SIMULATION AND EXPERIMENT OF BUBBLY FLOW INSIDE THROTTLING GROOVE 被引量：7

SIMULATION AND EXPERIMENT OF BUBBLY FLOW INSIDE THROTTLING GROOVE

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摘要 The relationship between pressure distribution and cavitation （noise） inside throttling groove is investigated by numerical simulation and experimental method. A valve pocket with several transducers is performed to detect the pressure distributions inside the valve chamber, and the results fit quite well with the computational fluid dynamics（CFD） analysis. High-speed imaging techniques are employed to investigate the cavitation mechanisms, in particular bubble inception and cluster formation near the throttling groove. A spectrum analyzer is used to measure the sound pressure level of noise generated by the bubble flow. It is found that the pressure distributions inside the groove are sensitive to the valve port configuration and back pressure. The pressure distribution determines the bubble size and number passing through the valve grooves and the sound pressure level of noise induced by collapsing bubbles. The inlet pressure mainly affects the saturation degree of bubbly flow inside the groove and the intensity of sound nressure level accordingly. The relationship between pressure distribution and cavitation （noise） inside throttling groove is investigated by numerical simulation and experimental method. A valve pocket with several transducers is performed to detect the pressure distributions inside the valve chamber, and the results fit quite well with the computational fluid dynamics（CFD） analysis. High-speed imaging techniques are employed to investigate the cavitation mechanisms, in particular bubble inception and cluster formation near the throttling groove. A spectrum analyzer is used to measure the sound pressure level of noise generated by the bubble flow. It is found that the pressure distributions inside the groove are sensitive to the valve port configuration and back pressure. The pressure distribution determines the bubble size and number passing through the valve grooves and the sound pressure level of noise induced by collapsing bubbles. The inlet pressure mainly affects the saturation degree of bubbly flow inside the groove and the intensity of sound nressure level accordingly.

作者 FU Xin DU Xuewen ZOU Jun YANG Huayong JI Hong

机构地区 State Key Laboratory of Fluid Power Transmission and Control School of Fluid Power and Control Engineering

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2007年第5期37-41,共5页 中国机械工程学报（英文版）

基金 Selected from Proceedings of the 7th International Conference on Frontiers of DesignManufacturing(ICFDM'2006) This project is supported by National Basic Research Program of China(973 Program,No.2006CB705400) National Natural Science Foundation of China(No.50575200).

关键词 Pressure distribution Throuling groove Valve Cavitation Noise Pressure distribution Throuling groove Valve Cavitation Noise

分类号 TH16 [机械工程—机械制造及自动化]

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参考文献10

1HE L, RUIZ F. Effect of cavitation on flow and turbulence in plain orifices for high-speed atomization[J]. Atom Sprays, 1995, 5(6): 69-84.
2ARCOUMANIS C, FLORA H, GAVAISES M, et al. Investigation of cavitation in a vertical multi-hole diesel injector[R]. SAE Paper, 1999, 1999-01-0524.
3ARCOUMANIS C, GAVAISES M. Linking nozzle flow with spray characteristics in a diesel fuel injection system[J]. Atom Sprays, 1998, 8(3): 307-347.
4NAGASAKA K, TAKAGI T, KOYANAGI K, et al. The development of fine atomization injector[J]. JSAE Rev., 2000, 21(3): 309-313.
5MARTIN C S, MEDLARZ H, WIGGERT D C, et al. Cavitation inception in spool valve[J]. ASME, J. Fluids Eng., 1981, 103: 564-574.
6OSHIMA S H, LEINO T, LINJAMA M, et al. Effect of cavitation in water hydraulic poppet valves[J]. International Journal of Fluid Power, 2001, 2(3): 5-13.
7MITCHELL T M, HAMMITT F G. Asymmetric cavitation bubble collapse[J]. ASME, J. Fluids Eng., 1973, 95: 29-37.
8WARJITO S W, MOCHIZUKI O, KIYA M. Bubbly flow undergoing a steep pressure gradient[J]. Exp. Fluids, 2002, 33(5): 620-628.
9GAO Dianrong. Investigation of flow structure inside spool valve with FEM and PIV methods[J]. International Journal of Fluid Power, 2004, 5(1): 51-56.
10冀宏,傅新,杨华勇,王庆丰.非全周开口滑阀压力分布测量研究[J].机械工程学报,2004,40(4):99-102. 被引量：16

