A consistent co-rotational formulation for aerodynamic nonlinear analysis of flexible frame structures

TL;DR

This paper introduces a novel co-rotational formulation for accurately analyzing aerodynamic forces on flexible frame structures experiencing large displacements and rotations, validated through numerical examples including wind turbine simulations.

Contribution

It presents a new consistent co-rotational approach combining quasi-steady theory and virtual work principles for fluid-structure interaction analysis.

Findings

Accurate computation of aerodynamic forces for large displacements.

Validated against analytic solutions and lumped mass approaches.

Effective in complex wind turbine analysis.

Abstract

The design of structures submitted to aerodynamic loads usually requires the development of specific computational models considering fluid-structure interactions. Models using structural frame elements are developed in several relevant applications such as the design of advanced aircraft wings, wind turbine blades or power transmission lines. In the case of flexible frame structures submitted to fluid flows, the consistent computation of inertial and aerodynamic forces for large displacements is a challenging task. In this article we present a novel formulation for the accurate computation of aerodynamic forces for large displacements and rotations using the co-rotational approach, the quasi-steady theory and the principle of virtual work. This formulation is coupled with a reference consistent co-rotational formulation for computing internal and inertial forces, providing a unified set of nonlinear balance equations. A numerical resolution procedure is proposed and implemented within the open-source library ONSAS. The proposed formulation and its implementation are validated through the resolution of five examples, including a realistic wind turbine analysis problem. The results provided by the proposed formulation are compared with analytic solutions and solutions obtained using a lumped mass approach. The proposed formulation provides accurate solutions for challenging numerical problems with large displacements and rotations.