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Integration of Data Analytics and Data Mining for Machine Failure Mitigation and Decision Support in Metal–Mechanical Industry

Author

Listed:
  • Sidnei Alves de Araujo

    (Informatics and Knowledge Management Post-Graduation Program, Nove de Julho University (UNINOVE), Vergueiro Street, 235/249—Liberdade, São Paulo 01504-001, Brazil)

  • Silas Luiz Bomfim

    (Industrial Engineering Post Graduation Program, Federal University of ABC, São Bernardo do Campo, São Paulo 09606-045, Brazil)

  • Dimitria T. Boukouvalas

    (Informatics and Knowledge Management Post-Graduation Program, Nove de Julho University (UNINOVE), Vergueiro Street, 235/249—Liberdade, São Paulo 01504-001, Brazil)

  • Sergio Ricardo Lourenço

    (Industrial Engineering Post Graduation Program, Federal University of ABC, São Bernardo do Campo, São Paulo 09606-045, Brazil)

  • Ugo Ibusuki

    (Industrial Engineering Post Graduation Program, Federal University of ABC, São Bernardo do Campo, São Paulo 09606-045, Brazil)

  • Geraldo Cardoso de Oliveira Neto

    (Industrial Engineering Post Graduation Program, Federal University of ABC, São Bernardo do Campo, São Paulo 09606-045, Brazil)

Abstract

Background : The growing complexity of production processes in the metal–mechanical industry demands ever more effective strategies for managing machine and equipment maintenance, as unexpected failures can incur high operational costs and compromise productivity by interrupting workflows and delaying deliveries. However, few studies have combined end-to-end data analytics and data mining methods to proactively predict and mitigate such failures. This study aims to develop and validate a comprehensive framework combining data analytics and data mining to prevent machine failures and support decision-making in a metal–mechanical manufacturing environment. Methods: First, exploratory data analytics were performed on the sensor and logistics data to identify significant relationships and trends between variables. Next, a preprocessing pipeline including data cleaning, data transformation, feature selection, and resampling was applied. Finally, a decision tree model was trained to identify conditions prone to failures, enabling not only predictions but also the explicit representation of knowledge in the form of decision rules. Results : The outstanding performance of the decision tree (82.1% accuracy and a Kappa index of 78.5%), which was modeled from preprocessed data and the insights produced by data analytics, demonstrates its ability to generate reliable rules for predicting failures to support decision-making. The implementation of the proposed framework enables the optimization of predictive maintenance strategies, effectively reducing unplanned downtimes and enhancing the reliability of production processes in the metal–mechanical industry.

Suggested Citation

  • Sidnei Alves de Araujo & Silas Luiz Bomfim & Dimitria T. Boukouvalas & Sergio Ricardo Lourenço & Ugo Ibusuki & Geraldo Cardoso de Oliveira Neto, 2025. "Integration of Data Analytics and Data Mining for Machine Failure Mitigation and Decision Support in Metal–Mechanical Industry," Logistics, MDPI, vol. 9(3), pages 1-16, August.
    • Handle: RePEc:gam:jlogis:v:9:y:2025:i:3:p:109-:d:1719768
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    References listed on IDEAS

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    Cited by:

    1. Bita Ghasemkhani & Recep Alp Kut & Derya Birant & Reyat Yilmaz, 2025. "Balanced Hoeffding Tree Forest (BHTF): A Novel Multi-Label Classification with Oversampling and Undersampling Techniques for Failure Mode Diagnosis in Predictive Maintenance," Mathematics, MDPI, vol. 13(18), pages 1-45, September.

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