SCADA-Driven big data framework for fault prediction in spiral steel pipe manufacturing using fuzzy and neural network models
Article Sidebar
Issue Vol. 22 No. 1 (2026)
-
Development of dead-reckoning sensor system for indoor environments
1-19
-
A real-time adaptive traffic light control algorithm at urban intersections for smart cities
20-34
-
A text-guided vision model for enhanced recognition of small instances
35-46
-
Reinforcement learning for solving optimization problems: Opportunities and limitations on the example of the assignment problem
47-62
-
SCADA-Driven big data framework for fault prediction in spiral steel pipe manufacturing using fuzzy and neural network models
63-81
-
Enhanced ELECTRE III method with interval-valued hesitant fuzzy linguistic sets for multi-criteria group decision-making in smart supply networks
82-98
-
Models for calculating the integral quality indicator of the offset printing process for the IIOT-system
99-109
-
A scalable and cost-effective forest fire detection approach using deep transfer learning on a Raspberry Pi cluster
110-122
-
Addressing non-stationarity with stochastic trend in the context of limited time series data: An experimental survey in healthcare analytics
123-139
-
Efficient multi-robot exploration of unknown environments using inverted ant colony optimization and reinforcement learning
140-153
-
A comprehensive review of metaheuristic algorithms for mobile robot path planning
154-170
-
Smart Autolube: Optimized machine learning-based pressure prediction for AIoT lubrication systems
171-183
-
Application of artificial intelligence methods to determine the optimal process parameters in resistance projection welding of steel nuts
184-198
-
Development of non-destructive vibration method for classification of bone fracture severity
199-213
-
Quantifying pain: An AI-driven approach to detecting pain levels via facial expressions
214-227
Main Article Content
DOI
Authors
Abstract
The increasing complexity of spiral steel pipe production necessitates the implementation of intelligent forecasting methods to predict potential failures. This, in turn, enables the development of reliable evaluation techniques aimed at minimizing unanticipated breakdowns and enhancing the efficacy of maintenance strategies. In the present study, a novel SCADA-integrated framework is proposed, which incorporates Fuzzy Comprehensive Evaluation (FCE) and Artificial Neural Networks (ANN) into mid-to-long-term reliability analysis and machine learning-based short-term fault prediction. The architecture performs dynamic analysis on the health of the equipment, welding, alignment, hydraulics, and motor systems using a synthetic SCADA dataset that includes more than 100,000 time-series data points. The generation of imprecise reliability grades is predicated on essential indicators, including mean time between failures (MTBF), mean time to repair (MTTR), the level of failure, and the difficulty of its detection. These indicators are subsequently modeled through artificial neural networks (ANNs) to enable real-time inference. The multi-week sensor window and alarm logs are used with tree-based classifiers and statistical models to predict faults up to four weeks in advance. The mean prediction accuracy is over 91%, and a cost-benefit analysis indicates that active maintenance planning can result in significant financial savings. The combined use of fuzzy logic and neural networks is particularly valuable in manufacturing environments because it integrates human-like reasoning with data-driven learning, enabling robust decision-making under uncertainty. The all-inclusive solution is a financially reasonable and scalable alternative for implementing predictive diagnostics in industrial steel pipe production settings.
