Sage Journals: Discover world-class research

Abstract

In the manufacturing process of carbon fiber-reinforced plastics composites, if the cure pressure that can form the hydrostatic pressure of resin is transferred inhomogeneously to the interior of composite structures, the critical imperfections such as voids and delamination which damage the mechanical properties and restrict subsequent use will be formed. Therefore, the present work reports the experimental research and analysis on the effect of random vibration applied to the curing system of carbon fiber-reinforced plastic laminates, mainly aiming at the reduction of the void content and improvement of mechanical performance under the vacuum pressure. The range of acceleration of vibrations was covered from 5 g to 15 g, for different periods of random vibration. Conducting a facile thermogravimetric analysis-based methodology, the influence of random vibration on the composite density, fiber volume fraction and void content of carbon fiber reinforced plastic laminates was analyzed. And the influence of voids on the interlaminar shear strength of materials was compared in terms of the initiation and propagation of interlaminar failure. In addition, the scanning electron microscopy was employed to observe the fracture surfaces of the composite specimens, which confirmed the different behaviors of fiber–matrix interface of various curing processes. The major benefits of the current research are that, the application of random vibration during the curing process can better wet through fibers by resin and increase the fiber volume fraction while reducing the bubbles and volatile gas of composite laminates at the same time.

Keywords

Carbon fiber-reinforced plastics random vibration process thermogravimetric analysis voids interlaminar shear strength

Get full access to this article

View all access options for this article.

References

Kardos

Dudukovic

Dave

. Void growth and resin transport during processing of thermosetting-Matrix composites. Adv Polym Sci 1986; 80: 101–123.

Li j Zhang

Liang

et al.

Statistical characterization and robust design of RTM processes. Compos Part A Appl Sci Manuf 2005; 36: 564–580.

Mohamad

Ugla

Erklig

. A comparative study on the interlaminar shear strength of carbon, glass, and Kevlar fabric/epoxy laminates filled with SiC particles. J Compos Mater 2017; 51: 1–9.

Hernández

Sket

Molina-Aldareguıa

et al.

Effect of curing cycle on void distribution and interlaminar shear strength in polymer-matrix composites. Compos Sci Technol 2011; 85: 1331–1341.

Mouritz

Leong

Herszberg

. A review of the effect of stitching on the in-plane mechanical properties of Ebre-reinforced polymer composites. Compos A Appl Sci Manuf 1997; 28: 979–991.

Liu

Zhang

Wang

et al.

Effects of cure cycles on void content and mechanical properties of composite laminates. Compos Struct 2006; 73: 303–309.

Costa

Rezende

Almeida

SFM

. Effect of void content on the moisture absorption in polymeric composites. Compos Polym Plast Technol Eng 2006; 45: 691–698.

Boey

FYC

Lye

. Void reduction in autoclave processing of thermoset composites. I – high pressure effects on void reduction. II – void reduction in a microwave curing process. Composites 1992; 23: 261–265.

Zhu

et al.

Influence of voids on the tensile performance of carbon/epoxy fabric laminates. J Mater Sci Technol 2011; 27: 69–73.

10.

Scott

Sinclair

Spearing

et al.

Influence of voids on damage mechanisms in carbon/epoxy composites determined via high resolution computed tomography. Sci Technol 2014; 90: 147–153.

11.

Krehl

Gillespie

et al.

Process and performance evaluation of the vacuum-assisted process. J Compos Mater 2004; 38: 1803–1814.

12.

Davies

Day

Bond

et al.

Effect of cure cycle heat transfer rates on the physical and mechanical properties of an epoxy matrix composite. Key Eng Mater 2007; 9: 545–548.

13.

Chaowasakoo

Sombatsompop

. Mechanical and morphological properties of fly ash/epoxy composites using conventional thermal and microwave curing methods. Compos Sci Technol 2007; 67: 2282–2291.

14.

Zhang

Liu

Huang

et al.

The effect of carbon-fiber surface properties on the electron-beam curing of epoxy-resin composites. Compos Sci Technol 2002; 62: 331–337.

15.

