Hydrodynamic-static hybrid journal bearing with orifice restrictor is a kind of bearing that the throttling effect is realized by orifice restrictor and the second throttling effect is realized by shallow recess. There is a shortage of the existing theory that can not study the load characteristics which are affected by the recess structure parameters and operation parameters in analytical method. It is inconvenient for engineers to use the computational fluid dynamics software, due to the disadvantage of long period of calculation. On the assumption of subsection linearization of pocket pressure, a method is proposed to analyze the deep-shallow bearing characteristics, such as load capacity, bearing stiffness, flow rate and temperature ascending relationship. The analytical method is used to study bearing characteristics with the different structure parameters and working parameters, such as supply pressure, spindle speed, oil inlet aperture, shallow depth and initial oil film thickness. It is demonstrated that stiffness is close to the biggest value and temperature rising is close to the lowest one, when the shallow depth is thicker than the initial oil film by twice or three times, in the conditions that all other structural parameters and operating parameters are unchanged. The reliability of the analytical method has been verified by comparing experimental results with the analytical values.
MENG Shuguang
,
XIONG Wanli
,
WANG Shaoli
,
Lü Lang
,
ZHENG Lianggang
. Analytical Research on Characteristics of Deep-shallow Journal Bearings with Orifice Restrictors[J]. Journal of Mechanical Engineering, 2015
, 51(22)
: 191
-201
.
DOI: 10.3901/JME.2015.22.191
[1] 武弘毅. 动静压轴承讲座:第三讲?动静压混合轴承的结构[J]. 机械工人:冷加工,1990(3):57-62. WU Hongyi. Dynamic and static pressure bearing lecture Ⅲ:Structure of hydrodynamic and hydrostatic journal bearings[J]. Journal of Mechanical Workers:Cold work,1990(3):57-62.
[2] 武弘毅,冯明. WMB型动静压混合轴承的基本性能[J]. 设备管理与维修,1991(6):14-16. WU Hongyi,FENG Ming. WMB type hydrostatic and hydrodynamic hybrid bearing[J]. Plant Maintenance Engineering,1991(6):14-16.
[3] ROWE W B. Hydrostatic,aerostatic and hybrid bearing design[M]. Oxford:Butterworth-Heinemann,2012.
[4] 许尚贤. 液体静压和动静压滑动轴承设计[M]. 南京:东南大学出版社,1989. XU Shangxian. Hydrostatic and hybrid bearing design[M]. Nanjing:Southeast University Press,1989.
[5] 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.
[6] 孙恭寿,冯明. 液体动静压混合轴承设计[M]. 北京:世界图书出版公司,1989. SUN Gongshou,FENG Ming. Design for liquid hydro-hybrid bearings[M]. Beijing:World Book Inc.,1989.
[7] 李健,程先华. 动静压支承滑动轴承性能分析[J]. 上海交通大学学报,2006,40(12):2026-2029. LI Jian,CHEN Xianhua. The analysis of dynamic and static back journal bearing’s performance[J]. Journal of Shanghai Jiao Tong University,2006,40(12):2026-2029.
[8] 江桂云,王勇勤,严兴春,等. 油膜轴承动静压混合效应的分析[J]. 机械设计,2010,27(7):86-89. JIANG Guiyun,WANG Yongqin,YAN Xingchun,et al. Analysis on hybrid hydrodynamic-static effect of oil film bearings[J]. Journal of Mechanical Design,2010,27(7):86-89.
[9] 郭胜安,侯志泉,熊万里,等. 基于CFD的深浅腔液体动静压轴承承载特性研究[J]. 制造技术与机床,2012(9):57-61. GUO Shengan,HOU Zhiquan,XIONG Wanli,et al. Bearing characteristics study on liquid hybrid bearing based on CFD[J]. Journal of Technology and Machine Tool,2012(9):57-61.
[10] 刘豪杰,郭红,张绍林. 基于FLUENT的深浅腔动静压轴承油膜压力研究[J]. 润滑与密封,2013,38(10):35-38. LIU Haojie,GUO Hong,ZHANG Shaolin. Research on static characteristics of deep/shallow pockets hybrid,bearing based on FLUENT[J]. Journal of Lubrication Engineering,2013,38(10):35-38.
[11] 郭力,沈志伟,刘桂萍. 高效精密磨床砂轮主轴深浅腔动静压轴承静特性分析[J]. 润滑与密封,2014,39(2):1-8. GUO Li,SHEN Zhiwei,LIU Guiping. Analysis of static characteristics of the liquid hybrid bearings with deep-shallow cavity in a high efficiency and precision spindle of grinder[J]. Journal of Lubrication Engineering,2014,39(2):1-8.
[12] GAO Gengyuan,YIN Zhongwei,JIANG Dan et al. Numerical analysis of plain journal bearing under hydrodynamic lubrication by water[J]. Tribology International,2014,75:31-38.
[13] LI Q,YU G,LIU S,et al. Application of computational fluid dynamics and fluid structure interaction techniques for calculating the 3D transient flow of journal bearings coupled with rotor systems[J]. Chinese Journal of Mechanical Engineering,2012,25(5):926-932.
[14] LI Q,LIU S,PAN X,et al. A new method for studying the 3D transient flow of misaligned journal bearings in flexible rotor-bearing systems[J]. Journal of Zhejiang University Science A,2012,13(4):293-310.
[15] 熊万里,侯志泉,吕浪,等. 基于动网格模型的液体动静压轴承刚度阻尼计算方法研究[J]. 机械工程学报,2012,48(23):118-126. XIONG Wanli,HOU Zhiquan,Lü Lang,et al. Method for calculating stiffness and damping coefficients of hybrid bearings based on dynamic mesh model [J]. Journal of Mechanical Engineering,2012,48(23):118-126.
[16] 侯志泉. 基于CFD动网格方法的液体静压主轴回转精度机理研究[D]. 长沙:湖南大学,2013. HOU Zhiquan. Research on rotational accuracy mechanism of hydrostatic spindle based on CFD dynamic mesh method[D]. Changsha:Hunan University,2013.
[17] 李庆杨,莫孜中,祁力群,等. 非线性方程组的数值解法[M]. 北京:科学出版社,1987. LI Qingyang,MO Zizhong,QI Liqun,et al. The numerical solution of nonlinear equations[M]. Beijing:Science Press,1987.
