低温液氮泵空化模型修正及内部流动数值研究
|
摘要
为了研究低温泵内的空化流动,考虑热力学效应,对现有Zwart空化模型进行了修正,并通过NACA0015水翼的空化实验验证了修正后模型的可行性。同时采用数值模拟的方法分析低温泵在输送液氮介质时所产生的空化流动现象,获得了低温泵的空化性能、叶片表面中间流线上的载荷分布情况和流道内的温度分布规律。研究结果对准确预测低温泵的空化性能,提高低温泵的抗空化能力具有意义。
Cryogenic pump is a kind of centrifugal pump used to transport cryogenic medium, which is more prone to cavitation than ordinary pump. In order to study the cavitation flow in cryopump,the existing Zwart cavitation model was modified by considering the thermodynamic effect, and the feasibility of the modified model was verified by the cavitation experiment of NACA0015 hydrofoil. At the same time, the cavitation flow phenomena of cryopump when transporting liquid nitrogen medium are analyzed by numerical simulation. The cavitation performance of cryopump, the load distribution on the middle streamline of blade surface and the temperature distribution in the pump channel are obtained. The research results can be used for reference in accurately predicting the cavitation performance of cryopump and improving the anti-cavitation ability of cryopump.
Cryogenic pump is a kind of centrifugal pump used to transport cryogenic medium, which is more prone to cavitation than ordinary pump. In order to study the cavitation flow in cryopump,the existing Zwart cavitation model was modified by considering the thermodynamic effect, and the feasibility of the modified model was verified by the cavitation experiment of NACA0015 hydrofoil. At the same time, the cavitation flow phenomena of cryopump when transporting liquid nitrogen medium are analyzed by numerical simulation. The cavitation performance of cryopump, the load distribution on the middle streamline of blade surface and the temperature distribution in the pump channel are obtained. The research results can be used for reference in accurately predicting the cavitation performance of cryopump and improving the anti-cavitation ability of cryopump.
引文
1 Brennen C E.空化与空泡动力学[M]. 王勇, 潘中永译.镇江: 江苏大学出版社, 2013: 33-59.Brennen C E. Cavitation and Bubble Dynamics[M]. Wang Yong, Pan Zhongyong translated. Zhenjiang: Jiangsu University Press, 2013: 33-59.
2 关醒凡. 现代泵理论与设计[M]. 北京: 中国宇航出版社, 2011: 74-78.Guan Xingfan. Modern Pumps Theory and Design[M]. Beijing: China Astronautic Publishing House, 2011: 74-78.
3 Pang K, LI Y, Yang W, et al. A cavitation model considering thermodynamic and viscosity effects[J]. Engineering Computations, 2018, 35(6): 2308-2326.
4 邵雪, 伍继浩, 李强, 等. 部分流低温液氮泵性能及流动特性仿真研究[J]. 低温工程, 2015(3): 46-51.Shao Xue, Wu Jihao, Li Qiang, et al. Study on flow characteristics and performance of partial emission cryogenic liquid nitrogen pump[J]. Cryogenics, 2015(3): 46-51.
5 Shi Suguo, Wang Guoyu. Numerical calculation of thermal effect on cavitation in cryogenic fluids[J]. Chinese Journal of Mechanical En-gineering, 2012, 25(6): 1176-1183.
6 Sun Tiezhi, Wei Yinjie, Wang Cong. Three-dimensional numerical simulation of cryogenic cavitating flows of liquid nitrogen around hydrofoil[J]. Journal of Ship Mechanics, 2014, 18(12): 1434-1444.
7 吴钦, 王国玉. 低温介质质量传输空化模型的代理分析及优化 [J]. 应用力学学报, 2013, 30(5): 700-707.Wu Qin, Wang Guoyu. Surrogate-based analysis and optimization of the transport-based cryogenic cavitation model[J]. Chinese Journal of Applied Mechanics, 2013, 30(5): 700-707.
