A vacuum microgripping tool with integrated vibration releasing capability

Rong, Weibin; Fan, Zenghua; Wang, Lefeng; Xie, Hui; Sun, Lining

doi:10.1063/1.4891695

Cited by 35 publications

(19 citation statements)

References 24 publications

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“…These methods reduce the adhesion force by using pressure changes (vacuum tools) [6], voltage control [7], and dynamic effects (vibration) [8]- [13]. Among existing methods for active release, dynamic effects, i.e., the release of microobjects from an end-effector by vibrating the end-effector to generate inertial force, has drawn much attention recently owing to its high success rate.…”

Section: Et Al Attached a 20mentioning

confidence: 99%

“…For this experiment, On the other hand, for the 10-μm microbeads, a 40× objective lens was applied, providing a visual space of 128 μm × 128 μm. To release an object for precise positioning, the release height was a vital factor because it determined location accuracy after release [6] [9]. In this experiment, the release height was fixed to 20 μm by changing the Z-positions of both end-effectors (Figure 8(d)).…”

Section: Manipulation Of Various Sizes Of Objectsmentioning

confidence: 99%

“…However, they applied a special mechanism with two arms controlled by an electrostatic actuator and a piezoelectric (PZT) actuator to apply these methods. Rong et al separated 35 -100 μm microbeads from an end-effector with 4.5 ± 0.5 μm position accuracy by using vibration release with a vacuum tool [6].…”

Section: Et Al Attached a 20mentioning

confidence: 99%

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High-Speed Active Release End-Effector Motions for Precise Positioning of Adhered Micro-Objects

Kim¹,

Kojima²,

Kamiyama³

et al. 2018

WJET

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This paper presents a release method for micro-objects. To improve position accuracy after release, we propose 3D high-speed end-effector motions. The classical release task focuses on the detachment of a micro-object from an end-effector. The technique utilizes merely the vibration of the end-effector regardless of the pattern of movement. To release different sizes of microobjects and place them precisely at the desired locations in both air and liquid media, in this paper, we propose high-speed motions by analyzing the adhesion force and movement of micro-objects after separation. To generate high end-effector acceleration, many researchers have applied simple vibration by using an additional actuator. However, in our research, 3D high-speed motion with apt amplitude is accomplished by using only a compact parallel mechanism. To verify the advantages of the proposed motion, we compare five motions, 1D motions (in X-, Y-, and Z-directions) and circular motions (clockwise and counterclockwise directions), by changing the frequency and amplitude of the end-effector. Experiments are conducted with different sizes of microbeads and NIH3T3 cells. From these experiments, we conclude that a counterclockwise circular motion can release the objects precisely in air, while 1D motion in the Y direction and two circular motions can detach the objects at the desired positions after release in a liquid environment.

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Section: Et Al Attached a 20mentioning

confidence: 99%

Section: Manipulation Of Various Sizes Of Objectsmentioning

confidence: 99%

See 1 more Smart Citation

High-Speed Active Release End-Effector Motions for Precise Positioning of Adhered Micro-Objects

Kim¹,

Kojima²,

Kamiyama³

et al. 2018

WJET

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show abstract

“…For example, Kim et al [9] utilized high speed motions of an end effector to release object on the desired position. Rong et al and Takahashi et al presented a vacuum tool and voltage control method for precise releasing [10,11]. Moreover, it is difficult to deal with fragile objects, and contamination of the end effector is a weakness [12].…”

Section: Introductionmentioning

confidence: 99%

“…However, the main difficulty of contact manipulation is releasing micro-objects adhering to the manipulator because of large adhesion forces. Thus, to release microobjects at the desired position, special releasing strategies are necessary [9][10][11]. For example, Kim et al [9] utilized high speed motions of an end effector to release object on the desired position.…”

Section: Introductionmentioning

confidence: 99%

Analysis of rotational flow generated by circular motion of an end effector for 3D micromanipulation

et al. 2017

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This paper presents a non-contact manipulation method using rotational flow generated by high speed motion of a glass needle. In order to generate an applicable motion that can precisely control the speed and position of a target object around an end effector, a manipulator actuated by three piezoelectric actuators is proposed. A compact parallel link produces precise three-dimensional motions. To reach the required end-effector frequency and amplitude, which is necessary for generating the rotational flow that can make rotational movement of microbeads having patterned data, the end effector motion is generated by controlling the three piezoelectric actuators at high speed. In this paper, we focus on rotational flow created by two-dimensional circular motion of the end effector mounted on the parallel link. By changing the amplitude and frequency of the circular motion, the generated swirl flow is analyzed in 3D space using 9.6-μm microbeads. We analyzed the velocity toward to the root of the end effector and angular velocity around the end effector by formulating models. From the analyzed data, we verified that the rotational flow has potential to manipulate micro-objects precisely in 3D space.

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Soft‐Contact Acoustic Microgripper Based on a Controllable Gas–Liquid Interface for Biomicromanipulations

Zhou

Liu

Yan

et al. 2021

Small

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engineering, [2] drug delivery, [3] and biomedical research. [4] Until now, micromanipulation methods based on direct physical contact have been used widely.To achieve capture and transportation, different end-effectors have been introduced into systems, such as a microgripper for direct grasping [5] or driven by negative pressure [6] and a cantilever. [7] Through visual feedback, micromanipulation can be realized efficiently and effectively. However, direct contact between solid manipulation tools and bioentities may cause potential damage to living cells that would be difficult to observe by the naked eye. [8] Despite the potential damage to living cells during the manipulation process, the release of micro-objects also poses a significant challenge because of the adhesion force at the microscale due to direct physical contact.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/smll.202104579.

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A vacuum microgripping tool with integrated vibration releasing capability

Cited by 35 publications

References 24 publications

High-Speed Active Release End-Effector Motions for Precise Positioning of Adhered Micro-Objects

High-Speed Active Release End-Effector Motions for Precise Positioning of Adhered Micro-Objects

Analysis of rotational flow generated by circular motion of an end effector for 3D micromanipulation

Soft‐Contact Acoustic Microgripper Based on a Controllable Gas–Liquid Interface for Biomicromanipulations

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