Dynamics of perforated nanobeams subject to moving mass using the nonlocal strain gradient theory

•The model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches.•Developed mathematical-numerical model to study the dynamic response of the perforated nanobeam under moving mass.•The proposed model includes the length scale and microstructure ef...

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Published in	Applied Mathematical Modelling Vol. 96; pp. 215 - 235
Main Authors	Abdelrahman, Alaa A., Esen, Ismail, Özarpa, Cevat, Eltaher, Mohamed A.
Format	Journal Article
Language	English
Published	New York Elsevier Inc 01.08.2021 Elsevier BV
Subjects	Accelerometers Beam theory (structures) Centripetal force Context Continuum mechanics Coriolis force Dynamic behavior Equations of motion Finite element method Frequency filters Inertia Locking Mass flow Mathematical models Microstructure Moving load Moving loads Nanoelectromechanical systems Nonlocal strain gradient Parameter modification Perforated nanobeam Perforation Shape functions Stiffness Switches Timoshenko beams Vibration response Finite element method Dynamic behavior Perforated nanobeam Moving load Nonlocal strain gradient
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ISSN	0307-904X 1088-8691 0307-904X
DOI	10.1016/j.apm.2021.03.008

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Abstract	•The model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches.•Developed mathematical-numerical model to study the dynamic response of the perforated nanobeam under moving mass.•The proposed model includes the length scale and microstructure effects.•The effect of the moving mass (the inertia, Coriolis and centripetal forces, and the gravity force) or moving load are included.•Finite element model with nonclassical shape functions is developed. In the present manuscript, based on the nonlocal strain gradient theory, a nonclassical dynamic finite element model is developed to study and analyze the dynamic behavior of perforated nanobeam structures under moving mass/load. In the context of nonclassical continuum mechanics and Timoshenko beam theory, dynamic equations of motion of perforated nanobeams are derived including both size scale (nonlocal) and microstructure (strain gradient) effects. The modification of the geometrical parameters due to the perforation process is included in the equations of motion for squared holes arranged in the arrayed form. The effect of the moving mass (the inertia, Coriolis and centripetal forces, and the gravity force) or moving load are included in the proposed model. To remove shear locking problem in slender nanobeams, finite element model on nonclassical shape function basis is developed. Elements stiffness and mass matrices and force vector including the nonlocal and strain gradient effects are derived. The proposed model is verified and checked with previous works. Impacts of perforation, mass/load velocities, inertia of mass, microstructure parameter and nonlocal size scale effects on the dynamic and vibration responses of perforated nanobeam structures have been investigated in a wide context. The following model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches, accelerometers, and mass flow sensors, with perforation.
AbstractList	In the present manuscript, based on the nonlocal strain gradient theory, a nonclassical dynamic finite element model is developed to study and analyze the dynamic behavior of perforated nanobeam structures under moving mass/load. In the context of nonclassical continuum mechanics and Timoshenko beam theory, dynamic equations of motion of perforated nanobeams are derived including both size scale (nonlocal) and microstructure (strain gradient) effects. The modification of the geometrical parameters due to the perforation process is included in the equations of motion for squared holes arranged in the arrayed form. The effect of the moving mass (the inertia, Coriolis and centripetal forces, and the gravity force) or moving load are included in the proposed model. To remove shear locking problem in slender nanobeams, finite element model on nonclassical shape function basis is developed. Elements stiffness and mass matrices and force vector including the nonlocal and strain gradient effects are derived. The proposed model is verified and checked with previous works. Impacts of perforation, mass/load velocities, inertia of mass, microstructure parameter and nonlocal size scale effects on the dynamic and vibration responses of perforated nanobeam structures have been investigated in a wide context. The following model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches, accelerometers, and mass flow sensors, with perforation. •The model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches.•Developed mathematical-numerical model to study the dynamic response of the perforated nanobeam under moving mass.•The proposed model includes the length scale and microstructure effects.•The effect of the moving mass (the inertia, Coriolis and centripetal forces, and the gravity force) or moving load are included.•Finite element model with nonclassical shape functions is developed. In the present manuscript, based on the nonlocal strain gradient theory, a nonclassical dynamic finite element model is developed to study and analyze the dynamic behavior of perforated nanobeam structures under moving mass/load. In the context of nonclassical continuum mechanics and Timoshenko beam theory, dynamic equations of motion of perforated nanobeams are derived including both size scale (nonlocal) and microstructure (strain gradient) effects. The modification of the geometrical parameters due to the perforation process is included in the equations of motion for squared holes arranged in the arrayed form. The effect of the moving mass (the inertia, Coriolis and centripetal forces, and the gravity force) or moving load are included in the proposed model. To remove shear locking problem in slender nanobeams, finite element model on nonclassical shape function basis is developed. Elements stiffness and mass matrices and force vector including the nonlocal and strain gradient effects are derived. The proposed model is verified and checked with previous works. Impacts of perforation, mass/load velocities, inertia of mass, microstructure parameter and nonlocal size scale effects on the dynamic and vibration responses of perforated nanobeam structures have been investigated in a wide context. The following model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches, accelerometers, and mass flow sensors, with perforation.
Author	Abdelrahman, Alaa A. Özarpa, Cevat Eltaher, Mohamed A. Esen, Ismail
Author_xml	– sequence: 1 givenname: Alaa A. surname: Abdelrahman fullname: Abdelrahman, Alaa A. organization: Mechanical Design & Production Department, Faculty of Engineering, Zagazig University, P.O. Box 44519, Zagazig, Egypt – sequence: 2 givenname: Ismail surname: Esen fullname: Esen, Ismail organization: Department of Mechanical Engineering, Karabuk University, Karabuk, Turkey – sequence: 3 givenname: Cevat surname: Özarpa fullname: Özarpa, Cevat organization: Department of Mechanical Engineering, Karabuk University, Karabuk, Turkey – sequence: 4 givenname: Mohamed A. surname: Eltaher fullname: Eltaher, Mohamed A. email: meltaher@kau.edu.sa, mohaeltaher@gmail.com organization: Mechanical Engineering Department, Faculty of Engineering, King Abdulaziz University, P.O. Box 80204, Jeddah, Saudi Arabia
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Keywords	Finite element method Dynamic behavior Perforated nanobeam Moving load Nonlocal strain gradient
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Snippet	•The model is beneficial for the design of MEMS/NEMS structures such as frequency filters, resonators, relay switches.•Developed mathematical-numerical model... In the present manuscript, based on the nonlocal strain gradient theory, a nonclassical dynamic finite element model is developed to study and analyze the...
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SubjectTerms	Accelerometers Beam theory (structures) Centripetal force Context Continuum mechanics Coriolis force Dynamic behavior Equations of motion Finite element method Frequency filters Inertia Locking Mass flow Mathematical models Microstructure Moving load Moving loads Nanoelectromechanical systems Nonlocal strain gradient Parameter modification Perforated nanobeam Perforation Shape functions Stiffness Switches Timoshenko beams Vibration response
Title	Dynamics of perforated nanobeams subject to moving mass using the nonlocal strain gradient theory
URI	https://dx.doi.org/10.1016/j.apm.2021.03.008 https://www.proquest.com/docview/2547067655
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