Development of a finite element model of metal powder compaction process at elevated temperature

This paper presents the finite element modelling of metal powder compaction process at elevated temperature. In the modelling, the behaviour of powder is assumed to be rate independent thermo-elastoplastic material where the material constitutive laws are derived based on a continuum mechanics appro...

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Main Authors: Rahman M.M., Ariffin A.K., Nor S.S.M.
Other Authors: 55328831100
Format: Article
Published: 2023
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spelling my.uniten.dspace-307962023-12-29T15:53:27Z Development of a finite element model of metal powder compaction process at elevated temperature Rahman M.M. Ariffin A.K. Nor S.S.M. 55328831100 6701641666 23492827600 Continuum mechanics Experimentation Finite element modelling Staggered-incremental-iterative solution Yield criteria Compaction Continuum mechanics Deformation Elasticity Experiments Finite element method Powder metallurgy Simulators Compaction process Constitutive law Deformation behaviour Deformation process Elastoplastic materials Elevated temperature Experimental data Experimentation Finite element formulations Finite element modelling Finite element models Iterative solutions Large displacements Metal powder Non-Linearity Numerical simulation Staggered-incremental-iterative solution Systems of equations Yield criteria Yield models Powder metals This paper presents the finite element modelling of metal powder compaction process at elevated temperature. In the modelling, the behaviour of powder is assumed to be rate independent thermo-elastoplastic material where the material constitutive laws are derived based on a continuum mechanics approach. The deformation process of metal powder has been described by a large displacement based finite element formulation. The Elliptical Cap yield model has been used to represent the deformation behaviour of the powder mass during the compaction process. This yield model was tested and found to be appropriate to represent the compaction process. The staggered-incremental-iterative solution strategy has been established to solve the non-linearity in the systems of equations. Some numerical simulation results were validated through experimentation, where a good agreement was found between the numerical simulation results and the experimental data. � 2009 Elsevier Inc. All rights reserved. Final 2023-12-29T07:53:26Z 2023-12-29T07:53:26Z 2009 Article 10.1016/j.apm.2009.02.005 2-s2.0-67649643500 https://www.scopus.com/inward/record.uri?eid=2-s2.0-67649643500&doi=10.1016%2fj.apm.2009.02.005&partnerID=40&md5=44d8980567ac15de2c4f2ca118fc35c9 https://irepository.uniten.edu.my/handle/123456789/30796 33 11 4031 4048 All Open Access; Bronze Open Access Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Continuum mechanics
Experimentation
Finite element modelling
Staggered-incremental-iterative solution
Yield criteria
Compaction
Continuum mechanics
Deformation
Elasticity
Experiments
Finite element method
Powder metallurgy
Simulators
Compaction process
Constitutive law
Deformation behaviour
Deformation process
Elastoplastic materials
Elevated temperature
Experimental data
Experimentation
Finite element formulations
Finite element modelling
Finite element models
Iterative solutions
Large displacements
Metal powder
Non-Linearity
Numerical simulation
Staggered-incremental-iterative solution
Systems of equations
Yield criteria
Yield models
Powder metals
spellingShingle Continuum mechanics
Experimentation
Finite element modelling
Staggered-incremental-iterative solution
Yield criteria
Compaction
Continuum mechanics
Deformation
Elasticity
Experiments
Finite element method
Powder metallurgy
Simulators
Compaction process
Constitutive law
Deformation behaviour
Deformation process
Elastoplastic materials
Elevated temperature
Experimental data
Experimentation
Finite element formulations
Finite element modelling
Finite element models
Iterative solutions
Large displacements
Metal powder
Non-Linearity
Numerical simulation
Staggered-incremental-iterative solution
Systems of equations
Yield criteria
Yield models
Powder metals
Rahman M.M.
Ariffin A.K.
Nor S.S.M.
Development of a finite element model of metal powder compaction process at elevated temperature
description This paper presents the finite element modelling of metal powder compaction process at elevated temperature. In the modelling, the behaviour of powder is assumed to be rate independent thermo-elastoplastic material where the material constitutive laws are derived based on a continuum mechanics approach. The deformation process of metal powder has been described by a large displacement based finite element formulation. The Elliptical Cap yield model has been used to represent the deformation behaviour of the powder mass during the compaction process. This yield model was tested and found to be appropriate to represent the compaction process. The staggered-incremental-iterative solution strategy has been established to solve the non-linearity in the systems of equations. Some numerical simulation results were validated through experimentation, where a good agreement was found between the numerical simulation results and the experimental data. � 2009 Elsevier Inc. All rights reserved.
author2 55328831100
author_facet 55328831100
Rahman M.M.
Ariffin A.K.
Nor S.S.M.
format Article
author Rahman M.M.
Ariffin A.K.
Nor S.S.M.
author_sort Rahman M.M.
title Development of a finite element model of metal powder compaction process at elevated temperature
title_short Development of a finite element model of metal powder compaction process at elevated temperature
title_full Development of a finite element model of metal powder compaction process at elevated temperature
title_fullStr Development of a finite element model of metal powder compaction process at elevated temperature
title_full_unstemmed Development of a finite element model of metal powder compaction process at elevated temperature
title_sort development of a finite element model of metal powder compaction process at elevated temperature
publishDate 2023
_version_ 1806428085263794176
score 13.214268