static Tube
- 3.4.3 Angle-of-Attack Probe
- 3.4.4 Vertical Speed Indicator
- 3.4.5 Temperature Measurement
- 3.4.6 Turn-Slip Indicator
- 3.5 Aircraft Flight-Deck (Cockpit) Layout
- 3.5.1 Multifunctional Displays and Electronic Flight Information Systems
- 3.5.2 Combat Aircraft Flight Deck
- 3.5.3 Head-Up Display (HUD)
- 3.6 Aircraft Mass (Weights) and Centre of Gravity
- 3.6.1 Aircraft Mass (Weights) Breakdown
- 3.6.2 Desirable CG Position
- 3.6.3 Weights Summary
- Civil Aircraft
- 3.6.4 CG Determination
- Civil Aircraft
- 3.6.5 Bizjet Aircraft CG Location
- Classroom Example
- 3.6.6 Weights Summary
- Military Aircraft
- 3.6.7 CG Determination
- Military Aircraft
- 3.6.8 Classroom Worked Example
- Military AJT CG Location
- 3.7 Noise Emissions
- 3.7.1 Airworthiness Requirements
- 3.7.2 Summary
- 3.8 Engine-Exhaust Emissions
- 3.9 Aircraft Systems
- 3.9.1 Aircraft Control System
- 3.9.2 ECS: Cabin Pressurization and Air Conditioning
- 3.9.3 Oxygen Supply.
- 8.3 Uninstalled Turbofan Engine Performance Data
- Civil Aircraft.