Roles of the Interphase Stiffness and Percolation on the Behavior of Solid Propellants

Paul Aymé Toulemonde; Julie Diani; Pierre Gilormini; Geneviève Lacroix; Nancy Desgardin

doi:10.1002/prep.201600062

Roles of the Interphase Stiffness and Percolation on the Behavior of Solid Propellants

Paul Aymé Toulemonde
, Julie Diani
, Pierre Gilormini
, Geneviève Lacroix
, Nancy Desgardin

Research output: Contribution to journal › Article › peer-review

Abstract

Atomic force microscopy has provided access to local moduli for propellants prepared with bonding agents, which create a stiffness gradient in the matrix producing a stiffer interphase surrounding the fillers. The reinforcing impact of the bonding agent appears up to some distance and interphase percolation is observed. In order to better understand the impact of bonding agents on the stress and strain at break of propellants, finite element simulations are performed. Two-dimensional periodic cells containing randomly dispersed particles are considered, including both a cohesive zone model at the filler/matrix interface to account for possible debonding and an interphase that percolates or not. The influence of the interphase stiffness and of its percolation, on the stress and strain at break of the model propellants are evaluated through the use of a microstructure-based failure criterion.

Original language	English
Pages (from-to)	978-986
Number of pages	9
Journal	Propellants, Explosives, Pyrotechnics
Volume	41
Issue number	6
DOIs	https://doi.org/10.1002/prep.201600062
Publication status	Published - 1 Dec 2016
Externally published	Yes

Keywords

Finite element analysis
Interphase
Matrix/particle interface
Mechanical behavior
Propellants

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10.1002/prep.201600062

Cite this

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title = "Roles of the Interphase Stiffness and Percolation on the Behavior of Solid Propellants",

abstract = "Atomic force microscopy has provided access to local moduli for propellants prepared with bonding agents, which create a stiffness gradient in the matrix producing a stiffer interphase surrounding the fillers. The reinforcing impact of the bonding agent appears up to some distance and interphase percolation is observed. In order to better understand the impact of bonding agents on the stress and strain at break of propellants, finite element simulations are performed. Two-dimensional periodic cells containing randomly dispersed particles are considered, including both a cohesive zone model at the filler/matrix interface to account for possible debonding and an interphase that percolates or not. The influence of the interphase stiffness and of its percolation, on the stress and strain at break of the model propellants are evaluated through the use of a microstructure-based failure criterion.",

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doi = "10.1002/prep.201600062",

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T1 - Roles of the Interphase Stiffness and Percolation on the Behavior of Solid Propellants

AU - Toulemonde, Paul Aymé

AU - Diani, Julie

AU - Gilormini, Pierre

AU - Lacroix, Geneviève

AU - Desgardin, Nancy

PY - 2016/12/1

Y1 - 2016/12/1

N2 - Atomic force microscopy has provided access to local moduli for propellants prepared with bonding agents, which create a stiffness gradient in the matrix producing a stiffer interphase surrounding the fillers. The reinforcing impact of the bonding agent appears up to some distance and interphase percolation is observed. In order to better understand the impact of bonding agents on the stress and strain at break of propellants, finite element simulations are performed. Two-dimensional periodic cells containing randomly dispersed particles are considered, including both a cohesive zone model at the filler/matrix interface to account for possible debonding and an interphase that percolates or not. The influence of the interphase stiffness and of its percolation, on the stress and strain at break of the model propellants are evaluated through the use of a microstructure-based failure criterion.

AB - Atomic force microscopy has provided access to local moduli for propellants prepared with bonding agents, which create a stiffness gradient in the matrix producing a stiffer interphase surrounding the fillers. The reinforcing impact of the bonding agent appears up to some distance and interphase percolation is observed. In order to better understand the impact of bonding agents on the stress and strain at break of propellants, finite element simulations are performed. Two-dimensional periodic cells containing randomly dispersed particles are considered, including both a cohesive zone model at the filler/matrix interface to account for possible debonding and an interphase that percolates or not. The influence of the interphase stiffness and of its percolation, on the stress and strain at break of the model propellants are evaluated through the use of a microstructure-based failure criterion.

KW - Finite element analysis

KW - Interphase

KW - Matrix/particle interface

KW - Mechanical behavior

KW - Propellants

U2 - 10.1002/prep.201600062

DO - 10.1002/prep.201600062

M3 - Article

AN - SCOPUS:84992091754

SN - 0721-3115

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JO - Propellants, Explosives, Pyrotechnics

JF - Propellants, Explosives, Pyrotechnics

IS - 6

ER -

Roles of the Interphase Stiffness and Percolation on the Behavior of Solid Propellants

Abstract

Keywords

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