Thermal-fluid-solid Coupling Model and Performance Analysis of Single Metal Seals in Cone Bits

doi:10.3969/j.issn.1004-132X.2020.19.005

Abstract

Abstract: The asperity contacts, thermal-mechanics deformations and viscosity-temperature characteristics of seal end faces were considered comprehensively, the interrelated systems of sealing rings and auxiliary seals, lubricant films and sealing mediums were constructed, a thermal-fluid-solid coupling mathematical model was established for single metal seals in cone bits. Furthermore, the influences of key parameters such as environmental pressures and bit speeds on the film thickness distribution, temperature rises and sealing performances of single metal seals were studied. The results show that the gaps of single metal seal end faces gradually evolve from convergent to divergent with the increasing of drilling depths and environmental pressures. The extreme points of film thicknesses and temperature rises migrate from outer diameter to inner diameter, and the critical turning point of environmental pressures is around p0=11 MPa. Under the high pressure conditions, the contact pressures on the inner diameter sides of seal end faces increase, which is not conducive to the formation of lubricating films. The leakage rates and frictional forces of the sealing systems increase with the increasing of bit speeds, while the drilling efficiency may be improved by increasing the bit speeds reasonably under low pressure conditions.

Key words: cone bit, single metal seal, thermal-fluid-solid coupling, viscosity-temperature characteristic

摘要： 综合考虑密封端面间的粗糙接触、热力变形和黏温特性，构建了密封环与辅助密封件、润滑液膜与密封介质的关联体系，建立了牙轮钻头单金属密封热流固耦合数学模型，并研究了关键钻井参数如环境压力、钻头转速对单金属密封端面膜厚分布形态、温升变化及密封性能的影响规律。研究结果表明：随钻井深度和环境压力的增大，单金属密封端面间隙逐渐由收敛型演化为发散型，膜厚及温升极值点由外径侧向内径侧迁移，其临界转折点为环境压力p0=11 MPa附近；高压工况下，密封端面内径侧接触压力递增，不利于润滑油膜的形成；密封系统的泄漏率和摩擦力随钻头转速增大均有所增大，但在低压工况下可通过合理增大钻头转速来提高钻井效率。

关键词: 牙轮钻头, 单金属密封, 热流固耦合, 黏温特性

CLC Number:

TH117.2
TE24

MA Yi1,2；NI Yang1；MENG Xiangkai1,2；PENG Xudong1, 2；JIANG Jinbo1,2. Thermal-fluid-solid Coupling Model and Performance Analysis of Single Metal Seals in Cone Bits[J]. China Mechanical Engineering, DOI: 10.3969/j.issn.1004-132X.2020.19.005.

马艺1,2；倪洋1；孟祥铠1,2；彭旭东1,2；江锦波1, 2. 牙轮钻头用单金属密封热流固耦合模型与性能分析[J]. 中国机械工程, DOI: 10.3969/j.issn.1004-132X.2020.19.005.

References

［1］DENNEY D. New Slimhole Technology Maximizes Productivity in Middle East Horizontal-drilling Programs［J］. Journal of Petroleum Technology, 2005, 57(11):58-59.

［2］XIONG S H, SALANT R F. A Numerical Model of a Rock Bit Bearing Seal［J］. Tribology Transactions, 2000, 43(3):542-548.

［3］张毅, 常学平, 付玉坤, 等.钻井工况下单金属密封接触分析及实验研究［J］. 中国机械工程, 2018, 29(3):262-266.

ZHANG Yi, CHANG Xueping, FU Yukun, et al. Analysis and Experimental Research of Contact States of Single Metal Seal under Drilling Conditions［J］. China Mechanical Engineering, 2018, 29(3):262-266.

［4］张晓东, 张毅, 李一岚, 等. 单金属密封总装设计和润滑理论分析［J］. 机械设计与研究, 2013, 29(6):132-134.

ZHANG Xiaodong, ZHANG Yi, LI Yilan, et al. Container Design and Contact Research of Single Metal Seal［J］. Machine Design and Research, 2013, 29(6):132-134.

［5］BRUNETIERE N. An Analytical Approach of the Thermoelasto-hydrodynamic Behaviour of Mechanical Face Seals Operating in Mixed Lubrication［J］. Proceedings of the Institution of Mechanical Engineers, Part J:Journal of Engineering Tribology, 2010, 224(12):1221-1233.

