Analysis of the performance of a new concept for automatic draping of wide reinforcement fabrics with pre-shear: A virtual prototyping study

Christian Krogh; Peter H Broberg; Sebastian M Hermansen; Asbjørn M Olesen; Brian L V Bak; Esben Lindgaard; Erik Lund; Jørgen Kepler; Johnny Jakobsen

doi:10.1016/j.heliyon.2023.e20263

Analysis of the performance of a new concept for automatic draping of wide reinforcement fabrics with pre-shear: A virtual prototyping study

Heliyon. 2023 Sep 22;9(10):e20263. doi: 10.1016/j.heliyon.2023.e20263. eCollection 2023 Oct.

Authors

Christian Krogh¹, Peter H Broberg^{1

2}, Sebastian M Hermansen¹, Asbjørn M Olesen^{1

2}, Brian L V Bak^{1

2}, Esben Lindgaard^{1

2}, Erik Lund¹, Jørgen Kepler¹, Johnny Jakobsen¹

Affiliations

¹ Department of Materials and Production, Aalborg University, Fibigerstraede 16, 9220 Aalborg, Denmark.
² CraCS Research Group (cracs.aau.dk), Aalborg University, Fibigerstræde 16, 9220 Aalborg, Denmark.

Abstract

The layup process of large composite structures made from dry reinforcement fabrics is considered. One such structure is a wind turbine blade, for which the current draping process is mostly manual. Automating the draping process will, therefore, lower the costs. Based on a literature review, a new concept is synthesized and analyzed using an advanced finite element model with rigid multi-body kinematics and a dedicated material model for the fabric. The material model is calibrated using experimental coupon tests, i.e. the bias-extension test (shear) and Peirce's cantilever test (out-of-plane bending). The concept is analyzed numerically by means of a simple parameter study and draping test cases on a flat mold as well as a general double-curved mold. The simulation results show that the concept is feasible for the draping operation and is thus qualified for the subsequent physical prototyping.

Keywords: Draping; Finite element modeling; Glass fiber fabric; Laminated composites; Wind turbine blades.