In this study, the perforation of 6061-T651 aluminum alloy (AA) plates by 4340 steel ogive-nose projectiles with normal impacts is considered. The perforation process is assumed to be entirely due to ductile hole growth. Therefore, the cylindrical cavity expansion (CCE) approximation is employed to determine the ballistic limit and residual velocities for 26.3 mm-thick AA6061-T651 target plates. The target plates are considered to be fully elastically compressible, ductile, von Mises solids with the power-law strain hardening, strain rate hardening, and thermal softening due to thermo-mechanical coupling under adiabatic loading conditions. The dynamic CCE simulations based on the finite element method (FEM) provide solutions at various constant expansion velocities utilizing the transient solid-dynamics commercial software Abaqus. At each constant CCE velocity, a minute pre-existing cavity is expanded until the radial cavity-surface displacement reaches the characteristic length identified herein with the projectile shank radius. The corresponding radial stress at the cavity surface coincides with a nearly steady-state value. Subsequently, radial stress versus radial CCE velocity data are fitted with a full quadratic function that is then employed with Newton’s second law to define the axial force acting on the projectile’s nose due to the resistance of the target plate. The corresponding ballistic limit and residual velocities are obtained and demonstrated to be in fairly good agreement with both experimental perforation data and closed-form analytical solutions. The small disparity in results is discussed in detail.
Abaqus 2018 (2018) Simulia User Assistance. Dassault Systems.
2.
AngelRJGonzalez-PlatasJAlvaroM (2014) EosFit7c and a Fortran module (library) for equation of state calculations. Zeitschrift für Kristallographie - Crystalline Materials229: 405–419.
BourneNK (2012) On the failure and dynamic performance of materials. Experimental Mechanics52: 153–159.
5.
CamachoGTOrtizM (1997) Adaptive Lagrangian modelling of ballistic penetration of metallic targets. Computer Methods in Applied Mechanics and Engineering142(3–4): 269–301.
6.
CourantRFriedrichsKLewyH (1928) On the partial difference equations of mathematical physics. Mathematische Annalen100: 32–74.
7.
CrozierJMHunterSC (1970) Similarity solution for the rapid uniform expansion of a cylindrical cavity in a compressible elastic-plastic solid. The Quarterly Journal of Mechanics and Applied Mathematics23: 349–363.
8.
DevoreJL (1987) Probability and Statistics for Engineering and the Sciences. 2nd edition. Brooks/Cole Publishing Co.
9.
FeldgunVRYankelevskyDZ (2020) Constitutive equations for reliable projectile penetration analysis into a concrete medium. International Journal of Protective Structures11(2): 159–184.
10.
ForrestalMJWarrenTL (2008) Penetration equations for ogive-nose rods into aluminum targets. International Journal of Impact Engineering35: 727–730.
11.
ForrestalMJWarrenTL (2009) Perforation equations for conical and ogival nose rigid projectiles into aluminum plate targets. International Journal of Impact Engineering36: 220–225.
12.
ForrestalMJRosenbergZLukVK, et al. (1987) Perforation of aluminum plates with conical-nosed rods. Journal of Applied Mechanics54: 230–232.
13.
ForrestalMJOkajimaKLukVK (1988) Penetration of 6061-t651 aluminum targets with rigid long rods. Journal of Applied Mechanics55: 755–760.
14.
ForrestalMJLukVKBrarNS (1990) Perforation of aluminum armor plates with conical-nose projectiles. Mechanics of Materials10: 97–105.
15.
GradshteynLSRyzhikIM (1965) Table of Integrals, Series, and Products. Academic Press Inc.
16.
HillR (1950) The Mathematical Theory of Plasticity. Oxford University Press.
17.
HolmenJKJohnsenJHopperstadOS, et al. (2016) Influence of fragmentation on the capacity of aluminum alloy plates subjected to ballistic impact. European Journal of Mechanics – A/Solids55: 221–233.
18.
JohnsenJHolmenJKWarrenTL, et al. (2018) Cylindrical cavity expansion approximations using different constitutive models for the target material. International Journal of Protective Structures9: 199–225.
19.
JohnsonGRCookWH (1983) A constitutive model and data for metals subjected to large strains, high strain rates, and high temperatures. In: Proceedings of the 7th International Symposium on Ballistics. The Hague, 19–21 April 1983, pp 1–6.
