Sage Journals: Discover world-class research

Abstract

The acceptability of polymer-based composite materials is increasing with time due to superior mechanical and chemical properties. Still, scope of advancement in mechanical behavior of these materials motivated research fraternity to develop new materials. The present article aims to analyze the effect of environment conditions on newly fabricated glass fiber epoxy composites reinforced with variable SiC particles as secondary reinforcement. The evaluation of mechanical strength and effect of environmental conditions on composite performance was analyzed using tensile, compression, flexural, and impact strength testing on universal testing machine. The mechanical strength characterization demonstrated the effect of size and weight fraction of reinforced SiC particles on mechanical strength of composites. The surface morphology of samples was examined by field emission scanning electron microscopy with energy dispersive spectroscopy. Based on mechanical strength evaluation results, an exponential equation was developed to predict the composite life.

Keywords

Environment life prediction mechanical strength polymer matrix composite silicon carbide particulates

Get full access to this article

View all access options for this article.

References

Sathish Kumar

Naveen

Satheesh Kumar

. Hybrid fiber reinforced polymer composites – a review. J Reinf Plast Compos 2014; 33: 454–471.

Salih

. Study the effect of physical properties of polyester - Fiber glass. Aus J Basic Appl Sci 2009; 3: 4120–4124.

Allatin

Ibrahim

. Sea water effect on pinned-joint glass fibre composite materials. Compos Struct 2008; 85: 59–63.

Ray

. Effects of changing environment and loading speed on mechanical behavior of FRP composites. J Reinf Plast Compos 2006; 25: 1227–1240.

Huang

et al.

Multiscale carbon nanotubes woven glass fiber reinforced cyanate ester/epoxy composites for enhanced mechanical and thermal properties. Compos Sci Technol 2014; 104: 81–88.

Umboh

Adachi

Oishi

et al.

Mechanical properties of nano-silica particulate-reinforced epoxy composites considered in terms of crosslinking effect in matrix resins. J Mater Sci 2013; 48: 5148–5156.

Zaman

Phan

Kuan

et al.

Epoxy/graphene platelets nanocomposites with two levels of interface strength. Polymer 2011; 52: 1603–1611.

Ahmadi-Moghadam

Sharafimasooleh

Shadlou

et al.

Effect of functionalization of graphene nanoplatelets on the mechanical response of graphene/epoxy composites. Mater Des 2015; 66: 142–149.

Bozkurt

Kaya

Tanoğlu

. Mechanical and thermal behavior of non-crimp glass fiber reinforced layered clay/epoxy nanocomposites. Compos Sci Technol 2007; 67: 3394–3403.

10.

Roubicek

Raclavska

Juchelkova

et al.

Wear and environmental aspects of composite materials for automotive braking industry. Wear 2008; 265: 167–175.

11.

Lin

G-M

Xie

G-Y

Sui

G-X

et al.

Hybrid effect of nanoparticles with carbon fibers on the mechanical and wear properties of polymer composites. Compos: Part B 2012; 43: 44–49.

12.

Olmos

Lopez

Gonzalez

. The nature of the glass fibre surface and its effect in the water absorption of glass/epoxy composites. The use of fluorescence to obtain information at the interface. Compos Sci Technol 2006; 66: 2758–2768.

13.

El Messiry

. Theoretical analysis of natural fiber volume fraction of reinforced composites. Alex Eng J 2013; 52: 301–306.

14.

Deepa

Sebastian

James

. Effect of inter particle distance and interfacial area on the properties of insulator conductor composites. Appl Phys Lett 2007; 91: 202904–202904.

15.

Slipenyuk

Kuprin

Milman

et al.

Properties of P/M processed particle reinforced metal matrix composites specified by reinforcement concentration and matrix-to-reinforcement particle size ratio. Acta Mater Papers 2006; 54: 157–166.

16.

Finot

Shen

Needleman

et al.

Micromechanical modeling of reinforcement fracture in particle-reinforced metal matrix composites. Metall Mater Trans A Papers 1994; 25: 2403–2420.

17.

Song

Xiao

. Modeling the fracture toughness and tensile ductility of SiCp/Al metal matrix composites. Mater Sci Eng A Papers 2008; 474: 371–375.

18.

Bartczak

Argon

Cohen

et al.

Toughness mechanism in semi-crystalline polymer blends: II. High-density polyethylene toughened with calcium carbonate filler particles. Polymer 1999; 40: 2347–2365.

19.

Zhang

Cao

et al.

The effects of particle size and content on the thermal conductivity and mechanical properties of Al2O3/high density polyethylene (HDPE) composites. eXPRESS Polym Lett 2011; 5: 581–590.

20.

S-Y

Feng

X-Q

Lauke

et al.

Effects of particle size, particle/matrix interface adhesion and particle loading on mechanical properties of particulate–polymer composites. Compos: Part B 2008; 39: 933–961.

21.

Ersoy

Garstka

Potter

et al.

Development of the properties of a carbon fibre reinforced thermosetting composite through cure. Compos: Part A 2010; 41: 401–409.

22.

Sorrentino

Bellini

Capriglione

et al.

Local monitoring of polymerization trend by an interdigital dielectric sensor. Int J Adv Manuf 2015; 79: 1007–1016.

23.

Seinfeld J, Pandis H and Spyros N. Atmospheric chemistry and physics - From air pollution to climate change. USA: John Wiley and Sons, 1998.

24.

Wang

Rao

Liang

et al.

Durability of glass fiber-reinforced polymer composites under the combine deffects of moisture and sustained loads. J Reinf Plast Compos 2015; 34: 1739–1754.

25.

Zrua

. Reliability baser safety factor for aircraft composite structures. Comput Struct 1993; 48: 745–748.

Glass fibers/SiC p reinforced epoxy composites: Effect of environmental conditions

Abstract

Keywords

Get full access to this article

References