Nowadays, the bottleneck of the fabrication of hybrid microsystems is the assembling phase of microscopic components. Indeed, at microlevel, as a result of the high surface to volume ratio, superficial forces become dominant with respect to other ones and the development of new handling techniques is strongly required. In this context, innovative handling systems have been studied at ITIA. The possibilitiy of controlling and exploiting the capillary force has been investigated and an original handling system, based on capillary force, has been conceived. The theoretical studies led to the development of a first prototype of a gripper with variable curvature and the results obtained from this prototype encouraged the development of a smaller prototype, able to manipulate objects with weight of the order of milligrams. Regarding the actuation system of such a gripper, smart materials seemed to be required. Specifically, a novel configuration based on electroactive polymers (EAP) has been conceived. A feasibility study to evaluate their functionality and performances, as actuation system, has been carried out and the results are presented in this paper.
EAP as actuator for a gripper with variable curvature
Pagano C;Fassi I
2007
Abstract
Nowadays, the bottleneck of the fabrication of hybrid microsystems is the assembling phase of microscopic components. Indeed, at microlevel, as a result of the high surface to volume ratio, superficial forces become dominant with respect to other ones and the development of new handling techniques is strongly required. In this context, innovative handling systems have been studied at ITIA. The possibilitiy of controlling and exploiting the capillary force has been investigated and an original handling system, based on capillary force, has been conceived. The theoretical studies led to the development of a first prototype of a gripper with variable curvature and the results obtained from this prototype encouraged the development of a smaller prototype, able to manipulate objects with weight of the order of milligrams. Regarding the actuation system of such a gripper, smart materials seemed to be required. Specifically, a novel configuration based on electroactive polymers (EAP) has been conceived. A feasibility study to evaluate their functionality and performances, as actuation system, has been carried out and the results are presented in this paper.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.