Phenomenology of the Maximum Fragment Mass Dependence Upon Ballistic Impact Parameters

Mastilović, Sreten

doi:10.1590/1679-78253058

Cited by 3 publications

(11 citation statements)

References 45 publications

(82 reference statements)

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“…The temperature definition (3.4) has the firm statistical-mechanics foundations since it follows from the canonical ensemble maximum-probability distribution. It was verified by the statistical hypothesis testing that the vibrational velocities obtained from these MD simulations represent a random sample corresponding to the Maxwell-Boltzmann distribution [12]. The temperature evolution in time and space can be vividly presented with a very high-resolution [11].…”

Section: Molecular Dynamicsmentioning

confidence: 78%

“…MD is a convenient tool to investigate dynamic response of solids under extreme loading conditions by high-resolution virtual testing. Therefore, it frequently assumes a role of a "computational microscope" to explore evolution of discrete systems at spatial and temporal scales that go beyond the current experimental limits (e.g., [3,[10][11][12]). The present approach is limited to the classic MD simulation technique in which the dynamic state of an atomic system is defined by laws of Newtonian mechanics with atomic motions being uniquely determined by empirical potentials.…”

Section: Molecular Dynamicsmentioning

confidence: 99%

“…Thus, a monatomic system (mimicking a monocrystalline sample) is comprised of atoms of equal masses = 0 ( = 1, ) that form an ideal triangular lattice and interact with their nearest neighbors according to the L-J (Lennard-Jones) potential. The Cauchy problem is solved numerically by using the Verlet algorithm and the neighbor-list method [9,13,14] with the time step as low as a fraction of femtosecond [11,12]. The extremely small time step, necessitated by the ultrahigh power of the simulated events, makes the simulations painstakingly time-consuming even for the relatively small model size.…”

Section: Molecular Dynamicsmentioning

confidence: 99%

“…and illustrated by Figure 6 [12]. The phenomenological model (4.9) is developed based on the reverse-sigmoid form of the Weibull equation (1.1b), where the three uppercase alphabetic letters ( , , ), as in the preceding cases, designate the fitting parameters (for example, in Figure 6a, = 4, = 7, = 2.2).…”

Section: High-velocity Expansion Of a Cylindricalmentioning

confidence: 99%

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Some sigmoid and reverse-sigmoid response patterns emerging from high-power loading of solids

Mastilović

2018

Theor appl mech (Belgr)

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The objective of the present review is twofold. First, it aims at highlighting some sigmoid and reverse-sigmoid response patterns observed recently in the course of simulations of the high-strain-rate loading of (mostly, quasibrittle) solids. Second, it aims at reviewing various properties of two models used frequently as curve fitting tools for nonlinear and saturable phenomena. These two models-inspired by the Hill and the Weibull cumulative distribution functions-are bounded by two horizontal asymptotes with a smooth transition between the baseline and the final saturation state, characterized by a non-negative (a non-positive) derivative at each point for the sigmoid (the reverse-sigmoid) shape. Although they were used primarily for data fitting because of their flexibility and effectiveness, these nonlinear models possess other properties useful for the analysis of the irreversible, nonlinear and far-from-equilibrium phenomena. The main features of these two models are systematically examined in this review. In spite of the fact that satisfactory curve-fitting of data could not be considered a proof of causality it could underline a pattern of behavior and, perhaps, provide an investigation guidance.

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Section: Molecular Dynamicsmentioning

confidence: 78%

Section: Molecular Dynamicsmentioning

confidence: 99%

Section: Molecular Dynamicsmentioning

confidence: 99%

Section: High-velocity Expansion Of a Cylindricalmentioning

confidence: 99%

See 2 more Smart Citations

Some sigmoid and reverse-sigmoid response patterns emerging from high-power loading of solids

Mastilović

2018

Theor appl mech (Belgr)

Self Cite

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“…The issue of dynamic fragmentation of solid material under impact loading is a long-term research topic in the fields of elastic-plastic mechanics, dynamic mechanical properties of material, aerospace and weapon science. At present, the main methods to simulate the dynamic fracture of solid material are finite element method (FEM) 2 , discrete element method (DEM) 3 , finite element method combined with discrete element method [4][5] , level set method 6 , molecular dynamics method 7 and smooth particle hydrodynamics (SPH) method [8][9][10] . The finite element method is difficult to display the discontinuity accurately such as crack, for it is difficult to deal with the contact problem of the crack surface and crack propagation on multiple elements 11 .…”

Section: Introductionmentioning

confidence: 99%

Simulation of Fragmentation Characteristics of Projectile Jacket Made of Tungsten Alloy after Penetrating Metal Target Plate using SPH Method

Cheng

Chen

et al. 2019

Def. Sc. Jl.

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A smooth particle hydrodynamics (SPH) model was used to simulate the fragmentation process of the jacket during penetrator with lateral efficiency (PELE) penetrating the metal target plate to study the fragmentation characteristics of PELE jacket made of tungsten alloy. The validity of the SPH model was verified by experimental results. Then the SPH model was used to simulate the jacket fragmentation under different impact velocity and thickness of target plate. The influence of impact velocity and thickness of target plate on the jacket fragmentation was obtained by analysing the mass distribution and quantity distribution of the fragments formed by the jacket. The results show that the dynamic fragmentation of tungsten alloy can be simulated effectively using the SPH model, Johnson-Cook strength model, maximum tensile stress failure criterion and stochastic failure model. When the thickness of target plate is fixed, the greater the impact velocity, the greater the pressure produced by the projectile impacting the target plate; with the increase of impact velocity, the mass of residual projectile decreases, the number of fragments formed by fragmentation of jacket increases linearly, and the average mass of fragments decreases exponentially. When the impact velocity is constant, the greater the thickness of the target plate, the longer the pressure duration by the projectile impacting the target plate; with the increase of the thickness of target plate, the mass of residual projectile decreases, the number of fragments formed by fragmentation of jacket increases linearly, and the average mass of fragments decreases exponentially. The numerical calculation model and research method adopted in this paper can be used to study the impact fragmentation of solid materials effectively.

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Shattering impact fragmentation of slender nanoprojectiles

Mastilović

2019

Meccanica

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Molecular dynamics simulations of the rigid-anvil collision test are performed to achieve the complete pulverization of slender nanoprojectiles. The simulation setup mimics the traditional Taylor test (the flatended nanoscale bars collide with a rough rigid wall) at striking velocities that reach an awesome range from 20 km/s to 120 km/s. The objective is to investigate, so called, shattering fragmentation, defined by the complete disintegration (pulverization) of the slender monocrystalline nanoprojectile into the cloud of monatomic debris (mmax = mmax1 ≡ 1). The critical impact energy associated with this transition from the stochastic to the deterministic fragment distribution is investigated at two widely different initial temperatures of the slender nanoprojectile while scaling its size in a self-similar manner by varying their widths (diameters) at a fixed aspect ratio. For all but the smallest nanoprojectiles, the minimum achievable mmax >> mmax1 is discussed based on the physically-limiting striking velocity range.

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Phenomenology of the Maximum Fragment Mass Dependence Upon Ballistic Impact Parameters

Cited by 3 publications

References 45 publications

Some sigmoid and reverse-sigmoid response patterns emerging from high-power loading of solids

Some sigmoid and reverse-sigmoid response patterns emerging from high-power loading of solids

Simulation of Fragmentation Characteristics of Projectile Jacket Made of Tungsten Alloy after Penetrating Metal Target Plate using SPH Method

Shattering impact fragmentation of slender nanoprojectiles

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