Abstract
This paper presents a comprehensive review of the developments made in rotating bearing fault diagnosis, a crucial component of a rotatory machine, during the past decade. A data-driven fault diagnosis framework consists of data acquisition, feature extraction/feature learning, and decision making based on shallow/deep learning algorithms. In this review paper, various signal processing techniques, classical machine learning approaches, and deep learning algorithms used for bearing fault diagnosis have been discussed. Moreover, highlights of the available public datasets that have been widely used in bearing fault diagnosis experiments, such as Case Western Reserve University (CWRU), Paderborn University Bearing, PRONOSTIA, and Intelligent Maintenance Systems (IMS), are discussed in this paper. A comparison of machine learning techniques, such as support vector machines, k-nearest neighbors, artificial neural networks, etc., deep learning algorithms such as a deep convolutional network (CNN), auto-encoder-based deep neural network (AE-DNN), deep belief network (DBN), deep recurrent neural network (RNN), and other deep learning methods that have been utilized for the diagnosis of rotary machines bearing fault, is presented.
Highlights
Motion is powered by electromechanical systems, which account for around 70% of the gross energy consumption in industrialized economies [1]
Methods for Bearing states (DBN)-Based that fault bearing diagnosis using the capability of AEs and the deep belief network (DBN) speed is a deep neural network that isMachine constructed from variousalayers highThe training of an has layers of visible and hidden unit tion performance without explicit feature extraction
We investigated the applications of deep learning algorithms for bearing fault diagnosis
Summary
Motion is powered by electromechanical systems, which account for around 70% of the gross energy consumption in industrialized economies [1]. By 2017, the global market was at the size of USD 96,967.9 million, and is expected to reach USD 136,496.1 by the year. One of the basic components that is used in industries is an electrical motor that converts electrical energy into mechanical energy. Based on motor types, the global market is divided into DC, or AC or hermetic motors, which in turn are further subdivided as: . The global market of electric motors can be further classified based on operating industries such as automotive vehicles, industrial machinery, aerospace, household, and commercial applications. In the manufacturing and automotive industries, due to an increase in demand for compressor systems, the industrial segment contributed the largest share in the year 2017, which is even estimated to increase by 2025 [3]
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