TY - GEN
T1 - Verification and Validation of a Generalized Orthotropic Material Model MAT213 Implemented in LS-DYNA
AU - Shyamsunder, Loukham
AU - Khaled, Bilal
AU - Holt, Nathan
AU - Hoffarth, Canio
AU - Rajan, Subramaniam
AU - Goldberg, Robert
AU - Carney, Kelly S.
AU - Dubois, Paul
AU - Blankenhorn, Gunther
N1 - Funding Information: Authors Shyamsunder, Khaled, Holt, Hoffarth and Rajan gratefully acknowledge the support of (a) the Federal Aviation Administration through Grant #12-G-001 titled “Composite Material Model for Impact Analysis”, William Emmerling, Technical Monitor, and (b) NASA through Contract Number: NN15CA32C titled “Development and Implementation of an Orthotropic Plasticity Progressive Damage Model for Transient Dynamic/Impact Finite Element Analysis of Composite Structures”, Robert Goldberg, Contracting Officer Representative. Publisher Copyright: © Copyright© (2018) by DEStech Publications, Inc. All rights reserved.
PY - 2018
Y1 - 2018
N2 - A general orthotropic material model has been developed which is suitable for impact analysis. The material model is driven by tabulated data rather than point-wise material properties data, and has been implemented into LS-DYNA. The stress-strain behavior of a material is one of the input tabulated data used to drive the material model which can be obtained either from experiment or virtual testing or a combination of both. The material model consists of three sub-models – deformation, damage and failure. The implementation of the sub-models and some of the salient features are presented in this paper. The second part of the paper presents some of the validation tests carried out using a unidirectional fiber reinforced composite, T800/F3900.
AB - A general orthotropic material model has been developed which is suitable for impact analysis. The material model is driven by tabulated data rather than point-wise material properties data, and has been implemented into LS-DYNA. The stress-strain behavior of a material is one of the input tabulated data used to drive the material model which can be obtained either from experiment or virtual testing or a combination of both. The material model consists of three sub-models – deformation, damage and failure. The implementation of the sub-models and some of the salient features are presented in this paper. The second part of the paper presents some of the validation tests carried out using a unidirectional fiber reinforced composite, T800/F3900.
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M3 - Conference contribution
T3 - 33rd Technical Conference of the American Society for Composites 2018
SP - 279
EP - 290
BT - 33rd Technical Conference of the American Society for Composites 2018
PB - DEStech Publications Inc.
T2 - 33rd Technical Conference of the American Society for Composites 2018
Y2 - 24 September 2018 through 27 September 2018
ER -