Reacting condensed phase explosives in direct contact

TL;DR

This paper introduces a new computational model and algorithm for simulating the complex interactions of multiple condensed phase explosives in direct contact, including their interaction with inert materials, validated through various case studies.

Contribution

It extends existing hybrid formulations to model multiple explosive interactions and develops a robust density retrieval method within an adaptive mesh framework.

Findings

Successfully simulates detonation interactions of different explosives in contact.

Validates robustness through rate-stick and shock-flow case studies.

Demonstrates explicit modeling of reactive particles in heterogeneous explosives.

Abstract

In this article we present a new formulation and an associated algorithm for the simultaneous numerical simulation of multiple condensed phase explosives in direct contact with each other, which may also be confined by (or interacting with one or more) compliant inert materials. Examples include composite rate-stick problems and interaction of shock waves with chemically-active particles in condensed-phase explosives. There are several formulations which address the compliant or structural response of confiners and particles due to detonations, but the direct interaction of explosives remains a challenge for most formulations and algorithms. The proposed formulation addresses this problem by extending the conservation laws and mixture rules of an existing hybrid formulation to model the interaction of multiple explosive mixtures. An algorithm for the solution of the resulting system of partial differential equations is presented, which includes a new robust method for the retrieval of the densities of the constituents of each explosive mixture. The algorithm is implemented in a hierarchical adaptive mesh refinement framework and validated against results from problems with known solutions. It is evaluated for robustness for rate-stick and shock-induced flows in particle-laden explosives case-studies. It is shown that the method can simulate the interaction of detonation waves produced by military grade and commercial explosives in direct contact, each with its own distinct equation of state and reaction rate law. The ability of the new model to simulate reactive particles which are explicitly resolved in a heterogeneous explosive is demonstrated by a case-study of a shock wave interacting with a high explosive bead embedded in liquid nitromethane.