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Production Engineering
Erschienen in: Production Engineering 3-4/2021

01.03.2021 | Production Process

A novel approach of combined edge detection and segmentation for tool wear measurement in machining

verfasst von: P. J. Bagga, M. A. Makhesana, K. M. Patel

Erschienen in: Production Engineering | Ausgabe 3-4/2021

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Abstract

Product quality in machined parts is governed by many factors, out of which the state of wear of the tool is one of the most critical factors. Knowing the condition of the tool wear makes it possible to optimize the tool life and simultaneously maintain the surface quality. There are methods of online wear measurement proposed in the literature, like correlating some physical parameters to the wear state of the tool. As the processes are indirect, they do not provide exact values of the tool wear, but only aids in classifying the wear into different states from mild to severe. This work is focused on developing direct tool wear measurement by applying image processing techniques, which is more accurate, and precise. It has a very negligible interruption in production, and helps in automation of the task of tool wear monitoring and replacing it. In this paper, a novel online tool wear measuring algorithm is proposed using combined techniques of edge detection and segmentation. A complementary metal–oxide–semiconductor (CMOS) sensor camera is utilized to capture the wear zone images. The tool’s wear value is extracted by establishing wear boundaries through image processing, threshold segmentation, edge detection, and morphological operation. The machining tests are performed on a CNC lathe. The tool wear measured by the proposed technique is compared with the measurements obtained by an optical microscope. The results demonstrated high detection accuracy of the proposed approach enabling online tool wear monitoring during the turning process.
Vorheriger Artikel A time series classification approach to non-destructive hardness testing using magnetic Barkhausen noise emission
Nächster Artikel Improving machinability of additively manufactured components with selectively weakened material

