The Analysis of Lateral Stability of Tailless Camar-3 With Winglets
Keywords:
Tailless UAV, dynamic wind tunnel test, aerodynamic stability derivatives, lateral stability, wingletsAbstract
This paper analyses the lateral stability of tailless CAMAR-3 Unmanned Aerial Vehicle (UAV) when its tail fin (i.e. V-tail) is reconfigured to the wingtips. A tailless UAV may have longer endurance time, compared to the present configuration of V-tail. Nevertheless, a tailless UAV may experience reduction in lateral stability due to loss of yaw control surfaces. In the preliminary design of tailless-winglets UAV, semi-empirical method is applied to estimate the aerodynamic lateral stability derivatives, in order to investigate the stability of both configurations of UAV. A dynamic test rig based on pure yawing motion is built, to measure the lateral stability derivatives of and The time response data of pure yawing oscillation give the natural frequency and damping ratio that describe the aerodynamic derivatives as a result from wind-on and wind-off tunnel tests. The result indicates that UAV with either configurations are laterally stable. However, the tailless-winglets CAMAR has a 13.86% reduction in aerodynamic yawing-moment-due-to-sideslip derivative , compared to CAMAR-3 with V-tail, whereas the aerodynamic yawing-moment-due-to-yaw-rate derivative of tailless-winglets CAMAR is 5.55% lesser thanthat of the CAMAR-3 with V-tail. The lateral stability degrades, as expected, caused by tail stabilizer removal. In conclusion, the idea of tail removal and using winglets as the directional controllers is feasible.
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