A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis

A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis

A numerical method for the precise calculation of temperature, velocity and pressure profiles of the α-β brass indirect hot extrusion process is presented. The method solves the Navier⁻Stokes equations for non-Newtonian liquids with strain-rate and temperature-dependent v...

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Main Authors: George Pashos, George A. Pantazopoulos, Ioannis Contopoulos
Format: Article
Language:English
Published: MDPI AG 2018-12-01
Series:Metals
Subjects:
brass extrusion
CFD simulation
extrusion failures
plastic deformation processing
Online Access:https://www.mdpi.com/2075-4701/8/12/1043
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spelling doaj-05ed2bf7f00941f8b4c87a1f72ee188d2020-11-25T00:45:22ZengMDPI AGMetals2075-47012018-12-01812104310.3390/met8121043met8121043A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure PrognosisGeorge Pashos0George A. Pantazopoulos1Ioannis Contopoulos2ELKEME Hellenic Research Centre for Metals S.A., 61st km Athens—Lamia National Road, 32011 Oinofyta, Viotias, GreeceELKEME Hellenic Research Centre for Metals S.A., 61st km Athens—Lamia National Road, 32011 Oinofyta, Viotias, GreeceELKEME Hellenic Research Centre for Metals S.A., 61st km Athens—Lamia National Road, 32011 Oinofyta, Viotias, GreeceA numerical method for the precise calculation of temperature, velocity and pressure profiles of the α-β brass indirect hot extrusion process is presented. The method solves the Navier⁻Stokes equations for non-Newtonian liquids with strain-rate and temperature-dependent viscosity that is formulated using established constitutive laws based on the Zener⁻Hollomon type equation for plastic flow stress. The method can be implemented with standard computational fluid dynamics (CFD) software, has relatively low computational cost, and avoids the numerical artifacts associated with other methods commonly used for such processes. A response surface technique is also implemented, and it is thus possible to build a reduced order model that approximately maps the process with respect to all combinations of its parameters, including the extrusion speed and brass phase constitution. The reduced order model can be a very useful tool for production, because it instantaneously provides important quantities, such as the average pressure or the temperature of hot-spots that are formed due to the combined effect of die/billet friction and the generation of heat from plastic deformation (adiabatic shear deformation heating). This approach can assist in the preliminary evaluation of the metal flow pattern, and in the prediction and prevention of critical extrusion failures, thus leading to subsequent process and product quality improvements.https://www.mdpi.com/2075-4701/8/12/1043brass extrusionCFD simulationextrusion failuresplastic deformation processing
collection DOAJ
language English
format Article
sources DOAJ
author George Pashos
George A. Pantazopoulos
Ioannis Contopoulos
spellingShingle George Pashos
George A. Pantazopoulos
Ioannis Contopoulos
A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
Metals
brass extrusion
CFD simulation
extrusion failures
plastic deformation processing
author_facet George Pashos
George A. Pantazopoulos
Ioannis Contopoulos
author_sort George Pashos
title A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
title_short A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
title_full A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
title_fullStr A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
title_full_unstemmed A Comprehensive CFD Model for Dual-Phase Brass Indirect Extrusion Based on Constitutive Laws: Assessment of Hot-Zone Formation and Failure Prognosis
title_sort comprehensive cfd model for dual-phase brass indirect extrusion based on constitutive laws: assessment of hot-zone formation and failure prognosis
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2018-12-01
description A numerical method for the precise calculation of temperature, velocity and pressure profiles of the α-β brass indirect hot extrusion process is presented. The method solves the Navier⁻Stokes equations for non-Newtonian liquids with strain-rate and temperature-dependent viscosity that is formulated using established constitutive laws based on the Zener⁻Hollomon type equation for plastic flow stress. The method can be implemented with standard computational fluid dynamics (CFD) software, has relatively low computational cost, and avoids the numerical artifacts associated with other methods commonly used for such processes. A response surface technique is also implemented, and it is thus possible to build a reduced order model that approximately maps the process with respect to all combinations of its parameters, including the extrusion speed and brass phase constitution. The reduced order model can be a very useful tool for production, because it instantaneously provides important quantities, such as the average pressure or the temperature of hot-spots that are formed due to the combined effect of die/billet friction and the generation of heat from plastic deformation (adiabatic shear deformation heating). This approach can assist in the preliminary evaluation of the metal flow pattern, and in the prediction and prevention of critical extrusion failures, thus leading to subsequent process and product quality improvements.
topic brass extrusion
CFD simulation
extrusion failures
plastic deformation processing
url https://www.mdpi.com/2075-4701/8/12/1043
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