Experimental investigation on the yield behavior of Nomex honeycombs under combined shear-compression

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A new circle-arc model was established to present the cellular structure. Dynamic response of models with density gradients under constant velocities is investigated by employing Ls-dyna 971. Compared with the uniform models, the quasi-static plateau stress of different layers seems a significant parameter correlated with the deformation mode except for inertia effect when the density gradient is introduced. The impact velocity becomes much more vital on the deformation of the unit cell than the density gradient. The stress at both the impact and stationary sides is investigated in details. Furthermore, the stress-strain curve is compared with the modified shock wave theory. The density gradient does have some remarkable influence on the energy absorption capability, and a certain density gradient is not always beneficial to the energy absorption. Irrespective of the impact velocity, there seems always a critical strain where the energy absorbed by all these specimens could approximate to nearly the same value. So the critical strain-velocity curve is plotted and gives the beneficial area for energy absorption pertinent to density gradients and impact velocity.

Section: Introductionmentioning

confidence: 99%

Dynamic crushing of uniform and density graded cellular structures based on the circle arc model

Zhang

Wei

Wang

et al. 2015

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“…Therefore, it is essential to model accurately the multiaxial failure behavior of the metallic foams under impact loading conditions, especially combined shear-compression which is the most realistic loading mode. The previous researches involving the dynamic mechanical property of the foams have been mostly limited to the uniaxial mechanical behavior, such as uniaxial failure strength, the plateau stress, the densification behavior and the energy absorption capacity (Zhao, 1997;Deshpande and Fleck, 2000b;Zhou et al, 2004a;Zhou et al, 2004b;Demiray et al, 2006; Latin American Journal of Solids and Structures 13 (2016) 665-689 Doyoyo and Mohr., 2006;Yu et al, 2006;Peroni et al, 2008;Peroni et al, 2012;Zhou et al, 2012aZhou et al, , 2012bZhou et al, , 2014Hangai et al, 2013;Pichler and Lackner, R.,Duarte et al, 2014;Kaya and Fleck, 2014;Li et al, 2014;Alvandi-Tabrizi et al, 2015;Storm et al, 2015;Vesenjak et al, 2016). But experimental investigations of metallic foams under dynamic multiaxial loading condition are not available by now.…”

Section: Zhiwei Zhoumentioning

confidence: 99%

“…Many works have been performed to study the rate effect in the mechanical behavior of the metallic foams, such as the uniaxial failure stress, the plateau stress, the densification behavior and the energy absorption capacity (Zhao,1997;Deshpande and Fleck, 2000b;Demiray et al, 2006;Yu et al, 2006;Zhou et al, 2012aZhou et al, , 2012bZhou et al, , 2014Castroa et al, 2013;Alia et al, 2014;Goel et al, 2014;Wang et al, 2014;Kishimoto et al, 2014;Caprino et al, 2015;Storm et al, 2015;Su et al, 2015). Nevertheless, little literature has involved the experimental failure surface, especially the dynamic failure surface which is very important for the engineering applications of the metallic foams.…”

Section: Determination Of Dynamic Failure Surfacementioning

confidence: 99%

Impact Response of Aluminium Alloy Foams Under Complex Stress States

Zhou

Wang

et al. 2016

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A series of dynamic tests were conducted on a closed-cell aluminum alloy foams in order to determine experimental failure surface under impact loading conditions. Quasi-static tests have also been performed to investigate failure mechanism under different stress paths. Three typical types of deformation modes can be observed, which corresponds to the different failure mechanism. The failure loci of the foam in principal stress plane are explored from quasistatic to dynamic loading conditions. A significant strength enhancement is identified experimentally. The expansion of the failure locus from the quasi-static to the dynamic test is almost isotropic. A modified failure criterion for the metallic foam is proposed to predict failure locus as a function of strain rate. This rate-dependence failure criterion is capable of giving a good description of the biaxial failure stresses over a wide range of the strain rates.

“…honeycombs or polymer (Deshpande and Fleck, 2000;Zhou et al, 2012a;2012b;Shen et al, 2010a). The performance of sandwich structures with an aluminium foam core and aluminium alloy sheets under low and high-velocity impact loading were analyzed by various experiments and numerical simulations.…”

Section: Latin American Journal Of Solids and Structures 12 (2015) 20mentioning

confidence: 99%

A numerical study on the impact behavior of foam-cored cylindrical sandwich shells subjected to normal/oblique impact

Zhou

Zhang

et al. 2015

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Finite element analysis was used to investigate the impact behavior of the foam-cored sandwich shells under the ballistic impact. The ballistic limit, failure mode of the face-sheet and energy absorption of the uniform/graded core were discussed in this paper. Based on the impact phase diagrams, the effects of several factors (i.e. projectile shape and diameter, face-sheet curvature and thickness) on the normal/oblique impact behavior were analyzed in detail. Results indicate that blunter and larger projectiles, higher impact velocity and thicker facesheets can significantly raise the impact-resistance performance of the targets. In addition, the behavior of ballistic impact becomes more complex as the result of the increasing oblique angle. KeywordsCylindrical sandwich shells; aluminium foam; oblique impact; impact phase diagram; numerical simulation.