Signal pre-processing techniques for fault signature enhancement in a bearing health monitoring system used in the automotive industry

##plugins.themes.bootstrap3.article.main##

##plugins.themes.bootstrap3.article.sidebar##

Published Oct 26, 2023
Ehsan Jafarzadeh Sara Rahimifard Paola Sant Anna Yu Cao Frances Tenney Hossein Sadjadi

Abstract

Traditional internal combustion engine vehicles have low transmission bearing failure rates in their lifespans. However, the prolonged lifespan of electric and autonomous vehicles can surpass the reliable life of bearing designs, which poses a risk of bearing failure and loss of propulsion. Compared to replacing bearings on a fixed schedule to ensure reliability, a bearing health monitoring system is a more cost-effective solution. Despite extensive research on bearing condition monitoring, implementing well-known methods such as vibration spectrum analysis in vehicles can be challenging due to vibrations from vehicle components and the road. This paper explores and compares the effect of various pre-processing techniques on the spectrum of a faulty bearing with various fault levels. To achieve this objective, faults with the width size of 0.1 mm (mild), 0.5 mm (moderate) and 2 mm (severe) were injected into the inner race of a ball bearing. A bench setup was then used to capture the vibrations of multiple vehicle components including the faulty ball bearing under various speed/ load conditions. Phase domain transform, envelope and Fourier transform were used as the core signal processing steps, and advanced signal processing methods for removing discrete frequencies from other components and enhancing the fault signature were explored. 4 health indicators were then developed from the vibration spectrum of the vibration signals and calculated for the captured data. Next, for each fault level, the area under Receiver operating characteristic (ROC) curve was calculated and used as a metric to compare the performance of our health monitoring system for classification of faulty and healthy bearings. For our best health indicator, the results show that applying minimum entropy deconvolution, and spectral kurtosis-based band pass filtering increases the ROC area from 0.40, 0.99, 1.0 to 0.86, 1.0 and 1.0 for the mild, moderate, and severe inner race faults, respectively. This implies that although applying only phase domain transform, envelope and Fourier transform might be enough for moderate and severe faults, advanced signal processing is needed to enhance the fault signature for early detection of mild faults.

How to Cite

Jafarzadeh, E., Rahimifard, S., Sant Anna, P. ., Cao, Y., Tenney, F., & Sadjadi, H. (2023). Signal pre-processing techniques for fault signature enhancement in a bearing health monitoring system used in the automotive industry. Annual Conference of the PHM Society, 15(1). https://doi.org/10.36001/phmconf.2023.v15i1.3522
Abstract 331 | PDF Downloads 247

##plugins.themes.bootstrap3.article.details##

Keywords

bearing health monitoring, fault injection, signal processing, vibration analysis, prognostics, ROC

References
Antoni, J. (2006). The spectral kurtosis: a useful tool for characterising non-stationary signals. Mechanical Systems and Signal Processing, 20(2), 282-307.

Antoni, J., & Randall, R. B. (2004). Unsupervised noise cancellation for vibration signals: part I—evaluation of adaptive algorithms. Mechanical Systems and Signal Processing, 18(1), 89-101.

Darlow, M. S., Badgley, R. H., & Hogg, G. W. (1974). Application of High-Freuqency Resonance Techniques for Bearing Diagnostics in Helicopter Gearboxes. Army Air Mobility Research and Development Laboratory, 74-77.

Deloitte University Press. (2016). Gearing for Change: Preparing for transformation in the automotive ecosystem. Deloitte University Press.

Garner G, D. S. (2021). Brinell Fault Injection to Enable Development of a Wheel Bearing Fault Monitoring System for Automobiles. Annual Conference of the PHM Society .

Garner G, S. P. (2021). Modeling the Business Value of a Predictive Maintenance System using Monte Carlo Simulation. Annual Conference of the PHM Society.

Haram MH, L. J. (2021). Feasibility of utilising second life EV batteries: Applications, lifespan, economics, environmental impact, assessment, and challenges. Alexandria Engineering Journal, 60(5), 4517-36.

Jafarzadeh, E. L. (2022). Fault injection method and ground-truth state of health development for a low-cost bearing fault monitoring system in the automotive industry. Annual Conference of the Prognostics and Health Management Society.

Lybeck N, M. S. (2007). Validating prognostic algorithms: a case study using comprehensive bearing fault data. 2007 IEEE Aerospace Conference .

Motavalli, J. (2020, 11 12). Million-Mile Batteries? They're Coming. (AutoWeek) Retrieved 02 24, 2021, from https://www.autoweek.com/news/a34620676/million-mile-batteries-theyre-coming/

Nabhan A, G. N. (2015). bearing fault detection techniques - a review. Turkish Journal of Engineering, Science and Technology, 3(2), 1-8.

P, W. (2019). Charger collaborations power global electric vehicle expansion. Engineering, 5(6), 991-2.

Pan S, F. L. (2021). Shared use of electric autonomous vehicles: Air quality and health impacts of future mobility in the United States. Renewable and Sustainable Energy Reviews.

Park J, K. S. (2021). Frequency energy shift method for bearing fault prognosis using microphone sensor. Mechanical Systems and Signal Processing, 147.

Randall, R. B. (2011). A comparison of methods for separation of deterministic and random signals. (pp. 11-19). International Journal of Condition Monitoring.

Randall, R. B., & Antoni, J. (2011). Rolling element bearing diagnostics - A tutorial. Mechanical Systems and Signal Processing, 25, 485-520.

Rao SS, T. M. (1994). Reliability-based design of automotive transmission systems. Reliability Engineering & System Safety, 46(2), 159-69.

Sawalhi, N. R. (2005). Spectral kurtosis optimization for rolling element bearings. Proceedings of the Eighth International Symposium on Signal Processing and Its Applications. Sydney, NSW, Australia: IEEE.

Sawalhi, N., Randall, R. B., & Endo, H. (2007). The enhancement of fault detection and diagnosis in rolling element bearings using minimum entropy deconvolution combined with spectral kurtosis. Mechanical Systems and Signal Processing, 21(6), 2616-2633.

Simmons, R. (1997, August). Calculating G-RMS. (NASA) Retrieved April 2020

SKF. (2014). Bearing damage and failure analysis. SKF Explorer.

Smith WA, R. R. (2015). Rolling element bearing diagnostics using the Case Western Reserve University data: A benchmark study. Mechanical systems and signal processing, 1(64), 100-31.

Sutherlin, R. G. (2017). Wheel Bearing Brinelling and a Vehicle Curb Impact DOE to Understand Factors Affecting Bearing Loads. SAE International.

Tandon, N. ,. (1999). A review of vibration and acoustic measurement methods for the detection of defects in rolling element bearings. Tribology International 32, 469–480.

Upadhyay RK, K. L. (2013). Rolling element bearing failure analysis: A case study. Case studies in engineering failure analysis, 1(1), 15-7.

Wiggins, R. A. (1978). Minimum entropy deconvolution. Geoexploration, 21-35.
Section
Industry Experience Papers

Most read articles by the same author(s)

<< < 1 2