AI-Driven Predictive Maintenance for Industrial Assets using Edge Computing and Machine Learning

Authors

  • Darshit Thakkar Independent Researcher, USA
  • Ravi Kumar Independent Researcher, USA

DOI:

https://doi.org/10.55544/jrasb.3.1.55

Keywords:

Predictive Maintenance, Industrial Assets, Edge Computing, Machine Learning, Anomaly Detection, Remaining Useful Life

Abstract

The increasing complexity and scale of industrial assets, such as machinery, equipment, and infrastructure, have led to a growing need for effective predictive maintenance strategies. Traditional time-based or reactive maintenance approaches often fall short in addressing the dynamic nature of asset degradation and failure patterns. This study explores the integration of artificial intelligence (AI) and machine learning (ML) algorithms with edge computing to develop an intelligent predictive maintenance framework for industrial assets. By processing sensor data and executing ML models closer to the source, at the edge, this approach enables real-time anomaly detection, remaining useful life (RUL) estimation, and proactive maintenance scheduling. The paper outlines the key methods involved, including sensor data preprocessing, feature engineering, ML model development, and deployment on edge devices. It also discusses the benefits of this integration, such as reduced downtime, improved asset reliability, and enhanced operational efficiency. Furthermore, the study highlights emerging trends, such as transfer learning, ensemble modeling, and adaptive learning, which enhance the flexibility, accuracy, and adaptability of the AI-driven predictive maintenance system. The findings demonstrate the transformative potential of this synergy, empowering industrial operations to transition from reactive to predictive maintenance, ultimately optimizing asset performance and reducing maintenance costs.

Downloads

Download data is not yet available.

Metrics

Metrics Loading ...

References

Mehrabi, M.G., Dehghani, A., Rahmani, A.M. and Ghasempour, A. (2023). Edge-Enabled Predictive Maintenance for Industrial Assets Using Machine Learning. IEEE Transactions on Industrial Informatics, 19(7), pp.4682-4693.

Gu, F., Ren, L., Tseng, K.J. and Mathew, J. (2024). Transfer Learning for Scalable Predictive Maintenance in Heterogeneous Industrial Assets. IEEE Transactions on Industry Applications, 60(2), pp.1391-1400.

Hu, C., Youn, B.D., Wang, P. and Yoon, J.T. (2023). Ensemble of Data-Driven Prognostic Models for Robust Prediction of Remaining Useful Life. Mechanical Systems and Signal Processing, 167, p.108417.

Kamal, R., Islam, M.M., Akhter, S. and Rahman, M.H. (2024). Adaptive Learning for Predictive Maintenance of Industrial Assets in Dynamic Environments. IEEE Transactions on Automation Science and Engineering, 21(3), pp.1501-1512.

Desai, F., Chowdhury, D., Kaur, R., Peeters, M., Arya, R.C., Wander, G.S., Gill, S.S. and Buyya, R. (2022). HealthCloud: A system for monitoring health status of heart patients using machine learning and cloud computing. Internet of Things, 17, p.100485.

Uppal, M., Gupta, D., Juneja, S., Sulaiman, A., Rajab, K., Rajab, A., Elmagzoub, M.A. and Shaikh, A. (2022). Cloud-based fault prediction for real-time monitoring of sensor data in hospital environment using machine learning. Sustainability, 14(18), p.11667.

Bal, P.K., Mohapatra, S.K., Das, T.K., Srinivasan, K. and Hu, Y.C. (2022). A joint resource allocation, security with efficient task scheduling in cloud computing using hybrid machine learning techniques. Sensors, 22(3), p.1242.

Kanungo, S., Rai, A. and Sharma, V. (2024). Optimizing Resource Utilization in Edge-Based IoT Analytics using Adaptive Learning. International Journal of Distributed Sensor Networks, 20(3), pp.1-12.

Jiang, L., Xu, W., Zhang, H. and Chen, Y. (2024). Edge Computing and Machine Learning for IoT: A Powerful Combination. IEEE Internet of Things Journal, 11(2), pp.1421-1433.

Qiu, M., Liang, W., Zhang, J. and Xie, R. (2023). Federated Learning for Secure and Privacy-Preserving IoT Applications. IEEE Transactions on Industrial Informatics, 19(5), pp.3585-3595.

Downloads

Published

2024-02-28

How to Cite

Thakkar, D., & Kumar, R. (2024). AI-Driven Predictive Maintenance for Industrial Assets using Edge Computing and Machine Learning. Journal for Research in Applied Sciences and Biotechnology, 3(1), 363–367. https://doi.org/10.55544/jrasb.3.1.55