In this work, the response of a bonded carbon-fibre-reinforced plastic composite panel, which had been manufactured by bonding two laminates together, to impact, penetration, and perforation by a high-velocity steel sphere has been studied. The response of a relatively thick (about 12 mm) laminate has been compared with similar data from previous work by Hazell et al. where relatively thin monolithic laminates were impacted by the same type of projectile. It was found that the ballistic performance of the system was increased over the impact energy range of interest when compared with these similar, relatively thin composite laminates. Furthermore, both the energy absorbed per unit thickness of laminate and the level of damage as measured by a C-Scan system when the panels were perforated at normal incidence and oblique incidence were similar. This raises the prospect of reducing experimental testing at oblique angles, if the behaviour at normal incidence is known.
CantwellW. J.MortonJ.The impact resistance of composite materials – a reviewComposites22 (5) (1991347–362
2.
RichardsonM. O. W.WisheartM. J.Review of low-velocity impact properties of composite materialsComposites, Part A: Appl. Sci. Mfg27 (12) (19961123–1131
3.
MortonJ.GodwinE. W.Impact response of tough carbon fibre compositesComposite Structs13 (19891–19
4.
CantwellW. J.CurtisP. T.MortonJ.An assessment of the impact performance of CFRP reinforced with high-strain carbon fibresComposites Sci. Technol.25 (2) (1986133–148
5.
CurtisP. T.BishopS. M.An assessment of the potential of woven carbon fibre-reinforced plastics for high performance applicationsComposites15 (4) (1984259–265
6.
RobinsonP.DaviesG. A. O.Impactor mass and specimen geometry effects in low velocity impact of laminated compositesInt. J. Impact Engng12 (2) (1992189–207
7.
CantwellW. J.MortonJ.Comparison of the low and high velocity impact response of CFRPComposites20 (6) (1989545–551
8.
BlandP. W.DearJ. P.Observations on the impact behaviour of carbon-fibre reinforced polymers for the qualitative validation of modelsComposites, Part A: Appl. Sci. Mfg32 (20011217–1227
9.
HammondR. I.ProudW. G.GoldreinH. T.FieldJ. E.High-resolution optical study of the impact of carbon-fibre reinforced polymers with different lay-upsInt. J. Impact Engng30 (200469–86
10.
TanabeY.AokiM.Stress and strain measurements in carbon-related materials impacted by high-velocity steel spheresInt. J. Impact Engng28 (20031045–1059
HosurM. V.VaidyaU. K.UlvenC.JeelaniS.Performance of stitched/unstitched woven carbon/epoxy composites under high velocity impact loadingComposite Structs64 (2004455–466
13.
Lopez-PuenteJ.ZaeraR.NavarroC.Experimental and numerical analysis of normal and oblique ballistic impacts on thin carbon/epoxy woven laminatesComposites, Part A: Appl. Sci. Mfg39 (2008374–387
14.
TanabeY.AokiM.FujiiK.KasanoH.YasudaE.Fracture behavior of CFRPs impacted by relatively high-velocity steel sphereInt. J. Impact Engng28 (2003627–642
15.
FujiiK.AokiM.KiuchiN.YasudaE.TanabeY.Impact perforation behavior of CFRP using high velocity steel sphereInt. J. Impact Engng27 (2002497–508
16.
LiuD.RajuB. B.DangX.Impact perforation resistance of laminated and assembled composite platesInt. J. Impact Engng24 (2000733–746
17.
LamontagneC. G.ManuelpillaiG. N.TaylorE. A.TennysonR. C.Normal and oblique hypervelocity impacts on carbon fibre/peek compositesInt. J. Impact Engng23 (1999519–532
18.
LamontagneC. G.ManuelpillaiG. N.KerrJ. H.TaylorE. A.TennysonR. C.BurchellM. J.Projectiles density, impact angle and energy effects on hypervelocity impact damage to carbon fiber/PEEK compositesInt. J. Impact Engng26 (2001381–398
19.
HazellP. J.KisterG.StennettC.BourqueP.CooperG.Normal and oblique penetration of woven CFRP laminates by a high velocity steel sphereComposites, Part A: Appl. Sci. Mfg39 (2008866–874
20.
HazellP. J.StennettC.CooperG.The shock and release behaviour of an aerospace-grade cured aromatic amine epoxy resinPolym. Composites29 (10) (20081106–1110
21.
GerlachR.SiviourC. R.PetrinicN.WiegandJ.Experimental characterisation and constitutive modelling of RTM-6 resin under impact loadingPolymer49 (11) (20082728–2737
22.
Appleby-ThomasG. J.HazellP. J.StennettC.The variation in lateral and longitudinal stress gauge response within an RTM 6 epoxy resin under one-dimensional shock loadingJ. Mater. Sci.44 (22) (20096187–6198
23.
MillettJ. C. F.BourneN. K.MeziereY. J. E.VignjevicR.LukyanovA.The effect of orientation on the shock response of a carbon fibre-epoxy compositeComposites Sci. Technol.67 (20073253–3260
24.
HazellP. J.StennettC.CooperG.The effect of specimen thickness on the shock propagation along the in-fibre direction of an aerospace-grade CFRP laminateComposites, Part A: Appl. Sci. Mfg40 (2) (2009204–209
25.
ASTM D3171–06
26.
Cryogenic materials data handbook, Vol. 1, Technical Documentary Report AFML-TDR-64–280, 1970, sections A–C (Air Force Materials Laboratory, Air Force Command, Wright-Patterson Air Force Base, Dayton, Ohio).
27.
HazellP. J.CowieA.KisterG.StennettC.CooperG. A.Penetration of a woven CFRP laminate by a high velocity steel sphere impacting at velocities of up to 1875 m/sInt. J. Impact Engng136 (9) (20091136–1142
28.
GoldsmithW.FinneganS. A.Normal and oblique impact of cylindro-conical and cylindrical projectiles on metallic platesInt. J. Impact Engng4 (2) (198683–105
29.
GuptaN. K.MadhuV.An experimental study of normal and oblique impact of hard-core projectile on single and layered platesInt. J. Impact Engng19 (1997395–414
30.
HazellP. J.Appleby-ThomasG. J.A study on the energy dissipation of several different CFRP-based targets completely penetrated by a high velocity projectileComposite Structs91 (2009103–109
31.
32.
Hysol® Product 0151. Product Description Sheet, Loctite, Rocky Hill, Connecticut, May 2002
