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Your search keyword '"Fariborz, S. J."' showing total 18 results
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18 results on '"Fariborz, S. J."'

1. Transient in-plane analysis of cracked general orthotropic planes.

Author

Sadeghi, J., Vafa, J. P., and Fariborz, S. J.

Subjects
NUMERICAL solutions to integral equations, EDGE dislocations, SURFACE cracks, DISLOCATION density, IMPACT loads
Abstract

An edge dislocation with a time-dependent Burgers vector in an orthotropic plane is analyzed. The stress field caused by a dynamic point force in the intact plane is determined. The displacement discontinuity of dislocation and direction of point load are at arbitrary angles with the Material Principal Axes (MPA), the general orthotropic plane. The density of dislocations is employed to construct integral equations for orthotropic planes weakened by several interacting cracks, making arbitrary angles with the MPA. The numerical solution of integral equations results in the density of dislocations on a crack surface. The results are employed to determine time-dependent Stress Intensity Factors (SIFs) at the tips of a crack and Crack Opening Displacement (COD). In the problem of general orthotropic planes containing cracks subjected to dynamic loads, crack orientations may cause their partial/total closing. Under the hypothesis of frictionless contact, we devise an iterative procedure to handle crack closing, as well. By contrast to cracks in the directions of MPA, expressions for the two modes of SIFs contain the density functions of both the climb and glide of the edge dislocation. Therefore, mode I SIF at an open tip of a crack may not be positive. Conversely, positive mode I SIF may occur at a closed crack tip. Numerical results of the SIFs and COD for several examples of orthotropic planes under dynamic point loads, while weakened by single and double parallel cracks, are presented. Moreover, in double cracks cases, the interaction between cracks is studied. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Cracked layers on flexible foundation under Low-Velocity moving Patch-Loads.

Author

Sadeghi, J., Vafa, J. P., and Fariborz, S. J.

Subjects
EDGE dislocations, ELASTIC analysis (Engineering), SURFACE cracks, LIVE loads, ENERGY dissipation
Abstract

The analysis of an intact elastic layer resting on a flexible foundation subjected to patch-loads moving with a constant velocity, on the layer-free boundary, is carried out. Structural energy dissipation is modeled by viscous damping. Quasi-static analysis of edge dislocation is accomplished. Based on these solutions, integral equations are derived for a crack perpendicular to the boundary of layers under moving patch-loads. Dynamic excitation may partially/completely close the crack surface. Crack closing, in the absence of friction, is taken into account. The effects of load velocity and energy dissipation on crack stress intensity factors and opening displacement are investigated. [ABSTRACT FROM AUTHOR]

Published
2024
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11. A higher-order micro-beam model with application to free vibration.

Author

Noori, J., Fariborz, S. J., and Vafa, J. P.

Subjects
*GIRDERS, *FREE vibration, *STRAINS & stresses (Mechanics), *BERNOULLI-Euler method, *DIFFERENTIAL equations
Abstract

The free vibration of micro-beams is analyzed employing three different beam models. The previously obtained equations of motion for Bernoulli–Euler and Timoshenko models are solved analytically. A higher-order model is devised, which satisfies the lateral boundary conditions of micro-beams. The equations of motion with associated boundary conditions are derived by means of Hamilton's principle. The generalized differential quadrature method is used for the solution of the equations. The first five natural frequencies are obtained for micro-beams with three length-scale parameter/height ratios and five different boundary conditions. [ABSTRACT FROM PUBLISHER]

Published
2016
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18. A higher-order shell model applied to shells with mixed boundary conditions

Author

Yaghoubshahi, M, Asadi, E, and Fariborz, S J

Abstract

By means of the principle of virtual work, the governing equations together with the required boundary conditions of a higher-order shear deformation theory are formulated for the analysis of laminated shells under static loads. A system of 31 first-order partial differential equations is performed for the determination of stress resultants and displacement components. These equations are then solved numerically, utilizing the generalized differential quadrature method for two isotropic cylindrical panels with equal arc length but different radii having S2-type simply supported boundary conditions. The results matched those of other theories. Another analysis is carried out for composite cylindrical panels with two lamination schemes, five different mixed boundary conditions, and two length-to-thickness ratios. The results are compared against solutions obtained from ANSYS finite-element software.

Published
2011
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