Add to ORKGThe effectiveness of transpiration for simulation of structural deformations in steady and unsteady aeroelastic applications is examined. The majority of the investigations were performed using a highly integrated, finite-element code for the multidisciplinary analysis of flight vehicles. A supplement to this code, which allows for the generation of deflected meshes using modal superposition, was developed in this study. This research demonstrated that the transpiration boundary condition has strong potential for applications in unsteady aeroelastic analysis, such as in the prediction of flutter boundaries
In the last two decades there have been extensive developments in computational unsteady transonic a...
A finite difference code was developed for modeling inviscid, unsteady supersonic flow by solution o...
An obvious reason for studying unsteady flows is the prediction of the effect of unsteady aerodynami...
Modifications to an existing three-dimensional, implicit, upwind Euler/Navier-Stokes code (CFL3D Ver...
The current status of computational methods for unsteady aerodynamics and aeroelasticity is reviewed...
Modifications to a three dimensional, implicit, upwind, unstructured-grid Euler code for aeroelastic...
Research in the area of computational unsteady transonic flows about airfoils and wings, including a...
This paper builds on the computational aeroelastic results published previously and generated in sup...
In the past decade, there has been much activity in the development of computational methods for the...
In transonic flutter problems where shock motion plays an important part, it is believed that accura...
Modifications to the CFL3D three dimensional unsteady Euler/Navier-Stokes code for the aeroelastic a...
Research in the area of computational, unsteady transonic flows about airfoils and wings, including ...
Computational fluid dynamics methods have been widely accepted for transonic aeroelastic analysis. P...
For an accurate prediction of the steady and unsteady behaviour of an aircraft it is necessary to ta...
A computational method to perform transonic aeroelastic and aeroservoelastic calculations in the tim...
In the last two decades there have been extensive developments in computational unsteady transonic a...
A finite difference code was developed for modeling inviscid, unsteady supersonic flow by solution o...
An obvious reason for studying unsteady flows is the prediction of the effect of unsteady aerodynami...
Modifications to an existing three-dimensional, implicit, upwind Euler/Navier-Stokes code (CFL3D Ver...
The current status of computational methods for unsteady aerodynamics and aeroelasticity is reviewed...
Modifications to a three dimensional, implicit, upwind, unstructured-grid Euler code for aeroelastic...
Research in the area of computational unsteady transonic flows about airfoils and wings, including a...
This paper builds on the computational aeroelastic results published previously and generated in sup...
In the past decade, there has been much activity in the development of computational methods for the...
In transonic flutter problems where shock motion plays an important part, it is believed that accura...
Modifications to the CFL3D three dimensional unsteady Euler/Navier-Stokes code for the aeroelastic a...
Research in the area of computational, unsteady transonic flows about airfoils and wings, including ...
Computational fluid dynamics methods have been widely accepted for transonic aeroelastic analysis. P...
For an accurate prediction of the steady and unsteady behaviour of an aircraft it is necessary to ta...
A computational method to perform transonic aeroelastic and aeroservoelastic calculations in the tim...
In the last two decades there have been extensive developments in computational unsteady transonic a...
A finite difference code was developed for modeling inviscid, unsteady supersonic flow by solution o...
An obvious reason for studying unsteady flows is the prediction of the effect of unsteady aerodynami...