Intelligent Hardness Prediction of Bearing Rings Using Pulsed Eddy Current Testing

Bearings are central components of rotating machinery. Original equipment manufacturers must utilize high-quality bearings for desirable performances and safety of the equipment. Hardness, which is directly linked to product performance and reliability, is, thus, an essential mechanical property of bearings. As a result, it is necessary to evaluate the hardness during the manufacturing process. However, because of the complicated transformation of microstructures during heat treatment, there is no an established noncontact, quick, and affordable method for measuring the hardness of bearings. This article describes a pulsed eddy current testing (PECT)-based novel method utilizing deep learning for reliable nondestructive testing of bearing rings. The continuous wavelet transform (CWT) was used to combine the time-frequency information in the PECT signals, and the deep learning models were trained to predict hardness. In addition, we compared and optimized the network’s performance in feature maps, the number of convolutional kernels, and the learning rate. The results indicate that the developed novel method has an average error of 1.37% and a maximum error of 1.89%, exhibiting good hardness prediction accuracy and stability.

[1]  José A. Núñez-López,et al.  Positioning Improvement for a Laser Scanning System using cSORPD control , 2021, IECON 2021 – 47th Annual Conference of the IEEE Industrial Electronics Society.

[2]  Vera Tyrsa,et al.  3D Optical Machine Vision Sensors With Intelligent Data Management for Robotic Swarm Navigation Improvement , 2021, IEEE Sensors Journal.

[3]  Baoling Liu,et al.  Noncontact and nondestructive evaluation of heat-treated bearing rings using pulsed eddy current testing , 2021 .

[4]  C. He,et al.  A Sensitivity Mapping Technique for Tensile Force and Case Depth Characterization Based on Magnetic Minor Hysteresis Loops , 2020 .

[5]  Oleg Sergiyenko,et al.  Geometric analysis of a laser scanner functioning based on dynamic triangulation , 2020, 2020 IEEE 29th International Symposium on Industrial Electronics (ISIE).

[6]  Xinxin Li,et al.  Nonlinear ultrasonic characterization of carburized case depth , 2020 .

[7]  S. Kahrobaee,et al.  Characterization of Hadfield Steels Subjected to Various Heat-Treating Processes by Nondestructive Eddy Current Method , 2020, Russian Journal of Nondestructive Testing.

[8]  Ling Wang,et al.  Further understanding of rolling contact fatigue in rolling element bearings - A review , 2019, Tribology International.

[9]  Ping Wang,et al.  Reliable characterization of bearing rings using Eddy current and Barkhausen noise data fusion , 2019, Journal of Magnetism and Magnetic Materials.

[10]  Gui Yun Tian,et al.  Non-destructive hardness prediction for 18CrNiMo7-6 steel based on feature selection and fusion of Magnetic Barkhausen Noise , 2019, NDT & E International.

[11]  Mengbao Fan,et al.  Automatic classification of heat-treated bearing rings based on the swept frequency eddy current technique , 2019, Insight - Non-Destructive Testing and Condition Monitoring.

[12]  R. Hübler,et al.  Elasto – Plastic materials behavior evaluation according to different models applied in indentation hardness tests , 2019, Measurement.

[13]  Wendy Flores-Fuentes,et al.  Circular Scanning Resolution Improvement by its Velocity Close Loop Control , 2019, 2019 IEEE 28th International Symposium on Industrial Electronics (ISIE).

[14]  Bin Wu,et al.  Simultaneous quantitative prediction of tensile stress, surface hardness and case depth in medium carbon steel rods based on multifunctional magnetic testing techniques , 2018, Measurement.

[15]  Guangmin Sun,et al.  A Novel Prediction Method for Hardness Using Auto-regressive Spectrum of Barkhausen Noise , 2018, Journal of Nondestructive Evaluation.

[16]  Wu Bin,et al.  Quantitative Prediction of Surface Hardness in 12CrMoV Steel Plate Based on Magnetic Barkhausen Noise and Tangential Magnetic Field Measurements , 2018 .

[17]  J. Mohapatra,et al.  Magnetic Hysteresis Loop Technique as a NDE Tool for the Evaluation of Microstructure and Mechanical Properties of 2.25Cr–1Mo Steel , 2018 .

[18]  Yun Fu,et al.  Residual Dense Network for Image Super-Resolution , 2018, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[19]  Duan-Yu Chen,et al.  Deep-Learning-Based Earth Fault Detection Using Continuous Wavelet Transform and Convolutional Neural Network in Resonant Grounding Distribution Systems , 2018, IEEE Sensors Journal.

[20]  Yujie Wei,et al.  Case study: The effect of running distance on the microstructure and properties of railroad axle bearings , 2018 .

[21]  Qinghua Zhang,et al.  Fault Diagnosis of a Rolling Bearing Using Wavelet Packet Denoising and Random Forests , 2017, IEEE Sensors Journal.

[22]  Gui Yun Tian,et al.  Pulsed eddy current thickness measurement using phase features immune to liftoff effect , 2017 .

[23]  Faizal Mustapha,et al.  On the correlation between microstructural evolution and ultrasonic properties: a review , 2015, Journal of Materials Science.

[24]  H. Lee,et al.  Effects of differences in hardness measurement procedures on the traceability chain and calibration process , 2013 .

[25]  Oleg Sergiyenko,et al.  Surface recognition improvement in 3D medical laser scanner using Levenberg-Marquardt method , 2013, Signal Process..

[26]  Tribikram Kundu,et al.  Material hardness and ageing measurement using guided ultrasonic waves. , 2013, Ultrasonics.

[27]  Sudhir Misra,et al.  Evaluating changes in fundamental cross-sectional mode of vibrations using a modified time domain for impact echo data , 2012 .

[28]  A. Sorsa,et al.  Quantitative prediction of residual stress and hardness in case-hardened steel based on the Barkhausen noise measurement , 2012 .

[29]  O. Stupakov,et al.  Detection of spring steel surface decarburization by magnetic hysteresis measurements , 2011 .

[30]  W Yin,et al.  Measurement of decarburisation of steel rods with an electromagnetic sensor using an analytical model , 2009, 2009 IEEE Instrumentation and Measurement Technology Conference.

[31]  R. Aoyagi,et al.  Comparison of Ultrasonic-Hardness-Tester Hardness and Micro-Vickers Hardness , 2007 .

[32]  Didier Chicot,et al.  Eddy currents and hardness testing for evaluation of steel decarburizing , 2006 .

[33]  Yang-Tse Cheng,et al.  Scaling, dimensional analysis, and indentation measurements , 2004 .

[34]  G. Pharr,et al.  Measurement of hardness and elastic modulus by instrumented indentation: Advances in understanding and refinements to methodology , 2004 .

[35]  J. García-Martín,et al.  Measurement of hardness increase for shot-peened austenitic TX304HB stainless steel tubes with electromagnetic Non-Destructive testing , 2020 .

[36]  Mengbao Fan,et al.  Extraction of LOI Features From Spectral Pulsed Eddy Current Signals for Evaluation of Ferromagnetic Samples , 2019, IEEE Sensors Journal.

[37]  Gregory N. Haidemenopoulos,et al.  STEELS FOR BEARINGS , 2016 .

[38]  Gui Yun Tian,et al.  A FEATURE EXTRACTION TECHNIQUE BASED ON PRINCIPAL COMPONENT ANALYSIS FOR PULSED EDDY CURRENT NDT , 2003 .

[39]  Hsuen-Chyun Shyu,et al.  Construction of a Morlet Wavelet Power Spectrum , 2002, Multidimens. Syst. Signal Process..