Bonding analysis of carbon/epoxy composites with viscoelastic acrylic adhesive

Fotsing, Edith Roland; Miron, F.; Eury, Y.; Ross, Annie; Ruiz, Édu

doi:10.1016/j.compositesb.2012.03.009

Cited by 16 publications

(4 citation statements)

References 20 publications

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“…The same comparative analysis was not made for the VHB material. However, investigations on bonding of acrylic adhesive on carbon/epoxy laminates reported by Fotsing et al 18 showed that the use of primer is necessary to achieve optimal adhesion strength. Therefore, the same trend is expected with regard to the shear modulus of the VHB material.…”

Section: Effect Of Bonding Qualitymentioning

confidence: 99%

Dynamic characterization of viscoelastic materials used in composite structures

Fotsing

Sola

Ross

et al. 2013

Journal of Composite Materials

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The main focus of this paper is the experimental comparative analysis of the viscoelastic properties of acrylic- and silicon-based viscoelastic materials. These materials are widely used in the aeronautic industry for structural and/or damping applications. It is therefore required to determine their viscoelastic properties such as shear modulus and loss factor following their integration to aircraft composite structures. The influence of material thickness, bonding quality, curing and cocuring with composite material was evaluated using dynamic mechanical analysis machine in plan shear configuration. This comparative analysis in the 0–600 Hz frequency range provides useful information that should be taken into consideration when designing bonded joints for structural and/or damping applications. The small variation of the acrylic-based material loss factor over a wide range of frequencies suggests that this material is a good candidate for damping applications at room temperature in metallic structures where no curing is required. However, cocuring of acrylic-based material with composite laminae increases its shear modulus up to six times with respect to the uncured material whereas its loss factor is reduced by about 20%. On the other hand, the silicon-based material remains stable after thermal treatment (curing and cocuring) suggesting that it is well suited for in situ damping treatment involving laminate composite structure. However, at room temperature its shear modulus after cocuring is lowered by almost 25% due to poor bonding quality, which depends on the nature of the substrate.

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Section: Effect Of Bonding Qualitymentioning

confidence: 99%

Dynamic characterization of viscoelastic materials used in composite structures

Fotsing

Sola

Ross

et al. 2013

Journal of Composite Materials

Self Cite

View full text Add to dashboard Cite

show abstract

“…Diab and Wu [2]) presented a viscoelastic model which is a generalized Maxwell constitutive model to describe the long term behavior of the adhesive layer bonding FRP sheet to concrete, the FRPeconcrete interface. Fotsing et al [3] analyzed bonding behavior of carbon/epoxy composites with viscoelastic acrylic adhesive. Chowdhur and Xia [4] used experimental method integrated with finite element analysis to determine the interface strength between an elastic isotropic material and the a linear viscoelastic material.…”

Section: Introductionmentioning

confidence: 99%

Effect of viscoelastic interface on three-dimensional static and vibration behavior of laminated composite plate

Alibeigloo

2015

Composites Part B: Engineering

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“…Depending on the nature of the matrix, fiber-reinforced polymeric composites can be divided into thermoset and thermoplastic composites. Carbon fiber reinforced thermoset composites were the first to be developed and used because of their lower cost comparing with thermoplastic matrix composites [1][2][3][4][5] . In recent years, with the development of curing technology, thermoplastic composites are replacing thermoset composites in many application fields, thanks to their easy short processing cycles, longer shelf life, lower storage costs, recyclability, higher impact resistance, and higher repair potential.…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical investigation on temperature field and joints tensile failure for CF/PPS-Al alloy interlocking induction welding

Qin¹,

Wang²,

et al. 2022

Preprint

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The induction welding has been recognized as one of potential and high-efficiency joining methods for thermoplastic composite materials. In this study, a numerical simulation model with containing both induction wielding heat transfer and joint tensile failure process for CF/PPS-Al alloy interlocking induction welding was established based on software COMSOL Mulitiphysics and Abaqus/Explicit. The CF/PPS-Al7075 interlocking welding joints with special designed macro-scale interlocking were tested under tensile loads, and the corresponding single lap-shear strength, energy absorption and failure mechanisms were investigated by combining the experimental and numerical approaches. Finally, the influence of macro-scale interlocking geometric parameters on joint tensile strength was also discussed. The results indicate that the proposed model can effectively predict the temperature distribution in the welding process and the tensile failure process of the joint. It is also presented that the addition of macro-scale interlocking features can effectively improve the ultimate load (47%) and energy absorption capacity (48%) of the CF/PPS-Al alloy induction welded joints. Meanwhile, the number of addition PPS films in the welding zone and the inclination angle have greater contribution on the tensile strength of the welded joints.

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Bonding analysis of carbon/epoxy composites with viscoelastic acrylic adhesive

Cited by 16 publications

References 20 publications

Dynamic characterization of viscoelastic materials used in composite structures

Dynamic characterization of viscoelastic materials used in composite structures

Effect of viscoelastic interface on three-dimensional static and vibration behavior of laminated composite plate

Experimental and numerical investigation on temperature field and joints tensile failure for CF/PPS-Al alloy interlocking induction welding

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