TY - GEN
T1 - Buckling analysis of advanced grid stiffened composite cylinders
AU - Lim, Kang Hee
AU - He, Wei
AU - Guan, Zhi Dong
PY - 2014
Y1 - 2014
N2 - Advanced Grid Stiffened(AGS) composite cylindrical shells are widely used in aerospace industry. This study analyzes the buckling loads for various types of grid structures of AGS composite cylindrical shells. The grid structures are classified as Angle-grid, Iso-grid, Kagome-grid, Ortho-grid, Orthotropic-grid and the characteristics had been analyzed for each grid type. In this study, the various types of grid structure were designed that weight of the whole structure keeps a constant. Under the condition of constant-weight, design variables such as grid angle, number of the grid, h/t ratio of the grid were controlled, and buckling loads of the grid structures were analyzed. The results were analyzed for each type of grid and each design variable of the structures. This study was performed through finite element method and the accuracy of the analysis was verified by previous studies. Finally, buckling modes were analyzed with the thickness of the skin. The selection for the most appropriate design variables had been verified for each grid type and the result can be applied to the optimization of grid structure design, and is also very helpful for reducing the computational cost and obtaining optimization values more accurately.
AB - Advanced Grid Stiffened(AGS) composite cylindrical shells are widely used in aerospace industry. This study analyzes the buckling loads for various types of grid structures of AGS composite cylindrical shells. The grid structures are classified as Angle-grid, Iso-grid, Kagome-grid, Ortho-grid, Orthotropic-grid and the characteristics had been analyzed for each grid type. In this study, the various types of grid structure were designed that weight of the whole structure keeps a constant. Under the condition of constant-weight, design variables such as grid angle, number of the grid, h/t ratio of the grid were controlled, and buckling loads of the grid structures were analyzed. The results were analyzed for each type of grid and each design variable of the structures. This study was performed through finite element method and the accuracy of the analysis was verified by previous studies. Finally, buckling modes were analyzed with the thickness of the skin. The selection for the most appropriate design variables had been verified for each grid type and the result can be applied to the optimization of grid structure design, and is also very helpful for reducing the computational cost and obtaining optimization values more accurately.
KW - Advanced grid stiffened structure
KW - Buckling load
KW - Composite cylinder
KW - Grid structure
UR - https://www.scopus.com/pages/publications/84896294410
U2 - 10.4028/www.scientific.net/AMR.875-877.755
DO - 10.4028/www.scientific.net/AMR.875-877.755
M3 - 会议稿件
AN - SCOPUS:84896294410
SN - 9783037859933
T3 - Advanced Materials Research
SP - 755
EP - 762
BT - Material Research and Applications
PB - Trans Tech Publications
T2 - 2012 International Conference on Advanced Material and Manufacturing Science, ICAMMS 2012
Y2 - 20 December 2012 through 21 December 2012
ER -