Journal of the Japan Society for Composite Materials Volume 13, Issue 5

Stiffness Optimization of Laminated Composite Plates and Shells Based upon Netting Theory

The present paper treats the optimal design problems of laminated composite plates and shells based upon the netting theory in which the stiffnesses other than the longitudinal Young's modulus are neglected. Some stiffness characteristics are examined, that is, the vibration and buckling characteristics of laminated composite plates and the buckling characteristics of laminated composite cylindrical shells. Optimal laminate configurations for the vibration and the buckling are also obtained by using the netting theory and compared with the results based upon the lamination theory. Applicability and limitation of the netting theory to the laminated plates and shells are verified through the numerical examples.

An Experimental Study of Interlaminar Toughness of Satin Woven Fabric Composite

An experimental study is done on the interlaminar fracture toughness of GFRP (Glass/Polyester) and CFRP (Carbon/Epoxy) satin woven fabric composites. Both fracture toughnesses G_Ic and G_IIc are measured by the use of DCB (Double Cantilever Beam) and ENF (End Notched Flexure) specimens, respectively. The fracture toughnesses in thread and wart direc-tions are also measured to study its dependency on the direction of the crack propagation. As expected, G_IIc is found higher than G_Ic for both GFRP and CFRP. The DCB experiment shows that the fracture toughness G_Ic to initiate the crack propagation is much higher than the dynamic one during the unstable crack propagation. So, unstable crack propagations are observed once the crack starts to propagate until the energy release rate drops significantly due to its propagation under the condition of constant deflection. Both G_Ic and G_IIc are found to depend on the direction of the crack propagation (parallel or transverse to thread direction).