| Autore |
Sengupta Tapan Kumar <1955->
|
| Pubbl/distr/stampa |
Chichester, England : , : Wiley, , 2015
|
| Descrizione fisica |
1 online resource (519 p.)
|
| Disciplina |
629.132/3001
|
| Collana |
Aerospace Series
|
| Soggetto topico |
Aerodynamics
|
| Soggetto genere / forma |
Electronic books.
|
| ISBN |
1-118-78757-9
1-118-78754-4
|
| Formato |
Materiale a stampa  |
| Livello bibliografico |
Monografia |
| Lingua di pubblicazione |
eng
|
| Nota di contenuto |
Theoretical and Computational Aerodynamics; Contents; Series Preface; Preface; Acknowledgements; 1 Introduction to Aerodynamics and Atmosphere; 1.1 Motivation and Scope of Aerodynamics; 1.2 Conservation Principles; 1.2.1 Conservation Laws and Reynolds Transport Theorem (RTT); 1.2.2 Application of RTT: Conservation of Linear Momentum; 1.3 Origin of Aerodynamic Forces; 1.3.1 Momentum Integral Theory: Real Fluid Flow; 1.4 Flow in Accelerating Control Volumes: Application of RTT; 1.5 Atmosphere and Its Role in Aerodynamics; 1.5.1 Von Kármán Line; 1.5.2 Structure of Atmosphere
1.5.3 Armstrong Line or Limit1.5.4 International Standard Atmosphere (ISA) and Other Atmospheric Details; 1.5.5 Property Variations in Troposphere and Stratosphere; 1.6 Static Stability of Atmosphere; Bibliography; 2 Basic Equations of Motion; 2.1 Introduction; 2.1.1 Compressibility of Fluid Flow; 2.2 Conservation Principles; 2.2.1 Flow Description Method: Eulerian and Lagrangian Approaches; 2.2.2 The Continuity Equation: Mass Conservation; 2.3 Conservation of Linear Momentum: Integral Form; 2.4 Conservation of Linear Momentum: Differential Form
2.4.1 General Stress System in a Deformable Body2.5 Strain Rate of Fluid Element in Flows; 2.5.1 Kinematic Interpretation of Strain Tensor; 2.6 Relation between Stress and Rate of Strain Tensors in Fluid Flow; 2.7 Circulation and Rotationality in Flows; 2.8 Irrotational Flows and Velocity Potential; 2.9 Stream Function and Vector Potential; 2.10 Governing Equation for Irrotational Flows; 2.11 Kelvin's Theorem and Irrotationality; 2.12 Bernoulli's Equation: Relation of Pressure and Velocity; 2.13 Applications of Bernoulli's Equation: Air Speed Indicator; 2.13.1 Aircraft Speed Measurement
2.13.2 The Pressure Coefficient2.13.3 Compressibility Correction for Air Speed Indicator; 2.14 Viscous Effects and Boundary Layers; 2.15 Thermodynamics and Reynolds Transport Theorem; 2.16 Reynolds Transport Theorem; 2.17 The Energy Equation; 2.17.1 The Steady Flow Energy Equation; 2.18 Energy Conservation Equation; 2.19 Alternate Forms of Energy Equation; 2.20 The Energy Equation in Conservation Form; 2.21 Strong Conservation and Weak Conservation Forms; 2.22 Second Law of Thermodynamics and Entropy; 2.23 Propagation of Sound and Mach Number; 2.24 One-Dimensional Steady Flow
2.25 Normal Shock Relation for Steady Flow2.26 Rankine--Hugoniot Relation; 2.27 Prandtl or Meyer Relation; 2.28 Oblique ShockWaves; 2.29 Weak Oblique Shock; 2.30 Expansion of Supersonic Flows; Bibliography; 3 Theoretical Aerodynamics of Potential Flows; 3.1 Introduction; 3.2 Preliminaries of Complex Analysis for 2D Irrotational Flows: Cauchy--Riemann Relations; 3.2.1 Cauchy's Residue Theorem; 3.2.2 Complex Potential and Complex Velocity; 3.3 Elementary Singularities in Fluid Flows; 3.3.1 Superposing Solutions of Irrotational Flows; 3.4 Blasius' Theorem: Forces and Moment for Potential Flows
3.4.1 Force Acting on a Vortex in a Uniform Flow
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| Record Nr. | UNINA-9910463522403321 |
Info
Theoretical and computational aerodynamics / / Tapan K. Sengupta
