蜻蜓——向动力飞行过渡期间的空气动力学

Jason K. Cornelius, D. Adams, L. Young, J. Langelaan, T. Opazo, S. Schmitz, Lev Rodovskiy, B. Villac
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引用次数: 3

摘要

蜻蜓号着陆器将在其外壳内进行大约7 - 10年的太空旅行后进入土卫六大气层。进入大气层后,展开主降落伞,释放隔热罩,着陆器将开始过渡到动力飞行(TPF)。TPF是用于蜻蜓旋翼着陆器的空中部署的机动序列。该程序在着陆器释放后旋翼轻载时开始,在达到稳态下降条件时结束。多旋翼无人机系统的空中部署是一个涉及控制器选择与调优、轨迹规划与优化以及计算流体动力学分析的多学科问题。本文介绍了TPF中转子流动状态从风车制动状态,经过湍流尾迹状态和旋涡环状态,并成功进入正常工作状态的过渡过程。将粒子群优化后的控制器标称轨迹绘制在旋翼空气动力学状态图上,以显示沿TPF机动的流态轨迹。初步的CFD模拟结果表明,在TPF的早期阶段,单个转子推力和功率的变化伴随着转子性能的成功稳定。相互作用的空气动力学研究还表明,在机动开始时,着陆器周围的预释放流场是良性的。此外,着陆器稳定轴向下降的结果显示了先前观察到的上转子同轴转子受旋涡环状态影响的屏蔽现象。
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Dragonfly - Aerodynamics during Transition to Powered Flight
The Dragonfly lander will enter the Titan atmosphere following an approximate 7–10-year journey through space inside its aeroshell. After atmospheric entry, deployment of the main parachute, and heatshield release, the lander will begin its transition to powered flight (TPF). TPF is a maneuver sequence used for mid-air deployment of the Dragonfly rotorcraft lander. The sequence starts just after lander release with the rotors lightly loaded and finishes when a steadystate descent condition has been attained. Mid-air deployment of a multicopter unmanned aerial system is a multidisciplinary problem involving controller choice and tuning, trajectory planning and optimization, and computational fluid dynamics analyses. This paper is an introduction to the transition of rotor flow states in TPF from the windmill brake state, through the turbulent wake state and vortex ring state, and the successful emergence into a normal operating state. A particle swarm optimized controller’s nominal trajectory is plotted on a rotor aerodynamics state chart to show the trajectory’s path through the flow states along the TPF maneuver. Results of preliminary CFD simulations show the variance of individual rotor thrust and power in the early stages of TPF followed by a successful stabilization of rotor performance. Interactional aerodynamic studies also characterize the pre-release flowfield around the lander to be benign at the start of the maneuver. Additionally, results for the lander in steady axial descent show a previously observed coaxial rotor shielding phenomenon of the upper rotor from the effects of vortex ring state.
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