Assessing Fixed and Moving Mesh Methods for Hydrodynamic Free Surface Simulation in Induction Melting

P. Garcia-Michelena; O. Gordo-Burgoa; N. Herrero-Dorca; I. Vicario; I. Crespo; G. Arruebarrena; X. Chamorro

Assessing Fixed and Moving Mesh Methods for Hydrodynamic Free Surface Simulation in Induction Melting

P. Garcia-Michelena^*, O. Gordo-Burgoa, N. Herrero-Dorca, I. Vicario, I. Crespo, G. Arruebarrena, X. Chamorro

^*Corresponding author for this work

Smart, efficient and sustainable metal processes

Research output: Contribution to conference › Paper › peer-review

Abstract

This study develops a coupled finite element method (FEM) approach to optimize induction-melting processes by accurately simulating multiphysics phenomena. It integrates a magneto-hydrodynamic model to represent magnetic fields and Lorentz forces, crucial for fluid flow and pressure fields. Comparing fixed and moving mesh techniques, it assesses their effectiveness in capturing free surface deformation. Experimental validation in an aluminum induction-melting furnace confirms the model's accuracy. Insights gained contribute to advancing computational methods in metallurgical process optimization, particularly in understanding magneto-hydrodynamic behavior during induction melting.

Original language	English
Pages	766-767
Number of pages	2
Publication status	Published - 2024
Event	75th World Foundry Congress, WFC 2024 - Deyang, China Duration: 25 Oct 2024 → 30 Oct 2024

Conference

Conference	75th World Foundry Congress, WFC 2024
Country/Territory	China
City	Deyang
Period	25/10/24 → 30/10/24

Keywords

induction melting
multiphysics modelling

Cite this

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title = "Assessing Fixed and Moving Mesh Methods for Hydrodynamic Free Surface Simulation in Induction Melting",

abstract = "This study develops a coupled finite element method (FEM) approach to optimize induction-melting processes by accurately simulating multiphysics phenomena. It integrates a magneto-hydrodynamic model to represent magnetic fields and Lorentz forces, crucial for fluid flow and pressure fields. Comparing fixed and moving mesh techniques, it assesses their effectiveness in capturing free surface deformation. Experimental validation in an aluminum induction-melting furnace confirms the model's accuracy. Insights gained contribute to advancing computational methods in metallurgical process optimization, particularly in understanding magneto-hydrodynamic behavior during induction melting.",

keywords = "induction melting, multiphysics modelling",

author = "P. Garcia-Michelena and O. Gordo-Burgoa and N. Herrero-Dorca and I. Vicario and I. Crespo and G. Arruebarrena and X. Chamorro",

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T1 - Assessing Fixed and Moving Mesh Methods for Hydrodynamic Free Surface Simulation in Induction Melting

AU - Garcia-Michelena, P.

AU - Gordo-Burgoa, O.

AU - Herrero-Dorca, N.

AU - Vicario, I.

AU - Crespo, I.

AU - Arruebarrena, G.

AU - Chamorro, X.

PY - 2024

Y1 - 2024

N2 - This study develops a coupled finite element method (FEM) approach to optimize induction-melting processes by accurately simulating multiphysics phenomena. It integrates a magneto-hydrodynamic model to represent magnetic fields and Lorentz forces, crucial for fluid flow and pressure fields. Comparing fixed and moving mesh techniques, it assesses their effectiveness in capturing free surface deformation. Experimental validation in an aluminum induction-melting furnace confirms the model's accuracy. Insights gained contribute to advancing computational methods in metallurgical process optimization, particularly in understanding magneto-hydrodynamic behavior during induction melting.

AB - This study develops a coupled finite element method (FEM) approach to optimize induction-melting processes by accurately simulating multiphysics phenomena. It integrates a magneto-hydrodynamic model to represent magnetic fields and Lorentz forces, crucial for fluid flow and pressure fields. Comparing fixed and moving mesh techniques, it assesses their effectiveness in capturing free surface deformation. Experimental validation in an aluminum induction-melting furnace confirms the model's accuracy. Insights gained contribute to advancing computational methods in metallurgical process optimization, particularly in understanding magneto-hydrodynamic behavior during induction melting.

KW - induction melting

KW - multiphysics modelling

UR - http://www.scopus.com/inward/record.url?scp=86000007611&partnerID=8YFLogxK

M3 - Paper

AN - SCOPUS:86000007611

SP - 766

EP - 767

T2 - 75th World Foundry Congress, WFC 2024

Y2 - 25 October 2024 through 30 October 2024

ER -

Assessing Fixed and Moving Mesh Methods for Hydrodynamic Free Surface Simulation in Induction Melting

Abstract

Conference

Keywords

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