Abstract
Pneumatic linear peristaltic actuators can offer some potential advantages when compared with conventional ones. Low cost, virtually unlimited stroke and easy implementation of curved motion profiles are among those benefits. On the downside, these actuators suffer high mechanical stress, which leads to short endurance and increased leakage between chambers during the actuator lifetime. This paper contributes to this field by experimentally characterizing the life behavior of a prototype of a linear pneumatic peristaltic actuator where force—instead of displacement—between rollers is imposed. It is shown that the use of an imposed force configuration has a significant impact in the actuator life time. In fact, the proposed actuator configuration has an average endurance of up to 250% higher than the one previously presented in the literature. This result was obtained while maintaining almost zero leakage between chambers, despite the hose wear throughout the service life. Finally, this paper explores the use of different hose geometries to increase the actuator life span. To this end, a preliminary study is presented where two different 3D printed hose cross sections are tested and compared with a circular one.
Highlights
Pneumatic systems have been attractive in industry due to their high power to weight ratio, high velocities and the simplicity in implementing linear motion
Reported in [16]: all hoses failed in the folding region, and while a clear tearingare wassimilar visibletointhe hoses and FLEXIGOM AIR (FGA), the all hoses failed in the folding region, and while a clear tearing was visible in hoses
This section was devoted to preliminary findings regarding the use of different hose geometries
Summary
Pneumatic systems have been attractive in industry due to their high power to weight ratio, high velocities and the simplicity in implementing linear motion. Its use in control tasks that require smooth velocity control or arbitrary positioning has been hindered by the control challenges caused by the compressibility of air and by the nonlinear behavior of friction. This, along with the claimed low energetic efficiency when compared to servo electromechanical alternatives [1,2,3] has been leading industry to progressively replace pneumatic linear actuators with their electromechanical counterparts. Despite this scenario, pneumatic driven actuators still present several advantages. Reaching confined spaces, dealing with unknown environments, interacting with humans or manipulating complex shaped objects are a few examples of such tasks [4,5,6]
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