［6］彭旭东, 刘鑫, 孟祥铠, 等. 核主泵用双锥度端面流体静压机械密封热弹流效应研究［J］. 摩擦学学报, 2012, 32(3):244-250.

PENG Xudong, LIU Xin, MENG Xiangkai, et al. Thermo-elasto-hydrostatic Effect Analysis of a Double Tapered Hydrostatic Mechanical Seal in Reactor Coolant Pumps［J］. Tribology, 2012, 32(3):244-250.

［7］LIU Ying, LIU Wei, LI Yongjian, et al. Mechanism of a Wavy-tilt-dam Mechanical Seal under Different Working Conditions［J］. Tribology International, 2015, 90:43-54.

［8］AYADI K, BRUNETIERE N, TOURNERIE B, et al. Experimental and Numerical Study of the Lubrication Regimes of a Liquid Mechanical Seal［J］. Tribology International, 2015, 92:96-108.

［9］温诗铸, 黄平. 摩擦学原理［M］. 北京:清华大学出版社, 2012.

WEN Shizhu, HUANG Ping. Principles of Tribology［M］. Beijing:Tsinghua University Press, 2012.

［10］PATIR N, CHENG H S. Application of Average Flow Model to Lubrication between Rough Sliding Surfaces［J］. Journal of Lubrication Technology, 1979, 101(2):220-229.

［11］XIONG Shunhe. Numerical Model of a Rock Bit Bearing Seal［D］. Atlanta:Georgia Institute of Technology, 2001.

［12］HARP S R, SALANT R F. Analysis of Mechanical Seal Behavior during Transient Operation［J］. Journal of Tribology, 1998, 120(2):191-197.

［13］WANG Bingqing, PENG Xudong, MENG Xiangkai. A Thermo-elastohydrodynamic Lubrication Model for Hydraulic Rod O-ring Seals under Mixed Lubrication Conditions［J］. Tribology International, 2019, 129:442-458.

［14］RUAN B, SALANT R F, GREEN I. A Mixed Lubrication Model of Liquid/Gas Mechanical Face Seals［J］. Tribology Transactions, 1997, 40(4):647-657.

［15］卢美亮. 单金属密封变形分析与结构优化［D］. 成都:西南石油大学, 2017.

LU Meiliang. Deformation Analysis and Structure Optimization of Single Metal Seal［D］. Chengdu:Southwest Petroleum University, 2017.

［16］高斌超, 孟祥铠, 李纪云, 等. 机械密封热力耦合有限元模型与密封性能分析［J］. 摩擦学学报, 2015, 35(5):550-556.

GAO Binchao, MENG Xiangkai, LI Jiyun, et al. Thermal-mechanical Coupled Finite Element Model and Seal Performance Analysis of Mechanical Seals［J］. Tribology, 2015, 35(5):550-556.

［17］ZHANG Yi, ZHANG Xiaodong, CHANG Xueping, et al. Experimental and Optimization Design of Offshore Drilling Seal［J］. Polish Maritime Research, 2017, 24(3):72-78.

［18］ZHANG Yi, ZHANG Xiaodong, CHANG Xueping, et al. Wear Morphology Analysis and Structural Optimization of Cone Bit Bearing Seals［J］. Industrial Lubrication and Tribology, 2018, 70(1):59-67.

［19］ZHAO Yangsheng, FENG Zijun, XI Baoping, et al. Limit of Crustal Drilling Depth［J］. Journal of Rock Mechanics and Geotechnical Engineering, 2017, 9(5):989-992.

［20］刘志鹏, 况雨春, 王亚萍. 牙轮钻头密封试验机工作机理研究［J］. 机械设计与制造, 2009(8):191-193.

LIU Zhipeng, KUANG Yuchun, WANG Yaping. Research on Working Principle of a Roller Bits Seal Testing Machine［J］. Machinery Design & Manufacture, 2009(8):191-193.

［21］BRUNETIERE N, TOURNERIE B, FRENE J. TEHD Lubrication of Mechanical Face Seals in Stable Tracking Mode:Part 2—Parametric Study［J］. Journal of Tribology, 2003, 125(3):617-627.