Your search keyword '"BALLISTICS"' showing total 7 results

1. Experiment/simulation correlation-based methodology for metallic ballistic protection solutions.

Author

Cosquer, Yohan, Longère, Patrice, Pantalé, Olivier, and Gailhac, Claude

Subjects

COMPUTER simulation, BALLISTICS, FINITE element method, ALUMINUM alloys, PROJECTILES

Abstract

A methodology is developed based on the coupling of a finite element code with an optimisation module for the design of land vehicle armouring composed of lightweight aluminium alloy and high strength steel plate. Following an experiment/simulation correlation, a numerical model has been built and calibrated considering monolithic plates and then verified considering a bi-metal protection against tungsten carbide projectile mimicking the core of a 7.62x51 AP8 ammunition. In addition, a method is proposed to obtain the vres - vi curve for the full 7.62x51 AP8 bullet from the vres - vi curve obtained from the core only. [ABSTRACT FROM AUTHOR]

Published

2023

2. The effect of the orientation of cubical projectiles on the ballistic limit and failure mode of AA2024-T351 sheets.

Author

De Vuyst, T., Vignjevic, R., Albero, A. Azorin, Hughes, K., Campbell, J.C., and Djordjevic, N.

Subjects

*PROJECTILES, *BALLISTICS, *FAILURE mode & effects analysis, *FINITE element method, *ENERGY dissipation

Abstract

This paper presents the results of an investigation of the ballistic limits and failure modes of AA2024-T351 sheets impacted by cubical projectiles. The effect of cube orientation on the ballistic limit and failure modes was considered in detail. Three impact configurations were investigated. Configuration one, two and three considered face, edge or corner impacts correspondingly. The experimental results were complemented with finite element analysis results in order to explain the observations. The lowest ballistic limit (202 m/s) was observed when the cube edge impacted on the target. In the cube face impacts, the ballistic limit was higher (223 m/s), and the highest ballistic limit (254 m/s) was observed for the corner impact. Although the face impact did not have the lowest ballistic limit, this impact configuration resulted in the least amount of projectile energy loss for impacts above the ballistic limit. With the aid of finite element modelling, it was possible to develop a better understanding of the test results and explain that the observed differences in impact response were not just due to a difference in projectile frontal area, but also due to the combination of the localised deformation near the projectile impact point and the resulting global (dishing) deformation. [ABSTRACT FROM AUTHOR]

Published

2017

3. Ballistic Limit of High-Strength Steel and Al7075-T6 Multi-Layered Plates Under 7.62-mm Armour Piercing Projectile Impact.

Author

Rahman, N. A., Abdullah, S., Zamri, W. F. H., Abdullah, M. F., Omar, M. Z., and Sajuri, Z.

Subjects

*BALLISTICS, *HIGH strength steel, *STRUCTURAL plates, *PROJECTILES, *ALUMINUM alloys, *FINITE element method

Abstract

This paper presents the computational-based ballistic limit of laminated metal panels comprised of high strength steel and aluminium alloy Al7075-T6 plate at different thickness combinations to necessitate the weight reduction of existing armour steel plate. The numerical models of monolithic configuration, double-layered configuration and triple-layered configuration were developed using a commercial explicit finite element code and were impacted by 7.62 mm armour piercing projectile at velocity range of 900 to 950 m/s. The ballistic performance of each configuration plate in terms of ballistic limit velocity, penetration process and permanent deformation was quantified and considered. It was found that the monolithic panel of high-strength steel has the best ballistic performance among all panels, yet it has not caused any weight reduction in existing armour plate. As the weight reduction was increased from 20-30%, the double-layered configuration panels became less resistance to ballistic impact where only at 20% and 23.2% of weight reduction panel could stop the 950m/s projectile. The triple-layered configuration panels with similar areal density performed much better where all panels subjected to 20-30% weight reductions successfully stopped the 950 m/s projectile. Thus, triple-layered configurations are interesting option in designing a protective structure without sacrificing the performance in achieving weight reduction. [ABSTRACT FROM AUTHOR]

Published

2016

4. The ballistic resistance of thin aluminium plates with varying degrees of fixity along the circumference.

Author

Tiwari, G., Iqbal, M.A., Gupta, P.K., and Gupta, N.K.

