ISSN 2594-5327
68º Congresso da ABM — vol. 68, num.68 (2013)
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Abstract
Composite laminates display a complex behavior due to their microstructure, with a through-thickness variation of the displacement and stress fields dependent on the fiber orientation in each layer. Aiming to develop reduced-order numerical models mimicking the real response of composite structures, we investigate the capability and the accuracy of finite element analyses coupling layered shell and solid kinematics. This study represents the first step of a work with the goal of accurately matching stress evolution in regions close to possible impact locations, where delamination is expected to take place, with reduced computational costs. Close to such locations a three-dimensional space modeling is adopted, whereas in the remainder of the structure a less demanding shell modeling is chosen. To test the coupled approach, results of numerical simulations are presented for a quasistatically loaded cross-ply orthotropic plate, either simply supported or fully clamped along its boundary.
Composite laminates display a complex behavior due to their microstructure, with a through-thickness variation of the displacement and stress fields dependent on the fiber orientation in each layer. Aiming to develop reduced-order numerical models mimicking the real response of composite structures, we investigate the capability and the accuracy of finite element analyses coupling layered shell and solid kinematics. This study represents the first step of a work with the goal of accurately matching stress evolution in regions close to possible impact locations, where delamination is expected to take place, with reduced computational costs. Close to such locations a three-dimensional space modeling is adopted, whereas in the remainder of the structure a less demanding shell modeling is chosen. To test the coupled approach, results of numerical simulations are presented for a quasistatically loaded cross-ply orthotropic plate, either simply supported or fully clamped along its boundary.
Keywords
Composite laminates; Finite element simulations; Reduced order modeling; Solid-shell coupling.
Composite laminates; Finite element simulations; Reduced order modeling; Solid-shell coupling.
How to refer
Salerno, Gigliola;
Mariani, Stefano;
Corigliano, Alberto.
REDUCED ORDER MODELING OF COMPOSITE LAMINATES THROUGH SOLID-SHELL COUPLING
,
p. 2968-2977.
In: 68º Congresso da ABM,
São Paulo,
2013.
ISSN: 2594-5327
, DOI 10.5151/2594-5327-23346