Static strength and fatigue life of pinned hybrid titanium-composite single-lap-shear joints
Christoph Kralovec, Andreas Dengg, Martin Schagerl, Arne Schiller, Chiara Bisagni, Miriam Löbbecke, Jan Haubrich, Robert Hanelt
Abstract
Modern aircraft structures consist of a multi-material mix, dominated by high-performance composites, but also including metal alloys, e.g., for load introduction parts. This experimental research investigates the static and fatigue strength of pinned hybrid titanium-composite single-lap-shear joints. The Ti6Al4V adherend is manufactured by laser powder bed fusion. The joining is done by co-curing with the carbon fiber reinforced polymer adherend. The static tests focus on damage initiation and ultimate load, and are benchmarked by identical joints without pins. The fatigue tests focus on damage initiation and propagation. Digital image correlation is used for damage monitoring. Results show, (i) a high ratio of static ultimate failure to damage initiation load, (ii) early low-cycle damage initiation but then long high-cycle fatigue life until failure, and (iii) the crack stopping effect of the interlocking pins. Furthermore, visual joint failure analysis reveals a variety of damage modes, suggesting comprehensive testing and proper pin design. • Design and manufacturing details of considered pinned hybrid titanium-composite single-lap-shear joint are presented. • A high static ultimate load relative to static damage initiation load is demonstrated and attributed to the interlocking pin array using benchmark joints. • A high-cycle fatigue life after low-cycle damage initiation is found, characterized and attributed to the interlocking pin array by means of continuous digital image correlation-based damage monitoring. • A variety of load and damage size dependent damage modes are revealed by visual joint failure analysis.