Static, stability and dynamic analyses of second strain gradient elastic Euler–Bernoulli beams

A simplified second strain gradient Euler–Bernoulli beam theory with two non-classical elastic coefficients in addition to the classical constants is presented. The governing equation and the associated classical and non-classical boundary conditions are derived with the aid of variational principle...

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Published in:Acta mechanica 2021-04, Vol.232 (4), p.1425-1444
Main Authors: Ishaquddin, Md, Gopalakrishnan, S.
Format: Article
Language:English
Subjects:
Analysis
Beam theory (structures)
Boundary conditions
Cantilever beams
Classical and Continuum Physics
Control
Differential equations
Dynamic stability
Dynamical Systems
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Euler-Bernoulli beams
Exact solutions
Free vibration
Gaussian beams (optics)
Heat and Mass Transfer
Laplace transforms
Original Paper
Parameters
Phase velocity
Solid Mechanics
Stability analysis
Strain analysis
Theoretical and Applied Mechanics
Variational principles
Vibration
Wave propagation
Wavelengths
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Gopalakrishnan, S.
description A simplified second strain gradient Euler–Bernoulli beam theory with two non-classical elastic coefficients in addition to the classical constants is presented. The governing equation and the associated classical and non-classical boundary conditions are derived with the aid of variational principles. The simplified second strain gradient theory is governed by an eighth-order differential equation with displacement, slope, curvature and triple derivative of displacement as degrees of freedom. This theory can be reduced to the first strain gradient and classical Euler–Bernoulli beam theories. Analytical solutions for static behaviour, free vibration and stability analyses are presented for different boundary conditions and length scale parameters. Using the numerical Laplace transform, a spectral element is developed for dynamic analysis of a cantilever beam subjected to a Gaussian pulse. Further, spectrum and dispersion relations are derived to study wave propagation characteristics. The gradient effects on the structural response are assessed and compared with the corresponding first strain gradient and classical beam theories. Observations show that the second strain gradient theory exhibiting stiffer behaviour in comparison to the first strain gradient and classical theories. The beam deflection decreases whereas frequencies and buckling load increase for increasing values of the gradient coefficient in comparison to the first strain gradient and classical theories. The forced response for a finite beam reveals a decrease in the amplitude and a shift to smaller time values with an increase in the value of length scale parameter. Additionally, the second strain gradient beam shows a dispersive behaviour, and for a given frequency the wavenumber decreases and the phase speed increases with an increase in the length scale parameter as compared to the first strain gradient beam theory.
doi_str_mv 10.1007/s00707-020-02902-5
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Observations show that the second strain gradient theory exhibiting stiffer behaviour in comparison to the first strain gradient and classical theories. The beam deflection decreases whereas frequencies and buckling load increase for increasing values of the gradient coefficient in comparison to the first strain gradient and classical theories. The forced response for a finite beam reveals a decrease in the amplitude and a shift to smaller time values with an increase in the value of length scale parameter. 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Observations show that the second strain gradient theory exhibiting stiffer behaviour in comparison to the first strain gradient and classical theories. The beam deflection decreases whereas frequencies and buckling load increase for increasing values of the gradient coefficient in comparison to the first strain gradient and classical theories. The forced response for a finite beam reveals a decrease in the amplitude and a shift to smaller time values with an increase in the value of length scale parameter. 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The governing equation and the associated classical and non-classical boundary conditions are derived with the aid of variational principles. The simplified second strain gradient theory is governed by an eighth-order differential equation with displacement, slope, curvature and triple derivative of displacement as degrees of freedom. This theory can be reduced to the first strain gradient and classical Euler–Bernoulli beam theories. Analytical solutions for static behaviour, free vibration and stability analyses are presented for different boundary conditions and length scale parameters. Using the numerical Laplace transform, a spectral element is developed for dynamic analysis of a cantilever beam subjected to a Gaussian pulse. Further, spectrum and dispersion relations are derived to study wave propagation characteristics. The gradient effects on the structural response are assessed and compared with the corresponding first strain gradient and classical beam theories. Observations show that the second strain gradient theory exhibiting stiffer behaviour in comparison to the first strain gradient and classical theories. The beam deflection decreases whereas frequencies and buckling load increase for increasing values of the gradient coefficient in comparison to the first strain gradient and classical theories. The forced response for a finite beam reveals a decrease in the amplitude and a shift to smaller time values with an increase in the value of length scale parameter. Additionally, the second strain gradient beam shows a dispersive behaviour, and for a given frequency the wavenumber decreases and the phase speed increases with an increase in the length scale parameter as compared to the first strain gradient beam theory.</abstract><cop>Vienna</cop><pub>Springer Vienna</pub><doi>10.1007/s00707-020-02902-5</doi><tpages>20</tpages><oa>free_for_read</oa></addata></record>
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subjects Analysis
Beam theory (structures)
Boundary conditions
Cantilever beams
Classical and Continuum Physics
Control
Differential equations
Dynamic stability
Dynamical Systems
Engineering
Engineering Fluid Dynamics
Engineering Thermodynamics
Euler-Bernoulli beams
Exact solutions
Free vibration
Gaussian beams (optics)
Heat and Mass Transfer
Laplace transforms
Original Paper
Parameters
Phase velocity
Solid Mechanics
Stability analysis
Strain analysis
Theoretical and Applied Mechanics
Variational principles
Vibration
Wave propagation
Wavelengths
title Static, stability and dynamic analyses of second strain gradient elastic Euler–Bernoulli beams
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