MHS'95. Proceedings of the Sixth International Symposium on Micro Machine and Human Science
DOI: 10.1109/mhs.1995.494235
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Miniature robot with micro capillary capturing probe

Abstract: In this report, a micro capillary capturing probe which is based on surface tension of water is described. This probe is composed of a capillary of glass, small solenoids and micro magnetic piston. Quick reciprocating motion of magnetic piston which is accelerated by solenoids current can push and pull the water in capillary. At the end of capillary, the water drop can grow to reach the small object on the surface, contain it with help of surface tension and retract into the capillary. Simple principle and des… Show more

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Cited by 10 publications
(12 citation statements)
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“…In the limit of submillimetric droplets, accurate positioning and/or force feedback are typically employed to avoid potentially damaging impacts between gripper and components. A prior gripper had a water-filled glass capillary whose pushpull action deformed the protruding water drop to change the working range of the gripper [27]. We developed a compliant capillary gripper by using a shock insulator lock (formed by a sliding piston, see Fig.…”
Section: Realization Of the Capillary Grippermentioning
confidence: 99%
“…In the limit of submillimetric droplets, accurate positioning and/or force feedback are typically employed to avoid potentially damaging impacts between gripper and components. A prior gripper had a water-filled glass capillary whose pushpull action deformed the protruding water drop to change the working range of the gripper [27]. We developed a compliant capillary gripper by using a shock insulator lock (formed by a sliding piston, see Fig.…”
Section: Realization Of the Capillary Grippermentioning
confidence: 99%
“…For example, a microhandling strategy using a capillary gripper, which picks parts by capillary force, has been developed [2]. For such a gripper, releasing can be achieved with a creative combination of capillary forces and inertia [35].…”
Section: Microhandling Strategiesmentioning
confidence: 99%
“…The lack of medium affects various things: (1) the capillary force of water, which has a strong contribution to adhesion in air, is nonexisting; (2) because there is no medium, van der Waals forces could be stronger; (3) because vacuum environment is often in SEM, where there will be a lot of electrostatic charges, electrostatic interactions will be more significant; (4) thermal conduction through tool and substrate is the major method of heat transportation, and radiation is usually insignificant; proper system design is important to avoid heat buildup and its consequences.…”
Section: Ambient Environment For Robotic Microhandlingmentioning
confidence: 99%
“…A microgripper can handle objects by applying force mechanically using various actuators [41]; or handle objects by other techniques, such as vacuum [40,42], electrostatic force [43,44], capillary force [45,46], ice [47] and airflow (Benoulli effect) [48]. Besides mechanical microgrippers, vacuum microgrippers are especially widely used in handling larger microparts of hundreds of microns due to their simplicity.…”
Section: Introductionmentioning
confidence: 99%