Abstract
Composite materials and especially those made from pre-impregnated (prepreg) material are widely used in the aerospace industry. To achieve the tight assembly dimensional tolerances required, manufacturers rely on additional manufacturing steps like shimming or machining, which generate extra waste, which are time-consuming and expensive. Prepreg sheets come naturally with fiber and resin volume content variability that leads manufacturers to guarantee cured ply thicknesses within a typical +/−5% margin of their nominal values. For thick laminates, this can equate to a thickness variability of as much as a few millimeter. To solve the issue, it is proposed to twin in situ laser measurements of the uncured prepreg thickness with numerical simulations of the laminate autoclave consolidation and cure process and to adjust the number of additional sacrificial plies in the laminate based on the model predictions. This reduces the need for expensive and time-consuming trial and error approaches, extra machining operations, and results in the production of a part with high accuracy dimensions. Data for IM7/8552 and IM7/977-3 are presented to demonstrate the potential of the method to reach an almost exact target thickness for flat panels.
Issue Section:
Research Papers
Topics:
Composite materials,
Fibers,
Laminates,
Resins,
Modeling,
Temperature,
Simulation,
Viscosity,
Manufacturing,
Lasers
References
1.
Hubert
, P.
, and Poursartip
, A.
, 1998
, “A Review of Flow and Compaction Modelling Relevant to Thermoset Matrix Laminate Processing
,” J. Reinf. Plast. Compos.
, 17
(4
), pp. 286
–318
. 2.
Sorba
, G.
, Binetruy
, C.
, Leygue
, A.
, and Comas-Cardona
, S.
, 2017
, “Squeeze Flow in Heterogeneous Unidirectional Discontinuous Viscous Prepreg Laminates: Experimental Measurement and 3d Modeling
,” Compos. Part A: Appl. Sci. Manuf.
, 103
, pp. 196
–207
. 3.
Engmann
, J.
, Servais
, C.
, and Burbidge
, A. S.
, 2005
, “Squeeze Flow Theory and Applications to Rheometry: A Review
,” J. Non-Newtonian Fluid Mech.
, 132
(1
), pp. 1
–27
. 4.
Hubert
, P.
, and Poursartip
, A.
, 2001
, “Aspects of the Compaction of Composite Angle Laminates: An Experimental Investigation
,” J. Compos. Mater.
, 35
(1
), pp. 2
–26
. 5.
Lightfoot
, J. S.
, Wisnom
, M. R.
, and Potter
, K.
, 2013
, “A New Mechanism for the Formation of Ply Wrinkles Due to Shear Between Plies
,” Compos. Part A: Appl. Sci. Manuf.
, 49
, pp. 139
–147
. 6.
Belnoue
, J. P.-H.
, and Hallett
, S. R.
, 2020
, “A Rapid Multi-Scale Design Tool for the Prediction of Wrinkle Defect Formation in Composite Components
,” Mater. Des.
, 187
, p. 108388
. 7.
Netzel
, C.
, Mordasini
, A.
, Schubert
, J.
, Allen
, T.
, Battley
, M.
, Hickey
, C.
, Hubert
, P.
, and Bickerton
, S.
, 2021
, “An Experimental Study of Defect Evolution in Corners by Autoclave Processing of Prepreg Material
,” Compos. Part A: Appl. Sci. Manuf.
, 144
, p. 106348
. 8.
Potter
, K.
, Langer
, C.
, Hodgkiss
, B.
, and Lamb
, S.
, 2007
, “Sources of Variability in Uncured Aerospace Grade Unidirectional Carbon Fibre Epoxy Preimpregnate
,” Compos. Part A: Appl. Sci. Manuf.
, 38
(3
), pp. 905
–916
. 9.
Potter
, K.
, Khan
, B.
, Wisnom
, M.
, Bell
, T.
, and Stevens
, J.
, 2008
, “Variability, Fibre Waviness and Misalignment in the Determination of the Properties of Composite Materials and Structures
,” Compos. Part A: Appl. Sci. Manuf.
, 39
(9
), pp. 1343
–1354
. 10.
Mesogitis
, T.
, Skordos
, A.
, and Long
, A.
, 2014
, “Uncertainty in the Manufacturing of Fibrous Thermosetting Composites: A Review
,” Compos. Part A: Appl. Sci. Manuf.
