Low-velocity impact behavior of fiber metal laminates

Tsartsaris, Nikolaos; Meo, Michele; Dolce, Ferdinando; Polimeno, Umberto; Guida, Michele; Marulo, Francesco

doi:10.1177/0021998310376108

Cited by 69 publications

(39 citation statements)

References 11 publications

(10 reference statements)

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“…[39,67] 2011 -Experimental Study was done on glare 5-3/2 specimens to investigate the effects of different specimen geometry and lay-up sequence towards the low velocity impact response. [68] 2011 -Low velocity impact response of glare FML was investigated at different impact velocity and the nature, shape of the damage were quantified through destructive microphotography and non-destructive ultrasonic techniques. [27] 2012 -Impact response of magnesium based FML was determined through experiments.…”

Section: Simulation Of Low Velocity Impact On Fmlsmentioning

confidence: 99%

“…-External and internal damage effects on each metal face sheets and embedded composite layers were accurately found by computing absorbed energy on each stacking layers. [68] 2011 LS-DYNA -Glass based multilayered FML was modeled using shell elements and both intra and inter laminar failure was specified using appropriate damage criteria. -Contour plots for different composite failure was able to obtain which helps to quantify the magnitude of damage and its severity.…”

Section: Key Aspectsmentioning

confidence: 99%

“…Tsartsaris [68] simulated glass based FMLs to investigate its lowvelocity impact response using LSDYNA3D finite element code. Meso-scale approach was utilized to model the FML layers having elastic plastic metal layers and linear elastic GFRP layer with Chang-Chang failure criteria.…”

Section: Numerical Modeling Of Fml With Fe Softwarementioning

confidence: 99%

See 2 more Smart Citations

Low velocity impact response of fibre-metal laminates – A review

Chai

Manikandan

2014

Composite Structures

268

126

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Section: Simulation Of Low Velocity Impact On Fmlsmentioning

confidence: 99%

Section: Key Aspectsmentioning

confidence: 99%

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Low velocity impact response of fibre-metal laminates – A review

Chai

Manikandan

2014

Composite Structures

268

126

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“…Depending upon the nature of connection, an optional failure criterion can be defined in all tie-break contacts. In this study, an extended form of dycoss discrete crack failure [37][38][39][40][41] criteria which is based on the fracture model defined in a cohesive material that includes a bilinear traction separation law with quadratic mixed mode delamination criterion and a Benzeggagh-Kenane [42] damage propagation formulation was used. The distance between two points initially in contact in the normal and tangential directions corresponds to complete material failure referred as ultimate displacements in the interface cohesive model.…”

Section: Delamination Failure Modelingmentioning

confidence: 99%

Modeling Low Velocity Impact Response of Carbon Fiber Reinforced Aluminum Laminates (CARALL)

Dhaliwal

Newaz

2016

J. dynamic behavior mater.

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Fiber metal laminates (FMLs) have shown great potential in lightweight aerospace applications. Carbon fiber reinforced aluminum laminates (CARALL) is a lightweight system that has received less attention than aramid reinforced aluminum laminates. These FMLs have adhesively bonded layered plies. We have developed CARALL without the use of adhesives. The epoxy resin from the carbon fiber epoxy is used to adhesively bond the aluminum layers. In this study, CARALL laminates having a 3/2 configuration, with Aluminum 5052-H32 as the outer layer were prepared using a vacuum press without using any adhesive film. Primary failure modes observed were cracks in non-impacted aluminum layer, carbon fiber (CFRP) layer fracture and delamination between aluminum and CFRP layers. Finite element modeling was used to predict low velocity impact response of these FMLs by considering Chang-Chang damage criteria for CFRP layers and nonlinear elasto-plasticity along with progressive damage mechanics for aluminum layers. Delamination was modeled by using traction separation law and damage criterion proposed by Benzeggagh-Kenane was used for interface damage evolution. The damage size of CARALL FMLs was characterized using C-scan equipment and compared with the finite element predictions. Numerical simulation was used to predict load-displacement histories, delamination area, absorbed energy, damage morphologies on impacted and non-impacted sides and tensile failures of CFRP layers for impact event at three different energy levels. Predicted impact behavior results match well with experimental results. The threshold impact energy, energy at which perforation failure was induced in all metallic and fiber reinforced layers for these CARRAL laminates was found to be around 31 J.

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“…However, debonding affects the load transfer between the metal and composite layers, as well as the interaction between different damage modes during an impact, which makes it important in the damage process [12]. Owing to this, debonding has been implemented in the recent theoretical and finite element models in order to study low-velocity impact behaviour [6,16,[18][19][20]. However, the models have been utilized to simulate the high-energy impact response of FMLs, which includes all the different damage modes.…”

mentioning

confidence: 99%

The Effects of Debonding on the Low-Velocity Impact Response of Steel-CFRP Fibre Metal Laminates

et al. 2016

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The effect of metal-composite debonding on low-velocity impact response, i.e. on contact force-central deflection response, deformation profiles and strains on the free surfaces was studied. We focused on type 2/1 fibre metal laminate specimens made of stainless steel and carbon fibre epoxy layers, and tested them with drop-weight impact and quasi-static indentation loadings. Local strains were measured with strain gauges and full-field strains with a 3-D digital image correlation method. In addition, finite element simulations were performed and the effects of debonding were studied by exploiting cohesive elements. Our results showed that debonding, either the initial debonding or that formed during the loading, lowers the slope of the contact force-central deflection curve during the force increase. The debonding formation during the rebound phase was shown to amplify the rebound of the impact side, i.e. to lower the ultimate post-impact deflection. The free surface strains were studied on the laminate's lower surface at the area outside the debond damage. In terms of in-plane strains, debonding formation during impact and indentation, as well as the initial debonding, lowered the peripheral strain and resulted in a positive change in the radial strain.

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Low-velocity impact behavior of fiber metal laminates

Cited by 69 publications

References 11 publications

Low velocity impact response of fibre-metal laminates – A review

Low velocity impact response of fibre-metal laminates – A review

Modeling Low Velocity Impact Response of Carbon Fiber Reinforced Aluminum Laminates (CARALL)

The Effects of Debonding on the Low-Velocity Impact Response of Steel-CFRP Fibre Metal Laminates

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