Multiscale bending and free vibration analyses of functionally graded graphene platelet/fiber composite beams
Multiscale bending and free vibration analyses of functionally graded graphene platelet/fiber composite beams
In the present work, bending and free vibration analyses of multilayered functionally graded (FG) graphene platelet (GPL) and fiber-reinforced hybrid composite beams are carried out using the parabolic function based shear
deformation theory. Parabolic variation of transverse shear stress across the thickness of beam and transverse shear stress-free conditions at top and bottom surfaces of the beam are considered, and the proposed formulation incorporates a transverse displacement field. The present theory works only with four unknowns and is computationally efficient. Hamilton's principle has been employed for deriving the governing equations. Analytical solutions are obtained for both the bending and free vibration problems in the present work considering different variations of GPLs and fibers distribution, namely, FG-X, FG-U, FG-A, , and FG-O for beams having simply-supported boundary condition. First, the matrix is assumed to be strengthened using GPLs, and then the fibers are embedded. Multiscale modeling for material properties of functionally graded graphene platelet/fiber hybrid composites (FGGPL/FHRC) is performed using Halpin-Tsai micromechanical model. The study reveals that the distributions of GPLs and fibers have significant impacts on the stresses, deflections, and natural frequencies of the beam. The number of layers and shape factors widely affect the behavior of FG-GPL-FHRC beams. The multilayered FG-GPL-FHRC beams turn out to be a good approximation to the FG beams without exhibiting the stress-channeling effects.
hybrid composite, bending, free vibration, graphene platelet, fiber composite, functionally graded material
707-720
Garg, A.
66fe6776-8e5b-4df4-bc81-c99b93b6acca
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Chalak, H.D.
74de1112-474b-40bd-b5e7-88a6306ba3f1
Belarbi, M.O.
0c5aeed5-017e-4507-82cd-0ecd8118333f
Li, L.
3de2a5ea-cc8a-4e17-a7b3-6cc2eb9adcd2
Sahoo, R.
77c3dac6-8c4c-496e-8f36-55102438321a
10 September 2022
Garg, A.
66fe6776-8e5b-4df4-bc81-c99b93b6acca
Mukhopadhyay, T.
2ae18ab0-7477-40ac-ae22-76face7be475
Chalak, H.D.
74de1112-474b-40bd-b5e7-88a6306ba3f1
Belarbi, M.O.
0c5aeed5-017e-4507-82cd-0ecd8118333f
Li, L.
3de2a5ea-cc8a-4e17-a7b3-6cc2eb9adcd2
Sahoo, R.
77c3dac6-8c4c-496e-8f36-55102438321a
Garg, A., Mukhopadhyay, T., Chalak, H.D., Belarbi, M.O., Li, L. and Sahoo, R.
(2022)
Multiscale bending and free vibration analyses of functionally graded graphene platelet/fiber composite beams.
Steel and Composite Structures, 44 (5), .
(doi:10.12989/scs.2022.44.5.707).
Abstract
In the present work, bending and free vibration analyses of multilayered functionally graded (FG) graphene platelet (GPL) and fiber-reinforced hybrid composite beams are carried out using the parabolic function based shear
deformation theory. Parabolic variation of transverse shear stress across the thickness of beam and transverse shear stress-free conditions at top and bottom surfaces of the beam are considered, and the proposed formulation incorporates a transverse displacement field. The present theory works only with four unknowns and is computationally efficient. Hamilton's principle has been employed for deriving the governing equations. Analytical solutions are obtained for both the bending and free vibration problems in the present work considering different variations of GPLs and fibers distribution, namely, FG-X, FG-U, FG-A, , and FG-O for beams having simply-supported boundary condition. First, the matrix is assumed to be strengthened using GPLs, and then the fibers are embedded. Multiscale modeling for material properties of functionally graded graphene platelet/fiber hybrid composites (FGGPL/FHRC) is performed using Halpin-Tsai micromechanical model. The study reveals that the distributions of GPLs and fibers have significant impacts on the stresses, deflections, and natural frequencies of the beam. The number of layers and shape factors widely affect the behavior of FG-GPL-FHRC beams. The multilayered FG-GPL-FHRC beams turn out to be a good approximation to the FG beams without exhibiting the stress-channeling effects.
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Published date: 10 September 2022
Keywords:
hybrid composite, bending, free vibration, graphene platelet, fiber composite, functionally graded material
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Local EPrints ID: 483844
URI: http://eprints.soton.ac.uk/id/eprint/483844
ISSN: 1229-9367
PURE UUID: 9dcdbb3e-0cd2-4d57-a3c2-2b77705066cf
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Date deposited: 06 Nov 2023 18:22
Last modified: 18 Mar 2024 04:10
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Contributors
Author:
A. Garg
Author:
T. Mukhopadhyay
Author:
H.D. Chalak
Author:
M.O. Belarbi
Author:
L. Li
Author:
R. Sahoo
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