Abstract
Induction motors (IM) are key components of any industrial process; hence, it is important to carry out continuous monitoring to detect incipient faults in them in order to avoid interruptions on production lines. Broken rotor bars (BRBs), which are among the most regular and most complex to detect faults, have attracted the attention of many researchers, who are searching for reliable methods to recognize this condition with high certainty. Most proposed techniques in the literature are applied during the IM startup transient, making it necessary to develop more efficient fault detection techniques able to carry out fault identification during the IM steady state. In this work, a novel methodology based on motor current signal analysis and contrast estimation is introduced for BRB detection. It is worth noting that contrast has mainly been used in image processing for analyzing texture, and, to the best of the authors’ knowledge, it has never been used for diagnosing the operative condition of an induction motor. Experimental results from applying the approach put forward validate Unser and Tamura contrast definitions as useful indicators for identifying and classifying an IM operational condition as healthy, one broken bar (1BB), or two broken bars (2BB), with high certainty during its steady state.
Highlights
IntroductionRotary machines, such as induction motors (IM), have become essential tools for industrial processes due to their low cost and ruggedness [1]
A hold-out type dataset is employed [37], where 180 trials are performed on each induction motors (IM) condition
Most previous works in the reviewed literature carry out Broken rotor bars (BRBs) detection during the induction motor startup transient, since the fault is easier to observe under this regime because of the increased current in the rotor circuit and sometimes under the condition of heavy load to amplify the effects of BRBs in the stator current [39]
Summary
Rotary machines, such as induction motors (IM), have become essential tools for industrial processes due to their low cost and ruggedness [1]. These machines undergo different types of failures associated with the rotor, the stator, or the bearings due to distinct operational circumstances. An incipient fault in an IM is usually silent, and it can generate distinct types of problems, such as interruption of a production line and damage to surrounding machinery, and, in the worst scenario, it might cause a total collapse of the system, which would provoke significant economic losses for an industry [2,3]. Continuous monitoring of IM is essential for detecting incipient faults in a timely manner and keeping the industrial processes working properly [4]
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