W. R. Van Dalsem scite author profile

W. R. Van Dalsem

5Publications

26Citation Statements Received

13Citation Statements Given

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Ames Research Center

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Computation of viscous transonic flow over porous airfoils

Chen

Chow

Dalsem

et al. 1989

Journal of Aircraft

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The viscous effects on transonic flow past an airfoil that contains a shallow cavity beneath a porous surface are studied numerically. The porous region occupies a small portion of the total airfoil surface and is located near the shock. Both an interactive boundary-layer (IBL) algorithm and a thin-layer Navier-Stokes (TLNS) algorithm have been modified for use in studying the outer flow, whereas a stream-function formulation has been used to model the inner flow in the small cavity. The coupling procedure at the porous surface is based on Darcy's law and on the assumption of a constant total pressure in the cavity. In addition, a modified Baldwin-Lomax turbulence model is used to consider the transpired turbulent bounday layer in the TLNS approach, and the Cebeci-Smith turbulence model is used in the IBL approach. According to the present analysis, a porous surface can reduce the wave drag appreciably, but it can also increase viscous losses. As has been observed experimentally in nonlifting airfoils, the numerical results indicate that the total drag may be reduced at higher Mach numbers and increased at lower Mach numbers. Furthermore, the streamline patterns of passive-shock and boundarylayer interaction are revealed in this study.

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Numerical simulation of a complete STOVL aircraft in ground effect

Smith

Chawla

Dalsem

1991

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The efficient simulation of separated three-dimensional viscous flows using the boundary-layer equations

Dalsem

Steger

1985

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Simulation of transonic separated airfoil flow by finite-difference viscous-inviscid interaction

Dalsem

Steger

1985

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Numerical Investigation of a Jet in Ground Effect with a Crossflow

Dalsem

Panaras

Steger

1987

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A wind tunnel investigation was conducted in the Low Speed Wind Tunnel (V/STOL.) to determine the velocities in the recirculation region of the flow field produced by the interaction of a jet impinging on a ground plane with crossflow. Axial and vertical velocity component measurements were obtained with a forward-scattering laser Doppler velocimeter. Test results provide two-component velocity fields and indicate that the jet-to-free-stream velocity ratio is much more important in determining the flow field than the magnitude of the individual velocities.

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W. R. Van Dalsem

Computation of viscous transonic flow over porous airfoils

Numerical simulation of a complete STOVL aircraft in ground effect

The efficient simulation of separated three-dimensional viscous flows using the boundary-layer equations

Simulation of transonic separated airfoil flow by finite-difference viscous-inviscid interaction

Numerical Investigation of a Jet in Ground Effect with a Crossflow

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