一种新型轮滑起落架飞机定向整流控制系统的设计与性能

Q. Yin, H. Sun, Tao Li, X. Wei, J. Song
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引用次数: 0

摘要

针对平面机身结构、传统轮式起落架收放空间狭小的高超声速飞机,设计了一种新型轮滑式起落架,该起落架在力分配和作动方式上与传统起落架有所不同。为了捕捉轮滑起落架飞机的方向控制性能,基于某型飞机的数据,建立了飞机地面滑行非线性动力学数学模型。通过对轮滑起落架作动器和差动制动控制系统的实验,验证了带压力传感器的电动轮滑作动器模型与试验结果吻合较好,表明了模型的有效性和差动制动响应的快速性。然后基于优化方法和模糊控制理论,设计了一种新的模糊组合方向纠偏控制律。与PD轮滑差动制动控制相比,在整个滑行过程中,方向整流效率提高了140%以上。此外,该组合控制律还能有效地减小横摆角响应的超调。最后,在各种工况下验证了所设计组合方向控制律的稳定性和鲁棒性。
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Design and Performance of Directional Rectification Control System in an Aircraft with a Novel Type of Wheel-Ski Landing Gear
For a hypersonic-speed aircraft with a flat fuselage structure that has narrow space for a traditional wheel-type landing gear retraction, a novel type of wheel-ski landing gear is designed, which is different from traditional landing gears in force distribution and actuation methods. In order to capture the direction control performance of an aircraft with the wheel-ski landing gear, the aircraft ground taxiing nonlinear dynamic mathematical model is built based on a certain type of aircraft data. The experiment of the wheel-ski landing gear actuator and the differential brake control system is carried out to verify that the electric wheel-ski actuator model with the pressure sensor is in good agreement with the test results, indicating the model validity and the speediness of the differential brake response. Then a new fuzzy combined direction rectifying control law is designed based on the optimisation method and the fuzzy control theory. Comparing with the PD wheel-ski differential brake control, the direction rectifying efficiencies increase higher than 140% during the whole taxiing process. In addition, the combined control law can also decrease the overshoots of the yaw angle responses effectively. Finally, the stability and robustness of the designed combined direction control law are verified under various working conditions.
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