Nonlinear finite element aeroelastic modelling of reinforced aircraft skin panels

Abstract

Panel flutter is an aeroelastic phenomenon that can cause critical structural failure in aerospace vehicles operating at supersonic speeds. A reliable modelling of such phenomenon is crucial for safely predicting the fatigue life of aerospace skin, thus being of great importance to structural design. Moreover, aircraft panels are typically composed of large plates which are internally reinforced by stringers, longerons and/or frames. The use of such stiffening elements ends up subdividing the panel into multiple cells which can interact during flutter, thereby potentially making the aeroelastic motion more complex and dangerous. In this context, the present work proposes the study and implementation of a computational finite element model for the study of nonlinear flutter in stiffened panels. The coupling of the Mindlin plate model and the Timoshenko beam model, both in geometrically nonlinear regime, is proposed. The model and the analyses will tackle both isotropic and laminated panels. The aerodynamic load will be computed through first-order piston theory, which provides good results for high-supersonic flows. (AU)