Understanding the shock and detonation response of high explosives at the continuum and meso scales

Handley, Caroline; Lambourn, B. D.; Whitworth, N. J.; James, H. R.; Belfield, William

doi:10.1063/1.5005997

Cited by 159 publications

(107 citation statements)

References 152 publications

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“…In our simulations, however, we have used a cutoff diameter of 70 μm, so that all particles below this are not considered. Ideally the discarded HMX would be lumped with the binder to create a homogeneous blend, sometimes referred to as a “dirty binder” . However, since the detonation properties for the blend are not known, we treat the blend as a single material of inert binder (Estane).…”

Section: Resultsmentioning

confidence: 99%

“…Our approach has been to develop a multiscale approach where the details at the microscale are connected to the mesoscale, since the microstructure can play an important role in detonation initiation [1][2][3][4][10][11][12][13][14][15][16]. As a first step, we run simulations of void collapse and collect ignition times and total power output as a function of shock pressure and void diameter [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

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Multiscale Approach to Shock to Detonation Transition in Energetic Materials

Jackson

Short

2019

Propellants Explo Pyrotec

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In this work we present a multiscale approach for coupling the dynamics of void collapse at the microscale to simulations at the mesoscale. We solve the reactive Euler equations, with the energy equation augmented by a power deposition term. The reaction rate at the mesoscale is modelled using a pressure‐dependent power law. The deposition term is based on previous simulations of void collapse, modelled at the mesoscale as hot‐spots. The equation of state was previously calibrated for PBX 9501. The run‐to‐detonation distance is calculated as part of the numerical solution procedure. Results for 1‐D, 2‐D homogeneous, and 2‐D heterogeneous medium are presented, and show good agreement to experimental data.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Multiscale Approach to Shock to Detonation Transition in Energetic Materials

Jackson

Short

2019

Propellants Explo Pyrotec

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“…Reaction then develops into a “hump” or “spike” behind the leading wave, similar to what is observed in the embedded velocity gauge data . We note that while experimental data more closely resembles that of a rounded “hump,” the “spike” is a characteristic of the Lee‐Tarver reaction rate , and this particular feature could be improved via adaptation of a current burn model . Regardless, the effective heat release allows the material impedance to grow, so that energy is propagated forward along the right‐running characteristics; this increases the strength of the leading wave.…”

Section: Simulation Resultsmentioning

confidence: 99%

“…Thus, the application of stochastic process modelling to current burn models (e. g. CREST, SURF, AWSD, SHS, etc. ) is beyond the scope of this work. Instead, it is thought that the stochastic nature of the SDT problem will have its greatest influence near the impact surface and at early times, and a simplified description of the early stages of shock initiation is considered here in a one‐dimensional scenario.…”

Section: Mathematical Modelmentioning

confidence: 99%

“…A third approach, atomistic simulations, is acknowledged here as it pertains to the mesoscale, but it is not discussed in detail. These efforts are summarized in a recent review paper by Handley et al [22], which provides for additional context and identifies some of the knowledge gaps within the field. From this body of literature, it is clear that a large gap exists between the data being generated at the mesoscale and the calibration of continuum burn model parameters; indeed, the current work is focused on finding a link between the meso and continuum scales in some meaningful way.…”

Section: Introductionmentioning

confidence: 99%

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Modelling the Fluctuations of Reactive Shock Waves in Heterogeneous Solid Explosives as Stochastic Processes

Kittell

Yarrington

Lechman

et al. 2019

Propellants Explo Pyrotec

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While current phenomenological burn models are useful for describing the average or bulk reactive flow behaviour of heterogeneous explosives, one fundamental weakness inherent to these models is the loss of detailed microstructural information at the scale of the calculation. In order to include the effects of the microstructure, and in particular the underlying material heterogeneities that influence the build‐up to detonation, a new paradigm is put forth for modelling sub‐grid, reaction‐induced fluctuations (i. e. “hot spots”) at the continuum level. This modelling approach assumes that the reaction rate is stochastic, rather than deterministic, and it uses Langevin‐type equations with a mathematical framework built upon Itô calculus and Lambourn's CIM model for shocked heterogeneous explosives. This approach follows directly from our previous letter, Ref. [1], and is inspired by the probability density function (pdf) methods used in turbulent reactive flows. Here, the stochastic burn model is derived, implemented, and exercised far beyond what has been shown in previous work. New hydrocode simulation results demonstrate the role of stochastic fluctuations during shock initiation; these fluctuations are approximated by collections of discrete particles, that evolve with drift (i. e. deterministic) and diffusion (i. e. stochastic) coefficients. Additionally, the particle values are propagated and averaged to calculate the heat release, yield strength, and material impedance in each computational cell. Hydrocode simulation results further show how the fluctuating hot spot energy may or may not be transmitted to the wave front, and result in a detonation wave‐like structure. The fundamental stochastic nature of this model permits simulations to have varying outcomes with the same initial conditions; this allows for go/no‐go estimation (e. g., marginal or failed detonations), which might possibly be calibrated using the statistical distributions from real materials. Mesoscale calculations of shocked heterogeneous explosives also show that these fluctuations are physically justified (i. e., Ref. [2]), and it is hypothesized that the pdf functions provide a link between the meso(grain) and continuum scales for practical engineering calculations. Thus, our approach is a paradigm shift for building efficient, reduced order continuum burn models, that represent the sub‐grid stochastic behaviour of shocked heterogeneous solid explosives.

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