XYZ Micropositioning System Based on Compliance Mechanisms Fabricated by Additive Manufacturing

Ferrara-Bello, Andres; Vargas-Chable, Pedro; Vera-Dimas, J. G.; Vargas-Bernal, Rafael; Tecpoyotl-Torres, M.

doi:10.3390/act10040068

Cited by 9 publications

(9 citation statements)

References 61 publications

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“…The structure of the micromanipulation systems is composed of different elements, usually a control system, a displacement platform, a tool for holding the sample, and a microscopic visual servo drive system, as well as various displacement and force sensors [7]. The sliding platform and the clamping tool are mechanical elements that can be manufactured with compliant [8] or rigid [9] body mechanisms. There is an increasing trend to create designs with compliant mechanisms due to their advantages over rigid body ones, because being structures manufactured in one piece, they are lubricant-free, have no friction losses, no backlash, and mass production is easily facilitated, and there are other advantages, such as high precision and low weight [10].…”

Section: Introductionmentioning

confidence: 99%

Additive Manufactured Piezoelectric-Driven Miniature Gripper

2023

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In several cases, it is desirable to have prototypes of low-cost fabrication and adequate performance. In academic laboratories and industries, miniature and microgrippers can be very useful for observations and the analysis of small objects. Piezoelectrically actuated microgrippers, commonly fabricated with aluminum, and with micrometer stroke or displacement, have been considered as Microelectromechanical Systems (MEMS). Recently, additive manufacture using several polymers has also been used for the fabrication of miniature grippers. This work focuses on the design of a piezoelectric-driven miniature gripper, additive manufactured with Acrylonitrile Butadiene Styrene (PLA), which was modeled using a pseudo rigid body model (PRBM). It was also numerically and experimentally characterized with an acceptable level of approximation. The piezoelectric stack is composed of widely available buzzers. The aperture between the jaws allows it to hold objects with diameters lower than 500 mm, and weights lower than 1.4 g, such as the strands of some plants, salt grains, metal wires, etc. The novelty of this work is given by the miniature gripper’s simple design, as well as the low-cost of the materials and the fabrication process used. In addition, the initial aperture of the jaws can be adjusted, by adhering the metal tips in the required position.

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Section: Introductionmentioning

confidence: 99%

Additive Manufactured Piezoelectric-Driven Miniature Gripper

2023

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“…The properties of the beams, such as stiffness and damping, were able to be tuned under the influence of magnetic fields. Ferrara-Bello et al [ 19 ] applied a micropositioning system actuated by three piezoelectric stacks to control the position and displacement in the three dimensions along the XYZaxis. The main disadvantage of micropositioning platforms is the limited size of their workspaces.…”

Section: Introductionmentioning

confidence: 99%

Omnidirectional Manipulation of Microparticles on a Platform Subjected to Circular Motion Applying Dynamic Dry Friction Control

et al. 2022

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Currently used planar manipulation methods that utilize oscillating surfaces are usually based on asymmetries of time, kinematic, wave, or power types. This paper proposes a method for omnidirectional manipulation of microparticles on a platform subjected to circular motion, where the motion of the particle is achieved and controlled through the asymmetry created by dynamic friction control. The range of angles at which microparticles can be directed, and the average velocity were considered figures of merit. To determine the intrinsic parameters of the system that define the direction and velocity of the particles, a nondimensional mathematical model of the proposed method was developed, and modeling of the manipulation process was carried out. The modeling has shown that it is possible to direct the particle omnidirectionally at any angle over the full 2π range by changing the phase shift between the function governing the circular motion and the dry friction control function. The shape of the trajectory and the average velocity of the particle depend mainly on the width of the dry friction control function. An experimental investigation of omnidirectional manipulation was carried out by implementing the method of dynamic dry friction control. The experiments verified that the asymmetry created by dynamic dry friction control is technically feasible and can be applied for the omnidirectional manipulation of microparticles. The experimental results were consistent with the modeling results and qualitatively confirmed the influence of the control parameters on the motion characteristics predicted by the modeling. The study enriches the classical theories of particle motion on oscillating rigid plates, and it is relevant for the industries that implement various tasks related to assembling, handling, feeding, transporting, or manipulating microparticles.

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“…This enduring trend [2], together with the consequent evolution of massive low-cost and large-scale semiconductor and microelectronics technologies [3], also triggered the conception and manufacturing of micromechanical structures [4], paving the way to the birth and growth of Micro Electro-Mechanical Systems (MEMS) [5][6][7][8]. MEMS can be used as extremely miniaturized sensors, actuators, microgrippers [9][10][11], with different sorts of actuation [12][13][14], piezoelectric resonators [15,16], and wave-guides [17], to only name but a few. They share with microelectronic devices the same conceptual platform: processes, technologies, and facilities able to produce low-cost, large-volume fabrication steps [18,19].…”

Section: Introductionmentioning

confidence: 99%

Downsizing Effects on Micro and Nano Comb Drives

et al. 2022

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Downscaling has been a focal task of Electronics and Electromechanics in the last few decades, and a great engine for technological progress as well. Nevertheless, a scaling operation affects device physics, functioning and performance. The present paper investigates about the impact of scaling on a test case compliant electrostatic micro or nano actuator that is under development with two preferred micro fabrication methods, namely, thick SOI and thin amorphous silicon. A series of numerical trials on materials strength, electro-mechanical characteristics, sensitivity and overall actuation performance have been carried out at different grades of down-scaling and of aspect ratio. This gave rise to new design charts that we propose here as a predictive and friendly guide to select the most appropriate micro fabrication method.

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XYZ Micropositioning System Based on Compliance Mechanisms Fabricated by Additive Manufacturing

Cited by 9 publications

References 61 publications

Additive Manufactured Piezoelectric-Driven Miniature Gripper

Additive Manufactured Piezoelectric-Driven Miniature Gripper

Omnidirectional Manipulation of Microparticles on a Platform Subjected to Circular Motion Applying Dynamic Dry Friction Control

Downsizing Effects on Micro and Nano Comb Drives

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