Due to their remarkable characteristics, laminated composite shells and plates are commonly found in various engineering fields such as mechanical, civil, aerospace, marine, and automotive applications. Composite shells and plates of varying thickness are widely used in different industries due to their light weight and compact design.
Recent studies have focused on the dynamic characteristics of these materials, and meshfree methods have attracted significant attention from researchers.
Kwak Song Hun, a researcher at the Faculty of Mechanical Science and Technology, has proposed a meshfree Jacobi point interpolation (MJPI) approach for the dynamic analysis of sandwich laminated conical and cylindrical shells with varying thickness.
First, he established theoretical formulations for sandwich laminated shells with varying thickness using the modified variational principle within the framework of first-order shear deformation theory (FSDT). Then, he expanded the displacement components of the sandwich shell using the MJPI shape function and Fourier series in the meridional and circumferential directions, respectively.
He verified the accuracy and reliability of the proposed MJPI shape function through the comparison with the numerical results from published literature and the commercial simulation tool Abaqus. Finally, he investigated the effects of different parameters such as thickness gradient, thickness power index and boundary condition on the free vibration and dynamic response of the sandwich laminated shell.
For more information, you can refer to his paper “A Meshfree Approach for Dynamic Analysis of Sandwich Conical and Cylindrical Shells with Varying Thicknesses” in “Acta Mechanica Solida Sinica” (SCI).
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