Influence of machining conditions on friction in metal cutting process – A review

Grzesik, Wit; Rech, Joel

doi:doi.org/10.17814/mechanik.2019.4.33

Artykuł - szczegóły

Tytuł artykułu

Influence of machining conditions on friction in metal cutting process – A review

Autorzy

Grzesik Wit , Rech Joel

Wybrane pełne teksty z tego czasopisma

http://www.mechanik.media.pl/

Identyfikatory

DOI

doi.org/10.17814/mechanik.2019.4.33

Warianty tytułu

Wpływ warunków obróbki na tarcie w procesie skrawania metali – przegląd literatury

Języki publikacji

Abstrakty

This paper presents a range of variable machining factors which influence substantially friction directly or by the tool wear developed in the cutting zone. The group of direct factors include the workpiece and cutting tool materials coupled, the cutting/sliding velocity, cooling media supplied to the tool-chip contact zone, modification of the tool contact faces by micro-texturing. Special attention was paid to the tool wear evolution and its pronounced effect on changes of the contact conditions.

Przedstawiono wiele zmiennych czynników procesowych, które istotnie wpływają – bezpośrednio lub pośrednio przez zużycie ostrza – na tarcie występujące w strefie skrawania. Grupa czynników bezpośrednich obejmuje: materiał obrabianego przedmiotu i narzędzia skrawającego, prędkość skrawania/poślizgu, media chłodzące dostarczane do strefy kontaktu oraz modyfikację powierzchni kontaktowych ostrza narzędzia przez mikroteksturyzowanie. Specjalną uwagę zwrócono na ewolucję zużycia narzędzia i jej dominujące oddziaływanie na zmiany warunków kontaktowych.

Słowa kluczowe

metal cutting friction contact conditions wear

skrawanie metali tarcie warunki kontaktowe zużycie

Wydawca

Stowarzyszenie Inżynierów i Techników Mechaników Polskich

Czasopismo

Mechanik

Rocznik

2019

Tom

R. 92, nr 4

Strony

242--248

Opis fizyczny

Bibliogr. 27 poz., rys., tabl.

