Purpose - The purpose of this paper is to report research which led to the realization of a robot for miniaturized assembly endowed with high-accuracy and high-operative flexibility.
Design/methodology/approach - The proposed solution is a microassembly system composed of a Cartesian parallel robot with flexure revolute joints and a modular gripper with metamorphic fingertips, capable of adapting their shape to different micro-objects. The fingertips are realized by electro-discharge machining from a sheet of superelastic alloy. Thanks to its modularity, the gripper can be arranged with two opposite fingers or three fingers placed at 120 degrees. The fingers are actuated by a piezoelectric linear motor with nanometric accuracy.
Findings - The experimental results on the prototype are very interesting. The measured positioning accuracy of the linear motors is 0.5 mu m; the end-effector positioning accuracy is lower, due to the non-perfect kinematics and hysteresis of the flexure joints; however, these effects can be compensated by the direct measurement of the end effector position or by visual feedback. The metamorphic design of the fingertips remarkably increases the grasping force; moreover, the grasping is more stable and reliable.
Practical implications - The introduction of this microassembly system can fulfil the needs of a wide range of industrial applications, thanks to its accurate positioning in a relatively large workspace. The cost of the machine is relatively low, thanks to its modularity.
Originality/value - The combination of Cartesian parallel kinematics, cog-free linear motors and superelastic flexure revolute joints allows one to obtain high-positioning accuracy; the metamorphic fingertips enhance the grasping effectiveness and flexibility.

• 出版日期2010