This paper aims at the elastic buckling of multilayered thin-walled conical shells with power-law
distributed material properties under the axial load and lateral pressure based on the experimental study of palm
trunks. The material properties of the shells are assumed to vary continuously in the radial direction. Relations
and analytical approaches for linear buckling response are presented by using the layer-wise shell theory. The
buckling behaviors of the conical shells subjected to axial and transverse loads are investigated. Parametric study
in geometry (relative thickness, relative stiffness and cone angle) is performed to enhance the overall buckling
resistance and minimize the weight. Numerical results show the possibility to achieve larger load-carrying capacity
by simultaneously optimizing the material and geometric parameters based on the structure of palm trunks.
WU Lei1 (吴 磊), LIU Wangyu2* (刘旺玉), SU Zhangming2 (苏章明),WANG Ningling2 (汪宁陵), HUANG Jiale2 (黄家乐)
. Buckling Design of Conical Shells Based on Palm Trunks: Survey of Power-Law Distributed Thin-Walled Conical[J]. Journal of Shanghai Jiaotong University(Science), 2016
, 21(3)
: 313
-319
.
DOI: 10.1007/s12204-016-1727-y
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