[1] CORBETT J,MCKEOWN P A,PEGGS G N,et al. Nanotechnology:International developments and emerging products[J]. Annals of the CIRP,2000,49(2):523-545.
[2] ABELE E,ALTINTAS Y,BRECHER C. Machine tool spindle units[J]. Annals of the CIRP,2010,59(2):781-802.
[3] 熊万里,雪冰,吕浪,等. 液体动静压电主轴关键技术综述[J]. 机械工程学报,2009,45(9):1-18. XIONG Wanli,YANG Xuebing,LÜ Lang,et al. Review on key technology of hydrodynamic and hydrostatic and hydrostatic high-frequency motor spindles[J]. Journal of Mechanical Engineering,2009,45(9):1-18.
[4] 袁巨龙,张飞虎,戴一帆,等. 超精密加工领域科学技术发展研究[J]. 机械工程学报,2010,46(15):161-177. YUAN Julong,ZHANG Feihu,DAI Yifan,et al. Development research of science and technologies in ultra-precision machining field[J]. Journal of Mechanical Engineering,2010,46(15):161-177.
[5] CAO Hongrui,ZHANG Xingwu,CHEN Xuefeng. The concept and progress of intelligent spindles:A review[J]. International Journal of Machine Tools and Manufacture, 2017(112):21-52.
[6] 熊万里,胡灿,吕浪,等. 可控节流参数对液体静压轴承特性的影响研究[J]. 机械工程学报,2018,54(21):63-71. XIONG Wanli,HU Can,LÜ Lang,et al. Research on the influence of controllable restrictor parameters on the characteristics of hydrostatic journal bearings[J]. Journal of Mechanical Engineering,2018,54(21):63-71.
[7] BENTLY D E,GRANT J W,HANIFAN P C,et al. Active controlled hydrostatic bearings for a new generation of machines[R]. ASME Paper No.2000-GT-354.
[8] SALAZAR J G,SANTOS I F. On the controllability and observability of actively lubricated journal bearings with pads featuring different nozzle-pivot configurations[J]. ASME Journal of Tribology,2017,139(3):1-17.
[9] CAI Z,QUEIROZ M S,KHONSARI M M. On the active stabilization of tilting-pad journal bearings[J]. Journal of Sound and Vibration,2004,273(1):421-428.
[10] YANG Xiaogao,WANG Yongqin,JIANG Guiyun,et al. Dynamic characteristics of hydrostatic active journal bearing of four oil recesses[J]. Tribology Transactions,2014,58(1):7-17.
[11] KYTHK P,EHMANN C,NORDMANN R. Active vibration μ-synthesis-control of a hydrostatically supported flexible beam[J]. Journal of Mechanical Science and Technology,2007(21):924-929.
[12] PARK C H,OH Y J,SHAMOTO E,et al. Compensation for five DOF motion errors of hydrostatic feed table by utilizing actively controlled capillaries[J]. Precision Engineer,2006,30(3):299-305.
[13] LIU Zichao,PAN Wei,LU Changhou,et al. Numerical analysis on the static performance of a new piezoelectric membrane restrictor[J]. Industrial Lubrication and Tribology,2016,68(5):521-529.
[14] ROWE W B. Advances in hydrostatic and hybrid bearing technology[J]. Journal of Mechanical Engineering Science,1989,203(43):225-242.
[15] LI Hongqi,SHIN Y C. Analysis of bearing configuration effects on high speed spindles using an integrated dynamic thermos-mechanical spindle model[J]. International Journal of Machine Tools and Manufacture,2004,44(4):347-364.
[16] MERUANE V,PASCUAL R. Identification of nonlinear dynamic coefficients in plain journal bearings[J]. Tribology International,2008,41(8):743-754.
[17] 熊万里,侯志泉,吕浪,等. 液体静压主轴回转误差的形成机理研究[J]. 机械工程学报,2014,50(7):112-119. XIONG Wanli,HOU Zhiquan,LÜ Lang,et al. Study on the mechanism of hydrostatic spindle rotational error motion[J]. Journal of Mechanical Engineer,2014,50(7):112-119.
[18] JANG G H,YOON J W. Nonlinear dynamic analysis of a hydrodynamic journal bearing considering the effect of a rotating or stationary herringbone groove[J]. Journal of Tribology,2002,124(2):297-304.
[19] PHALLE V M,SHARMA S C,JAIN S C. Influence of wear on the performance of a 2-lobe multirecess hybrid journal bearing system compensated with membrane restrictor[J]. Tribology International,2011,44(4):380-395.
[20] 张直明. 滑动轴承的流体动力润滑理论[M]. 北京:高等教育出版社,1986. ZHANG Zhiming. Hydrodynamic lubrication theory of sliding bearings[M]. Beijing:Higher Education Press,1986. |