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Journal of Intelligent Manufacturing

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01-10-2015

Cutting tool operational reliability prediction based on acoustic emission and logistic regression model

Authors: Hongkun Li, Yinhu Wang, Pengshi Zhao, Xiaowen Zhang, Peilin Zhou

Published in: Journal of Intelligent Manufacturing | Issue 5/2015

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Abstract

Working status of cutting tools (CTs) is crucial to the products’ precision. If broken down, it may lead to waste product. Condition monitoring and life prediction are beneficial to the manufacturing process. In this research, Logistic regression models (LRMs) and acoustic emission (AE) signal are used to evaluate reliability. Based on different conditions estimation, CTs are investigated to determine the best maintenance time. Based on experimental data analysis, AE and cutting force signals have better linear relationship with CT wearing process. They can be used to demonstrate CT degradation process. Frequency band energy is determined as characteristic vector for AE signal using wavelet packet decomposition. Two reliability estimation models are constructed based on cutting force and AE signals. One uses both signals, while the other uses only AE signal. The reliability degree can be estimated using the two models, independently. AE feature extraction and LRM can effectively estimate CT conditions. As it is difficult to monitor cutting force in a practical working condition, it is an effective method for CT reliability analysis by the combination of AE and LRM method. Experimental investigation is used to verify the effectiveness of this method.

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Alonso, F. J., & Salgado, D. R. (2008). Analysis of the structure of vibration signals for tool wear detection. Mechanical Systems and Signal Processing, 22(3), 735–748. doi:10.1016/j.ymssp.2007.09.012.CrossRef

Bender, R., & Kuss, O. (2010). Methods to calculate relative risks, risk differences, and numbers needed to treat from logistic regression. Journal of Clinical Epidemiology, 63(1), 7–8.CrossRef

Caesarendra, W., Widodo, A., & Yang, B.-S. (2010). Application of relevance vector machine and logistic regression for machine degradation assessment. Mechanical Systems and Signal Processing, 24(4), 1161–1171. doi:10.1016/j.ymssp.2009.10.011.CrossRef

Chen, B., Chen, X., & Li, B. (2011a). Reliability estimation for cutting tools based on logistic regression model using vibration signals. Mechanical Systems and Signal Processing, 25(7), 2516–2537.CrossRef

Chen, B. J., Chen, X. F., & Li, B. (2011b). Reliability estimation for cutting tool based on logistic regression model. Chinese Journal of Mechanical Engineering, 47(18), 158–164.CrossRef

Dimla S, D. E. (2002). The correlation of vibration signal features to cutting tool wear in a metal turning operation. The International Journal of Advanced Manufacturing Technology, 19(10), 705–713.CrossRef

Ding, F., He, Z. J., & Zi, Y. Y. (2009). Reliability assessment based on equipment condition vibration feature using proportional hazard model. Chinese Journal of Mechanical Engineering, 45(13), 89–94.CrossRef

Heng, A., Zhang, S., Tan, A. C., & Mathew, J. (2009). Rotating machinery prognostics: State of the art, challenges and opportunities. Mechanical Systems and Signal Processing, 23(3), 724–739.CrossRef

Huang, S. N., Tan, K. K., Wong, Y. S., de Silva, C. W., Goh, H. L., & Tan, W. W. (2007). Tool wear detection and fault diagnosis based on cutting force monitoring. International Journal of Machine Tools and Manufacture, 47(3–4), 444–451. doi:10.1016/j.ijmachtools.2006.06.011.CrossRef

Jardine, A. K., Lin, D., & Banjevic, D. (2006). A review on machinery diagnostics and prognostics implementing condition-based maintenance. Mechanical Systems and Signal Processing, 20(7), 1483–1510.

Jemielniak, K., & Kwiatkowski, L. (1998). Diagnosis of tool wear based on cutting forces and acoustic emission measures as inputs to a neural network. Journal of Intelligent Manufacturing, 9(5), 447–455.

Kious, M., Ouahabi, A., Boudraa, M., Serra, R., & Cheknane, A. (2010). Detection process approach of tool wear in high speed milling. Measurement, 43(10), 1439–1446.CrossRef

Liu, B. (2005). Selection of wavelet packet basis for rotating machinery fault diagnosis. Journal of Sound and Vibration, 284(3–5), 567–582. doi:10.1016/j.jsv.2004.06.047.CrossRef

Martin, D. (1977). Early warning of bank failure: A logit regression approach. Journal of Banking and Finance, 1(3), 249–276.CrossRef

Mill Data Set. (2007). BEST lab. UC Berkeley.

Peng, C. Y. J., Lee, K. L., & Ingersoll, G. M. (2002). An introduction to logistic regression analysis and reporting. Journal of Educational Research, 96(1), 3–14.CrossRef

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, 18(2), 199–221. doi:10.1016/s0888-3270(03)00075-x.CrossRef

Sharma, V. S., & Sharma, S. (2007). Cutting tool wear estimation for turning. Journal of Intelligent Manufacturing, 19(1), 99–108.CrossRef

Sukhomay, P., & Heyns, P. (2009). Tool wear monitoring and selection of optimum cutting conditions with progressive tool wear effect and input uncertainties. Journal of Intelligent Manufacturing, 22(4), 491–504.

Venkatesh, K., & Mengchu, Z. (1997). Design of artificial neural networks for tool wear monitoring. Journal of Intelligent Manufacturing, 8(3), 215–226.CrossRef

Wang, Z., & Wlofhard, L. (1996). Feature-filtered fuzzy clustering for condition monitoring of tool wear. Journal of Intelligent Manufacturing, 7(1), 13–22.CrossRef

Xiaoyu, W., & wen, W. (2008). Design of neural network-based estimator for tool wear modeling in hard turning. Journal of Intelligent Manufacturing, 19(4), 383–396.CrossRef

Yan, J., Ko, M., & Lee, J. (2004). A prognostic algorithm for machine performance assessment and its application. Production Planning and Control, 15(8), 796–801. doi:10.1080/09537280412331309208.CrossRef

Yan, J., & Lee, J. (2005). Degradation assessment and fault modes classification using logistic regression. Journal of Manufacturing Science and Engineering, 127(4), 912–914.CrossRef

Zhu, K., Wong, Y. S., & Hong, G. S. (2009). Wavelet analysis of sensor signals for tool condition monitoring: A review and some new results. International Journal of Machine Tools and Manufacture, 49(7–8), 537–553. doi:10.1016/j.ijmachtools.2009.02.003.CrossRef

Zio, E. (2009). Reliability engineering, old problems and new challenges. Reliability Engineering and System Safety, 94(2), 125–141. doi:10.1016/j.ress.2008.06.002.CrossRef

Title: Cutting tool operational reliability prediction based on acoustic emission and logistic regression model
Authors: Hongkun Li
Yinhu Wang
Pengshi Zhao
Xiaowen Zhang
Peilin Zhou
Publication date: 01-10-2015
Publisher: Springer US
Published in: Journal of Intelligent Manufacturing / Issue 5/2015
Print ISSN: 0956-5515
Electronic ISSN: 1572-8145
DOI: https://doi.org/10.1007/s10845-014-0941-4

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