Subjects

*BALLISTICS, *ALUMINUM construction, *VISCOELASTIC materials, *COMPUTER simulation, *STRUCTURAL plates, *PROJECTILES, *FINITE element method

Abstract

The ballistic performance of thin aluminium targets and influence thereon of different circumferential fixity conditions were studied both experimentally and by finite element simulations. A pressure gun was employed to carry out the experiments while the numerical simulations were performed on ABAQUS/Explicit finite element code using Johnson–Cook elasto-viscoplastic material model. 1 mm thick 1100-H12 aluminium plates of free span diameter 255 mm were normally impacted by 19 mm diameter ogive and blunt nosed projectiles. The boundary conditions of the plate were varied by varying the region of fixity along its circumference as 100%, 75%, 50% and 25% in experiments and the numerical simulations. Further, simulations were carried out to compare the response of the plates with 50% and 75% continuous fixity with those with two and three symmetrical intermittent regions of 25% fixity respectively. The variation in the boundary condition has been found to have insignificant influence on the failure mode of the target however; it significantly affected the mechanics of target deformation and its energy absorption capacity. The ballistic limit increased with decrease in the region of fixity. It decreased for intermittent fixity in comparison with equivalent continuous fixity. And, it has been found to be higher for the impact with projectile having blunt nose in comparison with the one having ogive nose. [ABSTRACT FROM AUTHOR]

Published

2014

5. A numerical analysis of the dynamic behaviour of sheet steel perforated by a conical projectile under ballistic conditions

Author

Jankowiak, T., Rusinek, A., and Wood, P.

Subjects

*SHEET-steel, *PROJECTILES, *BALLISTICS, *FINITE element method, *NUMERICAL analysis, *COMPUTER simulation

Abstract

Abstract: The paper describes a numerical study on the perforation of sheet steel by a projectile under high impact velocity to predict the ballistic behaviour and, in particular the ballistic limit. The parametric study is performed for several of the important variables in the numerical model using Abaqus/Explicit finite element code and their effects are reported in the paper. The variables considered include the target configuration (thickness), constitutive material model of the target, mass of the projectile, friction between the projectile and the target and shape of the projectile. The effect of the material behaviour was also studied through the use of two constitutive relations and to conclude the ballistic curves were calculated for several different target materials using data from literature. The numerical results were compared with existing data sourced from the literature and an analytical model was used to compare the trend obtained using numerical simulations in terms of ballistic limit. [Copyright &y& Elsevier]

Published

2013

6. Finite element analysis to predict penetration and perforation of thick FRP laminates struck by projectiles

Author

He, T., Wen, H.M., and Qin, Y.

Subjects

*FINITE element method, *FORCING (Model theory), *BALLISTICS, *COMPOSITE materials

Abstract

Abstract: This paper examines the penetration and perforation of fibre-reinforced plastic (FRP) laminates struck by rigid projectiles with different nose shapes within a wide range of impact conditions using ABAQUS/Explicit code. It is assumed that the FRP laminate target response can be represented by a velocity dependent forcing function which eliminates discretizing the target as well as the need for a complex contact algorithm. The forcing function is then applied to the surface of the projectiles as boundary conditions in the numerical model. With this combined analytical and computational technique we can obtain the depth of penetration, residual velocity, ballistic limit, transient response in terms of time-histories of displacement/penetration, velocity and deceleration of the projectile. It is shown that the model predictions are in good correlation with available experimental data. [Copyright &y& Elsevier]

Published

2008

7. An investigation of the constitutive behavior of Armox 500T steel and armor piercing incendiary projectile material.

Author

Iqbal, M.A., Senthil, K., Sharma, P., and Gupta, N.K.

Subjects

*STEEL, *HOPKINSON bars (Testing), *STRAINS & stresses (Mechanics), *PROJECTILES, *FINITE element method

Abstract

A detailed investigation has been carried out for studying the constitutive behavior of Armox 500T steel and armor piercing incendiary projectile (API) material under varying stress state, strain rate and temperature. The characterization of Armox 500T steel showed increase in its strength with increase in stress triaxiality as well as strain rate. Increment in temperature, on the other hand, induced significant increase in the material ductility while reducing its strength. The API projectile material remained insensitive to stress-triaxiality and strain rate; however, it was highly sensitive to thermal effects. Results thus obtained from experiments on the specimens of both the materials were subsequently employed for calibrating the material parameters of Johnson–Cook (JC) flow and fracture model. The calibrated JC model for Armox 500T steel has been validated by numerically simulating the high strain rate tension tests performed on split Hopkinson pressure bar apparatus. The ballistic experiments were carried out wherein 8 and 10 mm thick Armox 500T steel target plates were impacted by 7.62 and 12.7 API projectiles respectively at a normal incidence with a velocity of nearly 830 m/s. The results of the ballistic tests were reproduced through finite element simulations performed on ABAQUS/Explicit finite element code employing calibrated JC model for the target as well as the projectile material. Experimental and numerical findings with respect to failure mechanism and ballistic resistance of the target are presented and discussed. It is seen that the computed failure modes and residual velocities accurately matched the experiments. Further, the ballistic limit of the target material was obtained numerically and the values obtained were validated through the Recht–Ipson empirical model. [ABSTRACT FROM AUTHOR]

Published

2016