December 22, 2024
Valiollah Ghaffari

Valiollah Ghaffari

Academic Rank: Associate professor
Address: Persian Gulf University
Degree: Ph.D in Electrical Engineering
Phone: 07733442269
Faculty: Faculty of Intelligent Systems and Data Science

Research

Title
Online Fault Diagnosis of Rotating Industrial Equipment Based on Semi-Supervised Artificial Intelligence
Type Thesis
Keywords
يادگيري نيمه نظارت شده، تشخيص خطا، ماشي نآالت دوار، شبكه عصبي كانولوشن، شبكه عصبي فازي پويا
Researchers mohamad morteza gholami (Student) , Amin Torabi Jahromi (Primary advisor) , Valiollah Ghaffari (Primary advisor) , Hossein Haghbin (Advisor)

Abstract

Background: Rotating machinery is critical in various industries, including power plants, and plays a significant role in maintaining the continuous operation of industrial processes. The reliability of these machines is highly dependent on their proper functioning. Therefore, fault detection in rotating machinery, such as generators, pumps, motors, and compressors, is crucial to prevent catastrophic failures and minimize unplanned downtime. Any proposed fault detection method for these machines must be computationally efficient, reliable, and easy to implement. In this study, we propose an online fault detection method for rotating machinery based on semi-supervised artificial intelligence, utilizing auxiliary signals from the equipment to identify and predict faults. Aim: Specifically, we aim to utilize a 1D CNN architecture for feature extraction of the side signals which reflect the working faults of the rotating machinery and to develop a state-of-the-art semi supervised neural network structure by using DFNN which can accurately classify and detect the faults while considering the normal model drift of the machine. The model will be tried to be simple enough to be implementable in common and economical industrial computing boards. Methodology: In this research, we use a classified dataset of rotating machinery in semi-supervised learning and label all the data. Then, for the purpose of feature extraction, we input the data into a CNN. Finally, after feature extraction, we use the DFNN method for data classification. Conclusions: The main findings of this research are a semi-supervised learning CNN structure, which is classified by DFNN for rotating machinery fault detection. In this research, we obtained the initial model using labeled data through a semisupervised neural network. Subsequently, we pseudo-labeled the unlabeled data using this model. Finally, we implemented the final model with an accuracy of 99.88% for rotating machinery fault detection using b