二级参考文献5

1曹秉刚,史维祥,中野和夫.内流式锥阀液动力及阀芯锥面压强分布的实验研究[J].西安交通大学学报,1995,29(7):7-13. 被引量：35
2Shigeru O, Tsuneo I. Cavitation phenomena and performan-ce of oil hydraulic poppet valve. Bulletin of JSME,1985,28(244):2 264～2 271
3Shigeru O, Timo L, Matti L, et al. Effect of cavitation in water hydraulic poppet valves.International Journal of Fluid Power,2001,2(3):5～13
4冀宏,傅新,杨华勇.非全周开口滑阀稳态液动力研究[J].机械工程学报,2003,39(6):13-17. 被引量：78
5冀宏,傅新,杨华勇.几种典型液压阀口过流面积分析及计算[J].机床与液压,2003,31(5):14-16. 被引量：82

共引文献15

1冀宏,傅新,杨华勇,王庆丰.节流槽型阀口噪声特性试验研究[J].机械工程学报,2004,40(11):42-46. 被引量：19
2傅新,杜学文.阀口高速流动中的气穴观测与流场分析[J].液压与气动,2006,30(7):29-31. 被引量：1
3杜学文,邹俊,傅新,冀宏,杨华勇.节流槽结构对气穴噪声的影响[J].浙江大学学报（工学版）,2007,41(3):456-460. 被引量：23
4傅新,杜学文,邹俊,杨华勇.孔隙高速流动中的气穴观测与噪声特性[J].机械工程学报,2007,43(4):98-102. 被引量：12
5杜诗文,李永堂,程晓蒙.电液锤主控换向阀流场分析及结构优化[J].机械工程与自动化,2007(4):16-18. 被引量：1
6禹红斌.液压转向阀内噪声因素的研究[J].上海汽车,2007(11):25-28. 被引量：2
7赵蕾,陈青,权龙.阀芯运动状态滑阀内部流场的可视化分析[J].农业机械学报,2008,39(11):142-145. 被引量：37
8郭熛,解宁,郭津津,刘杰.滑阀液动力研究及结构分析[J].液压气动与密封,2012,32(4):11-15. 被引量：18
9高俊庭,殷晨波,叶仪,李萍,周玲君.非全周开口的液压滑阀内部流场的CFD解析[J].液压与气动,2013,37(5):58-61. 被引量：7
10叶仪,殷晨波,刘辉,邹根,姜雪峰.节流槽阀口静态流动特性研究[J].农业机械学报,2014,45(6):308-316. 被引量：19

同被引文献38

1马彪,路华鹏,李和言.静液传动容积调速系统模型参考自适应控制[J].机床与液压,2006,34(11):172-173. 被引量：4
2訚耀保,张鹏,岑斌.偏转板射流伺服阀前置级流场分析[J].中国工程机械学报,2015,13(1):1-7. 被引量：27
3施卫东,张启华,陆伟刚.新型井泵水力设计及内部流动的数值模拟[J].江苏大学学报（自然科学版）,2006,27(6):528-531. 被引量：40
4Ye Qifang, Chen Jiangping. Dynamic analysis of a pi-lot-operated two-stage solenoid valve used in pneumaticsystem [ J ]. Simulation Modeling Practice and Theory,2009,17(5) :794 -816.
5Dasgupta K,Karmakar R. Modeling and dynamics ofsingle-stage pressure relief valve with directional dam-ping [J ]. Simulation Modeling Practice and Theory,2002,10(1/2) :51 -67.
6Choi Jin-Keun, Jayaprakash Arvind, Chahine GeorgesL. Scaling of cavitation erosion progression with cavitati-on intensity and cavitation source [ J ]. Wear, 2012(278/279) :53 -61.
7Jazi A, Masjedian, Rahimzadeh H. Waveform analysisof cavitation in a globe valve [ J ]. Ultrasonics, 2009(49) : 577 -582.
8Catania A E, Ferrari A, Spessa E. Temperature varia-tions in the simulation of high-pressure injection-systemtransient flows under cavitation [ J ]. International Journalof Heat and Mass Transfer, 2008 ,51 :2090 -2107.
9Li Zhang, Jing Luo,Yuan Ruibo, et al. The CFD ana-lysis of twin flapper-nozzle valve in pure water hydraulic[J]. Procedia Engineering, 2012 ,31 :220 - 227.
10冀宏,张继环,王东升,等.滑阀矩形节流槽阀口的流量系数[C]//第六届全国流体传动与控制学术会议.兰州:兰州理工大学,2010:74 -77.

