[1] 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.
[2] ROWE W B. Advances in hydrostatic and hybrid bearing technology[J]. Journal of Mechanical Engineering Science,1989,203(43):225-242.
[3] 丁振乾. 流体静压支撑设计[M]. 上海:上海科学技术文献出版社,1989. DING Zhenqian. Fluid hydrostatic support design[M]. Shanghai:Science and Technology Documents Press of Shanghai,1989.
[4] 熊万里,阳雪冰,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 high-frequency motor spindles[J]. Journal of Mechanical Engineering,2009,45(9):1-18.
[5] 熊万里,侯志泉,吕浪. 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. Study on the mechanism of hydrostatic spindle rotational error motion[J]. Journal of Mechanical Engineering,2014,50(7):112-119.
[6] 侯志泉,熊万里,吕浪,等. 轴颈形状误差对液体静压主轴回转精度的影响[J]. 机械工程学报,2016,52(15):147-154. HOU Zhiquan,XIONG Wanli,LÜ Lang. Study on the influence of the journal shape error for hydrostatic spindle rotational error motion[J]. Journal of Mechanical Engineering,2016,52(15):147-154.
[7] CHEN C H,KANG Y,CHANG Y P,et al. Influence of restrictor on the stability of the rigid rotor-hybrid bearing system[J]. Journal of Sound and Vibration,2006,297:635-648.
[8] SINGH N,SHARMA S C,JAIN S C,et al. Performance of membrane compensated multirecess hydrostatic/hybrid flexible journal bearing system considering various recess shapes[J]. Tribology International,2004,37:11-24.
[9] PHALLE V M,SHARMA S C,JAIN S C. Performance analysis of a 2-lobe worn multi-recess hybrid journal bearing system using different flow control devices[J]. Tribology International,2012,52(3):101-116.
[10] 朱有红,刘建亭,杨建玺,等. 液体静压轴承薄膜节流新结构的设计分析[J]. 轴承,2008(3):27-30. ZHU Youhong,LIU Jianting,YANG Jianxi,et al. Design analysis on new thin film restrictor of liquid hydrostatic bearing[J]. Bearing,2008(3):27-30.
[11] KANG Y,SHEN P C,CHANG Y P,et al. Modified predictions of restriction coefficient and flow resistance for membrane-type restrictors in hydrostatic bearing by using regression[J]. Tribology International,2007,40:1369-1380.
[12] GAO D R. Theoretical analysis and numerical simulation of the static and dynamic characteristics of hydrostatic guides based on progressive mengen flow controller[J]. Chinese Journal of Mechanical Engineering,2010,23(6):709-716.
[13] KANG Y,CHEN C,LEE H,et al. Design for static stiffness of hydrostatic bearings single-action variable compensations[J]. Industrial Lubrication and Tribology,2011,63(2):103-118.
[14] KANE N R,SIHLER J,SLOCUM A H. A hydrostatic rotary bearing with angled surface self-compensation[J]. Precision Engineering,2003,27(2):125-139.
[15] ZUO X B,WANG J M,YIN Z Q,et al. Self-compensated precision hydrostatic rotary bearing[J]. Advanced Materials Research,2013,662:674-677.
[16] 王勇勤,周巡,刘志芳. 基于伺服控制节流的静压推力轴承性能分析与研究[J]. 四川大学学报,2012,44(2):201-205. WANG Yongqin,ZHOU Xun,LIU Zhifang. Study on dynamic characteristics of hydrostatic thrust bearing with servo control[J]. Journal of Sichuan University,2012,44(2):201-205.
[17] HAUGAARD A M,SANTOS I F. Multi-orifice active tilting-pad journal bearings-harnessing of synergetic coupling effects[J]. Tribology International,2010,43(8):1374-1391.
[18] 熊万里. 可控节流器:中国,102562828A[P]. 2012-07-11. XIONG Wanli. Controllable restrictor:China,102562828A[P]. 2012-07-11. |