Influence of hydraulic versus pneumatic working fluids on quasi-static force response of fluidic artificial muscles

Abstract

There is currently an increased interest in extending the application of McKibben actuators beyond gaseous environments and working fluids. Extensive efforts have already established force response models for pneumatically driven McKibben actuators that are independent of working fluid material properties, however, the model’s independence to working fluid choice has yet to be validated with empirical evidence. This paper experimentally investigates the effect of working fluid type on the quasi-static pressure dependent force-contraction response of McKibben actuators. Using either air or water as the working fluid, characteristic isobaric force-contraction response curves are compared for both large and small-scale McKibben actuators. To ensure truly isobaric force-contraction characterizations, hydraulic and pneumatic pressure systems were developed to provide precise and accurate control of pressure. Experimental testing proved using air or water as the working fluid resulted in nearly identical isobaric force-contraction response curves, demonstrating that McKibben actuator’s quasi-static force response is independent of working fluid choice. This study establishes that the applicability of existing force response models for pneumatic McKibben actuators can be extended to any practical liquids or gases.