Affiliation:
1. Doctoral School of Mechanical Engineering, Hungarian University of Agriculture and Life Sciences (MATE), Páter K. 1, H-2100 Gödöllő, Hungary
2. Institute of Technology, Hungarian University of Agriculture and Life Science (MATE), Páter K. 1, H-2100 Gödöllő, Hungary
Abstract
In this study, a deep transfer learning model was developed using ResNet-101 architecture to diagnose double roller bearing defects. Vibration data were collected for three different load scenarios, including conditions without load, and for five different rotational speeds, ranging from 500 to 2500 RPM. Significantly, the speed condition of 2500 RPM has not previously been investigated, therefore offering a potential avenue for future investigations. This study offers a thorough examination of bearing conditions using multidirectional vibration data collected from accelerometers positioned in both vertical and horizontal orientations. In addition to transfer learning using ResNet-101, four additional models (VGG-16, VGG19, ResNet-18, and ResNet-50) were trained. Transfer learning using ResNet-101 consistently achieved the highest accuracy in all scenarios, with accuracy rates ranging from 90.78% to 99%. Scattergram Filter Bank 1 was used as the image input for training as a preprocessing method to enhance feature extraction. Research has effectively applied transfer learning to improve fault diagnosis accuracy, especially in limited data scenarios. This shows the capability of the method to differentiate between normal and faulty bearing conditions using signal-to-image transformation, emphasizing the potential of transfer learning to augment diagnostic performance in scenarios with limited training data.
Funder
Ministry of Innovation and Technology
AGIT FIEK
Reference50 articles.
1. Bearing fault diagnosis using transfer learning and optimised deep belief network;Zhao;Meas. Sci. Technol.,2022
2. A diagnosis framework based on domain adaptation for bearing fault diagnosis across diverse domains;Ma;ISA Trans.,2020
3. Machine learning algorithms for industrial fault diagnosis: Challenges and solutions;Manikandan;Mech. Syst. Signal Process.,2021
4. Deep convolutional transfer learning network: A new method for intelligent fault diagnosis of machines with unlabeled data;Guo;IEEE Trans. Ind. Electron.,2018
5. Gousseau, W., Antoni, J., Girardin, F., and Griffaton, J. (2016, January 10–12). Analysis of the Rolling Element Bearing data set of the Center for Intelligent Maintenance Systems of the University of Cincinnati. Proceedings of the CM2016, Paris, France.