Manufacturing Technology 2018, 18(2):321-324 | DOI: 10.21062/ujep/99.2018/a/1213-2489/MT/18/2/321

Machinability as a Phenomenon and the Operational Methods of Its Determination

Karol Vasilko, Zuzana Murčinková
Faculty of Manufacturing Technology. Technical University of Košice, Baerova 1, 080 01 Prešov, SR

Reliable method to detect relative machinability is based on constructing Taylor relation of tool durability on cutting speed for both observed materials. Optimal cutting speed for the observed material at constant durability can be detected from the relation. However, longterm test requires longer time of machining and consumption of material. Therefore a number of authors have observed the possibility of shortening the tests. There is a widespread opinion that shortened methods posses low reliability. On the other hand, those methods cannot be replaced in the conditions of actual operation. Some of them are analysed and modified as follows.

Keywords: workpiece, cutting tool, machinability, cutting speed

Published: April 1, 2018  Show citation

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Vasilko K, Murčinková Z. Machinability as a Phenomenon and the Operational Methods of Its Determination. Manufacturing Technology. 2018;18(2):321-324. doi: 10.21062/ujep/99.2018/a/1213-2489/MT/18/2/321.
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    References

    1. QUEHAJA, N, E. et al. (2012). Machinability of Metals, Methods and practical Application. Annals of DAAAM for 2012 & Proceeding of the rd International DAAAM Symposium, Volume 23, No. 1, ISSN 2304-1382 Go to original source...
    2. ANDONOV, I. (2011). Obrabotavaernost, Workabiliy, Avangard Prima, Sofia.
    3. ZOREV, N, N et al.: Razvitije nauki o rezanii metallov. Moskva, Mašinostrojenije, 167 s.
    4. FELDSTEIN, E.I. (1953). Obrabatyvajemost stali. Moskva, Mašgiz.
    5. FULMER, J. J., BLANTON, J. M. (1992) The effect of microstructure on the machinability of MPIF, FC-0208 cooper steel Advances. Powder Metallurgy &Particulate Materials, Vol 4, pp.283-296.
    6. DEGARMO, E. P., BLACK, J. T., KOHSER, R. A. (2002). Materials and processes in Manufacturing. Wiley, ISBN 0-471-65653-4.
    7. WOLDMAN, N, E, GIBHONS, R. C. (1951). Machinability and Machining of Metals. New York, McGraw-Hill, 1951-5, 518 p.
    8. MÁDL, J., KOUTNÝ, V. (2007). Machinability of Lead Free Copper Aloys. Manufacturing Technology, Vol 15, No. 5, ISSN 1213-2489. Go to original source...
    9. SEDLÁK, J. et al. (2015). High-Speed Cutting of Bearing Rings from Material 100Cr6. Manufacturing Technology, Vol. 15, No. 5, pp. 899-908. Go to original source...
    10. BOOTHROYD, G, W, KNIGHT, A, (2006). Fundametals of Machining and Machine Tools. Third Edition, CRC Press, 573 p.
    11. WINSTON, A, KNIGHT, G. (2005). Fundamental of Metal Machining and Machine Tools. Technology & Engineering, Boothroyd.
    12. KOCMAN, K. (2011). Application of magnetic correlation analysis on the choice and correction of cutting parameters for automated manufacturing systems. Manufacturing Technology, Vol 11, pp. 28-32. Go to original source...
    13. ŠALAK, A., SELECKÁ, M., DANNINGER, H. (2005). Machinability of powder metallurgy steels. Cambridge International Sience Publishing, pp. 836, ISBN 1-898326-82-7.

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