Repeatable Energy-Efficient Perching for Flapping-Wing Robots Using Soft Grippers

Krispin C. V. Broers, Sophie F. Armanini
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Abstract

With the emergence of new flapping-wing micro aerial vehicle (FWMAV) designs, a need for extensive and advanced mission capabilities arises. FWMAVs try to adapt and emulate the flight features of birds and flying insects. While current designs already achieve high manoeuvrability, they still almost entirely lack perching and take-off abilities. These capabilities could, for instance, enable long-term monitoring and surveillance missions, and operations in cluttered environments or in proximity to humans and animals. We present the development and testing of a framework that enables repeatable perching and take-off for small to medium-sized FWMAVs, utilising soft, non-damaging grippers. Thanks to its novel active-passive actuation system, an energy-conserving state can be achieved and indefinitely maintained while the vehicle is perched. A prototype of the proposed system weighing under 39 g was manufactured and extensively tested on a 110 g flapping-wing robot. Successful free-flight tests demonstrated the full mission cycle of landing, perching and subsequent take-off. The telemetry data recorded during the flights yields extensive insight into the system's behaviour and is a valuable step towards full automation and optimisation of the entire take-off and landing cycle.
使用软爪为扇翼机器人提供可重复的高能效栖息地
随着新型拍翼式微型飞行器(FWMAV)设计的出现,需要具备广泛而先进的任务能力。FWMAV 尝试适应和模仿鸟类和飞虫的飞行特征。虽然目前的设计已经实现了很高的机动性,但它们仍然几乎完全缺乏栖息和起飞能力。例如,这些能力可以实现长期监测和监视任务,以及在杂乱环境中或在靠近人类和动物的地方执行任务。我们介绍了一个框架的开发和测试情况,该框架利用柔软、无损伤的抓取器实现了中小型 FWMAV 的可重复栖息和起飞。由于采用了新颖的主动-被动致动系统,因此可以实现能量守恒状态,并在车辆栖息时无限期地保持这种状态。该系统的原型重量不到 39 克,已在一个重 110 克的拍翼机器人上进行了广泛测试。成功的飞行测试展示了着陆、栖息和随后起飞的整个任务周期。飞行期间记录的遥测数据对系统的行为产生了广泛的影响,是实现整个起飞和着陆周期的完全自动化和优化的重要一步。
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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