, 57
, pp. 67
–75
. 11.
Baran
, I.
, Cinar
, K.
, Ersoy
, N.
, Akkerman
, R.
, and Hattel
, J. H.
, 2017
, “A Review on the Mechanical Modeling of Composite Manufacturing Processes
,” Arch. Comput. Methods Eng.
, 24
, pp. 365
–395
. 12.
Levy
, A.
, and Hubert
, P.
, 2019
, “Vacuum-Bagged Composite Laminate Forming Processes: Predicting Thickness Deviation in Complex Shapes
,” Compos. Part A: Appl. Sci. Manuf.
, 126
, p. 105568
. 13.
Matveev
, M.
, Belnoue
, J.-H.
, Nixon-Pearson
, O.
, Ivanov
, D.
, Long
, A.
, Hallett
, S.
, and Jones
, I.
, 2019
, “A Numerical Study of Variability in the Manufacturing Process of Thick Composite Parts
,” Compos. Struct.
, 208
, pp. 23
–32
. 14.
Lange
, J.
, Altmann
, N.
, Kelly
, C.
, and Halley
, P.
, 2000
, “Understanding Vitrification During Cure of Epoxy Resins Using Dynamic Scanning Calorimetry and Rheological Techniques
,” Polymer
, 41
(15
), pp. 5949
–5955
. 15.
Halley
, P. J.
, and Mackay
, M. E.
, 1996
, “Chemorheology of Thermosets—An Overview
,” Polymer Eng. Sci.
, 36
(5
), pp. 593
–609
. 16.
van Ee
, D.
, and Poursartip
, A.
, 2009
, “Hexply 8552 Material Property Database for Use With Compro CCA and Raven,” Tech. Report.17.
Ng
, S.
, Boswell
, R.
, Claus
, S.
, Arnold
, F.
, and Vizzini
, A.
, 2000
, “Degree of Cure, Heat of Reaction, and Viscosity of 8552 and 977-3 HM Epoxy Resin
,” Tech. Report, Naval Air Warfare Center Aircraft Division.18.
DiBenedetto
, A. T.
, 1987
, “Prediction of the Glass Transition Temperature of Polymers: A Model Based on the Principle of Corresponding States
,” J. Polym. Sci. Part B: Polym. Phys.
, 25
(9
), pp. 1949
–1969
. 19.
Nielsen
, L.
, 1968
, “Crosslinking-Effect on Physical Properties of Polymers
,” Tech. Report, Monsanto Research Corporation.20.
Mantell
, S. C.
, Ciriscioli
, P. R.
, and Almen
, G.
, 1995
, “Cure Kinetics and Rheology Models for ICI Fiberite 977-3 and 977-2 Thermosetting Resins
,” J. Reinf. Plast. Compos.
, 14
(8
), pp. 847
–865
. 21.
Hautefeuille
, A.
, Comas-Cardona
, S.
, and Binetruy
, C.
, 2019
, “Mechanical Signature and Full-Field Measurement of Flow-Induced Large In-Plane Deformation of Fibrous Reinforcements in Composite Processing
,” Compos. Part A: Appl. Sci. Manuf.
, 118
, pp. 213
–222
. 22.
Belnoue
, J.
, Nixon-Pearson
, O. J.
, Ivanov
, D.
, and Hallett
, S. R.
, 2016
, “A Novel Hyper-viscoelastic Model for Consolidation of Toughened Prepregs Under Processing Conditions
,” Mech. Mater.
, 97
, pp. 118
–134
. 23.
Belnoue
, J. P.-H.
, Valverde
, M. A.
, Onoufriou
, M.
, Sun
, X. R.
, Ivanov
, D. S.
, and Hallett
, S. R.
, 2021
, “On the Physical Relevance of Power Law-Based Equations to Describe the Compaction Behaviour of Resin Infused Fibrous Materials
,” Int. J. Mech. Sci.
, 199
, p. 106425
. 24.
Hexcel
, 2020
, “Product Data Sheet
,” https://www.hexcel.com/user_area/content_media/raw/HexPly_8552_eu_DataSheet(1).pdf25.
26.
Hull
, D.
, and Clyne
, T.
, 1996
, An Introduction to Composite Materials
, 2nd ed., Cambridge University Press
, Cambridge, UK
.27.
Copyright © 2023 by ASME
You do not currently have access to this content.