引证文献7

1袁士豪,殷晨波,刘世豪.液压阀口二级节流特性[J].排灌机械工程学报,2012,30(6):715-720. 被引量：14
2袁士豪,殷晨波,刘世豪.机械负载敏感定量泵系统性能分析[J].农业工程学报,2013,29(13):38-45. 被引量：23
3袁士豪,殷晨波,叶仪.基于模糊综合判断的液压阀口节流特性优化[J].南京工业大学学报（自然科学版）,2013,35(6):23-28. 被引量：4
4袁士豪,殷晨波,叶仪,刘世豪.异型分压阀口节流槽节流特性研究[J].农业机械学报,2014,45(1):321-327. 被引量：6
5周玲君,殷晨波,叶仪,袁峰峰.V型液压阀口节流特性多目标优化[J].机械设计与制造,2014(5):166-169. 被引量：3
6李四海,袁士豪.二级节流阀口空化特性表征研究[J].中国机械工程,2015,26(16):2165-2169. 被引量：6
7冀宏,张硕文,刘新强,李瑞锋,李琼.射流偏转板劈尖形变对其零位特性的影响[J].兰州理工大学学报,2018,44(3):45-49. 被引量：9

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1安亮亮,曹卫彬,李树峰,麻平,连国党,杨双平.梳夹式红花采收机液压系统设计[J].中国农机化学报,2020,41(1):37-42. 被引量：5
2袁士豪,殷晨波,刘世豪.基于AMESim的平衡阀动态性能分析[J].农业机械学报,2013,44(8):273-280. 被引量：50
3袁士豪,殷晨波,叶仪.基于模糊综合判断的液压阀口节流特性优化[J].南京工业大学学报（自然科学版）,2013,35(6):23-28. 被引量：4
4周玲君,殷晨波,叶仪,袁峰峰.V型液压阀口节流特性多目标优化[J].机械设计与制造,2014(5):166-169. 被引量：3
5叶仪,殷晨波,刘辉,邹根,姜雪峰.节流槽阀口静态流动特性研究[J].农业机械学报,2014,45(6):308-316. 被引量：19
6韩彩锐,舒彩霞,李磊,李平,丁幼春,廖宜涛,廖庆喜.4SY-1.8型油菜割晒机液压驱动系统的设计[J].华中农业大学学报,2015,34(1):136-141. 被引量：9
7李宗.挖掘机铲斗阀芯优化设计[J].液压与气动,2015,39(4):118-121. 被引量：2
8段炼,袁寿其,胡林峰,李德桃,夏兴兰,俞建达.高压共轨喷油器控制阀空化研究[J].农业机械学报,2015,46(5):321-327. 被引量：10
9孔祥东,宋豫,艾超,胡建军,夏庆超.比例阀异形阀口流量特性PIV可视化实验研究[J].农业机械学报,2015,46(5):328-335. 被引量：15
10袁士豪,楼盼龙,吕剑昊.基于熵值分析的节流阀口节流特性[J].排灌机械工程学报,2015,33(1):61-66. 被引量：4

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2黄浩,郭梁.基于Workbench的比例多路阀流固耦合数值分析[J].机床与液压,2016,44(17):163-166. 被引量：4
3NI Yongyan YUAN Shouqi PAN Zhongyong YUAN Jianping.DETECTION OF CAVITATION IN CENTRIFUGAL PUMP BY VIBRATION METHODS[J].Chinese Journal of Mechanical Engineering,2008,21(5):46-49. 被引量：15
4寿青黎,严国祥.谈谈对德国GOEBEL公司液压传动系统的维护和保养[J].湖北造纸,2013(2):20-21.
5王思路,胡佳佳,陈哉李,张旦婷,王永佳,呼格吉乐.压力敏感滑轮伸缩椅的设计与研究[J].山东工业技术,2016(11):36-36. 被引量：1
6王光磊,同志学,张战平,韩应飞.基于AMESim的液压机械手负载敏感系统仿真研究[J].矿山机械,2011,39(12):105-109. 被引量：3
7李庆文,王东,陈学科.液压油气泡的消除方法[J].工程机械与维修,2008(5):154-154. 被引量：2
8罗小辉,胡军华,王晓斌,牛子华.Simulation and Experimental Research for Piping Damper with Plunger-type Accumulator[J].Journal of Marine Science and Application,2010,9(3):274-279.
9侯园园,葛世荣.铜销对钢盘摩擦副磨损率测试的尺寸效应[J].润滑与密封,2009,34(2):25-27. 被引量：2
10黄伯超,王少萍.变压力柱塞泵配流盘的压力敏感减振机理[J].北京航空航天大学学报,2012,38(10):1336-1340. 被引量：4

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