In-Situ Cure-Induced Strain Measurements Using Optical Fiber Bragg Gratings for Residual Stress Determinations in Thermosets

Lars P. Mikkelsen*, Jesper K. Jørgensen, Ulrich A. Mortensen, Tom L. Andersen

*Corresponding author for this work

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Abstract

A small experimental setup for in-situ measurement of the load-transferring strains during the curing process of thermosets is proposed. Combining the output from an unconstrained and a kinematically constrained setup, it is possible to design a cure profile for the first time, lowering the residual stresses in the final product while keeping the cure time short based on the output from a few simple experiments. The stress relaxation during the curing process under a kinetically constrained condition is accounted for by comparing the final cure-induced strain during a kinetically unconstrained and constrained cure experiment. The constrained polymer is curing between two laminates where the constraining layer is removed after finalizing the cure profile, making it possible to measure the final cure-induced strain for that case as well. The temperature at which the load-transferring point is reached is found to be a key process parameter from which the final cure-induced strains can be predicted for the unconstrained case. From the corresponding constrained cure experiments, the final residual stresses can be measured.
Original languageEnglish
Article number3
JournalSolids
Volume6
Issue number1
Number of pages22
ISSN2673-6497
DOIs
Publication statusPublished - 2025

Keywords

  • Load-transfer strain
  • FBG-sensor
  • Cure shrinkage
  • Composites
  • Manufacturing
  • Wind turbine blades

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