Numerical Simulation of a Ballistic Impact on Tensylon® UHMWPE Laminates Using the Plastic Kinematic Model in LS-Dyna®

Alil, Luminiţa Cristina; Matache, Liviu; Sandu, Simona Maria

doi:10.32754/jmt.2018.1.08

Cited by 4 publications

(3 citation statements)

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“…To initialize the thermodynamic state of the material, the Johnson-Cook material model requires an equation of state [27] which is defined by the card *EOS_LINEAR_POLYNOMINAL in which the pressure and initial relative volume are denoted by coefficients C0-C6 and V0, respectively and is presented in Table 3. Furthermore, for simulation of the lead cores, the model *MAT_PLASTIC_KINEMATIC is used and the material properties are given in Table 4 [28].…”

Section: Constitutive Materials Modelsmentioning

confidence: 99%

Stress Wave Mitigation Properties of Dual-meta Panels against Blast Loads

Pham

et al. 2021

International Journal of Impact Engineering

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Section: Constitutive Materials Modelsmentioning

confidence: 99%

Stress Wave Mitigation Properties of Dual-meta Panels against Blast Loads

Pham

et al. 2021

International Journal of Impact Engineering

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“…4 [38]. The contact between the metals and rubber is modelled by the keyword *TIED_SURFACE_TO_SURFACE and the keyword *CONTACT_INTERIOR is utilized for the rubber to eliminate the negative volume issue which often occurs due to large deformation of soft materials.…”

Section: Numerical Model Developmentmentioning

confidence: 99%

Model for analytical investigation on meta-lattice truss for low-frequency spatial wave manipulation

Pham

2021

Wave Motion

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“…Micro and macroscopic observations are given and among dissipative mechanisms identified, multi-delamination is observed. An attempt to a numerical modelling is given in [16] including earlier advances performed by this research team. They implemented an approximate adhesive model and could obtain fairly satisfying results that allow them to evaluate strain rate at 1.16.10 5 s À1 .…”

Section: Samples Descriptionmentioning

confidence: 99%

Laser Induced Shockwave as Delaminator of Composite Material for Ballistic Protection at High Strain Rate

Alil¹,

Арригони²,

Istrate³

et al. 2020

NATO Science for Peace and Security Series C: Environmental Security

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Societal concerns on security push light weight armor for ballistic protection to remain a topic of interest. Ultra-High Molecular Weight Polyethylene composites (UHMWPE) have shown appreciable performances for ballistic protection, because of their ability to mitigate kinetic energy of projectiles by various mechanisms of dissipation and because of their lower density. Among dissipative mechanisms of interest, delamination is one of them. In order estimate the bond strength between two plies, the laser induced shock wave technique has been utilized on Tensylon® thin panels. Firstly, this paper introduces this technique and its capabilities with respect to the characterization of ballistic protections at very high strain rates (10 6 s À1 ). Secondly, a set of experimental results is shown and interpreted to obtain the interply bond strength, through the spallation process. At last, experimental results are supported by a numerical model that is in the verge of being a predictive tool.

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Numerical Simulation of a Ballistic Impact on Tensylon® UHMWPE Laminates Using the Plastic Kinematic Model in LS-Dyna®

Cited by 4 publications

References 0 publications

Stress Wave Mitigation Properties of Dual-meta Panels against Blast Loads

Stress Wave Mitigation Properties of Dual-meta Panels against Blast Loads

Model for analytical investigation on meta-lattice truss for low-frequency spatial wave manipulation

Laser Induced Shockwave as Delaminator of Composite Material for Ballistic Protection at High Strain Rate

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