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Influence of Fiber Angle on Steady-State Response of Laminated Composite Rectangular Plates

Ahmad Saood, Arshad Khan, Md. Israr Equbal, Kuldeep K. Saxena, Chander Prakash, Nikolai Vatin, Saurav Dixit

2022Materials40 citationsDOIOpen Access PDF

Abstract

Significant advances in the field of composite structures continue to be made on a variety of fronts, including theoretical studies based on advances in structural theory kinematics and computer models of structural elements employing advanced theories and unique formulations. Plate vibration is a persistently interesting subject owing to its wider usage as a structural component in the industry. The current study was carried out using the Co continuous eight-noded quadrilateral shear-flexible element having five nodal degrees of freedom, which is ground on first-order shear deformation theory (FSDT). For small strain and sufficiently large deformation, the geometric nonlinearity is integrated using the Von Kármán assumption. The governing equations in the time domain are solved employing the modified shooting technique along with an arc-length and pseudo-arc-length continuation strategy. This work explored the effect of fiber angle on the steady-state nonlinear forced vibration response. To explain hardening nonlinearity, the strain and stress fluctuation throughout the thickness for a rectangular laminated composite plate is determined. The cyclic fluctuation of the steady-state nonlinear normal stress during a time period at the centre of the top/bottom surfaces is also provided at the forcing frequency ratio of peak amplitude in a nonlinear response. Because of the variation in restoring forces, the frequency spectra for all fiber angle orientations show significantly enhanced harmonic participation in addition to the fundamental harmonic.

Topics & Concepts

Nonlinear systemVibrationMaterials scienceQuadrilateralPlate theoryComposite numberMechanicsStructural engineeringShear (geology)StiffnessHarmonic balanceFrequency responseOrthotropic materialFinite element methodComposite materialPhysicsEngineeringAcousticsQuantum mechanicsElectrical engineeringComposite Structure Analysis and OptimizationVibration and Dynamic AnalysisStructural Analysis and Optimization
Influence of Fiber Angle on Steady-State Response of Laminated Composite Rectangular Plates | Litcius