A unified multi-phase and multi-material formulation for combustion modelling

TL;DR

This paper introduces a unified PDE-based model for simulating the complex elastoplastic and multi-material responses of explosives and confiners during detonation, capturing miscible and immiscible behaviors.

Contribution

It develops a novel integrated formulation combining Peshkov and Romenski's PDE system with multi-material explosive modeling, enabling comprehensive simulation of detonation phenomena.

Findings

Model accurately simulates nonlinear interactions in explosive systems.

Validated against exact solutions for various detonation scenarios.

Capable of handling diverse material states and interface dynamics.

Abstract

The motivation of this work is to produce an integrated formulation for material response due to detonation wave loading. Here, we focus on elastoplastic structural response. In particular, we are interested to capture miscible and immiscible behaviour within condensed-phase explosives arising from the co-existence of a reactive carrier mixture of miscible materials, and several material interfaces due to the presence of immiscible impurities such as particles or cavities. The dynamic and thermodynamic evolution of the explosive is communicated to one or more inert confiners through their shared interfaces, which may undergo severe topological change. We also wish to consider elastic and plastic structural response of the confiners, rather than make a hydrodynamic assumption for their behaviour. Previous work by these authors has met these requirements by means of the simultaneous solution of appropriate systems of equations for the behaviour of the condensed-phase explosive and the elastoplastic behaviour of the confiners. In the present work, we employ a single system of partial differential equations (PDEs) proposed by Peshkov and Romenski, which is able to account for different states of matter by means of generalising the concept of distortion tensors beyond solids. We amalgamate that formulation with a single system of PDEs which meets the requirement of co-existing miscible and immiscible explosive mixtures. We present the mathematical derivation and construct appropriate algorithms for its solution. The resulting model is validated against exact solutions for several use-cases, including mechanically- and thermally-induced, inviscid and viscous detonations. Results indicate that the model can accurately simulate a very broad range of problems involving the nonlinear interaction between reactive and inert materials within a single framework.