An improved understanding of the structural behavior of a composite bolted joint can yield weight and cost savings by enabling the designer to eliminate any unnecessary conservatism.Software tools for the design and analysis of large scale structural bolted joint assemblies of composite laminates are required to be robust, accurate and computationally efficient models to be useful in a military or commercial design environment.The proposed approach applies multi-fidelity modeling to manage the computational expense of solving these complex and challenging problems. A set of validated analysis tools will be developed by the investigators, combining various simulation approaches such as 3D FEA models, shell-based models with spring and gap elements to replace bolt connections and calibrated analytical models for nonlinear spring and gap element type models. Damage induced compliance changes in the laminate and its effect on the load redistribution among the fasteners will also be captured in the modeling toolset. In addition these analytical tools will be utilized to investigate the use of metallic foil reinforcements around bolt holes for predicting the failure behavior of multi-row bolted composite joints of hybrid materials such as carbon fiber laminates with interspersed stainless steel or titanium foil layers.Bolted composite joint,Multi-fidelity modeling,Hybrid metal and composite laminate,Bolted joint failure modes,surrogate model
