Authors: Cem Karacal, Sohyung Cho, William Yu

Abstract:

In metal cutting industries, mathematical/statistical models are typically used to predict tool replacement time. These off-line methods usually result in less than optimum replacement time thereby either wasting resources or causing quality problems. The few online real-time methods proposed use indirect measurement techniques and are prone to similar errors. Our idea is based on identifying the optimal replacement time using an electronic nose to detect the airborne compounds released when the tool wear reaches to a chemical substrate doped into tool material during the fabrication. The study investigates the feasibility of the idea, possible doping materials and methods along with data stream mining techniques for detection and monitoring different phases of tool wear.

Keywords: Tool condition monitoring, cutting tool replacement, data stream mining, e-Nose.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1074823

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1848

References:

[1] Kurada S, Bradley C (1997) A review of machine vision sensors for tool condition monitoring. Computers in Industry, 34:55-72.
[2] Cho S, Binsaed S, Asfour S (2008), Design of multi-sensor fusionbased tool condition monitoring system in end milling, International Journal of Advanced Manufacturing Technology, Submitted.
[3] Tansel IN, Trujillo ME, Bao WY (2001) Acoustic emission-based tool breakage detector for micro-end milling operations, International Journal of Modeling and Simulation, 21(1):10-16.
[4] Cho S, Asfour S, Onar A, Kaundinya N (2005) Tool breakage detection using support vector machine learning in a milling process, International Journal of Machine Tools and Manufacturing, 45(3), 241-249.
[5] Bhattacharyya P, Senupta D, Mukhopadhaya S (2007) Cutting force based real-time estimation of tool wear in face milling using a combination of signal processing techniques, Mechanical Systems and Signal, 21(6):2665-2683.
[6] Yesilyurt I, Ozturk H (2007) Tool condition monitoring in milling using vibration analysis, International Journal of Production Research, 45(4):1013-1028.
[7] Ghosh N, Ravi YB, Patra A, Mukhopadhyay S, Paul S, Mohanty AR, Chattopadhyay AB (2007) Estimation of tool wear during CNC milling using neural network based sensor fusion, Mechanical Systems and Signal Processing, 21:466-479.
[8] Norman P, Kaplan A, Rantatalo M, Svenningsson I (2007) Study of a sensor platform for monitoring machining of aluminum and steel, Measurement Science Technology, 18:1155-1166.
[9] Persaud K, Dodd GH (1982), Analysis of discrimination mechanisms in the mammalian olfactory system using a model nose, Nature, 299:352- 355.
[10] Bartlett PN, Blair N, Gardner JW (1993), Electronic nose: principles, applications and outlook, ASIC, 15e Colloque, Montpellier, 478-486.
[11] Gardner JW, Bartlett PN (1993), A brief history of electronic noses, Sensors and Actuators B., 18:211-220.
[12] Ghani JA, Choudhury IA, Masjuki HH (2004), Wear mechanism of TiN coated carbide and uncoated cermets tools at high cutting speed applications, Journal of Materials Processing Technology, 153- 154:1067-1073.
[13] Liu H, Wang Y & Lu X, "A Method To Choose Kernel Function and its Parameters for Support Vector Machines", Proceedings of the Fourth International Conference on Machine Learning and Cybernetics, Guangzhou, 18-21 August 2005.
[14] Fuke I, Prabhu VV, Cho S, George T, Singh J (2005), Rapid manufacturing of rhenium components using EB-PVD, Rapid Prototyping Journal, 11(2):66-73.
[15] Tsai MH, Sun SC, Chiu HT, Tsai CE, Chuang SH (1995), Metalorganic chemical vapor deposition of tantalum nitride by tertbutylimidortris - (diethylamido) tantalum for advanced metallization, Applied Physics Letter, 67:1128-1133.
[16] Witten IH, Frank E (2005), Data Mining: practical machine learning tools and techniques. 2nd Edition, Morgan Kaufmann, San Francisco, 2005.