Closed-form solution for the Timoshenko beam theory using a computer-based mathematical package

Abstract This paper investigates the influence of surface effects on free transverse vibration of piezoelectric nanowires (NWs). The dynamic model of the NW is tackled using nonlocal Timoshenko beam theory. By implementing this theory with consideration of both non-local effect and surface effect under simply support boundary condition, the natural frequencies of the NW are calculated. Also, a closed form solution is obtained in order to calculate fundamental buckling voltage. Finally, the effect of small scale effect on residual surface tension and critical electric potential is explored. The results can help to design piezo-NW based instruments.

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A closed-form solution for free vibration of multiple cracked Timoshenko beam and application

Vietnam Journal of Mechanics ◽

10.15625/0866-7136/9641 ◽

2017 ◽

Vol 39 (4) ◽

pp. 315-328

Author(s):

Nguyen Tien Khiem ◽

Duong The Hung

Keyword(s):

Free Vibration ◽

Closed Form ◽

Timoshenko Beam ◽

Crack Depth ◽

Closed Form Solution ◽

Beam Theory ◽

Frequency Equation ◽

Form Solution ◽

Mode Shapes ◽

Timoshenko Beams

A closed-form solution for free vibration is constructed and used for obtaining explicit frequency equation and mode shapes of Timoshenko beams with arbitrary number of cracks. The cracks are represented by the rotational springs of stiffness calculated from the crack depth. Using the obtained frequency equation, the sensitivity of natural frequencies to crack of the beams is examined in comparison with the Euler-Bernoulli beams. Numerical results demonstrate that the Timoshenko beam theory is efficiently applicable not only for short or fat beams but also for the long or slender ones. Nevertheless, both the theories are equivalent in sensitivity analysis of fundamental frequency to cracks and they get to be different for higher frequencies.

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Closure to “Closed‐Form Solution for Reinforced Timoshenko Beam on Elastic Foundation” by Jian‐Hua Yin

Journal of Engineering Mechanics ◽

10.1061/(asce)0733-9399(2001)127:12(1317.2) ◽

2001 ◽

Vol 127 (12) ◽

pp. 1317-1317

Author(s):

Jian‐Hua Yin

Keyword(s):

Closed Form ◽

Elastic Foundation ◽

Timoshenko Beam ◽

Closed Form Solution ◽

Form Solution ◽

Beam On Elastic Foundation

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Wave-Induced Vibrations of an Axial-Loaded Immersed Timoshenko Beam Carrying an Eccentric Tip Mass with Rotary Inertia

Journal of Ship Research ◽

10.5957/jsr.2010.54.1.15 ◽

2010 ◽

Vol 54 (01) ◽

pp. 15-33

Author(s):

Jong-Shyong Wu ◽

Chin-Tzu Chen

Keyword(s):

Closed Form ◽

Timoshenko Beam ◽

Forced Vibration ◽

Natural Frequencies ◽

Closed Form Solution ◽

Form Solution ◽

Rotary Inertia ◽

Mode Shapes ◽

Mode Superposition Method ◽

Tip Mass

Under the specified assumptions for the equation of motion, the closed-form solution for the natural frequencies and associated mode shapes of an immersed "Euler-Bernoulli" beam carrying an eccentric tip mass possessing rotary inertia has been reported in the existing literature. However, this is not true for the immersed "Timoshenko" beam, particularly for the case with effect of axial load considered. Furthermore, the information concerning the forced vibration analysis of the foregoing Timoshenko beam caused by wave excitations is also rare. Therefore, the first purpose of this paper is to present a technique to obtain the closed-form solution for the natural frequencies and associated mode shapes of an axial-loaded immersed "Timoshenko" beam carrying eccentric tip mass with rotary inertia by using the continuous-mass model. The second purpose is to determine the forced vibration responses of the latter resulting from excitations of regular waves by using the mode superposition method incorporated with the last closed-form solution for the natural frequencies and associated mode shapes of the beam. Because the determination of normal mode shapes of the axial-loaded immersed "Timoshenko" beam is one of the main tasks for achieving the second purpose and the existing literature concerned is scarce, the details about the derivation of orthogonality conditions are also presented. Good agreements between the results obtained from the presented technique and those obtained from the existing literature or conventional finite element method (FEM) confirm the reliability of the presented theories and the developed computer programs for this paper.

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