Vibration of rotating microbeams with axial motion in complex environments

Authors

Tarbiat Modares University

Abstract

In the present paper, the size-dependent vibrations and stability of rotating microbeams with axial motion embedded in a viscous medium with different supported boundary conditions in humid-thermal-magnetic environments under gravitational and axial loads are studied based on the coupled stress theory and Rayleigh beam model. The dynamic equations of the system are derived using the Hamilton principle. Using the Galerkin method and solving the eigenvalue problem, the backward and forward vibrational frequencies and the instability thresholds of the system are obtained. Comparative studies are performed to validate the results of the present study. The effects of various key parameters such as rotary inertia factor, substrate damping, flexural stiffness ratio on system dynamics are examined. The results showed that magnetic fields improve system performance in contrast to humid environments. Also, when the axial motion of the system is in the opposite direction of gravitational acceleration, gravitational forces reduce the instability threshold of the system and can change the system stability evolution. It is also shown that increasing the rotary inertia factor reduces vibrational frequencies and system stability. The modeling and the results of the present study can be useful in the optimal design of microswitches.

Keywords

Main Subjects

References

[1] Esmailpour Hamedani S, Hosseini M (2020) Nonlinear Vibration Analysis of Micro Rotating Euler-Bernoulli Beams Subjected to Loading Based on the Strain Gradient Theory. JSFM 10(3):181-193 (In Persian).
[2] Sarparast H, Ebrahimi‐Mamaghani A, Safarpour M, Ouakad H M, Dimitri R,  Tornabene F (2020) Nonlocal study of the vibration and stability response of small‐scale axially moving supported beams on viscoelastic‐Pasternak foundation in a hygro‐thermal environment. Math. Methods Appl. Sci. Doi: 10.1002/mma.6859.
[3] Yang X D, Yang J H, Qian Y J, Zhang W,  Melnik R V (2018) Dynamics of a beam with both axial moving and spinning motion: An example of bi-gyroscopic continua. Eur J Mech A Solids 69(2):231-237.
[4] Zhu K, Chung J (2019) Vibration and stability analysis of a simply-supported Rayleigh beam with spinning and axial motions. Appl. Math. Model. 66(4):362-382.
[5] Li X, Qin Y, Li Y H,  Zhao X (2018) The coupled vibration characteristics of a spinning and axially moving composite thin-walled beam. Mech. Adv. Mater. Struct. 25(9):722-731.
[6] Sahebkar S M, Ghazavi M R, Khadem S E,  Ghayesh M (2011) Nonlinear vibration analysis of an axially moving drillstring system with time dependent axial load and axial velocity in inclined well. Mech. Mach. 46(5):743-760.
[7] Ghayesh M H, Ghazavi M R, Khadem S E (2010) Non-linear vibration and stability analysis of an axially moving rotor in sub-critical transporting speed range. Struct. Eng. Mech. 34(4):507-523.
[8] Yuh J, Young T (1991) Dynamic modeling of an axially moving beam in rotation: simulation and experiment 20(3):34-40.
[9] Lee H P (1994) Vibration of a pretwisted spinning and axially moving beam.  Comput Struct. 52(3):595-601.
[10] Shafiei N, Ghadiri M, Mahinzare M (2019) Flapwise bending vibration analysis of rotary tapered functionally graded nanobeam in thermal environment. Mech. Adv. Mater. Struct. 26(2):139-155.
[11] Azimi M, Mirjavadi S S, Shafiei N, Hamouda A M S,  Davari E (2018) Vibration of rotating functionally graded Timoshenko nano-beams with nonlinear thermal distribution. Mech. Adv. Mater. Struct. 25(6):467-480.
[12] Ghadiri M, Hosseini S H S, Shafiei N (2016) A power series for vibration of a rotating nanobeam with considering thermal effect. Mech. Adv. Mater. Struct. 23(12):1414-1420.
[13] Naderi A, Rostami M, Farajollahi A, and Marashi SM (2022) Size-dependent vibration of rotating rayleigh microbeams with variable cross-section in complex environments. JSFM 11(1):159-171 (In Persian).
[14] Hamedani S E, Hosseini M (2020) Nonlinear Vibration Analysis of Micro Rotating Euler-Bernoulli Beams Subjected to Loading Based on the Strain Gradient Theory. JSFM 10(1):181-193 (In Persian).
[15] Bai Y, Suhatril M, Cao Y, Forooghi A,  Assilzadeh H (2021) Hygro–thermo–magnetically induced vibration of nanobeams with simultaneous axial and spinning motions based on nonlocal strain gradient theory. Eng Comput. 38(3):2509-2526.
[16] Dehrouyeh-Semnani A M, Mostafaei H,  Nikkhah-Bahrami M (2016) Free flexural vibration of geometrically imperfect functionally graded microbeams. Int. J. Eng. Sci. 105(2):56-79.
[17] Liang F, Yang X D, Qian Y J, Zhang W (2018) Transverse free vibration and stability analysis of spinning pipes conveying fluid. IJMS 137(1):195-204.
[18] Dehrouyeh-Semnani A M, Nikkhah-Bahrami M,  Yazdi M R H (2017) On nonlinear stability of fluid-conveying imperfect micropipes. Int. J. Eng. Sci. 120(2):254-271.
[19] Xu W, Pan G, Khadimallah M A,  Koochakianfard O (2021) Nonlocal vibration analysis of spinning nanotubes conveying fluid in complex environments. Waves Random Complex Media 1-33. Doi: 10.1080/17455030.2021.1970283.
[20] Mamaghani A E, Khadem S E, Bab S (2016) Vibration control of a pipe conveying fluid under external periodic excitation using a nonlinear energy sink. Nonlinear Dyn., 86(3):1761-1795
[21] Ebrahimi-Mamaghani A, Sotudeh-Gharebagh R, Zarghami R, Mostoufi N (2019) Dynamics of two-phase flow in vertical pipes.  J Fluids Struct. 87(1):150-173.
[22] Ebrahimi-Mamaghani A, Mostoufi N, Sotudeh-Gharebagh R, Zarghami R (2022) Vibrational analysis of pipes based on the drift-flux two-phase flow model. Ocean Eng. 249(1):139-165.
[23] Ebrahimi-Mamaghani A, Sotudeh-Gharebagh R, Zarghami R, Mostoufi N (2020) Thermo-mechanical stability of axially graded Rayleigh pipes. Mech. Based Des. Struct. Mach. 50(2):412-441.
[24] Ebrahimi-Mamaghani A, Forooghi A, Sarparast H, Alibeigloo A, Friswell  M I (2021) Vibration of viscoelastic axially graded beams with simultaneous axial and spinning motions under an axial load. Appl. Math. Model. 90(2):131-150.
[25] Afkhami Z, Farid M (2016) Thermo-mechanical vibration and instability of carbon nanocones conveying fluid using nonlocal Timoshenko beam model. JVC 22(2):604-618.
[26] Elaikh T E, Abed N M, Ebrahimi-Mamaghani A (2020) Free vibration and flutter stability of interconnected double graded micro pipes system conveying fluid.  Mater. Sci. Eng. 928(2):122-128.
[27] Lancaster P (2013) Stability of linear gyroscopic systems: A review. Linear Algebra Its Appl. 439(3):686-706.
[28] Banerjee JR, Su H (2004) Development of a dynamic stiffness matrix for free vibration analysis of spinning beams. Comput Struct. 82(5): 2189–2197.
[29] Sarparast H, Alibeigloo A, Borjalilou V, & Koochakianfard O (2022). Forced and free vibrational analysis of viscoelastic nanotubes conveying fluid subjected to moving load in hygro-thermo-magnetic environments with surface effects.  Arch. Civ. Mech. Eng., 22(4), 1-28.
 
