Prediction of Probabilistic Detonation Threshold via Millimeter‐Scale Microstructure‐Explicit and Void‐Explicit Simulations

Miller, Christopher; Kittell, David E.; Yarrington, Cole; Zhou, Min

doi:10.1002/prep.201900214

Cited by 18 publications

(9 citation statements)

References 34 publications

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“…Commercially‐based DEM techniques [25–28] are powerful for their computational practicality in modeling macroscale particulate flow behaviors governed by the elastic or rigid body collisions of thousands of highly mobile particles. However, powdered EM materials have been shown to behave as highly plastic particles under drop hammer dynamic loads [14–29]. Modeling those types of impacts require that the plasticity of the particles be considered in the numerical treatment.…”

Section: Experiments and Simulation Frameworkmentioning

confidence: 99%

“…Over the past thirty years, a significant number of numerical studies have been devoted to modeling the initiation of heterogeneous solid explosives and propellants [15–17]. These numerical methodologies now extend into modern multiscale computational techniques that are leveraged on large‐scale computational systems [18–22]. Solid phase FEA simulations cannot reflect the influential role of the phenomena that occur as the EM response becomes dominated by phase changes.…”

Section: Introductionmentioning

confidence: 99%

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Modeling and Simulation of RDX Powder Thermo‐Mechanical Response to Drop Impact

Yakaboski

Kumar

2021

Propellants Explo Pyrotec

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A computational framework to predict the deformation, flow, and compaction of an energetic material (EM) powder subjected to drop impact is discussed. Explicit dynamic finite element analysis was performed to simulate drop‐weight impact tests for comparison with experimental results and to gain insight into the ignition sensitivity of RDX powder. The computations simulated the Thermo‐Mechanical behavior of a thin layer of energetic powder subjected to drop impact to study the dependence of ignition sensitivity on the anvil material properties. By modeling high strength steel and a low strength copper anvil, a direct comparison is made on how energy dissipation within the EM is influenced by anvil properties. A hybrid finite element model is introduced that captures the mesoscale discrete particle nature of the powder response in regions of interest while using a continuum model elsewhere to reduce computational cost. To capture the mesoscale behavior, a multi‐particle finite element method (MPFEM) approach was used in selected regions in the hybrid model. Powder temperatures were computed to understand how the striker impact energy is dissipated by plasticity and friction into localized heating of the EM that triggers the ignition. Munition designers can use such a framework to study the low‐level impact sensitivity of munitions in a computationally efficient manner. Results of the simulation using the hybrid model suggest that copper anvil undergoes plastic deformation which absorbs a significant portion of the impact energy reducing the energy dissipated within the EM and suppressing ignition.

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Section: Experiments and Simulation Frameworkmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling and Simulation of RDX Powder Thermo‐Mechanical Response to Drop Impact

Yakaboski

Kumar

2021

Propellants Explo Pyrotec

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“…More details on how the 3D and 2D SEMSS designed using the capability (4) presented in this paper can allow the multiphysics ME and VE simulations, prediction of microscopic behaviors, and probabilistic UQ are given in Refs. [3,17,29,55].…”

Section: D Shock-to-detonation Sensitivity Analysis With Microstructmentioning

confidence: 99%

“…So far, the need for uncertainty quantification (UQ) has not been systematically addressed in many physics-based simulations. The use of SEMSS provides an important avenue to address this need and the concept has mostly been used in 2D simulations [3,[18][19][20][21][22][23][24][25][26][27][28][29][30] over the past decade.…”

Section: Introductionmentioning

confidence: 99%

Computational Design of Three-Dimensional Multi-Constituent Material Microstructure Sets with Prescribed Statistical Constituent and Geometric Attributes

Wei

Olsen

Miller

et al. 2020

Multiscale Sci. Eng.

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The generation of three-dimensional (3D) microstructures with multiple constituents is an important part of multiscale computational simulation and design for a wide range of materials including heterogeneous polycrystalline metals, ceramics, composites, and energetics. Realistic 3D microstructures for multiphase materials are difficult to obtain experimentally or computationally. Challenges include generation and representation of complex constituent morphologies, topological arrangement and distribution, defect description, and statistical conformity. Here, we present a novel technique for systematically composing complex 3D statistically equivalent microstructure sample sets (SEMSS) with prescribed statistical constituents and morphological attributes. Based on large libraries of varying representations of individual constituents, the technique can be used with experimental micro computerized tomography (CT) scans to establish SEMSS that track the attributes of existing materials as well as to design SEMSS for new materials not yet in existence for computational exploration. Heterogeneous systems involving different combinations of molecular crystallites, metallic particles, oxidizer granules, and a polymeric matrix are designed and generated to track the properties of an existing material. The corresponding SEMSS are used in multiphysics simulations accounting for coupled thermal-mechanical processes or thermal-mechanical-chemically reactive processes. The results are used to quantify microstructure-induced response variations and point out the limitations of two-dimensional (2D) microstructures that are direct sections of the full 3D microstructures. The use of the SEMSS has also enabled uncertainty quantification (UQ) and the development of probabilistic characterizations for variations in macroscopic responses due to intrinsic material microstructural heterogeneities.

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“…The frontier in computational energetic materials research is to develop predictive multi-scale models to guide the design process of novel materials with tailored performance via microstructural control 12,13 . Predictive frameworks of energetic material response to loads are a matter of concerted current development by several groups worldwide [14][15][16][17][18][19][20] ; such capabilities are needed to establish structure-property-performance (S-P-P) linkages as necessary precursors to materials-by-design of heterogeneous materials 12,21,22 . The work presented previous approaches.…”

mentioning

confidence: 99%

Deep learning for synthetic microstructure generation in a materials-by-design framework for heterogeneous energetic materials

Chun

Roy

Nguyen

et al. 2020

Sci Rep

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the sensitivity of heterogeneous energetic (He) materials (propellants, explosives, and pyrotechnics) is critically dependent on their microstructure. initiation of chemical reactions occurs at hot spots due to energy localization at sites of porosities and other defects. emerging multi-scale predictive models of He response to loads account for the physics at the meso-scale, i.e. at the scale of statistically representative clusters of particles and other features in the microstructure. Meso-scale physics is infused in machine-learned closure models informed by resolved meso-scale simulations. Since microstructures are stochastic, ensembles of meso-scale simulations are required to quantify hot spot ignition and growth and to develop models for microstructure-dependent energy deposition rates. We propose utilizing generative adversarial networks (GAn) to spawn ensembles of synthetic heterogeneous energetic material microstructures. the method generates qualitatively and quantitatively realistic microstructures by learning from images of He microstructures. We show that the proposed GAn method also permits the generation of new morphologies, where the porosity distribution can be controlled and spatially manipulated. Such control paves the way for the design of novel microstructures to engineer He materials for targeted performance in a materials-by-design framework.

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Prediction of Probabilistic Detonation Threshold via Millimeter‐Scale Microstructure‐Explicit and Void‐Explicit Simulations

Cited by 18 publications

References 34 publications

Modeling and Simulation of RDX Powder Thermo‐Mechanical Response to Drop Impact

Modeling and Simulation of RDX Powder Thermo‐Mechanical Response to Drop Impact

Computational Design of Three-Dimensional Multi-Constituent Material Microstructure Sets with Prescribed Statistical Constituent and Geometric Attributes

Deep learning for synthetic microstructure generation in a materials-by-design framework for heterogeneous energetic materials

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