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Experimental and numerical investigation of process-induced deformations of glass/epoxy wind turbine blade spar cap

Ammasai Sengodan, G; Joshi, SC; Chen, Z

Authors

SC Joshi

Z Chen



Abstract

A scaled, 7.5-mm thick, unidirectional glass/epoxy wind turbine spar cap cured in a vacuum-assisted oven was found to have attained non-uniform thickness along its length. Edge deformations were severe, leading to noticeable edge curvature even at the vacuum pressure. These unforeseen discrepancies could only be predicted and/or dealt beforehand through a process simulation that integrates the complete processing physics. A fully coupled numerical simulation of composites manufacturing was established and implemented for a portion of a spar cap in multiphysics finite element software. Phenomena such as resin flow-induced compaction and cure-induced deformation were captured. The simulation results indicated that even though the distorted edge of the laminate is trimmed off, there will still be some curvature left within the part. It was noted that simulating percolation flow of resin alone leads to less accurate deformation predictions. Therefore, a method to include shear flow-induced deformation of the resin-saturated fiber beds were proposed and implemented. Such a fully coupled and integrated procedure is useful for optimizing process parameters to achieve intended final part with accurate dimensions and minimal manufacturing-induced defects or deformities.

Citation

Ammasai Sengodan, G., Joshi, S., & Chen, Z. (2017). Experimental and numerical investigation of process-induced deformations of glass/epoxy wind turbine blade spar cap. Journal of Composite Materials, 51(27), https://doi.org/10.1177/0021998317693909

Journal Article Type Article
Online Publication Date Feb 14, 2017
Publication Date Feb 14, 2017
Deposit Date Sep 28, 2022
Journal Journal of Composite Materials
Print ISSN 0021-9983
Publisher SAGE Publications
Volume 51
Issue 27
ISBN 1530793X-00219983
DOI https://doi.org/10.1177/0021998317693909
Publisher URL https://doi.org/10.1177/0021998317693909