Modelling of cold extrusion with experimental verification

This paper reports on an experimental and finite element analysis (FEA) of the cold extrusion of high-grade (AA1100) aluminium. The influence of die angle, reduction ratio and die land on the extrusion force during the extrusion process was investigated. A forward extrusion die was designed and manu...

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Veröffentlicht in:	Journal of materials processing technology 2005-09, Vol.168 (2), p.360-366
Hauptverfasser:	Tiernan, P., Hillery, M.T., Draganescu, B., Gheorghe, M.
Format:	Artikel
Sprache:	eng
Schlagworte:	AA1100 aluminium Extrusion force Finite element analysis Forward extrusion Reduction ratio
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container_title	Journal of materials processing technology
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creator	Tiernan, P. Hillery, M.T. Draganescu, B. Gheorghe, M.
description	This paper reports on an experimental and finite element analysis (FEA) of the cold extrusion of high-grade (AA1100) aluminium. The influence of die angle, reduction ratio and die land on the extrusion force during the extrusion process was investigated. A forward extrusion die was designed and manufactured for the purpose of the experimental research. Interchangeable elements of the extrusion die allowed rapid change of the extrusion parameters to attain a high degree of experimental flexibility. A load cell, incorporated into the die design, allowed accurate determination of extrusion forces while a linear variable differential transformer (LVDT) provided automatic measurement of punch travel during the extrusion cycle. All data obtained from the instrumentation was captured and analysed using a personal computer (PC). A finite element analysis (FEA) of the cold extrusion process was undertaken in parallel with the experimental programme. The FEA simulation was carried out using ELFEN, FEA software, specifically produced for metal forming simulation. An axisymmetrical 2D geometric model of the tooling and billet was constructed for the analysis. Data obtained from the FE model included die-work piece contact pressure, effective stress and strain and material deformation velocity. The correlation between the experimental, calculated and FEA data obtained in this research is presented and discussed.
doi_str_mv	10.1016/j.jmatprotec.2005.02.249
format	Article
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The influence of die angle, reduction ratio and die land on the extrusion force during the extrusion process was investigated. A forward extrusion die was designed and manufactured for the purpose of the experimental research. Interchangeable elements of the extrusion die allowed rapid change of the extrusion parameters to attain a high degree of experimental flexibility. A load cell, incorporated into the die design, allowed accurate determination of extrusion forces while a linear variable differential transformer (LVDT) provided automatic measurement of punch travel during the extrusion cycle. All data obtained from the instrumentation was captured and analysed using a personal computer (PC). A finite element analysis (FEA) of the cold extrusion process was undertaken in parallel with the experimental programme. The FEA simulation was carried out using ELFEN, FEA software, specifically produced for metal forming simulation. An axisymmetrical 2D geometric model of the tooling and billet was constructed for the analysis. Data obtained from the FE model included die-work piece contact pressure, effective stress and strain and material deformation velocity. 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The influence of die angle, reduction ratio and die land on the extrusion force during the extrusion process was investigated. A forward extrusion die was designed and manufactured for the purpose of the experimental research. Interchangeable elements of the extrusion die allowed rapid change of the extrusion parameters to attain a high degree of experimental flexibility. A load cell, incorporated into the die design, allowed accurate determination of extrusion forces while a linear variable differential transformer (LVDT) provided automatic measurement of punch travel during the extrusion cycle. All data obtained from the instrumentation was captured and analysed using a personal computer (PC). A finite element analysis (FEA) of the cold extrusion process was undertaken in parallel with the experimental programme. The FEA simulation was carried out using ELFEN, FEA software, specifically produced for metal forming simulation. An axisymmetrical 2D geometric model of the tooling and billet was constructed for the analysis. Data obtained from the FE model included die-work piece contact pressure, effective stress and strain and material deformation velocity. 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The influence of die angle, reduction ratio and die land on the extrusion force during the extrusion process was investigated. A forward extrusion die was designed and manufactured for the purpose of the experimental research. Interchangeable elements of the extrusion die allowed rapid change of the extrusion parameters to attain a high degree of experimental flexibility. A load cell, incorporated into the die design, allowed accurate determination of extrusion forces while a linear variable differential transformer (LVDT) provided automatic measurement of punch travel during the extrusion cycle. All data obtained from the instrumentation was captured and analysed using a personal computer (PC). A finite element analysis (FEA) of the cold extrusion process was undertaken in parallel with the experimental programme. The FEA simulation was carried out using ELFEN, FEA software, specifically produced for metal forming simulation. 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subjects	AA1100 aluminium Extrusion force Finite element analysis Forward extrusion Reduction ratio
title	Modelling of cold extrusion with experimental verification
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