Hexsil tweezers for teleoperated micro-assembly

Keller, Chris G.; Howe, R.T.

doi:10.1109/memsys.1997.581771

Cited by 58 publications

(29 citation statements)

References 4 publications

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“…In addition, surface forces must be carefully controlled to prevent unwanted adhesion of microscopic parts to each other or tool surfaces [2]. For these reasons, noncontact, parallel assembly techniques in which a large number of components may be assembled simultaneously with microscale precision are being developed.…”

Section: Introductionmentioning

confidence: 99%

Microstructure to substrate self-assembly using capillary forces

Srinivasan

Liepmann

Howe

2001

J. Microelectromech. Syst.

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376

282

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Abstract-We have demonstrated the fluidic self-assembly of micromachined silicon parts onto silicon and quartz substrates in a preconfigured pattern with submicrometer positioning precision. Self-assembly is accomplished using photolithographically defined part and substrate binding sites that are complementary shapes of hydrophobic self-assembled monolayers. The patterned substrate is passed through a film of hydrophobic adhesive on water, causing the adhesive to selectively coat the binding sites. Next, the microscopic parts, fabricated from silicon-on-insulator wafers and ranging in size from 150 150 15 m 3 to 400 400 50 m 3 , are directed toward the substrate surface under water using a pipette. Once the hydrophobic pattern on a part comes into contact with an adhesive-coated substrate binding site, shape matching occurs spontaneously due to interfacial free energy minimization. In water, capillary forces of the adhesive hold the parts in place with an alignment precision of less than 0.2 m. Permanent bonding of the parts onto quartz and silicon is accomplished by activating the adhesive with heat or ultraviolet light. The resulting rotational misalignment is within 0.3 . Using square sites, 98-part arrays have been assembled in less than 1 min with 100% yield. The general microassembly approach described here may be applied to parts ranging in size from the nano-to milliscale, and part and substrate materials including semiconductors, glass, plastics, and metals. [602]

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Section: Introductionmentioning

confidence: 99%

Microstructure to substrate self-assembly using capillary forces

Srinivasan

Liepmann

Howe

2001

J. Microelectromech. Syst.

Self Cite

376

282

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“…It was found from the diverse micrograsping models in literature that researchers have predominantly emphasized on three major components during model development namely novel microfabrication techniques [9,10], new actuation methodologies [11][12][13] and manipulation of different materials [14][15][16] of smart structures have advanced the grasping technologies and enable compact, highly compliant, and monolithic mechanism to be realized. The fabrication techniques such as Electro Discharge Machining (EDM), LIGA, surface, bulk and laser micromachining, and photo lithography have paved a decisive breakthrough to the persisting constraints in micrograsping methodology particularly associated with the object-gripper compatibility, surface to surface interaction between the object and the gripper's jaws and nonlinearity during operation [9,10,17,18]. Furthermore, the realization of monolithic structure also demands the employment of different actuation strategy to satisfy the stringent requirements in precision microhandling operation since the application of conventional motor to drive the microgripper is insufficient to comply with the specifications.…”

Section: Introductionmentioning

confidence: 99%

Development of a novel flexure-based microgripper for high precision micro-object manipulation

Zubir

Shirinzadeh

Tian

2009

Sensors and Actuators A: Physical

151

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“…The size of such grippers is usually in the range of several millimeters to centimeters [14,25,[49][50][51]. Compliant mechanic structures are widely used in microgrippers.…”

Section: Introductionmentioning

confidence: 99%

“…The jaws or fingers are usually made of metals (e.g. stainless steel [14,22,25], nickel [51]) or silicon materials [50,26]. Some nanogrippers are also developed by applying nanotubes [52] or AFM cantilevers as the end-effector [32].…”

Section: Introductionmentioning

confidence: 99%

Automatic dextrous microhandling based on a 6-DOF microgripper

Zhou¹,

Korhonen²,

Laitinen³

et al. 2006

Journal of Micromechatronics

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The demand for automatic quality inspection of individual micro components increases strongly in micro optoelectronics industry. In many cases, quality inspection of those micro components needs dexterous microhandling. However, automatic dexterous handling of micro components is a very challenging issue which is barely explored. This paper presents a high-DOF (degrees of freedom) automatic dexterous handling and inspection system for micro optoelectronic components using a novel 6-DOF piezoelectric microgripper. The control system includes three hierarchical layers: actuator control layer, motion planning layer, and mission control layer. Machine vision is applied in automatic manipulation. The performance of the system is demonstrated in a vision based automatic inspection task for 100 300 300 × × μm sized optoelectronics components and reached a cycle time of s 3 . 0 1 . 7 ± .

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Hexsil tweezers for teleoperated micro-assembly

Cited by 58 publications

References 4 publications

Microstructure to substrate self-assembly using capillary forces

Microstructure to substrate self-assembly using capillary forces

Development of a novel flexure-based microgripper for high precision micro-object manipulation

Automatic dextrous microhandling based on a 6-DOF microgripper

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