Evaluation of XHVRB for capturing shock desensitization

Explosive shock desensitization phenomena have been recognized for some time. It has been demonstrated that pressure-based reactive flow models do not adequately capture the basic nature of the explosive behavior. Historically, replacing the local pressure with a shock captured pressure has dramatic...

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Hauptverfasser:	Tuttle, Leah, Schmitt, Robert, Kittell, Dave, Harstad, Eric
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Sprache:	eng
Schlagworte:	Computer simulation Desensitization Mathematical models Shock capturing
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creator	Tuttle, Leah Schmitt, Robert Kittell, Dave Harstad, Eric
description	Explosive shock desensitization phenomena have been recognized for some time. It has been demonstrated that pressure-based reactive flow models do not adequately capture the basic nature of the explosive behavior. Historically, replacing the local pressure with a shock captured pressure has dramatically improved the numerical modeling approaches. A pseudo-entropy based formulation using the History Variable Reactive Burn model, as proposed by Starkenberg, was implemented into the Eulerian shock physics code CTH. Improvements in the shock capturing algorithm in the model were made that allow reproduction of single shock behavior consistent with published Pop-plot data. It is also demonstrated to capture a desensitization effect based on available literature data, and to qualitatively capture multi-dimensional desensitization behavior. This model shows promise for use in modeling and simulation problems that are relevant to the desensitization phenomena. Issues are identified with the current implementation and future work is proposed for improving and expanding model capabilities.
doi_str_mv	10.1063/1.5044916
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subjects	Computer simulation Desensitization Mathematical models Shock capturing
title	Evaluation of XHVRB for capturing shock desensitization
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