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Artificial neural network based tool wear estimation on dry hard turning processes of AISI4140 steel using coated carbide tool

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Nowadays, finishing operation in hardened steel parts which have wide industrial applications is done by hard turning. Cubic boron nitride (CBN) inserts, which are expensive, are used for hard turning. The cheaper coated carbide tool is seen as a substitute for CBN inserts in the hardness range (45–55 HRC). However, tool wear in a coated carbide tool during hard turning is a significant factor that influences the tolerance of machined surface. An online tool wear estimation system is essential for maintaining the surface quality and minimizing the manufacturing cost. In this investigation, the cutting tool wear estimation using artificial neural network (ANN) is proposed. AISI4140 steel hardened to 47 HRC is used as a work piece and a coated carbide tool is the cutting tool. Experimentation is based on full factorial design (FFD) as per design of experiments. The variations in cutting forces and vibrations are measured during the experimentation. Based on the process parameters and measured parameters an ANN-based tool wear estimator is developed. The wear outputs from the ANN model are then tested. It was observed that as the model using ANN provided quite satisfactory results, and that it can be used for online tool wear estimation.
Rocznik
Strony
553--559
Opis fizyczny
Bibliogr. 24 poz., tab., wykr., rys.
Twórcy
autor
  • Department of Mechanical Engineering, Mar Ephraem College of Engineering and Technology, Marthandam, Kanyakumari, Tamilnadu 629171, India
autor
  • Centre for Automation and Robotics, Hindustan University, Chennai, Tamilnadu 603103, India
  • Department of Mechanical Engineering, Mepco Schlenk Engineering College, Sivakasi, Tamilnadu 626005, India
Bibliografia
  • [1] H. Aouci, M.A. Yallese, K. Chaoui, T. Mabrouki, and J.F. Rigal, “Analysis of surface roughness and cutting force components in hard turning with CBN tool: prediction model and cutting conditions optimization”, Measurement 45 (3), 344–353 (2012).
  • [2] I. Asilturk and H. Akkus, “Determining the effect of cutting parameters on surface roughness in hard turning using the Taguchi method”, Measurement 44 (9), 1697–1704 (2011).
  • [3] R. Suresh, S. Basavarajappa, and G.L. Samuel, “Some studies on hard turning of AISI 4340 steel using multilayer coated carbide tool”, Measurement 45 (7), 1872–1884 (2012).
  • [4] G. Bartarya and S.K. Choudhury, “State of the art in hard turning”, International Journal of Machine Tools & Manufacture 53 (1), 1–14 (2012).
  • [5] M. Rizal, J.A. Ghania, M.Z. Nuawia, and C.H.C. Harona, “Online tool wear prediction system in the turning process using an adaptive neuro-fuzzy inference system”, Applied Soft Computing 13 (4), 1960–1968 (2013).
  • [6] G.H. Lim, “Tool wear monitoring in machine turning”, Journal of Material processing technology 51 (1–4), 25–26 (1995).
  • [7] L. Dan and J. Mathew, “Tool wear and failure monitoring techniques for turning a review”, Int. J. Mach. Tools Manufact, 30 (4), 579–598 (1990).
  • [8] D.E. Dimla, “Sensor signals for tool-wear monitoring in metal cutting operations – a review of methods”, International Journal of Machine Tools & Manufacture 40 (4), 1073–1098 (2000).
  • [9] C. Scheffer, H. Kratz, P.S. Heyns, and F. Klock, “Development of a tool wear monitoring system for hard turning”, International Journal of Machine Tools & Manufacture 43 (10), 973–985 (2003).
  • [10] X. Wang, W. Wang, Y. Huang, N. Nguyen, and K. Krishnakumar, “Design of neural network-based estimator for tool wear modelling in hard turning”, J. Intell. Manuf. 19 (4), 383–396 (2008).
  • [11] M. Chmielewski and K. Pietrzak, “Metal-ceramic functionally graded materials – manufacturing, characterization, application”, Bull. Pol. Ac.: Tech. 64 (1), 151–160 (2016).
  • [12] D. Dinakaran, S. Sampathkumar, and N. Sivashanmugam, “An experimental investigation on monitoring of crater wear in turning using the ultrasonic technique”, International Journal of Machine Tools and Manufacture 49 (15), 1234–1237 (2009)
  • [13] B. Sick, “On-line and indirect tool wear monitoring in turning with artificial neural networks: a review of more than a decade of research”, Mechanical Systems and Signal Processing 16 (4), 487–546 (2002).
  • [14] A. Siddhpura and R. Paurobally, “A review of flank wear prediction methods for tool condition monitoring in a turning process”, Int. J. Adv. Manuf. Technol. 65 (1–4), 371–393 (2013).
  • [15] H. Chelladurai, V.K. Jain, and N.S. Vyas, “Development of a cutting tool condition monitoring system for high speed turning operation by vibration and strain analysis”, Int. J. Adv. Manuf. Technol. 37 (5–6), 471–485 (2008).
  • [16] D.E. Dimla, “The correlation of vibration signal features to cutting tool wear in a metal turning operation”, Int. J. Adv. Manuf. Technol. 19 (10), 705–713 (2002).
  • [17] O.B. Abouellatta and J. Madl, “Surface roughness prediction based on cutting parameters and tool vibrations in turning operation”, Journal of Material Processing Technology 11S8 (1–3), 269–277 (2001).
  • [18] D.E. Dimla and P.M. Lister, “On-line metal cutting tool condition monitoring.: I: Force and vibration analyses”, International Journal of Machine Tools and Manufacture, 40 (5), 739–768 (2000).
  • [19] V.S. Sharma, S.K. Sharma, A.K. Sharma, “Cutting tool wear estimation for turning”, J. Intell. Manuf. 19 (1), 99–108 (2008).
  • [20] S.H. Bhuiyan, I.A. Choudhury, and M. Dahari, “Monitoring the tool wear, surface roughness and chip formation occurrences using multiple sensors in turning”, Journal of Manufacturing Systems 33 (4), 476–487 (2014).
  • [21] T. Ozel and Y. Karpat, “Predictive modeling of surface roughness and tool wear in hard turning using regression and neural networks”, International Journal of Machine Tools and Manufacture 45 (4–5), 467–479 (2005).
  • [22] D.E. Dimla and P.M. Lister, “On-line metal cutting tool condition monitoring.: II: Tool-state classification using multi-layer perceptron neural networks”, International Journal of Machine Tools & Manufacture 40 (5), 769–78 (2000).
  • [23] F.J. Alonsoa and D.R. Salgado, “Analysis of the structure of vibration signals for tool wear detection”, Mechanical Systems and Signal Processing 22 (3), 735–748 (2008).
  • [24] D. Tanikić, V. Marinković, M. Manić, G. Devedžić, and S. Ranđelović, “Application of response surface methodology and fuzzy logic based system for determining metal cutting temperature”, Bull. Pol. Ac.: Tech. 64 (2), 435–445, (2016).
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-fef54c1c-e27f-4809-ac9a-07282e7548c8
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