Development of high performance machine tools

• Autorzy: Jędrzejewski J. , Kwaśny W.
• Języki publikacji: EN

Abstrakty

EN

This paper presents a general characteristic of modern cutting machine tools and their role in achieving high machining performance. The determinants of machine tool development, stemming from the constant development of products and their complexity and from market demands, are discussed in detail. Special attention is devoted to the improvement of the machine tool structure and its variations created in response to the continuous and flexible increase in machining efficiency. The importance of developing multitask, hybrid and reconfigurable structures is discussed. The essence of the development of multi-spindle units as the modules having a decisive influence on machining performance, precision and costs is described. Moreover, trends in the development of feed units and distance measuring systems are presented.

Słowa kluczowe

EN

machine tool; development; precision; performance; intelligence

• Wydawca: Wydawnictwo Wrocławskiej Rady FSNT NOT
• Czasopismo: Journal of Machine Engineering
• Rocznik: 2009
• Tom: Vol. 9, No. 2
• Strony: 5--31
• Opis fizyczny: Bibliogr. 26 poz., tab., rys.

Twórcy

autor

Jędrzejewski J.

• Institute of Production Engineering and Automation, Wroclaw University of Technology, Wroclaw, Poland

autor

Kwaśny W.

• Institute of Production Engineering and Automation, Wroclaw University of Technology, Wroclaw, Poland

Bibliografia

• 1. MARCOS M., AGUAYO F., CORRILERO M. S., SEVILLA L., ARES J. E., LAMA J. R., 2005, Towards the Next Generation of Manufacturing Systems FRABIHO: A synthesis Model for Distributed Manufacturing, Intelligent Production Machines and Systems D.T. Pham, E.E. Eldukhri and A.J. Soroka (eds) ELSEVIER, 35-40.
• 2. JĘDRZEJEWSKI J., 2008, Wysokowydajne obrabiarki wyzwaniem rosnącej konkurencyjności - rozwój konstrukcji i potrzeby przemysłu, STAL, 6, 42-47.
• 3. www.ntn.co.ip. 2005, NTN Corporation Products and Technology, New Products and Technology Info.
• 4. HON K., K., B., 2005, Performance and Development of Manufacturing System, Annals of the CIRP, 54/2, 139-154.
• 5. FLEISCHER I., SCHOPP M., BROOS A., WIESER I, 2007, Datenbasis fuer Lastabhangige Processengriffe - Modularisierung and Analyse von Anfalursahen zur erhohung der Vertigbarkeit von Werkzeugmaschinen, WT Werkstattstechnik online, Jahrgang 97/H7/8, 491-497.
• 6. BYRNE G., DORNFELD D., DENKENA B., 2003, Advancing Cutting Technology. Annals of the CIRP, 52/2, 483-507.
• 7. Anon 2000, 2000, Next generation manufacturing systems interim report, CAM.
• 8. WESTKAEMPER E., ALTING L., ARNDT G., 2000, Life Cycle Management and Assessment: Approaches and Visions Toward Sustainable Manufacturing, Annals of the CIRP, 49/2, 501-526.
• 9. NEUGEBAUER R., DENKENA B., WEGENER K., 2007, Mechatronic System for Machine Tools, Annals of the CIRP, 56/2, 657-686.
• 10. NOKAMINAMI M., TOKUMA T., MORIWAKI T., NAKAMOTO K., 2007, Optimal structure design methodology for compound multiaxis machine tools. Part I and II. International Journal of Automation Technology, 1/2.
• 11. MORIWAKI T., 2008, Multifunctional Machine Tool, CIRP Annals - Manufacturing Technology, 57, 736-749.
• 12. LORENZER TH., WEIKERT S., BOSSONI S., WEGENER K., 2007, Modeling and evaluation tool for supporting decisions on the design of reconfigurable machine tools, Journal of Manufacturing Systems, 26, 167-177.
• 13. JĘDRZEJEWSKI J., KWAŚNY W., POTRYKUS J., 1989, Beurteilung der Berechnungs Metoden fur die Besitimmung die Energiverluste in Walzlagem, Shmierungstechnik, 20, VDI Berlin, 243-244.
• 14. Introduction to Precision Machine Design, 2009, ADC Press Taylor and Francis Group, Jedrzejewski J., Chapter 3, Thermal Problems in Machine Tools Design and Operation, 75-128.
• 15. SOSHl M., YAMAZAKI K., MORI M., 2009, A study on the development of the multi - purpose spindle for quality productive machining, CIRP Winter Annual Meeting, Paris.
• 16. JĘDRZEJEWSKI J., GRZESIK W., KWAŚNY W., MODRZYCKI W., 2008, Process Machine Tool Thermal Interactions, Journal of Machine Engineering, 8/3, 91-106.
• 17. JĘDRZEJEWSKI J., KWAŚNY W., KOWAL Z., MODRZYCKI W., 2008, Operational behaviour of high speed spindle unit, MM Science Journal, October 2008, 39-43.
• 18. TANIGUCHI K., KUSUMI M., 2009, Development of 10 nanometer resolution of magnetic linear scale for precision CMC machine tool application, CIRP Winter Annual Meeting, Paris, January 2009.
• 19. AKAMATSU Y., MORI M., 2004, Development of Eco-friendly Oil Jet Lubricated Angular Contact Ball Bearings for Machine Tool, NTN Technical Review, 72.
• 20. KOWAL Z., 2009, Znaczenie i doskonalenie własności cieplnych obrabiarek. Inżynieria Maszyn, 13/3-4, 54-71.
• 21. MODRZYCKI W., 2009, Identyfikacja i kompensacja błędów obrabiarek. Inżynieria Maszyn, 13/3-4, 91-100.
• 22. YAMADA M., KONDO T., TANAKA F., KOSHINOMI T., 2007, Tilted tool axis machining on 5-axis machine tools, Int. Journal of Automation Technology, 1/2, 120-127.
• 23. MORIWAKIT., 2006, Trends in recent machine tool technologies, NTN Technical Review, 74, 2-7.
• 24. ALTINTAS Y., WECK M., 2004, Chatter stability of metal cutting and grinding. Annals of the CIRP, 53/2, 619.
• 25. Precision rolling bearings. Lubrication of bearings, NTN, 39-47.
• 26. KAKINO Y., 2004, Latest Trend of Main Spindle for NC Machine Tool, NTN Technical Review, 72, 2-5.