Manufacturing Technology 2014, 14(2):245-252 | DOI: 10.21062/ujep/x.2014/a/1213-2489/MT/14/2/245

Method of immediately cutting process stoppage

Karol Vasilko, Zuzana Murčinková
Faculty of Manufacturing Technologies with seat in Prešov, Technical University in Košice, Bayerova 1, Prešov, Slovak Republic

The paper dealt with method of immediately cutting process stoppage, process of chip formation and the non-linear finite element analysis. To be able to follow the process of chip formation and machined surface during machining, it is necessary to stop this process immediately, if it is possible. The paper provides results of non-linear numerical experiment for presented method. The state of plastic deformation in machined material and in front of the tool cutting edge enables to follow the intensity of deformation, friction process between the tool, chip and workpiece, sources of heat in the machining zone. Knowing these processes enables to select optimal tool geometry, cutting conditions, mainly cutting speed, cutting environment, tool material so that cutting process could run with minimal energy consumption and required quality of machined surface could be reached. To understand the process of chip formation is important for the theory and practice of machining of materials.

Keywords: machining, cutting conditions, chip formation, plastic deformation

Published: June 1, 2014  Show citation

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Vasilko K, Murčinková Z. Method of immediately cutting process stoppage. Manufacturing Technology. 2014;14(2):245-252. doi: 10.21062/ujep/x.2014/a/1213-2489/MT/14/2/245.
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    References

    1. NAJAYAMA, K.: Studies on the Mechanism of Metal Cutting. Bulletin Fac. Engineering. Yokohama. Nat. Univ.,8, 1959, 1
    2. OKUSHIMA, K., HITOMI, K.: An Analysis of the Mechanism of Ortogonal Cutting and its Application to Discotinuous Chip Formation. Trans. ASME, J. Eng. Ind. 83 B, 1961, 524 Go to original source...
    3. KOEHLER, G., EGGERT, J.: Vorrichtung zur Schnittunterbrechung beim Drehen. Industrie Anzeiger, 92, 6, 1970, 103
    4. ELLIS, J., KIRK, K., BARROW, G.: The Development of a Quick-Stop Device for Metal Cutting Research. International Journal MTDR, 9, 1969, 321 Go to original source...
    5. BUDA, J., VASILKO, K., STRÁŇAVA, J.: Neue Methode der Spanwurzelgewinnung zur Untersuchung des Sneidvorganges. Industrie Anzeiger, 90, 5, 1968, 79
    6. FURRER, J. C., DINICHERT, P.: Influence du rayon du tranchart de l'outil en coupe-orthogonale. Annals of the CIRP, 22/1, 1973, 19
    7. FURER, J. C., DINICHERT, P.: Vorrichtung zur plötzlichen Schnittunterbrechung Fertigung 3/74
    8. STEFFENS, K., KÖNIG, W.: Cloced Loop Simulation of Grinding. Annals of the CIRP, Vol. 22/1983 Go to original source...
    9. BUDA, J., VASILKO, K.: Spôsob získania koreňa triesky za nastavených podmienok rezania, bez špeciálnych prípravkov. Patent SR, č. 122243.
    10. BETZ, F.: Die Mikrogestalt abgespanter Oberflächen. Technische Rundschau, Nr. 54, 26th Dezember 1969
    11. LAUER-SMALTZ, H., KÖNIG, W.: Phenomenon of Wheel Loading Mechanism in Grinding. Annals of the CIRP, Vol. 2911/1980 Go to original source...
    12. BOKUČAVA, G.: Tribologija processa šlifovanija. Sabčota sakartvelo of a Quick-Stop. Device for Metal Cutting Research. Int. J. MTDR, 9, 1969, 321, Tbilisi, 1984, 235 s. Go to original source...
    13. HASHIMURA, M., UEDA, K., DORNFELD, D, MANABE, K.: Analysis of Three-Dimensional Burr Formation in Oblique Cutting. Annals of the CIRP, Vol. 44/1/1995 Go to original source...
    14. NAKAYAMA, K., ARAI, M, 1987, Burr formation in metal cutting. CIRP Annals, 36, 1, pp. 33-36 Go to original source...
    15. PŘIKRYL, Z., MUSÍLKOVÁ, R.: Teorie obrábění. Praha, SNTL/ALFA, 1971, 198 s.
    16. VASILKO, K., MÁDL, J.: Teorie obrábění 1. díl. Ústí n. Labem: Univerzita J.E.Purkyně, 2012, 298 s.
    17. NOVÁK, M.: Surfaces with high precision of roughness after grinding. Manufacturing Technology, vol. 12, No. 12, 2012, ISSN 1213-2489 Go to original source...
    18. DVOŘÁK, Z., LUKOVICS, I.,JAVOŘÍK,J.,BRIŠ, P.: Uložení strojů pracujících v dynamických podmínkach. Strojírenská technologie, IX, č. 4, 2009, s. 20-26
    19. MÁDL, J.: Design for Machining. Strojírenská technologie, 1X, 2009, s. 81-86 Go to original source...
    20. HOLÝ, Z.: Obráběcí a tvářecí stroje v České republice. Strojírenská technologie XII,březen 07, s. 3-7
    21. MURČINKOVÁ, Z., KOMPIŠ, V., ŠTIAVNICKÝ M.: Trefftz functions for 3D stress concentration problems. Computer Assisted Mechanics and Engineering Sciences. Vol. 15, no. 3-4 (2008), p. 305-318.
    22. MURČINKOVÁ, Z.: The computational models for simulation of cavity microstructure. Scientific Bulletin. Vol. 22, serie C (2008), p. 305-310.
    23. MURČINKOVÁ, Z., KOMPIŠ, V.: Advanced modelling of short-fibre reinforced composites. Strojnícky časopis. Roč. 59, č. 1 (2008), s. 27-40.
    24. VASILKO, K., MURČINKOVÁ, Z.: Analysis of geometric accuracy of turned workpieces. Manufacturing Technology. Vol. 13, no. 2 (2013), p. 247-252. Go to original source...

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