Sage Journals: Discover world-class research

Abstract

The present work describes the influence of different carbon black nanoparticles with different concentrations on the mechanical properties of a structural epoxy adhesive cured by dielectric and thermal heating. This work was undertaken to improve the understanding of the effect of carbon black nanoparticles concentration on the stiffness (Young’s modulus), strength (yield strength) and deformation of the adhesive. Two kinds of spherical carbon black nanoparticles with different dielectric properties and sizes were used. Specimens with different amounts of carbon black were manufactured for each nanoparticle. The mechanical properties of the adhesive were measured in bulk specimens. The mechanical properties were found to vary as a function of the carbon black amount. For the dielectric cure, the strength and stiffness of the adhesive decrease as the amount of carbon black nanoparticles increases. On the other hand, the adhesive showed an increase of the deformation with an increase of the carbon black concentration. The thermal cure showed a mechanical behaviour similar as the dielectric cure, but the curing time increases substantially. A scanning electron microscopy analysis was performed to analyse the surface fracture of the adhesive. The fracture surfaces of specimens cured by dielectric and thermal heating and without nanoparticles are similar, typical of brittle adhesive. For high carbon black amount, the fracture surfaces are typical of ductile adhesive.

Keywords

Carbon black epoxy adhesives dielectric heating microwave cure thermal cure mechanical properties SEM analysis

Get full access to this article

View all access options for this article.

References

da Silva

LFM

Öchsner

Adams

. Handbook of adhesion technology, Heidelberg: Springer, 2011.

Wei

Hawley

Delong

. Comparison of microwave and thermal cure of epoxy resins. Polym Eng Sci 1993; 33: 1132–1140.

Singer

Jow

Delong

et al.

Effects of processing on tensile properties of an epoxy/amine matrix: continuous electromagnetic and/or thermal curing. SAMPE Quarter 1989; 20: 14–18.

Bai

Djafari

Andreani

et al.

Comparative study of the mechanical behavior of an epoxy resin cured by microwaves with one cured thermally. Eur Polym J 1995; 31: 875–884.

Rao

RMVGK

. Cure studies on bifunctional epoxy matrices using a domestic microwave oven. Polym Test 2008; 27: 645–652.

Ayodele

Yarlagadda

PKDV

Oloyede

. Microwave processing of adhesive joints using a temperature feedback system. Int J Mach Tools Manuf 2001; 41: 209–225.

Tanikella RV, Allen SAB and Kohl PA. Novel low-temperature processing of polymer dielectrics on organic substrates by variable frequency microwave processing. In: 8th International symposium on advanced packaging materials, Stone Mountain, GA, USA, 3 March 2002–6 March 2002, pp.254–259.

Pethrick

. Design and ageing of adhesives for structural adhesive bonding – a review. Proc IMechE, Part L: J Materials: Design and Applications 2015; 229: 349–379.

Banea

da Silva

LFM

Campilho

RDSG

et al.

Smart adhesive joints: an overview of recent developments. J Adhes 2014; 90: 16–40.

10.

Abenojar

del Real

Martinez

et al.

Effect of silane treatment on SiC particles used as reinforcement in epoxy resins. J Adhes 2009; 85: 287–301.

11.

Abenojar

Martínez

Pantoja

et al.

Epoxy composite reinforced with nano and micro SiC Particles: curing kinetics and mechanical properties. J Adhes 2012; 88: 418–434.

12.

Abenojar

Martínez

Velasco

et al.

Effect of boron carbide filler on the curing and mechanical properties of an epoxy resin. J Adhes 2009; 85: 216–238.

13.

Barbosa

da Silva

LFM

Öchsner

et al.

Influence of the size and amount of cork particles on the impact toughness of a structural adhesive. J Adhes 2012; 88: 452–470.

14.

Banea

Da Silva

LFM

Carbas

RJC

et al.

Mechanical and thermal characterization of a structural polyurethane adhesive modified with thermally expandable particles. Int J Adhes Adhes 2014; 54: 191–199.

15.

Banea

Da Silva

LFM

Carbas

RJC

et al.

Structural adhesives modified with thermally expandable particles. J Adhes 2015; 91: 823–840.

16.

Banea

Da Silva

LFM

Carbas

RJC

et al.

Debonding on command of adhesive joints for the automotive industry. Int J Adhes Adhes 2015; 59: 14–20.

17.

Hashim AA. Smart nanoparticles technology. Rijeka, Croatia: InTech, 2012.

18.

Vilgis

Heinrich

Klüppel

. Reinforcement of polymer nano-coomposites: theory, experiments and applications, New York: Cambridge University Press, 2009.

19.

Liu

Zhang

. Absorption properties of carbon black/silicon carbide microwave absorbers. Compos: Part B 2011; 42: 326–329.

20.

Ting

Wang

et al.

Effect of carbon black content on electrical and microwave absorbing properties of polyaniline/carbon black nanocomposites. Polym Degrad Stabil 2008; 43: 483–488.

21.

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.

22.

Carbas

RJC

Marques

EAS

da Silva

LFM

et al.

Effect of cure temperature on the glass transition temperature and mechanical properties of epoxy adhesives. J Adhes 2013; 90: 104–119.

23.

Carbas

RJC

da Silva

LFM

Marques

EAS

et al.

Effect of post-cure on the physical and mechanical properties of epoxy adhesives. J Adhes Sci Technol 2013; 27: 2542–2557.

24.

da Silva

LFM

Dillard

Blackman

BRK

et al.

Testing Adhes Joint Weinheim, Germany: Wiley-VCH, 2012.

25.

da Silva

LFM

Adams

. Measurement of the mechanical properties of structural adhesives in tension and shear over a wide range of temperatures. J Adhes Sci Technol 2005; 19: 109–141.

26.

Carbas

RJC

da Silva

LFM

Andrés

LFS

. Effect of carbon black nanoparticles concentration on mechanical properties of an epoxy adhesive cured by dielectric heating. Microsc Microanal 2015; 21: 15–16.

27.

Liu

Qian

et al.

The response of carbon black filled high-density polyethylene. J Mater Process Technol 2010; 210: 1991–1996.

Effect of carbon black nanoparticles concentration on the mechanical properties of a structural epoxy adhesive

Abstract

Keywords

Get full access to this article

References