Book contents
- Frontmatter
- Contents
- Preface
- Preface to the First Edition
- 1 Introduction and Background
- 2 Fundamentals of Inviscid, Incompressible Flow
- 3 General Solution of the Incompressible, Potential Flow Equations
- 4 Small-Disturbance Flow over Three-Dimensional Wings: Formulation of the Problem
- 5 Small-Disturbance Flow over Two-Dimensional Airfoils
- 6 Exact Solutions with Complex Variables
- 7 Perturbation Methods
- 8 Three-Dimensional Small-Disturbance Solutions
- 9 Numerical (Panel) Methods
- 10 Singularity Elements and Influence Coefficients
- 11 Two-Dimensional Numerical Solutions
- 12 Three-Dimensional Numerical Solutions
- 13 Unsteady Incompressible Potential Flow
- 14 The Laminar Boundary Layer
- 15 Enhancement of the Potential Flow Model
- A Airfoil Integrals
- B Singularity Distribution Integrals
- C Principal Value of the Lifting Surface Integral IL
- D Sample Computer Programs
- Index
10 - Singularity Elements and Influence Coefficients
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- Preface to the First Edition
- 1 Introduction and Background
- 2 Fundamentals of Inviscid, Incompressible Flow
- 3 General Solution of the Incompressible, Potential Flow Equations
- 4 Small-Disturbance Flow over Three-Dimensional Wings: Formulation of the Problem
- 5 Small-Disturbance Flow over Two-Dimensional Airfoils
- 6 Exact Solutions with Complex Variables
- 7 Perturbation Methods
- 8 Three-Dimensional Small-Disturbance Solutions
- 9 Numerical (Panel) Methods
- 10 Singularity Elements and Influence Coefficients
- 11 Two-Dimensional Numerical Solutions
- 12 Three-Dimensional Numerical Solutions
- 13 Unsteady Incompressible Potential Flow
- 14 The Laminar Boundary Layer
- 15 Enhancement of the Potential Flow Model
- A Airfoil Integrals
- B Singularity Distribution Integrals
- C Principal Value of the Lifting Surface Integral IL
- D Sample Computer Programs
- Index
Summary
It was demonstrated in the previous chapters that the solution of potential flow problems over bodies and wings can be obtained by the distribution of elementary solutions. The strengths of these elementary solutions of Laplace's equation are obtained by enforcing the zero normal flow condition on the solid boundaries. The steps toward a numerical solution of this boundary value problem are described schematically in Section 9.7. In general, as the complexity of the method is increased, the “element's influence” calculation becomes more elaborate. Therefore, in this chapter, emphasis is placed on presenting some of the typical numerical elements upon which some numerical solutions are based (the list is not complete and an infinite number of elements can be developed). A generic element is shown schematically in Fig. 10.1. To calculate the induced potential and velocity increments at an arbitrary point P(xP, yP, zP) requires information on the element geometry and strength of singularity.
For simplicity, the symbol Δ is dropped in the following description of the singularity elements. However, it must be clear that the values of the velocity potential and velocity components are incremental values and can be added up according to the principle of superposition.
In the following sections some two-dimensional elements will be presented, whose derivation is rather simple. Three-dimensional elements will be presented later and their complexity increases with the order of the polynomial approximation of the singularity strength.
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- Low-Speed Aerodynamics , pp. 230 - 261Publisher: Cambridge University PressPrint publication year: 2001
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