THEORY AND EXPERIMENT ON THE VISCOUS HEATING OF FLUID DAMPER UNDER SHOCK ENVIRONMENT 被引量：2

THEORY AND EXPERIMENT ON THE VISCOUS HEATING OF FLUID DAMPER UNDER SHOCK ENVIRONMENT

下载PDF

导出

摘要 A specially designed fluid damper used as negative shock pulse generator in the shock resistance test system to dissipate the shock input energy in transient time duration is presented. The theoretical modeling based on the three-dimensional equation of heat transfer through a fluid element is created to predict the viscous heating in the fluid damper under shock conditions. A comprehensive experimental program that investigates the problem of viscous heating in the fluid damper under different shock conditions is conducted on the shock test machine to validate the analytical expression. Temperature histories for the fluid within the damper at two locations, the annular-oriflce and the-end-of stroke of the damper, are recorded. The experimental results show that the theoretical model can offer a very dependable prediction for the temperature histories in the damper for increasing input velocity. The theoretical model and experimental data both clearly indicate that the viscous heating in the damper is directly related to the maximum shock velocity input and the pressure between the two sides of the piston head. A specially designed fluid damper used as negative shock pulse generator in the shock resistance test system to dissipate the shock input energy in transient time duration is presented. The theoretical modeling based on the three-dimensional equation of heat transfer through a fluid element is created to predict the viscous heating in the fluid damper under shock conditions. A comprehensive experimental program that investigates the problem of viscous heating in the fluid damper under different shock conditions is conducted on the shock test machine to validate the analytical expression. Temperature histories for the fluid within the damper at two locations, the annular-oriflce and the-end-of stroke of the damper, are recorded. The experimental results show that the theoretical model can offer a very dependable prediction for the temperature histories in the damper for increasing input velocity. The theoretical model and experimental data both clearly indicate that the viscous heating in the damper is directly related to the maximum shock velocity input and the pressure between the two sides of the piston head.

作者 CHU Deying ZHANG Zhiyi WANG Gongxian HUA Hongxing WANG Yu

机构地区 State Key Laboratory of Vibration Chinese Navy Warship Research Center

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2008年第3期66-71,共6页 中国机械工程学报（英文版）

基金 Chinese Navy Warship Research Center(No.05131-1046)

关键词 Fluid damper Negative shock pulse generator Viscous heating Shock conditions Fluid damper Negative shock pulse generator Viscous heating Shock conditions

分类号 TH703.63 [机械工程—精密仪器及机械]

引文网络
相关文献

参考文献15

1BLACK C J. Experimental evaluation and characterization of yielding and viscous devices for the seismic protection of structures[D]. Berkeley: University of California, 2004.
2XU Y L,ZHOU H J. Damping cable vibration for a cable-stayed bridge using adjustable fluid dampers[J]. Journal of Sound and Vibration, 2007, 306(1-2): 349 360.
3WANG J Y, NI Y Q, KO J M, et al. Magneto-theological tuned liquid column dampers for vibration mitigation of tall buildings: modeling and analysis of open-loop control[J]. Computers and Structures, 2005, 83(25-26): 2 023-2 034.
4ZHANG W S, XU Y L. Vibration analysis of two building linked by Maxwell model-defined fluid dampers[J]. Jottmal of Sound and Vibration, 2000, 233(5): 775-796.
5MCMANUS S J, ST CLAIR K A, BOILEAU P E. Evaluation of vibration and shock attenuation performance of a suspension seat with a semi-active magneto-theological fluid damper [J]. Jottmal of Sound and Vibration, 2002, 253(1): 313-327.
6LEE C T, MOON B Y. Simulation and experimental validation of vehicle dynamic characteristics for displacement-sensitive shock absorber using fluid-flow modeling [J]. Mechanical System and Signal Processing, 2006, 20(2): 373-378.
7MAKRIS N. Viscous heating of fluid dampers. I: small-amplitude motions[J]. Journal of Engineering Mechanics, 1998, 124(11): 1 210-1 216.
8MAKRIS N, ROUSSOS Y, WHITTAKER A, et al. Viscous heating of fluid dampers II: large-amplitude motions[J]. Journal of Engineering Mechanics, 1998, 124(11): 1 217 1 223.
9LANDAU L D, LIFSHITz E M. Fluid mechanics, course of theoretical physics [M]. 2nd edition. Beijing: Butterworth-Heinemarm, 1999.
10BLACK C J, MAKRIS N. Viscous heating of fluid dampers under small and large amplitude motions: experimental studies and parametric modeling [J]. Journal of Engineering Mechanics, 2007, 133(5): 566-577.

