Industrial-scale prediction of cement clinker phases using machine learning.

Journal: Communications engineering
Published Date: May 24, 2025

Abstract

Cement production exceeds 4.1 billion tonnes annually, emitting 2.4 billion tonnes of CO annually, necessitating improved process control. Traditional models, limited to steady-state conditions, lack predictive accuracy for clinker mineralogical phases. Here, using a comprehensive two-year industrial dataset, we develop machine learning models that outperform conventional Bogue equations with mean absolute percentage errors of 1.24%, 6.77%, and 2.53% for alite, belite, and ferrite prediction respectively, compared to 7.79%, 22.68%, and 24.54% for Bogue calculations. Our models remain robust under varying operations and are evaluated for uncertainty and rare-event scenarios. Through post hoc explainable algorithms, we interpret the hierarchical relationships between clinker oxides and phase formation, providing insights into the functioning of an otherwise black-box model. The framework can potentially enable real-time optimization of cement production, thereby providing a route toward reducing material waste and ensuring quality while reducing the associated emissions under real-world conditions.

Authors

  • Sheikh Junaid Fayaz
    Indian Institute of Technology Delhi, New Delhi, India.
  • Néstor Montiel-Bohórquez
    Politecnico di Milano, Department of Energy, Milan, Italy.
  • Shashank Bishnoi
    Indian Institute of Technology Delhi, New Delhi, India.
  • Matteo Romano
    Politecnico di Milano, Department of Energy, Milan, Italy.
  • Manuele Gatti
    Politecnico di Milano, Department of Energy, Milan, Italy.
  • N M Anoop Krishnan
    Indian Institute of Technology Delhi, New Delhi, India. krishnan@iitd.ac.in.

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