Fillet curvature • Fillet curvature radius is invariant under pressure
Transport phenomena • Increase of core pressure → Growth of the flow of matter → Displacement of skin
resin and migration of adhesive resin → Thinner adhesive layer
Impact of processing parameters on adhesive fillet size and shape
of aerospace honeycomb composite sandwich panels
R.Trigueira, Prof. P. Hubert, Prof. V. Michaud
McGill University - Structure and Composite Materials Laboratory
Objectives • Out of Autoclave (OoA) Vacuum Bag Only (VBO) co-cure of honeycomb sandwich
panels
• Investigation on the effect of core pressure during processing on the interface between
the core and skins of co-cured honeycomb sandwich panels
Skins
Core
Honeycomb sandwich with cyanate ester/carbon fibres skins
Set-up
• Controlled core pressure
(80kPa, 30kPa and full
vacuum (FV))
• Placed in an oven for curing
• Recording of bag and core
pressure, as well as the flow
Sandwich panel
Adhesive A • Unsupported epoxy film, 100gsm
• Designed for VBO co-cure at 121°C
• Minimum viscosity : 30 Pa∙s
Materials Adhesive B
• Unsupported toughened epoxy film,
textured, 100gsm
• Designed for a cure at 150°C under
300kPa
• Minimum viscosity : 380 Pa∙s
Adhesive A, 80kPa
Adhesive A, 30kPa
Adhesive A, FV
Presence of defects
due to the lack of
resin in the skins
Dry-spots
Fillet height
H0 H1
• Both adhesives exhibit the same behaviour : the lower the pressure the higher the
fillets
• Interquartile range stays stable → Distribution of fillet heights is almost not impacted
by the core pressure.
Adhesive A , 30kPa
Adhesive A
R
Adhesive A, 30kPa
Fillet contact angle • Contact angle undergoes little to no variation with the pressure.
θ
Adhesive A, 30kPa
Adhesive A, FV
Scattering of the data can be due to cell wall curvature,
excrescent para-aramid fibres, toughening particles
(Adhesive B), motion of the skin (different advancing
and receding angles). Film thickness
• As the flow between the core and the bag increases (80 and 30kPa), the film
thickness lowers because of the transport phenomena.
Adhesive A, FV
Scattering of the data :
• Film thinner near the fillet : flow of matter not sufficient to refill this region
• Inhomogeneous topology of the skin
• Locally increased migration of adhesive resin
Adhesive A, horizontal line : initial film
thickness (84 µm)
Conclusions • For both adhesives, the lower the pressure, the larger the fillets.
• Transport phenomena are dominating the fillet formation for the 80 and 30kPa
conditions, decreasing the fillet quality.
• Core pressure seems to have little to no influence on the mechanisms driving the fillet
formation itself.
• Adhesive viscosity is a key factor in the fillet formation as it impacts the flow of matter.
Adhesive A
References • T. Centea, L. K. Grunenfelder, and S. R. Nutt. A review of out-of-autoclave
prepregs : Material properties, process phenomena, and manufacturing
considerations. Composites Part A, 70:132-154, 2015.
• S. Sequeira Tavares, N. Caillet-Bois, V. Michaud, and J. A E Månson. Vacuum-
bag processing of sandwich structures: Role of honeycomb pressure level on skin-
core adhesion and skin quality. Composites Science and Technology, 70(5):797-
803, 2010.
• J. Rion, Y. Leterrier, and J. A. E. Månson. Prediction of the adhesive fillet size for
skin to honeycomb core bonding in ultra-light sandwich structures. Composites
Part A: Applied Science and Manufacturing, 39(9):1547-1555, 2008.
• T. Centea, D. Zebrine, M. Anders, C. Elkin, and S. R. Nutt. Manufacturing of
Honeycomb Core Sandwich Structures: Film Adhesive Behavior Versus Cure
Pressure and Temperature. Proceedings of the Composites and Advanced
Materials Expo, 2016.
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