TY - GEN
T1 - Experimental and numerical investigations of the wake vortex system of a delta-Canard-Configuration
AU - Klar, Jan Ulrich
AU - Breitsamter, Christian
AU - Adams, Nikolaus
PY - 2010
Y1 - 2010
N2 - The presented investigation includes a combined experimental-numerical approach to quantify the wake vortex system of a high-agility aircraft from the near field up to the far field. Detailed near field data are obtained by low-speed wind tunnel tests on a delta-canard configuration of 1:15 scale. The measurements are performed at several angles of attack applying advanced hot-wire anemometry. For a wake distance of up to 16 wing spans, mean and turbulent velocity fields are measured. The upstream data are used to initialize Implicit Large-Eddy Simulations (ILES) aimed to compute the velocity fields of the wake vortex system over a wake distance of up to 50 spans. Here, a validation case is shown comparing measured and calculated wake data over a distance from 4 to 16 spans, with the ILES computations initialized by the measured quantities at a position of 2 wing spans. Compared to the experimental data, the numerical results show the expected lateral and vertical movement of the wake vortex system due to the interaction of the single vortices. The distributions of axial vorticity, cross flow velocities and turbulence intensities match well with the experimental data. In addition, the dissipation process can be observed, re-sulting in a reduction of circulation. In context of this study, the measured and computed velocity fields will be used to determine unsteady aerodynamic loads acting on a fighter aircraft encountering the wake. This is of great importance as wake induction may result in critical structural dynamic loads.
AB - The presented investigation includes a combined experimental-numerical approach to quantify the wake vortex system of a high-agility aircraft from the near field up to the far field. Detailed near field data are obtained by low-speed wind tunnel tests on a delta-canard configuration of 1:15 scale. The measurements are performed at several angles of attack applying advanced hot-wire anemometry. For a wake distance of up to 16 wing spans, mean and turbulent velocity fields are measured. The upstream data are used to initialize Implicit Large-Eddy Simulations (ILES) aimed to compute the velocity fields of the wake vortex system over a wake distance of up to 50 spans. Here, a validation case is shown comparing measured and calculated wake data over a distance from 4 to 16 spans, with the ILES computations initialized by the measured quantities at a position of 2 wing spans. Compared to the experimental data, the numerical results show the expected lateral and vertical movement of the wake vortex system due to the interaction of the single vortices. The distributions of axial vorticity, cross flow velocities and turbulence intensities match well with the experimental data. In addition, the dissipation process can be observed, re-sulting in a reduction of circulation. In context of this study, the measured and computed velocity fields will be used to determine unsteady aerodynamic loads acting on a fighter aircraft encountering the wake. This is of great importance as wake induction may result in critical structural dynamic loads.
KW - High agility aircraft
KW - Unsteady aerodynamics
KW - Wake penetration
KW - Wake vortex system
UR - http://www.scopus.com/inward/record.url?scp=84878518258&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84878518258
SN - 9781617820496
T3 - 27th Congress of the International Council of the Aeronautical Sciences 2010, ICAS 2010
SP - 4599
EP - 4610
BT - 27th Congress of the International Council of the Aeronautical Sciences 2010, ICAS 2010
T2 - 27th Congress of the International Council of the Aeronautical Sciences 2010, ICAS 2010
Y2 - 19 September 2010 through 24 September 2010
ER -