20.
KawaharaWA (1986) Compression materials testing at low to medium strain rates. ASME Winter Annual Meeting 86-WA/Mats-15: 1–5.
21.
LemaitreJ (2001) Handbook of Materials Behavior Models. Academic Press.
22.
LesterBTScherzingerWM (2019) Adiabatic Heating in Modular Plasticity Models. SAND2019-15003R. Sandia National Laboratories.
23.
ManesAPeroniLScapinM, et al. (2011) Analysis of strain rate behavior of an Al 6061 T6 alloy. Procedia Engineering10: 3477–3482.
24.
ManesASerpelliniFPaganiM, et al. (2014) Perforation and penetration of aluminium target plates by armour piercing bullets. International Journal of Impact Engineering69: 39–54.
25.
MasriR (2015) Ballistically equivalent aluminum targets and the effect of hole slenderness ratio on ductile plate perforation. International Journal of Impact Engineering89: 45–55.
26.
MasriRDurbanD (2006) Dynamic cylindrical cavity expansion in an incompressible elastoplastic medium. Acta Mechanica181: 105–123.
27.
MasriRRyanS (2024) Approximate theory of armour perforation by ductile hole expansion. International Journal of Impact Engineering187: 104925.
28.
MastilovicS (2022) A PD simulation-informed prediction of penetration depth of rigid rods through materials susceptible to microcracking. Meccanica57: 3051–3069.
29.
MastilovicSKrajcinovicD (1999) Penetration of rigid projectiles through quasi-brittle materials. Journal of Applied Mechanics66: 585–592.
30.
MingLPantaléO (2018) An efficient and robust VUMAT implementation of elastoplastic constitutive laws in Abaqus/Explicit finite element code. Mechanics and Industry19: 308.
31.
PiekutowskiAJForrestalMJPoormonKL, et al. (1996) Perforation of aluminum plates with ogive-nose steel rods at normal and oblique impacts. International Journal of Impact Engineering18: 877–887.
32.
PressWHTeukolskySAVetterlingWT, et al. (1990) Numerical Recipes the Art of Scientific Computing. Cambridge University Press.
33.
RechtRFIpsonTW (1963) Ballistic perforation dynamics. Journal of Applied Mechanics30: 384–390.
34.
RenG-MWuHFangQ, et al. (2017) Parameters of Holmquist–Johnson–Cook model for high-strength concrete-like materials under projectile impact. International Journal of Protective Structures8(3): 352–367.
35.
SalehM (2019) On the use of a modified Forrestal–Warren analytical perforation model for high hardness steel armour and Ti–6Al–4V. International Journal of Impact Engineering134: 103384.
36.
SenthilKIqbalMARupaliS (2019) Influence of impactor nature, mass, size and shape on ballistic resistance of mild steel and Armox 500 T steel. International Journal of Protective Structures10(2): 174–197.
37.
WangLYangLDomgX, et al. (2019) Dynamics of Materials: Experiments, Models and Applications. Elsevier.
38.
WangYZengXChenH, et al. (2021) Modified Johnson-Cook constitutive model of metallic materials under a wide range of temperatures and strain rates. Results in Physics27: 104498.
39.
WarrenTL (2024) Perforation of 5083-H131 aluminum armor plates by conical-nose tungsten rods with and without target inertia. International Journal of Impact Engineering190: 104971.
40.
WarrenTLForrestalMJ (1998) Effects of strain hardening and strain rate sensitivity on the penetration of aluminum targets with spherical-nosed rods. International Journal of Solids and Structures35: 3737–3753.
41.
WarrenTLJohnsonJKristoffersenM, et al. (2023) Solution for the dynamic elastically compressible power-law strain hardening cylindrical cavity-expansion problem. Journal of Dynamic Behavior of Materials9: 65–78.
42.
YadavSChichiliDRRameshKT (1995) The mechanical response of a 6061-T6 Al/Al2O3 metal matrix composite at high rates of deformation. Acta Metallurgica et Materialia12: 4453–4464.
43.
ZhouLWenH (2019) A new dynamic plasticity and failure model for metals. Metals9: 905.
