THE APPLYING OF HIGH-PERFORMANCE MACHINING METHOD FOR CUTTING OF STRUCTURAL STEELS


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Abstract

The implementation of high-speed machining (HSM) allows minimizing the processing time, raising the specific volume cutting efficiency, and achieving the range of advantages having a positive effect on the economic efficiency of this method. However, to implement this technology in practice, it is necessary to follow the set of measures and requirements to the manufacturing system. In particular, the wide use of HSM negates the necessity of having the expensive equipment – specialized CNC machines (computerized numerical control machines).

The research of HSM in practice resulted in the modifications of this type of processing – high-performance machining (HPM). The distinctive features of HPM are the reduced (as compared with HSM) spindle rotational speed (cutting speed) and the increased volumes of removed material (the depth and width of cutting). The goal of the research is the study of feasibility to apply HPM for cutting of structural steel using undedicated CNC machines widely used for traditional milling. When preparing and carrying out the research, the author took into account the mechanical properties of process material; MDTP (machine-device-tool-part) system stiffness; machine technical data; material, coating, and geometry of a cutting tool. The temperature in the cutting area and the work material and cutting tool temperature were recorded as well. The study determined the following mandatory parameters of the process: smooth, tangentially costate trajectories of a tool; angle of cutter spiral; cutter engagement angle. The calculation of cutting time and cutting specific volume showed the advantage of HPM as compared to the traditional CNC milling. The process parameters having a positive impact on tool wear are determined and the parameters constraining the process of HPM implementation are considered.

About the authors

Marina Valerievna Vilkina

Baltic State Technical University “VOENMEH” named after D.F. Ustinov, Saint-Petersburg

Author for correspondence.
Email: m.vilkina@mail.ru

postgraduate student, engineer of Chair “Process and manufacturing engineering of artillery equipment”

Russian Federation

References

  1. Grudov P.P. Speed Cutting. Skorostnye metody obrabotki metallov: doklady i tezisy dokladov na Moskovskoy konferentsii po skorostnym metodam obrabotki metallov. Moscow, Mashgiz Publ., 1949, pp. 239–269.
  2. Shchegolev A.V. The current status of speed milling, col. LONITOMASh. Moscow, Mashgiz Publ., 1948, pp. 52–64.
  3. Forssell P. Tool and method advances for efficient manufacturing, C-2940:139 US/01 AB. New York, Sandvik Coromant Publ., 2012. 23 p.
  4. Stepanov A. High Speed milling at present-day production. CAD/CAM/CAE Observer, 2003, no. 4, pp. 1–8.
  5. Davim J.P., ed. Machining and Machine-tools. New York, Woodhead Publ., 2013. 280 р.
  6. Exposure of High Speed Machining peak capacity. Technology overview. Siemens Product Lifecycle Management Software Inc., 2010, pp. 1–11.
  7. Vittington K., Vlasov V. High Speed Machining. SAPR i grafika, 2002, no. 11, pp. 10–17.
  8. High speed machining (HSM) – the effective way of modern cutting. International Workshop CA Systems And Technologies Forum. San Francisco, Moscone Center Publ., 2012, pp. 72–79.
  9. Zvontsov I.F., Ivanov K.M., Serebrenitskiy P.P. Podgotovka upravlyayushchikh programm dlya oborudovaniya s ChPU [Preparation of code for CNC machines]. Sankt Petersburg, BGTU Publ., 2016. 251 p.
  10. Canter N. The tribological challenges of high-speed machining. Tribology & Lubrication Technology Magazine, 2007, vol. 3, pp. 29–36.
  11. Danielson S., Georgeou T., Teo A. High Performance Machining: A Practical Approach to High Speed Machining. American Society for Engineering Education, 2008, vol. 6, pp. 1–11.
  12. Dashchenko A. Manufacturing Technologies for Machines of the Future. Berlin, Springer-Verlag Publ., 2003. 280 p.
  13. Blau P. Flushing Strategies for High Performance, Efficient and Environmentally Friendly Cutting. 12th Global Conference on Sustainable Manufacturing. USA, Elsevier Publ., 2015, pp. 361–366.
  14. HPC for improved efficiency on standard machine tools by using new fluid-driven spindles. Proceedings of the 11th Global Conference on Sustainable Manufacturing – Innovative Solutions. Berlin, Universitätsverlag der TU Publ., 2013, pp. 241–246.
  15. Zharoprochnye splavy: rukovodstvo po primeneniyu Sandvik Coromant, AB Sandvikens Tryckeri [Heat resistant super alloys: Application guide Sandvik Coromant, AB Sandvikens Tryckeri]. Moscow, Sandvik Publ., 2010. 132 p.
  16. GARANT ToolScout: spravochnik po rezaniyu [GARANT ToolScout: Metalworking guide]. Sankt Petersburg, Khoffman Publ., 2015. 653 p.
  17. High Performance Cutting (HPC) in the New Era of Digital Manufacturing. Procedia CIRP, 2016, vol. 46, pp. 1–6.
  18. Basic Catalog 2015/2016. Hoffmann Group. URL: hoffmann-group.com/RU/ru/horu/service/downloads/blaetterkatalog.
  19. Tools catalog SGS T-CARB. Intertulmash: promyshlennoe oborudovanie. URL: itmash.ru/ftpgetfile.php?id=293&module=files2014.
  20. Resource and Energy Efficiency in Machining Using High Performance and Hybrid Processes. Procedia CIRP: 5th CIRP Conference on High Performance Cutting, 2012, vol. 1, pp. 3–15.

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