Research on Mechanical Fault Diagnosis and Prediction Technology Based on Deep Learning

Jiahao Lv

doi:10.62051/vbkk3b17

Authors

Jiahao Lv

DOI:

https://doi.org/10.62051/vbkk3b17

Keywords:

Deep Learning; CNN-LSTM; Fault Diagnosis; Prediction.

Abstract

This study introduces an innovative deep learning architecture, amalgamating Convolutional Neural Networks (CNN) and Long Short-Term Memory (LSTM) networks, termed the CNN-LSTM model. Its efficacy in both identifying and anticipating mechanical failures is explored through an examination of vibration datasets sourced from actual industrial machinery. The assessment delves into the model's capabilities across various fault categories and severities. Findings indicate that the CNN-LSTM model exhibits remarkable precision in fault identification, with forecasted outcomes largely aligning with actual fault occurrences, thus corroborating its diagnostic efficacy. A comparative analysis against traditional diagnostic techniques further elucidates the superior performance of the proposed model, as evidenced by its enhanced accuracy, recall, and F1 score metrics. Such results underscore the deep learning model's advanced precision and dependability when addressing intricate fault prediction tasks. This study proves the superior performance of CNN-LSTM model in the task of mechanical fault diagnosis and prediction. This discovery provides strong evidence for the application of deep learning in industrial field, and provides new tools and methods for solving practical engineering problems.

Downloads

Download data is not yet available.

References

Su, L. , Deng, L. , Zhu, W. , & Zhao, S. (2020). Statistical detection of weak pulse signal under chaotic noise based on elman neural network. Wireless Communications and Mobile Computing, 2020(1), 1-12.

Qi, H., Shi, Y. , Tian, Y. , Mayhew, C. , Yu, D. L. , & Gomm, J. B. , et al. (2019). A new fault diagnosis and fault-tolerant control method for mechanical and aeronautical systems with neural estimators:. Advances in Mechanical Engineering, 11(11), 339-348.

Huo, J. , Lin, D. , & Qi, W. (2020). Intelligent fault diagnosis method of mechanical equipment based on fuzzy pattern recognition. Journal of Intelligent and Fuzzy Systems, 38(12), 1-8.

Li, L. , Zhou, X. , Zhang, X. , & Zhong, Z. (2020). Precision degradation prediction of inertial test turntable based on hidden markov model and optimized particle filtering:. Advances in Mechanical Engineering, 12(12), 413-424.

Luo, P. , Hu, N. , Zhang, L. , Shen, J. , & Chen, L. (2020). Adaptive fisher-based deep convolutional neural network and its application to recognition of rolling element bearing fault patterns and sizes. Mathematical Problems in Engineering, 2020(2), 1-11.

Jian, Y. , Qing, X. , He, L. , Zhao, Y. , Qi, X. , & Du, M. (2019). Fault diagnosis of motor bearing based on deep learning:. Advances in Mechanical Engineering, 11(9), 562-569.

Ding, X. , Lu, X. , Wang, D. , Lv, Q. , & Zhai, H. (2020). Rolling bearing fault diagnosis based on probabilistic mixture model and semi-supervised ladder network:. Advances in Mechanical Engineering, 12(12), 1-12.

Touzout, W. , Benazzouz, D. , Gougam, F. , Afia, A. , & Rahmoune, C. (2020). Hybridization of time synchronous averaging, singular value decomposition, and adaptive neuro fuzzy inference system for multi-fault bearing diagnosis:. Advances in Mechanical Engineering, 12(12), 49-54.

Bettahar, T. , Rahmoune, C. , Benazzouz, D. , & Merainani, B. (2020). New method for gear fault diagnosis using empirical wavelet transform, hilbert transform, and cosine similarity metric:. Advances in Mechanical Engineering, 12(6), 63-68.

Shang, Z. , Li, W. , Gao, M. , Liu, X. , & Yu, Y. (2021). An intelligent fault diagnosis method of multi-scale deep feature fusion based on information entropy. Chinese Journal of Mechanical Engineering, 34(1), 1-16.