1) capilliary compensated hybrid bearings
毛细管节流动静压轴承
2) restrictor (hydrostatic bearing)
节流器(静压轴承)
3) liquid hybrid bearing
流体动静压轴承
1.
This paper mainly discusses available structures of the liquid hybrid bearings and the key technologies that need to be solved for the liquid rocket engine turbopump.
针对液体火箭发动机涡轮泵特殊工作环境,讨论了流体动静压轴承可采用的结构形式和需要解决的关键技术。
4) hydro-hybrid bearing
动静压轴承
1.
Advantages employing hydro-hybrid bearing in super high speed grinder spindle was introduced, its working conditions were also analyzed.
阐述了超高速磨床磨头中使用液体动静压轴承的优点,综合分析了液体动静压混合轴承在高速磨头中的工况条件,基于具体实践和轴承性能数学模型,提出了一种崭新的实用化的高速液体动静压轴承的优化设计方法。
2.
Advantages employing hydro-hybrid bearing in Righ spead grinder spindle was introduced, its working conditions are also analyzed A brand new and practical optimal design method of high speed hydro-hybrid bearing is propose
阐述了高速磨床磨头中使用液体动静压轴承的优点 ,综合分析了液体动静压混合轴承在高速磨头中的工况条件 ,基于具体实践和轴承性能数学模型 ,提出了一种崭新的实用化的高速液体动静压轴承的优化设计方
5) Hybrid bearing
动静压轴承
1.
Dynamic Analysis of Hybrid Bearing with Shallow Recess;
阶梯浅油腔动静压轴承动特性分析
2.
Analysis of Circular Slot Entry Hybrid Bearing;
圆隙缝动静压轴承静特性分析
3.
Beginning with lubrication principle and based upon classical Reynolds theory,pressure field,structure coefficients of surface throttle hybrid bearing,and their effects on property of bearing were analyzed with finite difference method.
从润滑原理入手,以经典的Reynolds理论为基础,使用有限差分方法,对表面节流式动静压轴承的压力场、结构参数对承载特性的影响进行了分析研究。
6) hydrostatic journal bearings
动静压轴承
1.
The three-dimensional pressure distributions and temperature field of capillary-compensated,water-lubricated hydrostatic journal bearings with four deep recesses were analyzed.
以4腔、毛细节流形式下的深腔动静压轴承为研究对象,采用有限差分数值方法求解了广义雷诺方程,该过程考虑了紊流、粘度和密度随压力及温度变化的影响。
补充资料:毛细管吸入压
分子式:
CAS号:
性质:将单根毛细管垂直放置,并将其下端浸没在水面以下,由于水的表面张力而将水吸入管内,使毛务管内水的表面上升。毛细管的吸水力即称为毛细管力。令毛细管半径为r(cm),水的密度为ρ(g/cm3),水的表面张力为σ(dyn/cm),则毛细管的吸入压Pc(dyn/cm2)与毛细管内水的上升高度H(cm)之间的关系可用下式表示:,g为重力加速度;gc为重力换算系数;α为水与管壁的接触角,当固体壁面清洁时,α=0。由上式可以看出毛细管的吸入压Pc与毛细管的直径成反比。
CAS号:
性质:将单根毛细管垂直放置,并将其下端浸没在水面以下,由于水的表面张力而将水吸入管内,使毛务管内水的表面上升。毛细管的吸水力即称为毛细管力。令毛细管半径为r(cm),水的密度为ρ(g/cm3),水的表面张力为σ(dyn/cm),则毛细管的吸入压Pc(dyn/cm2)与毛细管内水的上升高度H(cm)之间的关系可用下式表示:,g为重力加速度;gc为重力换算系数;α为水与管壁的接触角,当固体壁面清洁时,α=0。由上式可以看出毛细管的吸入压Pc与毛细管的直径成反比。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条