Title :
Multi-batch micro-self-assembly via controlled capillary forces
Author :
Xiong, Xiaorong ; Hanein, Yael ; Wang, Weihua ; Schwartz, Daniel T. ; Böhringer, Karl F.
Author_Institution :
Dept. of Electr. Eng., Washington Univ., Seattle, WA, USA
Abstract :
Advances in silicon processing and microelectro-mechanical systems (MEMS) have made possible the production of very large numbers of very small components at very low cost in massively parallel batches. Assembly, in contrast, remains a mostly serial (i.e., non-batch) technique. We argue that massively parallel self-assembly of microparts will be a crucial enabling technology for future complex microsystems. As a specific approach, we present a technique for assembly of multiple batches of microparts based on capillary forces and controlled modulation of surface hydrophobicity. We derive a simplified model that gives rise to geometric algorithms for predicting assembly forces and for guiding the design optimization of self-assembling microparts. Promising initial results from theory and experiments and challenging open problems are presented to lay a foundation for general models and algorithms for self-assembly
Keywords :
batch processing (industrial); capillarity; force control; industrial manipulators; microassembling; micromanipulators; optimisation; controlled capillary forces; controlled modulation; distributed manipulation; enabling technology; geometric algorithms; massively parallel self-assembly; microparts; multi-batch micro-self-assembly; sensorless manipulation; surface hydrophobicity; Assembly; Batch production systems; Costs; Force control; Micromechanical devices; Optimized production technology; Predictive models; Self-assembly; Silicon; Solid modeling;
Conference_Titel :
Intelligent Robots and Systems, 2001. Proceedings. 2001 IEEE/RSJ International Conference on
Conference_Location :
Maui, HI
Print_ISBN :
0-7803-6612-3
DOI :
10.1109/IROS.2001.977167
