Numerical investigation of structural geometric nonlinearity effect in high-aspect-ratio wing using CFD/CSD coupled approach

摘要

An efficient and robust fluid-structure coupled methodology has been developed to investigate the linear and non-linear static aeroelastic behavior of flexible high-aspect-ratio wing. A three-dimensional open source finite element solver has been loosely coupled with an in-house Reynolds-averaged Navier-Stokes solver, designed for hybrid-unstructured meshes, to perform aero-structural coupled simulations. For volume mesh deformation and two-way data interpolation over non-matching grids interface, a radial basis function methodology combined with a data reduction algorithm has been used. This technique is efficient in handling large deflections and provides high-quality deformed meshes. Structural geometric nonlinearity has been considered to predict the deformations in the vertical and torsional directions caused by gravitational and aerodynamic loading. A multi-material finite element model has been generated to match the experimental configuration. Computational aeroelastic simulations were performed on an experimental high-aspect-ratio aeroelastic wing model with a slender body at the tip to get non-linear static deflections, twist and structure natural frequencies. The effect of the geometric nonlinearity is significant for large deformation analysis and has been high-lighted in the predicted maximum tip deflection and twist. Good qualitative and quantitative agreement has been achieved between the predicted results and the available experimental data.