[30] Lingling L, Ruonan M, & Koochakianfard O (2022). Size-dependent vibrational behavior of embedded spinning tubes under gravitational load in hygro-thermo-magnetic fields.  Proc Inst Mech Eng C J Mech Eng Sci, 09544062211068730.
[31] Zhou Z X, & Koochakianfard O (2022). Dynamics of spinning functionally graded Rayleigh tubes subjected to axial and follower forces in varying environmental conditions. EPJ Plus, 137(1), 1-35.
[32] Koochakianfard O, & Alibeigloo A (2022) Nonlocal vibration of nanobeam embedded in viscoelastic Pasternak foundation with longitudinal and rotational motions with surface effects, doi: 10.22060/MEJ.2022.21234.7407.
[33] Ebrahimi Mamaghani  A, & sarparast  H (2018). Target energy transfer from a doubly clamped beam subjected to the harmonic external load using nonlinear energy sink. JSFM, 8(4), 165-177. doi: 10.22044/jsfm.2018.6771.2571 (In Persian).
[34] Ebrahimi Mamaghani  A, Hosseini  R, Shahgholi M, & Sarparast H (2018). Free lateral vibration analysis of inhomogeneous beams under various boundary conditions. JSFM, 8(3), 123-135. doi: 10.22044/jsfm.2018.6350.2497 (In Persian).
Journal of Solid and Fluid Mechanics
Volume 12, Issue 4
September and October 2022
Pages 1-12

Files

Share

How to cite

Statistics