Abstract
This paper introduces a novel approach to increasing the lap joint strength, different than the traditional methods of either increasing the lap joint area or changing the joint geometry. This is accomplished by the selective use of rubber toughening in epoxy to optimize lap joint strength. This was accomplished in three stages, in the first stage an adduct was prepared, this was used to make bulk tensile specimens to calculate the bulk properties for various concentrations of rubber, i.e. 0, 10 & 20 parts per hundred parts of resin (epoxy). In the second stage finite element models were developed using the bulk properties previously obtained. Interfacial stresses were used to access the trends obtained by the selective use of rubber toughening at different location of the overlap in different configurations. The modeling of adhesive joints was done using ALGOR 2-D, linear and nonlinear Finite Element Analyses (FEA). In the third stage, conducting tensile shear tests on the lap joints validated the trends from the finite element models.
Finite element modeling and meshing of the lap joints having 25.4 mm and 50.8 mm adhesive overlap lengths were completed. Different configurations of rubber toughened and untoughened adhesive were tried in these two overlaps. The validation was done by tensile lap joint tests conducted on an Instron mechanical tester coupled with an extensometer.
Comparable strengths were obtained for completely toughened overlap and the configuration where only the edges of the adhesive overlap were toughened and the region in-between was untoughened. Also, the nonlinear FEA was shown to represent the experimental results more closely than the linear approach.
New Method to Study The Effect of Stacking Sequence on Composite Single-Lap Joint Strength