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PhD Defense "Advanced Control for a Three-Phase Electric Arc Furnace Producing Silico-Manganese" Minh Tuan Dinh

Thesis defence

On 13 February 2026

Valence

phd defence illustration

Minh Tuan DINH will defend his thesis titled Advanced Control for a Three-Phase Electric Arc Furnace Producing Silico-Manganese in front of the jury members 

  • Pr. Gabriele Pannocchia Director University of Pisa, Italy  Reviewer
  • Pr. Vicenc Puig Universitat Polit`ecnica de Catalunya, Spain  Reviewer
  • Pr. Alexandra Grancharova  Univ. of Chemical Technology and Metallurgy, Bulgaria  Examiner
  • Pr. John J. Martinez-Molina Gipsa-lab, Grenoble INP, UGA, France  Examiner
  • Dr. Alexandre Chenu Eramet Ideas, France  Invitee
  • Jonathan Lamboley  Eramet Ideas, France  Invitee
  • Dr. Dina Irofti EDF, France  Invitee
     
  • Olivier Lesage Eramet Ideas, France  Co-supervisor
  • Pr. Eduardo Mendes LCIS, Grenoble INP, UGA, France  Co-director
  • Dr. Ionela Prodan LCIS, Grenoble INP, UGA, France  Director

 

Abstract: 

Electric arc furnace (EAF) is widely used in the steel industry for melting and refining steel or alloy products, particularly manganese (Mn) ferroalloys, essential and irreplaceable ingredients in carbon steel production. In recent years, EAF technologies have shown steady growth in production capacity and global market share, driven by increasing demand for highly energy-efficient methods and the need for more environmentally friendly production. This has become especially important in the context of France’s ambition to achieve the 2050 Carbon Neutrality Plan. Mn ferroalloys are made by melting and reducing manganese ores, coke and fluxes in an EAF. This furnace relies on the Joule effect from a three-phase alternating current, transmitted through three electrodes, to provide the thermal energy for melting and reduction reactions. Electrical regulation, which directly controls energy use, is critical to furnace operation because it operates and reacts on short timescales, unlike most other process levers and indicators, such as input/output materials or temperatures. 

This thesis aims to develop a scalable and flexible control framework for a three-phase EAF producing Silico-Manganese capable of handling the complex system interconnections, explicitly incorporates operational constraints and improves electrical system stability and productivity. To this end, electrical principles such as Kirchhoff’s laws and Ohm’s law are used to model the system’s electrical behavior accurately. Moreover, well-established concepts such as MPC (Model Predictive Control) and MIP (Mixed-Integer Programming) are adapted and integrated into the optimization-based control design, ensuring effective and flexible strategic regulation of furnace operation. In addition, the design of computationally efficient solving algorithms using heuristic approaches is considered to address the computational demands of the MIP problem in real-time implementation. The control frameworks are validated through numerical simulations on the real-time SIL (Softaware-in-the-loop) simulator. Finally, we lay the groundwork for future research and further enhancements, while providing concrete steps toward the implementation of real model predictive control experiments. 

Keywords: Electric Arc Furnace, Submerged Arc Furnace, Electrical System, Model Predictive Control, Mixed-Integer Programming, Heuristic Rounding, Bilevel Optimization, Software-in-the-Loop Simulation.

Date

On 13 February 2026

Localisation

Valence

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PhD Defense Announcement (PDF, 423.48 KB)

Submitted on 10 June 2026

Updated on 10 June 2026