Modeling Dynamic Anisotropic Behaviour and Spall Failure in Commercial Aluminium Alloys AA7010

This paper presents a finite strain constitutive model to predict a complex elastoplastic deformation behaviour involves very high pressures and shockwaves in orthotropic materials of aluminium alloys. The previous published constitutive model is used as a reference to start the development in this...

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Veröffentlicht in:	Journal of dynamic behavior of materials 2018-06, Vol.4 (2), p.201-210
Hauptverfasser:	Mohd Nor, M. K., Ma’at, N., Ho, C. S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Aluminum base alloys Chemistry and Materials Science Constitutive models Deformation Elastoplasticity Equations of state Failure Impact tests Materials Science Mathematical models Metallic Materials Plate impact tests Shock waves Solid Mechanics Yield criteria
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container_title	Journal of dynamic behavior of materials
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creator	Mohd Nor, M. K. Ma’at, N. Ho, C. S.
description	This paper presents a finite strain constitutive model to predict a complex elastoplastic deformation behaviour involves very high pressures and shockwaves in orthotropic materials of aluminium alloys. The previous published constitutive model is used as a reference to start the development in this work. The proposed formulation that used a new definition of Mandel stress tensor to define Hill’s yield criterion and a new shock equation of state (EOS) of the generalised orthotropic pressure is further enhanced with Grady spall failure model to closely predict shockwave propagation and spall failure in the chosen commercial aluminium alloy. This hyperelastic-plastic constitutive model is implemented as a new material model in the Lawrence Livermore National Laboratory (LLNL)-DYNA3D code of UTHM’s version, named Material Type 92 (Mat92). The implementations of a new EOS of the generalised orthotropic pressure including the spall failure are also discussed in this paper. The capability of the proposed constitutive model to capture the complex behaviour of the selected material is validated against range of Plate Impact Test data at 234, 450 and 895 ms −1 impact velocities.
doi_str_mv	10.1007/s40870-018-0150-x
format	Article
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The implementations of a new EOS of the generalised orthotropic pressure including the spall failure are also discussed in this paper. 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K.</creatorcontrib><creatorcontrib>Ma’at, N.</creatorcontrib><creatorcontrib>Ho, C. S.</creatorcontrib><title>Modeling Dynamic Anisotropic Behaviour and Spall Failure in Commercial Aluminium Alloys AA7010</title><title>Journal of dynamic behavior of materials</title><addtitle>J. dynamic behavior mater</addtitle><description>This paper presents a finite strain constitutive model to predict a complex elastoplastic deformation behaviour involves very high pressures and shockwaves in orthotropic materials of aluminium alloys. The previous published constitutive model is used as a reference to start the development in this work. The proposed formulation that used a new definition of Mandel stress tensor to define Hill’s yield criterion and a new shock equation of state (EOS) of the generalised orthotropic pressure is further enhanced with Grady spall failure model to closely predict shockwave propagation and spall failure in the chosen commercial aluminium alloy. 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The previous published constitutive model is used as a reference to start the development in this work. The proposed formulation that used a new definition of Mandel stress tensor to define Hill’s yield criterion and a new shock equation of state (EOS) of the generalised orthotropic pressure is further enhanced with Grady spall failure model to closely predict shockwave propagation and spall failure in the chosen commercial aluminium alloy. This hyperelastic-plastic constitutive model is implemented as a new material model in the Lawrence Livermore National Laboratory (LLNL)-DYNA3D code of UTHM’s version, named Material Type 92 (Mat92). The implementations of a new EOS of the generalised orthotropic pressure including the spall failure are also discussed in this paper. 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subjects	Aluminum base alloys Chemistry and Materials Science Constitutive models Deformation Elastoplasticity Equations of state Failure Impact tests Materials Science Mathematical models Metallic Materials Plate impact tests Shock waves Solid Mechanics Yield criteria
title	Modeling Dynamic Anisotropic Behaviour and Spall Failure in Commercial Aluminium Alloys AA7010
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