Static and dynamic actuations of clamped-clamped V-shaped micro-resonators under electrostatic forces

•The static and dynamic analysis of electrostatically actuated V-shaped micro-resonators is presented.•The in-plane micro-beams are sandwiched between four electrodes (four ports) with uniform airgap.•With different V-shaped configurations, the structure may show only pull-in instability, the snap-t...

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Published in:Mechanical systems and signal processing 2021-06, Vol.155, p.107571, Article 107571
Main Authors: Alcheikh, N., Ouakad, H.M., Mbarek, S. Ben, Younis, M.I.
Format: Article
Language:English
Subjects:
Actuation
Beam theory (structures)
Buckling
Clamping
Eigenvalues
Electrostatic actuation
Euler-Bernoulli beams
Finite element method
In-plane V-shaped micro-beams
Mathematical models
Microbeams
Power consumption
Resonators
Silicon devices
Static and dynamic analysis
Vibration mode
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container_start_page 107571
container_title Mechanical systems and signal processing
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creator Alcheikh, N.
Ouakad, H.M.
Mbarek, S. Ben
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description •The static and dynamic analysis of electrostatically actuated V-shaped micro-resonators is presented.•The in-plane micro-beams are sandwiched between four electrodes (four ports) with uniform airgap.•With different V-shaped configurations, the structure may show only pull-in instability, the snap-through buckling, or both instabilities together.•The results can be promising for the realization of different wide–range tunable resonators. This work presents detailed static and dynamic analysis of electrostatically actuated in-plane micro-electro-mechanical V-shaped micro-beam resonators. An analytical model is presented, based on the Euler Bernoulli beam theory, which accounts for the nonlinear electrostatic forces and the mid-plane stretching. The model is utilized to simulate the static and eigenvalue problems of the beam under various DC actuation scenarios. The model is validated by comparing with a finite element model and with experimental data. The experiments are based on in-plane silicon devices. The micro-beams are sandwiched between four electrodes (four ports) with uniform airgap for various electrostatic actuation options. These electrodes not only offer various electrostatic actuation options, but also allow the detection of the three lowest symmetric and anti-symmetric resonance frequencies. Results are presented for several case studies of micro-beams resonators of various geometrical parameters and airgap dimensions. With various actuation options and different V-shaped configurations, the structure may show only pull-in instability, the snap-through buckling, or both instabilities together. The results enable careful characterization of the snap-through buckling with the ability of increasing the static deflection range before pull-in. Also, the results can be promising for the realization of different wide–range tunable micro-resonator and for various vibration modes. These results can be useful in micro-scale applications that can be beneficial for designing structures with low power consumption, high sensitivity, and wide tuning range.
doi_str_mv 10.1016/j.ymssp.2020.107571
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The model is utilized to simulate the static and eigenvalue problems of the beam under various DC actuation scenarios. The model is validated by comparing with a finite element model and with experimental data. The experiments are based on in-plane silicon devices. The micro-beams are sandwiched between four electrodes (four ports) with uniform airgap for various electrostatic actuation options. These electrodes not only offer various electrostatic actuation options, but also allow the detection of the three lowest symmetric and anti-symmetric resonance frequencies. Results are presented for several case studies of micro-beams resonators of various geometrical parameters and airgap dimensions. With various actuation options and different V-shaped configurations, the structure may show only pull-in instability, the snap-through buckling, or both instabilities together. 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An analytical model is presented, based on the Euler Bernoulli beam theory, which accounts for the nonlinear electrostatic forces and the mid-plane stretching. The model is utilized to simulate the static and eigenvalue problems of the beam under various DC actuation scenarios. The model is validated by comparing with a finite element model and with experimental data. The experiments are based on in-plane silicon devices. The micro-beams are sandwiched between four electrodes (four ports) with uniform airgap for various electrostatic actuation options. These electrodes not only offer various electrostatic actuation options, but also allow the detection of the three lowest symmetric and anti-symmetric resonance frequencies. Results are presented for several case studies of micro-beams resonators of various geometrical parameters and airgap dimensions. 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1096-1216
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source Elsevier
subjects Actuation
Beam theory (structures)
Buckling
Clamping
Eigenvalues
Electrostatic actuation
Euler-Bernoulli beams
Finite element method
In-plane V-shaped micro-beams
Mathematical models
Microbeams
Power consumption
Resonators
Silicon devices
Static and dynamic analysis
Vibration mode
title Static and dynamic actuations of clamped-clamped V-shaped micro-resonators under electrostatic forces
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