Twórcy

autor

Grzesik Wit

w.grzesik@po.opole.pl

Technical University of Opole, Poland

autor

Rech Joel

joel.rech@enise.fr

University of Lyon – ENISE, France

Bibliografia

[1] Grzesik W., Rech J. “Methods and devices for measuring metal cutting friction and wear”. Mechanik. 2 (2019): 85–89.
[2] Grzesik W., Nieslony P. ”Prediction of friction and heat flux in machining incorporating thermophysical properties of the coating-chip interface”. Wear. 256 (2004): 108–117.
[3] Ruiz de Eguilaz E., Rech J., Arrazola P. “Characterization of friction coefficient and heat partition coefficient between an AISI4140 steel and a TiN coated carbide – influence of (Ca, Mn, S) steel’s inclusions”. Proc. IMechE – part J: J. Engineering Tribology. 224 (2010): 1115–1127.
[4] Arrieta I., Courbon C., Cabanettes F., Arrazola P.J., Rech J. “Preliminary study on the tribological behaviour of ferritic-pearlitic steels”. Proceedings of the conference MUGV. 7–8 June 2018. Bordeaux (France).
[5] Rech J., Arrazola P.J., Claudin C., Courbon C., Pusavec F., Kopac J. “Characterization of friction and heat partition coefficients at the tool-work material interface in cutting”. CIRP Annals – Manufacturing Technology. 62, 1 (2013): 79–82.
[6] Claudin C., Mondelin A., Rech J., Fromentin G. “Effects of a straight oil on friction at the tool-work material interface in machining”. Int. Journal of Machine Tools and Manufacture. 50 (2010): 681–688.
[7] Cabanettes F., Rolland J., Dumont F., Rech J., Dimkovski Z. “Influence of Minimum Quantity Lubrication on friction characterizing tool-aluminum alloy contact”. Journal of Tribology. 138 (2016): doi:10.1115/1.4031990.
[8] Pottirayil A., Kailas S.V., Biswas S.K. “Experimental estimation of friction force in lubricated cutting of steels”. Wear. 269 (2010): 557–564.
[9] Banerjee C., Sharma A. “Identification of friction model for minimum quantity machining”. J. Clean Production. 83 (2014): 437–443.
[10] Courbon C., Pusavec F., Dumont F., Rech J., Kopac J. “Tribological behaviour of Ti6AL4V and Inconel 718 under dry and cryogenic conditions – Application to the context of machining with carbide tools”. Tribology International. 66 (2013): 72–82.
[11] Cristino V.A., Rosa P.A., Martins P.A. “Cutting under active and inert gas shields: A contribution to the mechanics of chip flow”. Int. J Machine Tools and Manufacture. 50 (2010): 892–900.
[12] Settineri L., Faga M.G., Lerga B. “Properties and performances of innovative coated tools for turning Inconel”. Int. Journal of Machine Tools and Manufacture. 48 (2008): 815–823.
[13] Klocke F., Settineri L., Lung D., Priarone P.C., Arft M. “High performance cutting of gamma titanium aluminides: influence of lubricoolant strategy on tool wear and surface integrity”. Wear. 302 (2013): 1136–1144.
[14] Grzesik W. “Advanced machining processes of metallic materials”. Elsevier (2017).
[15] Sutter G., Molinari A. “Analysis of the cutting force components and friction in high speed machining”. Trans. ASME J. Manuf. Science Technol. 127 (2005): 245–250.
[16] Rech J., Claudin C., Grzesik W., Zalisz Z. “Characterization of the friction properties of various coatings at the tool-chip-workpiece interfaces in dry machining of AISI 4140 steel”. Proc. IMechE – part J: J. Engineering Tribology. 222 (2008): 617–627.
[17] Zemzemi F., Rech J., Ben Salem W., Dogui A., Kapsa P. “Identification of friction and heat partition model at the tool-chip-workpiece interfaces in dry cutting of an Inconel718 alloy with CBN and coated carbide tools”. Advances in Manufacturing Science and Technology. 38 (2014): 5–21.
[18] Faverjon P., Rech J., Leroy R. “Influence of MQL on friction coefficient and workmaterial adhesion during machining of cast aluminium with various cutting tool substrates made od PCD, HSS and carbides”. Journal of Tribology. 153 (2013): 041602-1.
[19] Grzesik W. “Friction behaviour of heat isolating coatings in machining: mechanical, thermal and energy-based considerations”. Int. Journal of Machine Tools and Manufacture. 43 (2003): 145–150.
[20] Grzesik W., van Luttervelt C.A. “An investigation of the thermal effects in orthogonal cutting associated with multilayer coatings”. CIRP Annals – Manufacturing Technology. 50, 1 (2001): 53–56.
[21] Settineri L., Faga M.G., Gautier G., Perucca M. “Evaluation of wear resistance of AlSiTiN and AlSiCrN nanocomposite coatings for cutting tools”. Annals of the CIRP – Manuf. Technology. 57, 1 (2008): 575–578.
[22] Settineri L., Faga M.G. “Laboratory tests for performance evaluation of nanocomposite coatings for cutting tools”. Wear. 260 (2006): 326–332.
[23] Enomoto T., Sugihara T. “Improving anti-adhesive properties of cutting tool surfaces by nano-/micro-textures”. CIRP Annals – Manuf. Technology. 59/1 (2010): 597–600.
[24] Grzesik W. “Advanced protective coatings for manufacturing and engineering”. Hanser Gardner, Cincinnati (2003).
[25] Holmberg K., Matthews A. “Coating tribology. Properties, techniques and applications in surface engineering”. Elsevier, Amsterdam (1994).
[26] Grzesik W., Zak K. “Friction quantification in the oblique cutting with CBN chamfered tools”. Wear. 304 (2013): 36–42.
[27] Grzesik W., Denkena B., Zak K., Grove T., Bergman B. “Energy consumption characterization in precision hard machining using CBN cutting tool”. Int. Journal of Advanced Manufacturing Technology. 85 (2016): 2839–2845.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-6f8cf50c-080e-4ec8-8173-b5da24ac48e0