Motor current signature analysis for gearbox health monitoring: Experiment, signal analysis and classification

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Published Jul 8, 2014
Iñaki Bravo-Imaz Alfredo García-Arribas Susana Ferreiro Santiago Fernandez Aitor Arnaiz

Abstract

Preventing downtimes in machinery operation is becoming fundamental in industrial standards. The most common strategy to avoid costly production stoppages is the preventive maintenance, combining it with reactive maintenance in detected malfunctions. Condition-based maintenance can reduce costs, and help maintaining the quality of the produced goods. Gearboxes, as crucial elements in industrial machinery, are conventionally monitored using accelerometers, which are expensive and can be hard to install in place to provide useful information.
Motor current signature analysis overcomes these inconveniences. This analysis technique provides a non-intrusive method, and it is based on readily available signals. Changes in the input voltages are related with variations of the speed and/or load of the electric motor. The health state of the gearbox can be examined through an exhaustive analysis of the input currents.
A gear prognosis simulator (GPS) test bench has been used to perform an extensive experimentation campaign. This test bench is particularly convenient due to the flexibility it provides. Different sets of sensors can be placed in different positions, and multiple combinations of speeds and loads can be established. Three damage categories in the gears have been analyzed, high damage, moderate damage and little damage. The test parameters have been selected to simulate the working conditions of electromechanical actuators and machine tools. Constant speed and transient tests have been performed. In the transient tests, fast speed changes are performed to produce acceleration, to investigate the concomitant changes produced in the signal. The analysis has been performed in both the time and the frequency domain, and complementarily, using the wavelet decomposition. The results obtained allow discerning the different type of defects on the gears, thus allowing detecting the different fault conditions and enabling the assessment of the health state of the gearbox.

How to Cite

Bravo-Imaz, I., García-Arribas, A., Ferreiro, S., Fernandez, S., & Arnaiz, A. (2014). Motor current signature analysis for gearbox health monitoring: Experiment, signal analysis and classification. PHM Society European Conference, 2(1). https://doi.org/10.36001/phme.2014.v2i1.1486
Abstract 757 | PDF Downloads 152

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Keywords

condition monitoring, Motor Current Signature Analysis, Multi-stage gearbox

References
Chandran P., Lokesha M., Majumder M.C., Raheemv K.F. A. (2012) Application of Laplace Wavelet Kurtosis and Wavelet Statistical Parameters for Gear Fault Diagnosis, International journal of multidisciplinary sciences and engineering, vol. 3 (issue 9), pp. 1-8
Cusidó J., Romeral L., Ortega J.A., Rosero J.A., García Espinosa A. (2008). Fault Detection in Induction Machines Using Power Spectral Density in Wavelet Decomposition, IEEE Transactions on Industrial Electronics, vol. 55 (issue 2), pp. 633-643. doi:10.1109/TIE.2007.911960
Dhillon B.S. (2002). ENGINEERING MAINTENANCE A modern approach. USA: CRC Press
El Hachemi Benbouzid M. A. (2000). Review of Induction Motors Signature Analysis as a Medium for Faults Detection, IEEE Transactions on Industrial Electronics, vol. 47, (issue 5), pp. 984 - 993. doi: 10.1109/41.873206
Kar C., & Mohanty A.R. (2006). Monitoring gear vibrations through motor current signature analysis and wavelet transform. Mechanical Systems and Signal Processing, vol. 20 (issue 1), pp. 158-187
Peng Z.K., Chu F.L. (2004) Application of the wavelet transform in machine condition monitoring and fault diagnostics: a review with bibliography, Mechanical Systems and Signal Processing, vol. 18, pp. 199-221, doi: 10.1016/S0888-3270(03)00075-X
Rafiee J., Rafiee M.A., Tse P.W. (2010). Application of mother wavelet functions for automatic gear and bearing fault diagnosis, Expert Systems with Applications, vol. 37 (issue 6), pp. 4568-4579, doi: 10.1016/j.eswa.2009.12.051
Randall Robert B. (2002). State of the Art in Monitoring Rotating Machinery – Part 1, ISMA 2002 conference, September, Leuven, Belgium.
www.sndv.com/downloads/0403rand.pdf
Subasi A. (2007). EEG signal classification using wavelet feature extraction and a mixture of expert model, Expert model with applications, vol. 32, pp. 1084-1093, doi: 10.1016/j.eswa.200602.005
Section
Technical Papers

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