Accuracy of Spindle Units with Hydrostatic Bearings

1. Fedorynenko D., Boyko S., Sapon S. (2015), The search of the spatial functions of pressure in adjustable hydrostatic radial bearing, Acta Mechanica et Automatica, 9(1), 23-26.10.1515/ama-2015-0005Search in Google Scholar

2. Fedorynenko D., Sapon S., Boyko S.(2014), Considering of the thermal strains in determining the function of the radial clearance in hydrostatic bearing in high-speed spindle node, Technological systems, 2(10), 154-159.Search in Google Scholar

3. Fedorynenko D., Sapon S., Boyko S., Kosmach A. (2015), Information-measuring complex for research of spindle trajectories on hydrostatic bearings, Scientific Bulletin of National Mining University: scientific journal, 6(150), 42-48.Search in Google Scholar

4. Junpeng S., Guihua H., Yanqin Z., Yuhong D. (2008), Hardware-inthe-loop Simulation on Controllable Hydrostatic Thrust Bearing, IEEE International Conference on Automation and Logistics (ICAL 2008), 1095-1099.10.1109/ICAL.2008.4636314Search in Google Scholar

5. Junpeng S., Yanqin Z., PengchengL. (2007), Static flow simulation of hydrostatic bearing ellipse and sector curve based on fluent, Lubrication Engineering, 1, 93−95.Search in Google Scholar

6. Perovic B. (2012), Hydrostatic guides and bearings: basic principles, calculation and design of hydraulic plans (in German), Springer-Verlag Berlin Heidelberg.Search in Google Scholar

7. Rubinstein R.Y. (2007), Simulation and the Monte Carlo Method, Kroese – 2nd edition, Wiley.10.1002/9780470230381Search in Google Scholar

8. Sapon S.P.(2013), Methodology of experimental determination precisionspindle, Bulletin of Chernihiv State Technological University, A series of technical sciences, 1(63), 66-74.Search in Google Scholar

9. Savin L.A. (2006), Simulation of rotor systems with fluid friction bearings, Moscow: Engineering.Search in Google Scholar

10. Shen C.G., Wang G.C., Wang S.L. (2010), Computation and Analysis of Unbalancing Responses of High Speed Machining Tool System, Advanced Materials Research, 148-149(1), 40-46.10.4028/www.scientific.net/AMR.148-149.40Search in Google Scholar

11. Solomin O.V.(2007), Development of methods and tools of dynamic analysis of rotor systems with fluid friction bearings, phd thesis, Orel State University.Search in Google Scholar

12. Strutynsky V., Fedorynenko D. (2011), Statistical dynamics of spindle units for hydrostatic bearings, Nizhin: LLC “Publishing” Aspect-Polygraph.Search in Google Scholar

13. Wardle F. (2015), Ultra Precision Bearings, Cambridge: Elsevier.Search in Google Scholar

14. Xiaodong Y., Huaimin L. (2006), Computerized Simulation of Lubricating Characteristics of Circular Tilting Pad Thrust Bearing, Lubrication Engineering, 3, 84-87.Search in Google Scholar

15. Xiaodong Y., Huaimin L., Xiurong G. (2007), Numerical Analysis of Lubricating Characteristics of Sector Thrust Bearing Pad, Lubrication Engineering, 1, 123-125.Search in Google Scholar

16. Yu X.D., Zhang Y.Q. (2008), Numerical Simulation of Gap Flow of Sector Recess Multi-pad Hydrostatic Thrust Bearing, Proc. 2008 Asia Simulation Conference-7th Int. Conf. Simulation and Scientific Computing (ICSC 08), 675–679.Search in Google Scholar

17. Yuan S., Lin J., Liu Q. (2008), Finite Element Analysis of Machine Tool as a Whole, Machine Tool & Hydraulics,36(4):17-18,49.Search in Google Scholar

18. Zhao H., Yang J., Shen J.(2007), Simulation of thermal behaviour of a CNC machine tool spindle, International Journal of Machine Tool & Manufacture, 47(6), 1003-1010.10.1016/j.ijmachtools.2006.06.018Search in Google Scholar