Design and Testing of a Vertical Take-Off and Landing UAV Optimized for Carrying a Hydrogen Fuel Cell with a Pressure Tank

C. D. Wagter, B. Remes, R. Ruijsink, F. V. Tienen, E. V. D. Horst
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引用次数: 7

Abstract

Flight endurance is still a bottleneck for many types of unmanned air vehicle (UAV) applications. While battery technology improves over the years, for flights that last an entire day, batteries are still insufficient. Hydrogen-powered fuel cells offer an interesting alternative but pose stringent requirements on the platform. The required cruise power must be sufficiently low and flying with a pressurized tank poses new safety and shape constraints. This paper proposes a hybrid transitioning UAV that is optimized towards carrying a hydrogen tank and fuel cell. Hover is achieved using 12 redundant propellers connected to a dual Controller Area Network (CAN) bus and dual power supply. Forward flight is achieved using a tandem wing configuration. The tandem wing not only minimizes the required wingspan to minimize perturbations from gusts during hover, but it also handles the very large pitch inertia of the inline pressure tank and fuel cell very well. During forward flight, 8 of the 12 propellers are folded while the tip propellers counteract the tip vortexes. The propulsion is tested on a force balance and the selected fuel cell is tested in the lab. Finally, a prototype is built and tested in-flight using battery power. Stable hover, good transitioning properties, and stable forward flight are demonstrated.
搭载带压力罐氢燃料电池优化的垂直起降无人机设计与试验
对于许多类型的无人机(UAV)应用来说,飞行耐力仍然是一个瓶颈。尽管多年来电池技术不断进步,但对于持续一整天的飞行来说,电池仍然不足。氢动力燃料电池提供了一个有趣的替代方案,但对平台的要求非常严格。所需的巡航功率必须足够低,使用增压油箱飞行会带来新的安全和形状限制。提出了一种以携带氢罐和燃料电池为优化方向的混合过渡无人机。Hover是通过12个冗余螺旋桨连接到双控制器区域网络(CAN)总线和双电源来实现的。向前飞行是使用串联翼配置实现的。串联机翼不仅可以将悬停时所需的翼展最小化,以减少阵风的扰动,而且还可以很好地处理内联压力罐和燃料电池的巨大俯仰惯性。在向前飞行时,12个螺旋桨中的8个被折叠,而尖端螺旋桨抵消了尖端涡。推进装置在力平衡上进行测试,选定的燃料电池在实验室进行测试。最后,建造一个原型机,并在飞行中使用电池进行测试。证明了稳定的悬停、良好的过渡性能和稳定的前飞。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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