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Individual feature selection of rolling bearing impedance signals for early failure detection

Becker-Dombrowsky, Florian Michael ; Koplin, Quentin Sean ; Kirchner, Eckhard (2023)
Individual feature selection of rolling bearing impedance signals for early failure detection.
In: Lubricants, 11 (7)
doi: 10.3390/lubricants11070304
Article, Bibliographie

Abstract

Condition monitoring of technical systems has increasing importance for the reduction of downtimes based on unplanned breakdowns. Rolling bearings are a central component of machines because they often support energy-transmitting elements like shafts and spur gears. Bearing damages lead to a high number of machine breakdowns; thus, observing these has the potential to reduce unplanned downtimes. The observation of bearings is challenging since their behavior in operation cannot be investigated directly. A common solution for this task is the measurement of vibration or component temperature, which is able to show an already occurred bearing damage. Measuring the electrical bearing impedance in situ has the ability to gather information about bearing revolution speed and bearing loads. Additionally, measuring the impedance allows for the detection and localization of damages in the bearing, as early research has shown. In this paper, the impedance signal of five fatigue tests is investigated using individual feature selection. Additionally, the feature behavior is analyzed and explained. It is shown that the three different bearing operational time phases can be distinguished via the analysis of impedance signal features. Furthermore, some of the features show a significant change in behavior prior to the occurrence of initial damages before the vibration signals of the test rig vary from a normal state.

Item Type: Article
Erschienen: 2023
Creators: Becker-Dombrowsky, Florian Michael ; Koplin, Quentin Sean ; Kirchner, Eckhard
Type of entry: Bibliographie
Title: Individual feature selection of rolling bearing impedance signals for early failure detection
Language: English
Date: 20 July 2023
Publisher: MDPI
Journal or Publication Title: Lubricants
Volume of the journal: 11
Issue Number: 7
DOI: 10.3390/lubricants11070304
Abstract:

Condition monitoring of technical systems has increasing importance for the reduction of downtimes based on unplanned breakdowns. Rolling bearings are a central component of machines because they often support energy-transmitting elements like shafts and spur gears. Bearing damages lead to a high number of machine breakdowns; thus, observing these has the potential to reduce unplanned downtimes. The observation of bearings is challenging since their behavior in operation cannot be investigated directly. A common solution for this task is the measurement of vibration or component temperature, which is able to show an already occurred bearing damage. Measuring the electrical bearing impedance in situ has the ability to gather information about bearing revolution speed and bearing loads. Additionally, measuring the impedance allows for the detection and localization of damages in the bearing, as early research has shown. In this paper, the impedance signal of five fatigue tests is investigated using individual feature selection. Additionally, the feature behavior is analyzed and explained. It is shown that the three different bearing operational time phases can be distinguished via the analysis of impedance signal features. Furthermore, some of the features show a significant change in behavior prior to the occurrence of initial damages before the vibration signals of the test rig vary from a normal state.

Additional Information:

Artikel-ID: 304

Divisions: 16 Department of Mechanical Engineering
16 Department of Mechanical Engineering > Institute for Product Development and Machine Elements (pmd)
Date Deposited: 25 Jul 2023 05:16
Last Modified: 25 Jul 2023 06:26
PPN: 509896774
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