Effect of the granular material on the maximum holding force of a granular gripper

A granular gripper is a device used to hold objects by taking advantage of the phenomenon of Reynold's dilatancy. A membrane containing a granular sample is allowed to deform around the object to be held and then vacuum is used to jam the granular material inside the membrane. This allows to hold the object against external forces since deformation of the granular material is prevented by not allowing the system to increase its volume. The maximum holding force supported by the gripper depends on a number of variables. In this work, we show that in the regime of frictional holding (where the gripper does not interlock with the object), the maximum holding force as a function of the penetration of the object in the gripper does not depend on the granular material used to fill the membrane. Results for a variety of granular materials can be collapsed into a single curve if maximum holding force is plotted against the penetration depth achieved. The results suggest that a robotic arm capable of sensing the penetration depth can use this master curve to estimate the maximum holding force at each gripping operation.

Automated summary

A granular gripper uses Reynold's dilatancy to hold objects by jamming granular material inside a membrane, preventing deformation of the material and resisting external forces. The maximum holding force in the frictional holding regime does not depend on the granular material used, but rather on the penetration depth of the object in the gripper. By plotting maximum holding force against penetration depth, results for various granular materials can be collapsed into a single curve for estimating holding force in gripping operations.