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Abstract

Fiber-reinforced plastic (FRP) is a general kind of composite material used in many industries. This study examines the print-through phenomenon (PTP) via quantitative measurements on the gel-coated surface of FRP specimens. Moreover, finite element analysis is also adopted in this investigation. Based on a large number of experiments and computations, an average parameter, the arithmetic mean deviation is utilized to determine the degree of the PTP. Further, the reflections of a light image on a FRP surface were observed in photographs. Experimental results show that insulating residual stress can reduce PTP. Adding a core-mat layer to the FRP stacking scheme is a good solution for minimizing the PTP. In addition to using the core-mat materials, substitute materials used to prevent the PTP are also investigated.

Keywords

print-through phenomenon fiber-reinforced plastic surface properties SCRIMP

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References

Thompson

Brooks

Doel

. A nickel-carbon-fibre composite for large adaptive mirrors: fabrication methods and properties. Optics Exp 2008; 16(2): 1321–1330.

Theriaul PC. Print through elimination in fiber reinforced matrix composite mirrors and method of construction. United States Patent, No. 7022629, 2006.

Anagnostopoulos

Parthenios

Galiotis

. Thermal stress development in fibrous composites. Mater Lett 2008; 62(3): 341–345.

Choo

Bourke

MAM

Daymond

. A finite-element analysis of the inelastic relaxation of thermal residual stress in continuous-fiber-reinforced composites. Compos Sci Technol 2001; 61(12): 1757–1772.

White

Hahn

. Process modeling of composite material: residual stress development during cure. Part I. Model formulation. J Compos Mater 1992; 26(16): 2402–2422.

White

Hahn

. Process modeling of composite material: residual stress development during cure. Part II. Experimental validation. J Compos Mater 1992; 26(16): 2423–2453.

Iba

Chang

Kagawa

. Optically transparent continuous glass fiber-reinforced epoxy matrix composite: fabrication, optical and mechanical properties. Compos Sci Technol 2002; 62(15): 2043–2052.

Hochhalter

Massarello

Maji

Fuierer

. The origins of fiber print-through in lightweight composite optics. Proc SPIE 2006; 6289: 628–902.

Massarello

Hochhalter

Fuierer

Maji

. Composite mirror replication: curing coating and polishing. Proc SPIE 2005; 5868: 210–219.

10.

Massarello

Welsh

Hochhalter

Maji

Fuierer

. Fiber print-through mitigation technique for composite mirror replication. Opt Eng 2006; 45(12): 123401–123401.

11.

Massarello

Welsh

Hochhalter

Maji

Fuierer

. Quantifying the effects of curing parameters and composite characteristics on fiber print-through. J Adv Mater 2007; 39(3): 40–48.

12.

Lee

. Low temperature cure of unsaturated polyester resins with thermoplastic additives I. Dilatometry and morphology study. Polymer 2000; 41(2): 685–696.

13.

Lee

. Low temperature cure of unsaturated polyester resins with thermoplastic additives II. Structure formation and shrinkage control mechanism. Polymer 2000; 41(2): 697–710.

14.

Lee

Hsu

. Low temperature cure of unsaturated polyester resins with thermoplastic additives III. Modification of polyvinyl acetate for better shrinkage control. Polymer 2000; 41(2): 711–717.

15.

Lin

Liao

Jiang

Kuo

. Print-through phenomenon on the surface of GFRP: pilot study. J Compos Mater 2007; 41(26): 3055–3078.

16.

Lin

Liao

Jiang

. Methods to reduce the print-through phenomenon on the surface of FRP. J Reinf Plast Compos 2007; 26(4): 377–389.

17.

ABAQUS™ 6.6 Documentation http://www.cadfamily.com/online-help/ABAQUS/Documentation/docs/v6.6/books/stm/default.htm.

Study of the decrease in print-through phenomenon on fiber-reinforced plastic material

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