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Publications (6/6 displayed)
- 2018Maximization of fundamental frequency of layered composites using differential evolution optimizationcitations
- 2013A study of a microstructure-dependent composite laminated Timoshenko beam using a modified couple stress theory and a meshless methodcitations
- 2013Static Deformations and Vibration Analysis of Composite and Sandwich Plates Using a Layerwise Theory and a Local Radial Basis Functions-Finite Differences Discretizationcitations
- 2005Free vibration analysis of symmetric laminated composite plates by FSDT and radial basis functionscitations
- 2004Radial basis functions and higher-order shear deformation theories in the analysis of laminated composite beams and platescitations
- 2003Analysis of composite plates using higher-order shear deformation theory and a finite point formulation based on the multiquadric radial basis function methodcitations
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article
A study of a microstructure-dependent composite laminated Timoshenko beam using a modified couple stress theory and a meshless method
Abstract
A modified couple stress theory and a meshless method are used to study the bending of simply supported laminated composite beams subjected to transverse loads. The Timoshenko beam kinematics are employed to model the beam, by a modified couple stress theory. The governing equations for the Timoshenko beam are solved numerically using a meshless method based on collocation with radial basis functions. The numerical method is easy to implement and provides accurate results that are in excellent agreement with the analytical solutions. Moreover, the results show that the present model can capture the effects of the microstructure.