LOW-VELOCITY IMPACT OF COMPOSITE SANDWICH PLATE WITH FACESHEET INDENTATION DESCRIPTION
DOI:
https://doi.org/10.11113/jt.v77.6383Keywords:
Composite sandwich plate, honeycomb core, low-velocity impact, indentation, strain failureAbstract
Composite sandwich structures are applied in many engineering fields due to their high strength and stiffness but lightweight properties. There are currently not many studies that simultaneously consider both indentation and strain failure in the composite sandwich plate especially in presence of impact loading. Such knowledge is necessary to determine the facesheet strain after impact in order to find out whether the facesheet is totally failed as a result of indentation deformation. Hence, the purpose of this study is to model numerically the top facesheet indentation and strain failure of a fixed-end composite sandwich plate with honeycomb core when it is subjected to low-velocity impact at the center. The faceheets are made from Hercules AW193-PW prepreg consisting of AS4 fibers in a 3501-6 matrix (carbon/epoxy) with a stacking sequence of [0/90]. The honeycomb core is made from HRH 10 1/8-3.0 Nomex honeycomb (Ciba-Geigy). Type of the impactor used in this study is flat-ended cylinder, which is made from case-hardened steel. The composite sandwich plate is modeled as a two-dimensional problem with five and three degrees of freedom per node for the facesheets and honeycomb core, respectively. Only the stiffness matrix, [K], and the mass matrix, [M], are considered in determining the responses of the plate. Responses in terms of indentation, strain failure and displacement are explored for various facesheet and core properties. It is found that an increase in number of ply and ply thickness reduce the indentation on the top facesheet. Also, the most effective parameter in improving the strain failure of the top facesheet is the crushing resistance of the core.
References
Kueh, A. B. H., Seh, W. W., Shek, P. N., Tan, C. S. and Tahir, M.M. 2011. Maximum Local Thermal Effects Carpet Plot For Symmetric Laminated Composite Plates. Advanced Materials Research. 250: 3748-3751.
Kueh, A. B. H. 2013. Buckling of Sandwich Columns Reinforced By Triaxial Weave Fabric Composite Skin-Sheets. International Journal of Mechanical Sciences. 66: 45-54.
Chai, G. B. and Zhu, S. 2011. A Review Of Low-Velocity Impact On Sandwich Structures. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials Design and Applications. 225(4): 207-230.
Hosseini, M. and Khalili, S. M. R. 2013. Analytical Prediction Of Indentation And Low-Velocity Impact Responses Of Fully Backed Composite Sandwich Plates. Journal of Solid Mechanics. 5: 278-289.
Meidell, A. 2009. Minimum Weight Design Of Sandwich Beams With Honeycomb Core Of Arbitrary Density. Composites: Part B. 40: 284-291.
Abdolrahim, N., Liaghat, G. and Askari, H. A. 2008. Experimental Study Of Low Velocity Impact On Sandwich Panels With Honeycomb Core And Comparison With F.E.M Results. 13th European Conference of Composite Materials, Stockholm, Sweden. 2-5 June 2008.
Foo, C. C., Seah L. K. and Chai, G. B. 2007. A Model To Predict Low-Velocity Impact Response And Damage In Sandwich Composites. Composite Science and Technology. 68: 1348-1356.
Williamson, J. E. and Lagace, P. A. 1993. Response Mechanism In The Impact Of Graphite/Epoxy Honeycomb Sandwich Panels. American Society for Composites: Technical Conference. 287-297.
Hoo Fatt, M. S. and Park, K. S. 2001. Dynamic Models For Low-Velocity Impact Damage Of Composite Sandwich Panels Part B: Damage Initiation. Composite Structure. 52: 353-364.
Ju, J., Summers, J. D., Ziegert, J. and Fadel, G. 2012. Design of Honeycombs For Modulus And Yield Strain In Shear. Journal of Engineering Materials and Technology. 134(1): 1-15.
Abo Sabah, S. H. and Kueh, A. B. H. 2014. Finite Element Modeling Of Laminated Composite Plates With Locally Delaminated Interface Subjected To Impact Loading. The Scientific World Journal. Article ID 954070.
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