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High-Fidelity Aerostructural Gradient Computation Techniques with Application to a Realistic Wing Sizing

Authors
  • Achard, Timothée
  • Blondeau, Christophe
  • Ohayon, Roger
Publication Date
Nov 01, 2018
Source
Kaleidoscope Open Archive
Keywords
Language
English
License
Unknown
External links

Abstract

Aerostructural optimization is a keystone process to concurrently improve aerodynamic performance and reduce the structural mass of an aircraft. However, gradient-based multidisciplinary design optimization is efficient only if the computation of gradients is fast and accurate. To this end, we propose two high-fidelity aerostructural gradient computation techniques for strongly coupled aeroelastic systems. In the specific context of this work, we focus on design variables affecting structural stiffness only. Scalar objective functions like aerodynamic performance criteria are considered, as well as a field of structural grid forces. The most intrusive technique includes well-established direct and adjoint formulations that require substantial implementation effort. In contrast, we propose an alternative uncoupled non-intrusive approach easier to implement and yet capable of providing accurate gradient approximations. The accuracy of these methods is first demonstrated on the ONERA M6 Wing test-case. Their efficiency and applicability are then illustrated via a mass minimization problem applied to the Common Research Model (CRM). Both methods lead to very similar optimal designs and the detailed analysis of results promotes the non-intrusive approach as a promising gradient computation alternative.

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