Abstract
This study explores the application of recurrent neural networks (RNNs) to enhance machine reliability in industrial settings, specifically in predictive maintenance systems. Predictive maintenance uses previous sensor data to identify abnormalities and forecast machine breakdowns before they occur, lowering downtime and maintenance costs. RNNs are ideal with their unique capacity to handle sequential input while capturing temporal relationships. RNN-based models may reliably foresee machine breakdowns and detect early malfunction indicators, allowing for appropriate interventions. The paper investigates key RNN architectures, such as Long Short-Term Memory (LSTM) and Gated Recurrent Units (GRU), that have proven effective in addressing the limitations of traditional machine learning models, particularly in dealing with long-term dependencies and avoiding the vanishing gradient issue. LSTMs and GRUs are noted for their excellent performance in predictive maintenance, which requires precise failure predictions. However, obstacles persist, notably regarding data quality—sensor data is often noisy, missing, or inconsistent—and model interpretability since RNNs' "black-box" nature makes comprehending predictions challenging. Addressing these difficulties is critical for effective adoption in industrial settings. Future directions include integrating domain knowledge to improve model accuracy and creating hybrid models that combine RNNs with machine learning techniques, such as convolutional neural networks (CNNs) or support vector machines (SVMs), to improve predictive maintenance systems' robustness and scalability. These developments might considerably impact equipment dependability and operational efficiency in production.
Published Version
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