Pneumatic Artificial Muscle Actuators With Integrated Controls for Space Flight Applications

ASME 2019 Conference on Smart Materials, Adaptive Structures and Intelligent Systems Pub Date : 2019-12-05 DOI:10.1115/smasis2019-5630

Christopher J. Netwall, James P. Thomas, M. Kubista, Kerry A. Griffith, Christopher Kindle, Jordan Schlater, Joseph T. Hays, Phillip A. Feerst, N. Wereley

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Abstract

The U.S. Naval Research Laboratory (NRL) has been developing a space-rated 7 degree of freedom (DOF) robot arm with a high payload-to-mass ratio as an alternative design to motor-gear driven robotic manipulators. The robot arm employs antagonistic pairs of pneumatic artificial muscle (PAM) actuators to control each degree-of-freedom (DOF) to achieve large force outputs relative to the PAM component masses. A novel feature of the NRL PAM actuator was the integration of the pneumatic control components inside the pressure-bladder, which not only reduces the volume of the robotic arm hardware but also reduces the pressurized-gas actuation volume in the PAM enabling significant reductions in gas consumption during actuation. This multifunctional design enables reductions in launch-weight costs and increases in operational endurance for space applications. The integration of these PAMs into a well-designed robotic-arm structure, in tandem with a newly developed control algorithm, has the potential to exceed the performance metrics of traditional motor-driven robot arms. This paper describes the development of the improved efficiency PAM design that is advancing this technology towards space flight readiness.

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用于航天飞行的集成控制气动人工肌肉执行器

美国海军研究实验室(NRL)一直在开发一种具有高有效载荷-质量比的空间级7自由度(DOF)机器人手臂，作为电机齿轮驱动机器人操纵器的替代设计。机械臂采用对抗性气动人工肌肉(PAM)执行器对各自由度进行控制，以实现相对于PAM组件质量的大力输出。NRL PAM执行器的一个新特点是将气动控制组件集成在压力囊内，这不仅减少了机械臂硬件的体积，还减少了PAM中的加压气体驱动体积，从而显著降低了驱动过程中的气体消耗。这种多功能设计能够减少发射重量成本，并增加空间应用的操作续航时间。将这些pam集成到精心设计的机械臂结构中，再加上新开发的控制算法，有可能超越传统电机驱动的机械臂的性能指标。本文介绍了提高效率的PAM设计的发展，该设计正在推动该技术向太空飞行准备方向发展。

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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ASME 2019 Conference on Smart Materials, Adaptive Structures and Intelligent Systems

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