Towards a Soft Exosuit for Hypogravity Adaptation: Design and Control of Lightweight Bubble Artificial Muscles

Lower body soft exosuits have been shown to improve the capabilities of humans in a wide range of applications, from rehabilitation to worker enhancement. Their light weight and ability to be easily sewn into fabrics make them attractive for both terrestrial and space exploration applications. One u...

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Bibliographic Details
Published in2022 IEEE 5th International Conference on Soft Robotics (RoboSoft) pp. 651 - 656
Main Authors Pulvirenti, Emanuele, Diteesawat, Richard S., Hauser, Helmut, Rossiter, Jonathan
Format Conference Proceeding
LanguageEnglish
Published IEEE 04.04.2022
Subjects
Actuators
Fabrics
Muscles
Shape
Soft robotics
Space exploration
Steady-state
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Summary:Lower body soft exosuits have been shown to improve the capabilities of humans in a wide range of applications, from rehabilitation to worker enhancement. Their light weight and ability to be easily sewn into fabrics make them attractive for both terrestrial and space exploration applications. One unaddressed challenge in space exploration is the prevalence of low (hypo) gravity conditions, which can have a serious deleterious effect on the human body. To address this challenge we propose the hypogravity exosuit (or HEXsuit), which can help maintain the physical fitness and health of inter-planetary travellers. A core component of the HEXsuit is compliant, comfortable and efficient soft robotic artificial muscles. A recently proposed pneumatic actuator, the Bubble Artificial Muscle (BAM), is particularly suited for integration into hypogravity exosuits. In this work we explore the design and control of lightweight BAM actuators. Characterisation results show that a thin actuator is capable of high contraction, while a thicker actuator can be used for high load applications. Two control modes were implemented: displacement control and force control. Both controllers achieve low steady state error and show high accuracy. The displacement controller is also shown to be capable of maintaining the required displacement while actively changing external loads, a typical use case within the proposed hypogravity HEXsuit. Soft Robotics, Bubble Artificial Muscles, pneumatic, artificial muscle, exoskeleton, exosuit, space exploration
DOI:10.1109/RoboSoft54090.2022.9762121