The effect of metallic fiber geometry and multi-walled carbon nanotubes on the mechanical behavior of aluminum fiber-reinforced composite adhesive joints

Abstract

The effect of the geometry of metallic fibers on the mechanical response of aluminum fiber-reinforced composite adhesive joints was studied experimentally. Moreover, a combination of multi-walled carbon nanotubes and aluminum fibers was used for reinforcing the composite adhesive joints. Different geometries for the aluminum fibers including straight, twisted and spring-shaped with different pitch lengths were considered. The results indicated that the composite adhesive joints reinforced with a combination of multi-walled carbon nanotubes and aluminum fibers experienced the highest improvement of 171% in the strength compared to the unreinforced specimen. It was found out that the aluminum fiber geometry can significantly influence the adhesive joint behavior. Incorporating the twisted aluminum fibers into the adhesive layer increased, while the spring-shaped fibers decreased the strength of the composite adhesive joints compared to the straight aluminum fibers. The fracture surfaces of the composite adhesive joints were analyzed using scanning electron microscope.

Keywords

Composites nanomaterials/nanostructures mechanical properties/strength multi-walled carbon nanotube adhesive joint

Get full access to this article

View all access options for this article.

References

Zhang

Fracture toughness and fatigue life of MWCNT/epoxy composites. Mater Sci Eng 2008; 494: 380–384.

Kang

M-H

Choi

J-H

Kweon

J-H.

Fatigue life evaluation and crack detection of the adhesive joint with carbon nanotubes.

Compos Struct 2014; 108: 417–422.

Gkikas

, et al. Enhanced bonded aircraft repair using nano-modified adhesives. Mater Des 2012; 41: 394–402.

Zulkarnain

Mariatti

Azid

Effects of hybrid fillers based on micro-and nano-sized silver particles on the electrical performance of epoxy composites. J Mater Sci 2013; 24: 1523–1529.

Barbosa

da Silva

Öchsner

Effect of the amount of cork particles on the strength and glass transition temperature of a structural adhesive. Proc IMechE, Part L: J Materials: Design and Applications 2014; 228: 323–333.

Khalili

, et al. Experimental study of the influence of adhesive reinforcement in lap joints for composite structures subjected to mechanical loads. Int J Adhes Adhes 2008; 28: 436–444.

Akhavan-Safar

, et al. Influence of microcork particles on the lap shear strength of an epoxy adhesive subjected to fatigue loading and different environmental conditions. Proc IMechE, Part L: J Materials: Design and Applications 2020; 234: 851–858.

Khoramishad

Razavi

Metallic fiber-reinforced adhesively bonded joints. Int J Adhes Adhes 2014; 55: 114–122.

You

, et al. Effect of metal as part of fillet on the tensile shear strength of adhesively bonded single lap joints. Int J Adhes Adhes 2003; 23: 365–369.

10.

Kaji

Farahani

Ansari

A reinforcing technique for the adhesive bonded composite joints using metallic wires.

J Adhes Sci Technol 2017; 31: 1963–1975.

11.

Meguid

Sun

On the tensile and shear strength of nano-reinforced composite interfaces.

Mater Des 2004; 25: 289–296.

12.

Tutunchi

Kamali

Kianvash

Steel-epoxy composite joints bonded with nano-TiO2 reinforced structural acrylic adhesive. J Adhes 2015; 91: 663–676.

13.

Hsiao

K-T

Alms

Advin

SG.

Use of epoxy/multiwalled carbon nanotubes as adhesives to join graphite fiber reinforced polymer composites. Nanotechnology 2003; 14: 791.

14.

Gilbert

Hayes

Seferis

JC.

Nano‐alumina modified epoxy based film adhesives. Polym Eng Sci 2003; 43: 1096–1104.

15.

Kilik

Davies

Mechanical properties of adhesive filled with metal powders.

Int J Adhes Adhes 1989; 9: 224–228.

16.

Carbas

Da Silva

Andrés

Effect of carbon black nanoparticles concentration on the mechanical properties of a structural epoxy adhesive. Proc IMechE, Part L: J Materials: Design and Applications 2018; 232: 403–415.

17.

Ayatollahi

, et al. Mechanical properties of adhesively single lap-bonded joints reinforced with multi-walled carbon nanotubes and silica nanoparticles. J Adhes 2017; 93: 896–913.

18.

Moloney

Kausch

Stieger

Interfacial properties of filled epoxide resins. In: Adhesive joints. Berlin: Springer, 1984, pp.883–904.

19.

Khashaba

Othman

Najjar

Experimental analysis of composite scarf adhesive joints modified with multiwalled carbon nanotubes under bending and thermomechanical impact loads. Proc IMechE, Part L: J Materials: Design and Applications 2020; 2341: 48--64.

20.

Khoramishad

Khakzad

Toughening epoxy adhesives with multi-walled carbon nanotubes. J Adhes 2018; 94: 15–29.

21.

Metals Handbook. Vol.2 – properties and selection: nonferrous alloys and special-purpose materials. 10th ed. Cleveland, OH: ASM International, 1990.

22.

Khakpour

Ayatollahi

Akhavan-Safar

, et al. Mechanical properties of structural adhesives enhanced with natural date palm tree fibers: effects of length, density and fiber type. Compos Struct 2020; 237: 111950.

23.

Gholami

Khoramishad

da Silva

LFM.

Glass fiber-reinforced polymer nanocomposite adhesive joints reinforced with aligned carbon nanofillers. Compos Struct 2020; 253: 112814.

24.

Menjivar

Kirane

Surfactant assisted dispersion of MWCNT's in epoxy nanocomposites and adhesion with aluminum.

Polym Test 2020; 82: 106308.