STATIC AEROELASTIC STIFFNESS OPTIMIZATION OF A FORWARD SWEPT COMPOSITE WING WITH CFD CORRECTED AERO LOADS

Johannes K.S. Dillinger, Mostafa M. Abdalla, Yasser M. Meddaikar, Thomas Klimmek

DOI Number: N/A

Conference number: IFASD-2015-116

This paper presents an aero load correction strategy applicable to the static aeroelastic optimization of composite wings. The optimization framework consists of a successive convex subproblem iteration procedure, in which a gradient based optimizer consecutively solves a local approximation problem. Responses are approximated as a linear and/or reciprocal function of the laminate membrane and bending stiﬀness matrices A and D. Together with the laminate thicknesses h, they constitute the design variables in the optimization process. Internally, the design space is transformed from stiﬀness matrices to lamination parameters, resulting in a continuous and convex optimization problem. Structural responses considered in the stiﬀness optimization are strength, local buckling and mass; aileron eﬀectiveness, divergence, and twist constitute the aeroelastic responses. Steady aeroelastic loads are calculated with a doublet lattice method (DLM) embedded in the applied ﬁnite element solver, allowing for the generation of response sensitivities that incorporate the eﬀects of displacement-dependent, aeroelastic loads. To incorporate ﬂow phenomena that cannot be reproduced with DLM, a higher order aerodynamic method is considered. The developed correction methods and their application are presented in this paper. The correction is twofold, ﬁrstly aiming at a correction of DLM by means of camber and twist modiﬁcations applied directly to the doublet lattice mesh and secondly, by employing the capabilities of a higher order computational ﬂuid dynamics (CFD) solver, like the DLR-based TAU code. To this end, DLM loads transferred to the structure are rectiﬁed by means of the supposedly superior CFD results. The aero load correction method is applied in the stiﬀness optimization of a forward swept wing. First, a trim application without structural optimization is discussed, to demonstrate the convergence behavior of the correction forces. The results of a wing skin mass minimization with balanced and unbalanced laminates are presented. In particular, the diﬀerences between optimizations with and without aero correction are highlighted. Eventually, a stacking sequence optimization based on the continuous optimization results is demonstrated.

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Aeroelastic Constraints, CFD Correction, Composite, Doublet Lattice Method, Stacking Sequence Optimization, Stiﬀness Optimization

In Categories: 2. IFASD 2015, Aeroelastic Optimisation

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