Publication: Eigenfrequency optimization of variable stiffness manufacturable laminates using spectral chebyshev approach and lamination parameters
Program
KU-Authors
KU Authors
Co-Authors
Anamagh, Mirmeysam Rafiei
Shahabad, Peiman Khandar
Serhat, Gokhan
Bediz, Bekir
Advisor
Publication Date
Language
English
Type
Journal Title
Journal ISSN
Volume Title
Abstract
This study presents a meshless modeling approach to design variable-stiffness laminates considering manufacturing constraints. The governing equations are derived using lamination parameters and first-order shear deformation theory. The solution approach uses Chebyshev polynomials and Galerkin's method to obtain the discretized equations of motion. The developed framework was used to maximize the fundamental frequency of composite plates. The variable-stiffness designs provided up to 28.4% higher frequencies compared to optimum constant-stiffness laminates, although the actual level of improvement depends on the number of layers. Finally, manufacturable fiber paths were obtained considering the allowed fiber curvature, which can also reduce the frequency values.
Source:
Mechanics of Advanced Materials and Structures
Publisher:
Taylor & Francis
Keywords:
Subject
Materials science, multidisciplinary, Mechanics, Materials science, characterization and testing, Materials science, composites