Development of Flexible Tooling for Deformation Sensing Applied to Composite Materials Fabrication Process

Ariana F. Zelaya Matamoros; Daniel Maldonado-Hurtado; Juan Antonio García-Manrique; Philippe Causse; Salvador Sales

doi:10.4028/p-9Z6yJh

Paper Titles

Preface

Development of Flexible Tooling for Deformation Sensing Applied to Composite Materials Fabrication Process
p.3

Tribological Analysis and Operation Issues of SiO₂ Nanolubricants for MQL Machining Operations
p.11

Dimensional Analysis of the Wear of 3D Printed Dies Used to Form PC and PVC Sheets by Thermoforming
p.21

Analysis of Printing Parameters for Sheet Metal Bending with FDM Printed Tools
p.29

Development of a Low Cost Extrusion Based 3D Printer for High Performance Engineering Polymers
p.37

Metrological Assessment of Microtextured EDM Electrodes Generated by Additive Manufacturing and Electroforming
p.47

Thermal Error Compensation Strategy in Simultaneous Laser Multilateration for Volumetric Verification
p.57

Laser Profilometry Application in Welding Geometrical Characterization
p.65

HomeKey Engineering MaterialsKey Engineering Materials Vol. 960Development of Flexible Tooling for Deformation...

Development of Flexible Tooling for Deformation Sensing Applied to Composite Materials Fabrication Process

Abstract:

Among the existing techniques for composite materials manufacturing, Vacuum Assisted Resin Infusion (VARI) is a liquid composite molding (LCM) process where resin flows through a dry fiber preform to fully impregnate it. This method uses flexible film sealed onto a rigid mold to form the infusion cavity containing the fibers. As the fabric preform is impregnated, its thickness varies due to the changes in the applied compaction pressure. This thickness variation affects the resin flow and the final fiber volume fraction of the manufactured part. This study focuses on the initial steps of developing an integrated acquisition system for thickness variation monitoring during VARI. The conventional flexible tooling is to be replaced by a flexible membrane equipped with optical fiber Bragg grating (FBG) sensors. A prototype was developed by embedding FBG sensors in a silicon rubber material and initial measurements of a cylindrical profile curvature were performed. Preliminary results show satisfactory precision of the device, which opens a gap for a more precise and accurate thickness monitoring process during real part manufacturing.

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Periodical:

Key Engineering Materials (Volume 960)

Pages:

3-10

DOI:

https://doi.org/10.4028/p-9Z6yJh

Citation:

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Online since:

October 2023

Authors:

Ariana F. Zelaya Matamoros*, Daniel Maldonado-Hurtado, Juan Antonio García-Manrique, Philippe Causse, Salvador Sales

Keywords:

Fiber Brag Grating, Liquid Composite Molding, Soft Membrane

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References

[1] N.C. Correia, F.R., A.C. Long, C.D. Rudd, P. Simacek, S.G. Advani, Analysis of the vacuum infusion moulding process: I. Analytical formulation, Composites Part A: Applied Science and Manufacturing (2005) 1645-1656.