Conceptual Inflatable Fabric Structures for Protective Crew Quarters Systems in Space Vehicles and Space Habitat Structures

Cavallaro, Paul V.; Smith, Russell W.

doi:10.21236/ad1012988

Cited by 1 publication

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“…Finite element models have been used to predict the behavior and final shape of a range of elastomer-based inflatable actuators. [52][53][54][55] Existing models of textile-based actuators have typically been used for static structures [56][57][58][59] but there has been some recent work on finite element modeling of knitted textile actuators for wearable applications. 48,60 Nesler et al 61 and Fang et al 62 both presented an elegant analytical approach for predicting the behavior of unfolding textile-based actuators by modeling the energetics of inflating the actuator.…”

Section: Introductionmentioning

confidence: 99%

Unfolding Textile-Based Pneumatic Actuators for Wearable Applications

et al. 2022

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Textile based pneumatic actuators have recently seen increased development for use in wearable applications thanks to their high strength to weight ratio and range of achievable actuation modalities. However, the design of these textile-based actuators is typically an iterative process due to the complexity of predicting the soft and compliant behavior of the textiles. In this work we investigate the actuation mechanics of a range of physical prototypes of unfolding textile-based actuators to understand and develop an intuition for how the geometric parameters of the actuator affect the moment it generates, enabling more deterministic designs in the future. Under benchtop conditions the actuators were characterized at a range of actuator angles and pressures (0-136 kPa), and three distinct performance regimes were observed, which we define as Shearing, Creasing, and Flattening. During Flattening, the effects of both the length and radius of the actuator dominate with maximum moments in excess of 80 Nm being generated, while during Creasing the radius dominates with generated moments scaling with the cube of the radius. Low stiffness spring like behavior is observed in the Shearing regime, which occurs as the actuator approaches its unfolded angle. A piecewise analytical model was also developed and compared to the experimental results within each regime. Finally, a prototype actuator was also integrated into a shoulder assisting wearable robot, and on-body characterization of this robot was performed on five healthy individuals to observe the behavior of the actuators in a wearable application. Results from this characterization highlight that these actuators can generate useful on-body moments (10.74 Nm at 90°a ctuator angle) but that there are significant reductions compared to bench-top performance, in particular when mostly folded and at higher pressures.

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