Abstract
Fault diagnosis in high-speed machining centers (HSM) is critical in manufacturing systems, since early detection saves a substantial amount of time and money. It is known that 42% of failures in these centers occur in rotatory machineries, such as spindles, in which, the bearings are fundamental elements for effective operation. Nowadays, there are several machine- and deep-learning methods to diagnose the faults. To improve the performance of those traditional machine-learning tools, a deep-learning network that works on raw signals, which do not require previous analysis, has been proposed. The 1D Convolutional Neural Network (CNN) proposed model showed great capacity of adapting to three types of configurations and three different databases, despite a training set with a smaller number of categories. The network still detected faults at early damage stages. Additionally, the low computational cost shows the Deep-Learning Neural Network’s (DLNN) suitability for real-time applications in industry. The proposed structure reached a precision of 99%; real-time processing was around 8 ms per signal, and standard deviation of repeatability was 0.25%.
Highlights
Industry 4.0 has transformed the company environment, from a wide variety of sensors and control systems, to the development of new maintenance strategies
To evaluate the method based on 1D-Convolutional Neural Network (CNN) proposed in this paper, three databases were used: (1) the standard reference provided by Case Western Reserve University (CWRU), (2) the bearing failure dataset provided by T-Y Wu and (3) the dataset generated by the National Science Foundation (NSF) for Intelligent Maintenance Systems (IMS)
The proposed 1D-CNN was evaluated in line with three parameters: (1) accuracy
Summary
Industry 4.0 has transformed the company environment, from a wide variety of sensors and control systems, to the development of new maintenance strategies. One of the most popular maintenance strategies is based on decision making, which seeks to optimize performance times by detecting, replacing or repairing machine components before severe and costly problems [1]. The main components of rotating machines are the bearings, and most failures in industrial machinery occur due to their malfunction. Bearings are the main non-linear components of rotating machines, whose malfunctioning severely affects system operation. Several monitoring and preventive maintenance strategies have been proposed to guarantee the efficient operation of bearings. In many applications, such as turbines, aircraft engines and others, minor faults can cause dangerous and expensive side effects [3]
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