Ghiorse

Jurta

. Effects of low frequency vibration processing on carbon/epoxy laminates. Composites 1991; 22: 3–8.

16.

Muric-Nesic

Compston

Stachurski

. On the void reduction mechanisms in vibration assisted consolidation of fibre reinforced polymer composites. Compos Part A Appl Sci Manuf 2011; 42: 320–327.

17.

Muric-Nesic

Compston

Noble

et al.

Effect of low frequency vibrations on void content in composite materials. Compos Part A Appl Sci Manuf 2009; 40: 548–551.

18.

Kitselis

Traiforos

Manolakos

. The effect of resonance on the void content in CFRP tubes. Compos Part B Eng 2016; 106: 164–171.

19.

Meier

Kahraman

Seyhan

et al.

Evaluating vibration assisted vacuum infusion processing of hexagonal boron nitride sheet modified carbon fabric/epoxy composites in terms of interlaminar shear strength and void content. Compos Sci Technol 2016; 128: 94–103.

20.

Zhan

Chen

et al.

The influence of cure pressure on microstructure, temperature field and mechanical properties of advanced polymer-matrix composite laminates. Fiber Polym 2014; 15: 2404–2409.

21.

Zhan

Chen

et al.

Formation, Influence Mechanism and Experimental Characterization of Composite Porosity. Metal Mater Eng 2016; 45: 2282–2286.

22.

Seyhan

. Evaluatıng addıtıon of a membrane layer ın vacuum ınfusıon processıng of fıber reinforced epoxy composıtes in terms of flexural propertıes and void content. Anadolu Univ J Sci Technol A Appl Sci Eng 2017; 18: 456–467.

23.

Agius

Magniez

KJC

Fox

. Fracture behaviour of a rapidly cured polyethersulfone toughened carbon fibre/epoxy composite. Compos Part B Eng 2013; 92: 2119–2127.

24.

Agius

Magniez

KJC

Fox

. Cure behaviour and void development within rapidly cured out-of-autoclave composites. Compos Struct 2009; 47: 230–237.

25.

Little

Yuan

Jones

. Characterisation of voids in fibre reinforced composite materials. NDT&E INT 2012; 46: 122–127.

26.

Wright

. The carbon Eber-epoxy resin interfaces: a review. Compos Polym 1990; 3: 231–401.

27.

Agius

Fox

. Rapidly cured out-of-autoclave laminates: understanding and controlling the effect of voids on laminate fracture toughness. Part A Appl Sci Manuf 2015; 73: 186–194.

28.

Agius

Magniez

KJC

Fox

. Cure behaviour and void development within rapidly cured out-of-autoclave composites. Compos Part B Eng 2013; 47: 230–237.

29.

Costa

de Almeida

SMF

Rezendeb

. The influence of porosity on the interlaminar shear strength of carbon/epoxy and carbon/bismaleimide fabric laminates. Compos Sci Technol 2001; 61: 2101–2108.

30.

Maragoni

Carraro

Quaresimin

. Effect of voids on the crack formation in a [45/ − 45/0] s laminate under cyclic axial tension. Part A Appl Sci Manuf 2016; 91: 493–500.

31.

Lyashenko-Miller

Marom

. Delamination fracture toughness of UHMWPE fibers/polyurethane laminates interleaved with carbon nanotube‐reinforced polyurethane films. Polym Advan Technol 2017; 28: 606–612.

32.

Chang

Zhan

Tan

et al.

Optimization of curing process for polymer-matrix composites based on orthogonal experimental method. Fiber Polym 2017; 18: 148–154.

33.

Chang

Zhan

Tan

et al.

Void content and interfacial properties of composite laminates under different autoclave cure pressure. Compos Interf 2016; 24: 529–540.

34.

Wang

Zhao

et al.

Interlaminar shear behavior of basalt FRP and hybrid FRP laminates. J Compos Mater 2015; 50: 1073–1084.

Evaluating random vibration assisted vacuum processing of carbon/epoxy composites in terms of interlaminar shear strength and porosity

Abstract

Keywords

Get full access to this article

References