镶嵌式直线深槽流体动压型机械密封性能研究Investigation of Sealing Performance of Mosaic Hydrodynamic Mechanical Seal with Straight Line Deep Groove
刘杰,李鲲,吴兆山,李香,彭旭东
LIU Jie,LI Kun,WU Zhao-shan,LI Xiang,PENG Xu-dong
摘要(Abstract):
以端面开有直线深槽的镶嵌式密封结构为分析对象,建立了密封环与润滑液膜间的流固力耦合模型,采用有限差分和有限元法分别求解润滑方程和变形方程,研究了密封压力和转速对润滑液膜的影响规律,分析了操作参数对密封性能的影响。研究结果表明,由于直线深槽作用,密封端面形成了一定的波度和锥度,波度随着压力的升高而变大,但锥度增幅不是很明显,而对波度的变化影响较大。密封端面的波度和锥度随转速的变化不大。密封压力升高时,密封端面间的泄漏率增大,摩擦系数相应地减小;密封转速增大时,密封端面间的泄漏率变化不是很明显,而摩擦系数相应的增大。
Based on the structure of mosaic mechanical seal with straight deep line groove,the mathematic model was developed with the seal ring and lubrication film,which solves the lubrication and deformation equation with finite difference and element method respectively. The effect of the pressure and speed on lubrication film was studied and the operating parameters on mechanical performance were analyzed. It is found that the seal face with straight deep line can form the waviness and the taper. While the pressure elevated,the waviness becomes larger,the taper is fewer changed. But it has a large effect on the waviness. While the speed increases,the waviness and taper of the seal face has less variation. The higher the pressure is,the larger the leakage and the smaller the friction coefficient. With the speed rising,the leakage changes slowly and the friction coefficient becomes larger.
关键词(KeyWords):
核主泵;直线深槽;密封性能;流体动压效应
reactor coolant pump;straight line deep groove;seal performance;hydrodynamic effect
基金项目(Foundation): 国家科技支撑计划资助项目(2011BAF09B05);; 国家自然科学基金资助项目(50575152;51005209)
作者(Author):
刘杰,李鲲,吴兆山,李香,彭旭东
LIU Jie,LI Kun,WU Zhao-shan,LI Xiang,PENG Xu-dong
参考文献(References):
- [1]王玉明,黄伟峰,李永健.核电站一回路用机械密封[J].摩擦学学报,2011,31(4):408-415.
- [2]Loenhout G V,Olson A and J,Olliver,et al.Improving reactor coolant pump seal reliability at Dominion Surry nuclear power station[C].Fluid Sealing Conference,Milton Keynes,2011.
- [3]Mayer E.Mechanical seal[M].Beijing:Translated by Chemical Industry Press,1981.
- [4]Fuse T,Shimizu T,Nishiyama K.Development of highly reliable mechanical seal for nuclear power plant[J].Fluid Sealing,York,2003,10:405-419.
- [5]Key W E,Salant R F,Payvar P.Analysis of mechanical seal with deep hydropads[J].Tribology Transactions,1989,32(4):481-489.
- [6]James P,Netzel.The effect of interface cooling in controlling surface disturbances in mechanical face seals[J].Wear,1982,79:119-127.
- [7]Lebeck A O.Hydrodynamic lubrication in wavy contacting face seals-A two dimensional model[J].Lubrication Technology,1981,103:578-586.
- [8]Lebeck A O.Mechanical loading-A primary source of waviness in mechanical face seals[J].ASLE Transactions,1976,20(3):195-208.
- [9]Lebeck A O,Teale J L,Pierce R E.Hydrodynamic Lubrication and wear in wavy contacting face seals[J].Lubrication Technology,1978,100:81-90.
- [10]杨惠霞,顾永泉.圆弧深槽热流体动压机械密封理论研究[J].流体机械,1997,25(9):12-18.
- [11]王小燕,孟祥铠,刘鑫,等.核主泵用流体动压型机械密封耦合模型与性能分析[J].摩擦学学报,2013,33(2):169-176.
- [12]Payvar P,Salant R F.A computational method for cavitations in a wavy mechanical seal[J].Tribology,1992,114:199-204.
- [13]Lebeck A O.Principles and design of mechanical face seals[M].New York:Wiley,1991.
- [14]康玉茹,孟祥铠,彭旭东,等.核主泵用流体静压型机械密封耦合模型与性能分析[J].流体机械,2011,39(11):29-34.
- [15]黄泽沛,张君凯,王和顺,等.流体静压型核电主泵轴密封的研制[J].流体机械,2012,40(8):39-44.
- [16]陈立芳,徐晓丹,吴健伏,等.核安全级波纹膨胀节的设计[J].压力容器,2012,29(1):10,25-30.
- [17]张杰,李鲲,吴兆山,等.镶嵌式石墨密封环的压力变形研究[J].润滑与密封,2012,37(3):53-58.
- [18]张杰,李鲲,吴兆山,等.镶嵌式硬质合金密封环的压力变形研究[J].液压气动与密封,2012,37(2):29-33.