TY - GEN
T1 - Implementation of a tabulated failure model into a generalized composite material model suitable for use in impact problems
AU - Goldberg, Robert K.
AU - Carney, Kelly S.
AU - DuBois, Paul
AU - Hoffarth, Canio
AU - Khaled, Bilal
AU - Shyamsunder, Loukham
AU - Rajan, Subramaniam
AU - Blankenhorn, Gunther
N1 - Funding Information: Authors Hoffarth, Khaled, Shyamsunder and Rajan gratefully acknowledge the support of (a) the Federal Aviation Administration through Grant #12-G001 titled "Composite Material Model for Impact Analysis", William Emmerling, Technical Monitor, and (b) NASA through Contract Number: NN15CA32C titled "Development and Implementation of an Orthotopic Plasticity Progressive Damage Model for Transient Dynamic/Impact Finite Element Analysis of Composite Structures", Robert Goldberg, Contracting Officer Representative. Publisher Copyright: Copyright © (2017) by DEStech Publications, Inc. All rights reserved.
PY - 2017
Y1 - 2017
N2 - The need for accurate material models to simulate the deformation, damage and failure of polymer matrix composites under impact conditions is becoming critical as these materials are gaining increased use in the aerospace and automotive communities. The aerospace community has identified several key capabilities which are currently lacking in the available material models in commercial transient dynamic finite element codes. To attempt to improve the predictive capability of composite impact simulations, a next generation material model is being developed for incorporation within the commercial transient dynamic finite element code LS-DYNA. The material model, which incorporates plasticity, damage and failure, utilizes experimentally based tabulated input to define the evolution of plasticity and damage and the initiation of failure as opposed to specifying discrete input parameters such as modulus and strength. The plasticity portion of the orthotopic, threedimensional, macroscopic composite constitutive model is based on an extension of the Tsai-Wu composite failure model into a generalized yield function with a nonassociative flow rule. For the damage model, a strain equivalent formulation is used to allow for the uncoupling of the deformation and damage analyses. For the failure model, a tabulated approach is utilized in which a stress or strain based invariant is defined as a function of the location of the current stress state in stress space to define the initiation of failure. Failure surfaces can be defined with any arbitrary shape, unlike traditional failure models where the mathematical functions used to define the failure surface impose a specific shape on the failure surface. In the current paper, the complete development of the failure model is described and the generation of a tabulated failure surface for a representative composite material is discussed.
AB - The need for accurate material models to simulate the deformation, damage and failure of polymer matrix composites under impact conditions is becoming critical as these materials are gaining increased use in the aerospace and automotive communities. The aerospace community has identified several key capabilities which are currently lacking in the available material models in commercial transient dynamic finite element codes. To attempt to improve the predictive capability of composite impact simulations, a next generation material model is being developed for incorporation within the commercial transient dynamic finite element code LS-DYNA. The material model, which incorporates plasticity, damage and failure, utilizes experimentally based tabulated input to define the evolution of plasticity and damage and the initiation of failure as opposed to specifying discrete input parameters such as modulus and strength. The plasticity portion of the orthotopic, threedimensional, macroscopic composite constitutive model is based on an extension of the Tsai-Wu composite failure model into a generalized yield function with a nonassociative flow rule. For the damage model, a strain equivalent formulation is used to allow for the uncoupling of the deformation and damage analyses. For the failure model, a tabulated approach is utilized in which a stress or strain based invariant is defined as a function of the location of the current stress state in stress space to define the initiation of failure. Failure surfaces can be defined with any arbitrary shape, unlike traditional failure models where the mathematical functions used to define the failure surface impose a specific shape on the failure surface. In the current paper, the complete development of the failure model is described and the generation of a tabulated failure surface for a representative composite material is discussed.
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M3 - Conference contribution
T3 - 32nd Technical Conference of the American Society for Composites 2017
SP - 1315
EP - 1330
BT - 32nd Technical Conference of the American Society for Composites 2017
A2 - Yu, Wenbin
A2 - Pipes, R. Byron
A2 - Goodsell, Johnathan
PB - DEStech Publications Inc.
T2 - 32nd Technical Conference of the American Society for Composites 2017
Y2 - 23 October 2017 through 25 October 2017
ER -