Analysis and Optimization Design of Lubrication Load Characteristics for Large Dual-flow Oil Seal Pads under High Hydrogen Pressure with Multiple Coupling Fields

doi:10.3901/JME.260020

Abstract

Abstract: To address issues of journal bearing damage and uneven flow distribution in the dual-ring seal pads of an operational nuclear generator, this study employs a multi-field coupled spatial equilibrium algorithm to analyze their lubrication and load-bearing characteristics, aiming to resolve problems of wear, deformation, and failure. By integrating flow fields, temperature fields, and thermoelastic deformation, a multi-field coupled model is established to reveal the effects of oil film pressure, contact pressure, temperature distribution, and deformation on the performance of the seal pads. The study identifies stress concentration regions and operational clearance variations as the primary causes of seal pad damage. To enhance sealing performance, an optimized design is proposed by increasing the oil-sealing edge width on the air side and reducing it on the hydrogen side. After optimization, the relative load-bearing capacity of the seal pads increased by more than twofold, while the thrust-to-weight ratio decreased by 50%, achieving stable floating under various operating conditions and demonstrating excellent load-bearing capacity and compliance. The results indicate that the optimized design significantly improves the lubrication performance and operational reliability of the seal pads, providing valuable theoretical insights and practical guidance for the design and optimization of dual-ring oil sealing systems.

Key words: dual-flow oil seal pad, sealing edge parameters, thrust pad weight ratio, contact load, responsiveness

CLC Number:

TH113

PEI Shiyuan, HU Dejian, QIN Chuan, ZHANG Lei. Analysis and Optimization Design of Lubrication Load Characteristics for Large Dual-flow Oil Seal Pads under High Hydrogen Pressure with Multiple Coupling Fields[J]. Journal of Mechanical Engineering, 2026, 62(1): 272-284.

References

[1] 王笑微,刘永洛,尹文波,等.密封油含气量对氢冷发电机氢气纯度影响研究[J].热力发电,2021,50(4):109-113.WANG Xiaowei,LIU Yongluo,YIN Wenbo,et al.Influence of dissolved gas content in sealing oil on hydrogen purity of hydrogen-cooled generator[J].Thermal Power Generation,2021,50(4):109-113.
[2] 吕庆举,周党锋.核电厂氢冷双流环发电机氢气纯度降低的分析与处理[J].电力设备管理,2020(7):65-67,75.LÜ Qingju,ZHOU Dangfeng.The analysis and treatment of hydrogen purity reduction in hydrogen-cooled dual-flow ring generators of nuclear power plants[J].Electric Power Equipment Management,2020(7):65-67,75.
[3] 赵国钦.氢冷发电机密封瓦供油方式对发电机安全性影响分析[J].东北电力技术,2023,44(9):45-49.ZHAO Guoqin.Analysis of hydrogen cooled generator sealing pad oil supply mode to influence of generator safety[J].Northeast Electric Power Technology,2023,44(9):45-49.
[4] 徐新果,李丰均,姚坤.300MW氢冷机组氢气纯度下降的原因分析及处理[J].节能技术,2020,38(6):565-568,574.XU Xinguo,LI Fengjun,YAO Kun.Analysis and treatment of hydrogen purity decline in 300 mw hydrogen cooling unit[J].Energy Conservation Technology,2020,38(6):565-568,574.
[5] 杨彦肖,孙聆菱.氢冷发电机两种密封油系统对氢气纯度的影响[J].电力安全技术,2023,25(2):19-22.YANG Yanxiao,SUN Lingling.Influence of two sealing oil systems on hydrogen purity for hydrogen-cooled generator[J].Electric Safety Technology,2023,25(2):19-22.
[6] 宋伟,高伟,李敬豪,等.密封瓦引发振动及其与摩擦故障比较分析[J].汽轮机技术,2024,66(2):113-116,119.SONG Wei,GAO Wei,LI Jinghao,et al.Analysis of sealing bearing induced vibration and comparison with rub faults[J].Turbine Technology,2024,66(2):113-116,119.
[7] ARGHIR M,NGUYEN M H,TONON D,et al.Analytic modeling of floating ring annular seals[J].ASME Journal Eng Gas Turb Power,2011,134(5):577-586.
[8] SAN ANDRÉS L,DELGADO A.A novel bulk-flow model for improved predictions of force coefficients in grooved oil seals operating eccentrically[J].ASME Journal of Engineering for Gas Turbines and Power,2012,134(5):052509.
[9] CHILDS D W,GRAVISS M,RODRIGUEZ L E.The influence of groove size on the static and rotordynamic characteristics of short,laminar-flow annular seals[J].ASME Journal of Tribology,2007,129(2),398-406.
[10] DELGADO A,SAN ANDRÉS L.A model for improved prediction of force coefficients in grooved squeeze film dampers and oil seal rings[J].ASME Journal of Tribology,2010,132(3):032202.
[11] 许文君,王成木,岳婷,等.氢冷发电机双流环密封瓦改进设计及数值模拟[J].大电机技术,2020(4):39-44.XU Wenjun,WANG Chengmu,YUE Ting,et al.The improved design and numerical simulation of the double flow ring sealing tile for hydrogen-cooled generator[J].Large Electric Machine and Hydraulic Turbine,2020(4):39-44.
[12] 周海峰,李科文,刘维明,等.330 MW机组双流环密封油系统异常分析和处理[J].电力安全技术,2018,20(3):20-23.ZHOU Haifeng,LI Kewen,LIU Weiming,et al.Analysis and handling of abnormalities in the dual-flow seal oil system of a 330 MW unit[J].Electric Safety Technology,2018,20(3):20-23.
[13] 陈锦辉.氢冷发电机双流浮环密封油膜特性研究[J].电机技术,2020(5):9-14.CHEN Jinhui.Research on the oil film performance of double floating-ring seal for hydrogen-cooled generators[J].Electrical Machinery Technology,2020(5):9-14.
[14] 陈浩,李隆锋,倪仲俊.某电厂汽轮机发电机氢气纯度低原因分析及处理[J].科技资讯,2021,19(9):42-45.CHEN Hao,LI Longfeng,NI Zhongjun.Cause analysis and treatment of low hydrogen purity of steam turbine generator in a power plant[J].Science & Technology Information,2021,19(9):42-45.