8 赵月帅, 邵容平, 孙立臣, 等. 基于CFD方法的低温泵热力学设计与数值仿真研究[J]. 真空科学与技术学报, 2018, 38(6): 443-449.Zhao Yueshuai, Shao Rongping, Sun Lichen, et al. Thermal Design and Evaluation of Cryopump: A Simulation and Experimental Study[J]. Chinese Journal of Vacuum Science and Technology, 2018, 28(6): 443-449.
9 Ruggeri R S, Moore R D. Method for Prediction of Pump Cavitation Performance for Various Liquids, Liquid Temperatures, and Rotative Speeds[M]. Washington D.C.: National Aeronautics and Space Administration, 1969: 23-27.
10 Franc J P, Boltal G, Riondet M, et al. Thermodynamic effect on a cavitating inducer—part II: on-board measurements of temperature depression with in leading edge cavities[J]. Journal of Fluids Engineering, 2010, 132(2):41-49.
11 Cervone A, Bramanti C, Rapposelli E, et al. Thermal cavitation experiments on a NACA 0015 hydrofoil[J]. Journal of Fluids Engineering, 2006, 128(2): 326-331.
2 关醒凡. 现代泵理论与设计[M]. 北京: 中国宇航出版社, 2011: 74-78.Guan Xingfan. Modern Pumps Theory and Design[M]. Beijing: China Astronautic Publishing House, 2011: 74-78.
3 Pang K, LI Y, Yang W, et al. A cavitation model considering thermodynamic and viscosity effects[J]. Engineering Computations, 2018, 35(6): 2308-2326.
4 邵雪, 伍继浩, 李强, 等. 部分流低温液氮泵性能及流动特性仿真研究[J]. 低温工程, 2015(3): 46-51.Shao Xue, Wu Jihao, Li Qiang, et al. Study on flow characteristics and performance of partial emission cryogenic liquid nitrogen pump[J]. Cryogenics, 2015(3): 46-51.
5 Shi Suguo, Wang Guoyu. Numerical calculation of thermal effect on cavitation in cryogenic fluids[J]. Chinese Journal of Mechanical En-gineering, 2012, 25(6): 1176-1183.
6 Sun Tiezhi, Wei Yinjie, Wang Cong. Three-dimensional numerical simulation of cryogenic cavitating flows of liquid nitrogen around hydrofoil[J]. Journal of Ship Mechanics, 2014, 18(12): 1434-1444.
7 吴钦, 王国玉. 低温介质质量传输空化模型的代理分析及优化 [J]. 应用力学学报, 2013, 30(5): 700-707.Wu Qin, Wang Guoyu. Surrogate-based analysis and optimization of the transport-based cryogenic cavitation model[J]. Chinese Journal of Applied Mechanics, 2013, 30(5): 700-707.
8 赵月帅, 邵容平, 孙立臣, 等. 基于CFD方法的低温泵热力学设计与数值仿真研究[J]. 真空科学与技术学报, 2018, 38(6): 443-449.Zhao Yueshuai, Shao Rongping, Sun Lichen, et al. Thermal Design and Evaluation of Cryopump: A Simulation and Experimental Study[J]. Chinese Journal of Vacuum Science and Technology, 2018, 28(6): 443-449.
9 Ruggeri R S, Moore R D. Method for Prediction of Pump Cavitation Performance for Various Liquids, Liquid Temperatures, and Rotative Speeds[M]. Washington D.C.: National Aeronautics and Space Administration, 1969: 23-27.
10 Franc J P, Boltal G, Riondet M, et al. Thermodynamic effect on a cavitating inducer—part II: on-board measurements of temperature depression with in leading edge cavities[J]. Journal of Fluids Engineering, 2010, 132(2):41-49.
11 Cervone A, Bramanti C, Rapposelli E, et al. Thermal cavitation experiments on a NACA 0015 hydrofoil[J]. Journal of Fluids Engineering, 2006, 128(2): 326-331.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |