Abstract
Bearings are critical components found in most rotating machinery; their health condition is of immense importance to many industries. The varied conditions and environments in which bearings operate make them prone to single and multiple faults. Widespread interest in the improvements of single fault diagnosis meant limited attention was spent on multiple fault diagnosis. However, multiple fault diagnosis poses extra challenges due to the submergence of the weak fault by the strong fault, presence of non-Gaussian noise, coupling of the frequency components, etc. A number of existing convolutional neural network models operate on a distinct feature that is not enough to assure reliable results in the presence of these challenges. In this paper, extended feature sets in three homogenous deep learning models are used for multiple fault diagnosis. This ensures a measure of diversity is introduced to the health management dataset to obtain complementary solutions from the models. The outputs of the models are fused through blending ensemble learning. Experiments using vibration datasets based on bearing multiple faults show an accuracy of 98.54%, with an improvement of 2.74% in the overall effectiveness over the single models. Compared with other technologies, the results show that this approach provides an improved generalized diagnostic capability.
Highlights
Rolling bearings are used in a sizable number of machines to support and allow relative motion between machine parts that are in contact
The proposed solution was based on extended features achieved through three preprocessing methods
The models were fused in a homogenous blended ensemble learning method
Summary
Rolling bearings are used in a sizable number of machines to support and allow relative motion between machine parts that are in contact. They are found in operation in various industrial environments and are subjected to varied load conditions/speeds over a long time. The tough environment in which bearings operate, poor lubrication, manufacturing or installation errors promote single and multiple faults. Faults in bearings can bring about downtime, large financial losses, and in some cases death, due to abrupt failure while in operation [1,2,3]. Different approaches have been proposed for the diagnosis and prognosis of bearings To reduce or eliminate losses, accurate and reliable diagnosis is of utmost importance.
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