Probabilistic Model of Industrial Motor Reliability as a Function of Lubricant Degradation: A Case Study MDU-01 Motor Hyundai H21/32

Authors

  • Jonathan Jiménez Unidad académica de formación técnica y tecnológica, Universidad Laica Eloy Alfaro. El Carmen, Ecuador. https://orcid.org/0009-0008-4776-0433
  • Luis Chango Escuela de formación de tecnólogos, Escuela Politécnica Nacional, Quito-Ecuador. https://orcid.org/0009-0006-2908-8255
  • Erick López Unidad académica de formación técnica y tecnológica, Universidad Laica Eloy Alfaro. El Carmen, Ecuador https://orcid.org/0009-0001-0726-0599
  • Gladys Sotominga Instituto de posgrado, Universidad Técnica de Manabí, Portoviejo, Ecuador.

DOI:

https://doi.org/10.53591/easi.V3i2.2615

Keywords:

reliability modeling, lubricant degradation, Weibull distribution, condition-based maintenance, industrial diesel engines

Abstract

This work applies a probabilistic reliability model for industrial diesel engines based on lubricant degradation to the MDU-06 Hyundai H21/32 engine at thermal power station, Ecuador. The engine operated seamlessly from August 2023 until October 2025, generating power continuously. Thus, the model predicts dependability based on oil condition behavior rather than mechanical faults. The study offers a non-linear and multivariate degradation model to track the associated evolution of TBN, Sulfation, Nickel, and Vanadium. Stochastic degradation modeling and Weibull reliability estimation were used to estimate lubricant life under real operating conditions. Results show a Weibull shape parameter β = 8.3 and scale parameter η = 1920 hours, with dependability drastically decreasing after 2000 operational hours.
These results demonstrate that lubricant degradation can accurately forecast engine health, allowing predictive maintenance without interruption. Condition-based maintenance (CBM) procedures are optimized to maintain system dependability over 80% while lowering premature wear and maintenance costs with the suggested framework.

Author Biographies

  • Jonathan Jiménez, Unidad académica de formación técnica y tecnológica, Universidad Laica Eloy Alfaro. El Carmen, Ecuador.

    Master's degree in Industrial Design, Production, and Automation (2017), Electromechanical Engineer (2011). Part-time lecturer at the Faculty of Engineering Sciences, Eloy Alfaro Lay University of Manabí,
    Ecuador. Areas of expertise: energy efficiency, industrial maintenance, process automation, and energy management.

  • Luis Chango, Escuela de formación de tecnólogos, Escuela Politécnica Nacional, Quito-Ecuador.

    Master's degree in Electronics and Automation, specializing in Industrial Networks (2024), Electromechanical Engineer (2022), and Electromechanical Technologist (2016). Part-time lecturer in the Higher Technology in Electromechanics program at Eloy Alfaro Lay University of Manabí (ULEAM), Ecuador. Areas of expertise: industrial automation, process control, electromechanical maintenance, energy efficiency, and industrial network systems.

  • Erick López, Unidad académica de formación técnica y tecnológica, Universidad Laica Eloy Alfaro. El Carmen, Ecuador

    Master's degree in Industrial Maintenance (2023) and Naval Mechanical Engineer (2015). Professor at the Faculty of Engineering Sciences of the Eloy Alfaro Lay University of Manabí (ULEAM), Ecuador, and technical manager of EXTINNOVA, a company dedicated to electromechanical maintenance and specialized industrial services. Areas of expertise: predictive and corrective maintenance, electromechanical systems, industrial asset management, and industrial safety applied to the maintenance of generators and fire protection systems.

  • Gladys Sotominga, Instituto de posgrado, Universidad Técnica de Manabí, Portoviejo, Ecuador.

    Master's degree in Industrial Maintenance (2023) and Chemical Engineer (2021), with a solid background in industrial process management, operational reliability, and quality assurance. I currently work as a Chemical Control Operator in the Termopichincha Business Unit at CELEC EP, performing and supervising physicochemical analyses of technological fluids (process water, lubricating oils, fuels, and others), which are fundamental for the efficiency and availability of thermoelectric power generation systems.

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Published

2026-01-05

Issue

Vol. 4 No. 3 (2025): Edición regular

Section

Research articles

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Copyright (c) 2026 Jonathan Jiménez Gonzales, Luis Chango, Erick López, Gladys Sotominga

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How to Cite

Jiménez Gonzales, J. P., Chango Andrade, J. L., López Pazmiño, E. A., & Sotominga Espinoza, G. M. (2026). Probabilistic Model of Industrial Motor Reliability as a Function of Lubricant Degradation: A Case Study MDU-01 Motor Hyundai H21/32. EASI: Engineering and Applied Sciences in Industry, 4(3), 1-15. https://doi.org/10.53591/easi.V3i2.2615