We investigate the use of density-based topology optimization for the aeroelastic design of very flexible wings. This is achieved with a Reynolds-averaged Navier–Stokes finite volume solver, coupled to a geometrically nonlinear finite element structural solver, to simulate the large-displacement fluid-structure interaction. A gradient-based approach is used with derivatives obtained via a coupled adjoint solver based on algorithmic differentiation. In the example problem, the optimization uses strong coupling effects and the internal topology of the wing to allow mass reduction while maintaining the lift. We also propose a method to accelerate the convergence of the optimization to discrete topologies, which partially mitigates the computat...
The first part of this thesis presents the advances made in the Open-Source software SU2, towards t...
An algorithm for the structural optimization of wing body structures is presented in this paper. The...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/97076/1/AIAA2012-1922.pd
A strategy for density-based topology optimization of fluid-structure interaction problems is propos...
A previously developed density distribution-based structural topology optimization algorithm coupled...
Load-path-based topology optimization is used to synthesize a compliant adaptive aircraft wing leadi...
A series of novel algorithms for performing aerostructural shape and topology optimization are intro...
This paper presents a method for simultaneous optimization of the outer shape and internal topology ...
Topology optimization is the process of optimizing both the material layout and the connectivity ins...
This thesis presents new tools and techniques developed to address the challenging problem of high-f...
Several topology optimization problems are conducted within the ribs and spars of a wing box. It is ...
This work is funded by the Fixed Wing Project under NASA’s Fundamental Aeronautics Program.Peer revi...
This work considers the multi-objective aeroelastic optimization of a membrane micro air vehicle win...
Structural topology optimisation has been identified as the most challenging and economically reward...
The simultaneous optimization of aircraft shape and internal structural size for transonic flight is...
The first part of this thesis presents the advances made in the Open-Source software SU2, towards t...
An algorithm for the structural optimization of wing body structures is presented in this paper. The...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/97076/1/AIAA2012-1922.pd
A strategy for density-based topology optimization of fluid-structure interaction problems is propos...
A previously developed density distribution-based structural topology optimization algorithm coupled...
Load-path-based topology optimization is used to synthesize a compliant adaptive aircraft wing leadi...
A series of novel algorithms for performing aerostructural shape and topology optimization are intro...
This paper presents a method for simultaneous optimization of the outer shape and internal topology ...
Topology optimization is the process of optimizing both the material layout and the connectivity ins...
This thesis presents new tools and techniques developed to address the challenging problem of high-f...
Several topology optimization problems are conducted within the ribs and spars of a wing box. It is ...
This work is funded by the Fixed Wing Project under NASA’s Fundamental Aeronautics Program.Peer revi...
This work considers the multi-objective aeroelastic optimization of a membrane micro air vehicle win...
Structural topology optimisation has been identified as the most challenging and economically reward...
The simultaneous optimization of aircraft shape and internal structural size for transonic flight is...
The first part of this thesis presents the advances made in the Open-Source software SU2, towards t...
An algorithm for the structural optimization of wing body structures is presented in this paper. The...
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/97076/1/AIAA2012-1922.pd