Abstract
In recent years, the internet of things (IoT) represents the main core of Industry 4.0 for cyber-physic systems (CPS) in order to improve the industrial environment. Accordingly, the application of IoT and CPS has been expanded in applied electrical systems and machines. However, cybersecurity represents the main challenge of the implementation of IoT against cyber-attacks. In this regard, this paper proposes a new IoT architecture based on utilizing machine learning techniques to suppress cyber-attacks for providing reliable and secure online monitoring for the induction motor status. In particular, advanced machine learning techniques are utilized here to detect cyber-attacks and motor status with high accuracy. The proposed infrastructure validates the motor status via communication channels and the internet connection with economical cost and less effort on connecting various networks. For this purpose, the CONTACT Element platform for IoT is adopted to visualize the processed data based on machine learning techniques through a graphical dashboard. Once the cyber-attacks signal has been detected, the proposed IoT platform based on machine learning will be visualized automatically as fake data on the dashboard of the IoT platform. Different experimental scenarios with data acquisition are carried out to emphasize the performance of the suggested IoT topology. The results confirm that the proposed IoT architecture based on the machine learning technique can effectively visualize all faults of the motor status as well as the cyber-attacks on the networks. Moreover, all faults of the motor status and the fake data, due to the cyber-attacks, are successfully recognized and visualized on the dashboard of the proposed IoT platform with high accuracy and more clarified visualization, thereby contributing to enhancing the decision-making about the motor status. Furthermore, the introduced IoT architecture with Random Forest algorithm provides an effective detection for the faults on motor due to the vibration under industrial conditions with excellent accuracy of 99.03% that is significantly greater than the other machine learning algorithms. Besides, the proposed IoT has low latency to recognize the motor faults and cyber-attacks to present them in the main dashboard of the IoT platform.
Highlights
Worldwide, since the industrial revolution, rotary equipment has been widely used in many areas
This paper introduces a new internet of things (IoT) architecture for online monitoring of the faults of the induction motor instead of the traditional methods
The proposed IoT architecture is developed based on effective machine learning techniques to recognize the fault classes of the motor
Summary
Since the industrial revolution, rotary equipment has been widely used in many areas. Fault detection and diagnosis for induction motors become much more important. There are many kinds of motor failures which are categorized into two major types of faults including electrical faults and mechanical faults. Bearings are among the most important components in induction machines. Their load capability, running accuracy, noise levels, frictional heat, and useful life will directly affect the induction machines [5]. It is about 40% - 90% of all motor failures that come from bearing faults depending on the size of the motors [6]. The early detection and diagnosis of bearing faults could prevent sudden failure. This research subject still attracts great attention from the research community
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