Abstract
The design of a novel electrothermal microgripper device is shown, which is based on an improved chevron type actuator developed considering their elements parameterization, whose resistive model is also provided. The performance of the microgripper’s parameters, such as displacement, force, and temperature distribution, with convection for the voltage range from 0 up to 5 V, is evaluated through numerical and analytical simulation. Microgripper design was also improved with aid of parameterization. The effect on the microgripper performance due to its thickness is also analyzed, finding a considerable increment in force, when thickness increases. Its main advantage is given by the simplicity of the compliance arrangement of the microgrippers jaws. Considering convection, when 5 V are applied, 37.72 °C was generated at the jaw’s tips of the Improved Microgripper 2 (IMG2), implemented with silicon, this relatively low temperature increases its capabilities of application. When the IMG2 is implemented with polysilicon, its response is competitive comparing with a more complex microgripper, increase of displacement (50%) is shown, but a decrement of force (30%). The diameters allowed for the subjection objects are found between 84.64 µm and 108 µm, with weights lower than 612.2 µg. Some tests of subjection were performed using microcylinders of Au, glass ceramic, polycarbonate and carbon fiber, showing a permissible stress on them, considering its Young’s modulus, as well as the total reaction force induced. All simulations were done on Ansys software. The results demonstrate the feasibility of the future microgripper fabrication.
Highlights
Microelectromechanical systems (MEMS) involve both electronic and non-electronic elements, and perform functions that can include signal acquisition, signal processing, actuation, display and Actuators 2020, 9, 140; doi:10.3390/act9040140 www.mdpi.com/journal/actuatorsActuators 2020, 9, 140 control [1]
Chevron has been widely analyzed we only focus on its parameterization, which will be performed considering a single pair of bent beams
Improved Microgripper 2 (IMG2), implemented with silicon and polysilicon, holding aaaaaaa holding a microparticle made with different materials
Summary
Microelectromechanical systems (MEMS) involve both electronic and non-electronic elements, and perform functions that can include signal acquisition, signal processing, actuation, display and Actuators 2020, 9, 140; doi:10.3390/act9040140 www.mdpi.com/journal/actuators. Actuators 2020, 9, 140 control [1]. MEMS refer to a set of microsensors and microactuators that can perceive environments and have the ability of reacting to changes in those environments, using the control microcircuits [2]. Microactuators based on different actuation principles, such as shape memory alloys, electrostatic, electrothermal, piezoelectric, pneumatic, and electromagnetic approaches, have been devised to drive. Electrothermal actuation is widely applied in MEMS. It can generate a large output force by using low voltages [3]. The electrothermal actuation consists of the thermal expansion of the clamping arms, due to the
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