Generalized Kutta–Joukowski theorem for multi-vortex and multi-airfoil flow with vortex production——A general model

By using a special momentum approach and with the help of interchange between singularity velocity and induced flow velocity, we derive in a physical way explicit force formulas for twodimensional inviscid flow involving multiple bound and free vortices, multiple airfoils, and vortex production. The...

Full description

Saved in:
Bibliographic Details
Published in:Chinese journal of aeronautics 2014-10, Vol.27 (5), p.1037-1050
Main Authors: Bai, Chenyuan, Li, Juan, Wu, Ziniu
Format: Article
Language:English
Subjects:
Aerodynamics
Airfoils
Computational fluid dynamics
Drag force
Fluid flow
Lift force
Mathematical models
Multibody
Multiple vortices
Singularities
Theorems
Vortex production
Vortices
一般模型
定理
广义
流动
生产
翼型
自由涡
诱导速度
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:By using a special momentum approach and with the help of interchange between singularity velocity and induced flow velocity, we derive in a physical way explicit force formulas for twodimensional inviscid flow involving multiple bound and free vortices, multiple airfoils, and vortex production. These force formulas hold individually for each airfoil thus allowing for force decomposition, and the contributions to forces from singularities(such as bound and image vortices,sources, and doublets) and bodies out of an airfoil are related to their induced velocities at the locations of singularities inside this airfoil. The force contribution due to vortex production is related to the vortex production rate and the distance between each pair of vortices in production, thus frameindependent. The formulas are validated against a number of standard problems. These force formulas, which generalize the classic Kutta–Joukowski theorem(for a single bound vortex) and the recent generalized Lagally theorem(for problems without a bound vortex and vortex production) to more general cases, can be used to identify or understand the roles of outside vortices and bodies on the forces of the actual body, optimize arrangement of outside vortices and bodies for force enhancement or reduction, and derive analytical force formulas once the flow field is given or known.
ISSN:1000-9361
DOI:10.1016/j.cja.2014.03.014