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Literatur
1.
Karandikar JM, Abbas AE, Schmitz TL (2014) Tool life prediction using Bayesian updating. Part 2: turning tool life using a Markov Chain Monte Carlo approach. Precis Eng 38(1):18–27CrossRef
2.
3.
Lins RG, de Araujo PRM, Corazzim M (2020) In-process machine vision monitoring of tool wear for Cyber-Physical Production Systems. Robot Comput Integr Manuf 61:101859CrossRef
4.
Liang, S., & Shih, A. J. (2015). Analysis of machining and machine tools. Springer.
5.
Zhou Y, Xue W (2018) Review of tool condition monitoring methods in milling processes. Int J Adv Manuf Technol 96(5–8):2509–2523CrossRef
6.
Dutta S, Pal SK, Mukhopadhyay S, Sen R (2013) Application of digital image processing in tool condition monitoring: a review. CIRP J Manuf Sci Technol 6(3):212–232CrossRef
7.
Byrne G, Dornfeld D, Inasaki I, Ketteler G, König W, Teti R (1995) Tool condition monitoring (TCM)—the status of research and industrial application. CIRP Ann 44(2):541–567CrossRef
8.
Liang SY, Hecker RL, Landers RG (2004) Machining process monitoring and control: the state-of-the-art. J Manuf Sci Eng 126(2):297–310CrossRef
9.
Teti R, Jemielniak K, O’Donnell G, Dornfeld D (2010) Advanced monitoring of machining operations. CIRP Ann 59(2):717–739CrossRef
10.
D’Addona D, Segreto T, Simeone A, Teti R (2011) ANN tool wear modeling in the machining of nickel superalloy industrial products. CIRP J Manuf Sci Tech 4(1):33–37CrossRef
11.
Segreto T, Simeone A, Teti R (2013) Multiple sensor monitoring n nickel alloy turning for tool wear assessment via sensor fusion. Proc CIRP 12:85–90CrossRef
12.
Segreto T, Caggiano A, Karam S, Teti R (2017) Vibration sensor monitoring of nickel-titanium alloy turning for machinability evaluation. Sensors 17(12):2885CrossRef
13.
Segreto T, D’Addona D, Teti R (2020) Tool wear estimation in turning of Inconel 718 based on wavelet sensor signal analysis and machine learning paradigms. Prod Eng Res Devel 14(5):693–705CrossRef
14.
Ong P, Lee WK, Lau RJH (2019) Tool condition monitoring in CNC end milling using wavelet neural network based on machine vision. Int J Adv Manuf Technol 104(1–4):1369–1379CrossRef
15.
Castejón M, Alegre E, Barreiro J, Hernández LK (2007) On-line tool wear monitoring using geometric descriptors from digital images. Int J Mach Tools Manuf 47(12–13):1847–1853CrossRef
16.
Saeidi O, Torabi SR, Ataei M (2013) Development of a new index to assess the rock mass drillability. Geotech Geol Eng 31(5):1477–1495CrossRef
17.
Zhang C, Zhang J (2013) On-line tool wear measurement for ball-end milling cutter based on machine vision. Comput Ind 64(6):708–719CrossRef
18.
D’Addona DM, Teti R (2013) Image data processing via neural networks for tool wear prediction. Procedia CIRP 12:252–257CrossRef
19.
Pfeifer T, Wiegers L (2000) Reliable tool wear monitoring by optimized image and illumination control in machine vision. Measurement 28(3):209–218CrossRef
20.
Kim JH, Moon DK, Lee DW, Kim JS, Kang MC, Kim KH (2002) Tool wear measuring technique on the machine using CCD and exclusive jig. J Mater Process Technol 130:668–674CrossRef
21.
Sortino M (2003) Application of statistical filtering for optical detection of tool wear. Int J Mach Tools Manuf 43(5):493–497.CrossRef
22.
Obikawa T, Shinozuka J (2004) Monitoring of flank wear of coated tools in high speed machining with a neural network ART2. Int J Mach Tools Manuf 44(12–13):1311–1318CrossRef
23.
Liang, Y. T., Chiou, Y. C., & Louh, C. J. (2005). Automatic wear measurement of Ti-based coatings milling via image registration. In MVA (pp. 88–91).
24.
Jurkovic J, Korosec M, Kopac J (2005) New approach in tool wear measuring technique using CCD vision system. Int J Mach Tools Manuf 45(9):1023–1030CrossRef
25.
Xiong, G., Liu, J., & Avila, A. (2011, August). Cutting tool wear measurement by using active contour model based image processing. In 2011 IEEE International Conference on Mechatronics and Automation (pp. 670–675). IEEE.
26.
Wang WH, Hong GS, Wong YS (2006) Flank wear measurement by a threshold independent method with sub-pixel accuracy. Int J Mach Tools Manuf 46(2):199–207CrossRef
27.
Su JC, Huang CK, Tarng YS (2006) An automated flank wear measurement of microdrills using machine vision. J Mater Process Technol 180(1–3):328–335CrossRef
28.
Wang W, Wong YS, Hong GS (2005) Flank wear measurement by successive image analysis. Comput Ind 56(8–9):816–830CrossRef
29.
Kurada S, Bradley C (1997) A machine vision system for tool wear assessment. Tribol Int 30(4):295–304CrossRef
30.
Kene AP, Choudhury SK (2019) Analytical modeling of tool health monitoring system using multiple sensor data fusion approach in hard machining. Measurement 145:118–129CrossRef
31.
Dutta S, Pal SK, Sen R (2016) On-machine tool prediction of flank wear from machined surface images using texture analyses and support vector regression. Precis Eng 43:34–42CrossRef
32.
Hou Q, Sun J, Huang P (2019) A novel algorithm for tool wear online inspection based on machine vision. Int J Adv Manuf Technol 101(9–12):2415–2423CrossRef
33.
D’Addona DM, Matarazzo D, Ullah AS, Teti R (2015) Tool wear control through cognitive paradigms. Procedia CIRP 33:221–226CrossRef
34.
Astakhov VP (2011) Turning., Chapter 1 in book “MODERN MACHINING TECHNOLOGY: A practical guide”. In: Davim JP (eds) WOODHEAD/CHANDOS Oxford (UK), pp 1–78
35.
Astakhov VP (2004) The assessment of cutting tool wear. Int J Mach Tools Manuf 44(6):637–647CrossRef
36.
Moldovan OG, Dzitac S, Moga I, Vesselenyi T, Dzitac I (2017) Tool-wear analysis using image processing of the tool flank. Symmetry 9(12):296CrossRef
37.
Wayalun, P., Chomphuwiset, P., Laopracha, N., & Wanchanthuek, P. (2012, August). Images Enhancement of G-band Chromosome Using histogram equalization, OTSU thresholding, morphological dilation and flood fill techniques. In 2012 8th International Conference on Computing and Networking Technology (INC, ICCIS and ICMIC) (pp. 163–168). IEEE.
Metadaten
Titel
A novel approach of combined edge detection and segmentation for tool wear measurement in machining
verfasst von
P. J. Bagga
M. A. Makhesana
K. M. Patel
Publikationsdatum
01.03.2021
Verlag
Springer Berlin Heidelberg
Erschienen in
Production Engineering / Ausgabe 3-4/2021
Print ISSN: 0944-6524
Elektronische ISSN: 1863-7353
DOI
https://doi.org/10.1007/s11740-021-01035-5

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