Vallée, T.Keller, T.2007-06-222007-06-222007-06-22200610.1016/j.compositesb.2005.11.002https://infoscience.epfl.ch/handle/20.500.14299/9279WOS:0002366543000098453Quasi-static axial tension experiments were performed in a laboratory environment on epoxy bonded, balanced double-lap joints composed of pultruded GFRP flat profiles. The parameters investigated were the overlap length (from 50 to 100 mm), the adhesive layer thickness (I and 3 mm) and the degree of chamfering of the adherends. The measured axial strain profiles in the joints correlated well with numerical results obtained from a 2D finite element analysis. Failure initiation and propagation always occurred in the outer fiber-mat layers of the adherends. Charnfering reduced and smoothed the through-thickness tensile and shear stress peaks towards the chamfered joint edges. However, joint strength was not significantly improved by chamfering. The joint strength was predicted by means of a quadratic shear-tensile failure criterion for a failure location in the outer fiber-mat layer of the pultruided adherends and compared well to the measurements. The adhesive layer thickness had an insignificant influence on the stress-strain distributions along the overlaps and joint strengh. [All rights reserved Elsevier]AdhesivesFinite element analysisGlass fiber reinforcedplasticsStress-strain relationstext::journal::journal article::research article