同被引文献21

1宋雪萍,马辉,毛国豪,闻邦椿.基于CHMM的旋转机械故障诊断技术[J].机械工程学报,2006,42(5):126-130. 被引量：12
2何玲,郑钢铁.流体阻尼器中粘性发热的反馈作用与热平衡研究[J].应用力学学报,2006,23(4):505-510. 被引量：2
3何永勇,印欣运,褚福磊.基于小波尺度谱的转子系统碰摩声发射特性[J].机械工程学报,2007,43(6):149-153. 被引量：17
4VAN D G,WEVERS M,VAN HULLE M M.Wavelet packet decomposition for the identification of corrosion type from acoustic emission signals[J].International Journal of Wavelets,Multiresolution and Information Processing,2009,7(4):513-534.
5KALOGIANNAKIS G,QUINTELIER J,DE BAETS P,et al.Identification of wear mechanisms of glass/polyester composites by means of acoustic emission[J].Wear,2008,264(3):235-244.
6DUNEGAN H L.Modal analysis of acoustic emission signals[J].Journal of Acoustic Emission,1998,15(1):1-4.
7KOTNIK B,VLAJ D,KACIC Z,et al.Robust MFCC feature extraction algorithm using efficient additive and convolutional noise reduction procedures[C]//ICSLP'02 Proceedings,Denver,USA,2002:455-448.
8KATZ M.Fractals and the analysis of waveforms[J].Comput.Biol.Med.,1988,18(3):145-156.
9ROSANA E,GEORGE V.A comparison of waveform fractal dimension algorithms[J].IEEE Transactions on Circuits and Systems,2001,48(2):177-183.
10REYNOLDS D A.Speaker identification and verification using Gaussian mixture speaker models[J].Speech Communication,1995,17(1):91-108.

引证文献2

1邓艾东,包永强,赵力.基于高斯混合模型的转子碰摩声发射识别方法[J].机械工程学报,2010,46(15):52-58. 被引量：7
2王杰,苟仲秋,赵寿根,张永,张柏楠,魏传峰.流体微振动隔振器的热振耦合特性研究[J].振动与冲击,2020,39(11):248-257.

二级引证文献7

1于洋,杨平,杨理践.基于小波变换与统计分析的转子碰摩声发射特性研究[J].振动与冲击,2013,32(9):130-134. 被引量：7
2周勃,陈长征,张宇,孟强.风力机叶片裂纹的动态扩展特性研究[J].中国机械工程,2013,24(8):1108-1113. 被引量：5
3李巍华,戴炳雄,张绍辉.基于小波包熵和高斯混合模型的轴承性能退化评估[J].振动与冲击,2013,32(21):35-40. 被引量：23
4卢绪祥,刘雨佳,唐晟锟,苏一鸣,吴家腾,李录平.滑动轴承声发射信号分形特征提取及故障诊断研究[J].湖南电力,2015,35(4):64-68. 被引量：2
5刘吉彪,程军圣,刘燕飞.基于LCD和GMM的滚动轴承寿命预测方法[J].现代制造工程,2016(7):120-124. 被引量：5
6刘吉彪,程军圣,刘燕飞.基于LCD和GMM-VPMCD混合模型的滚动轴承退化状态识别[J].机械强度,2016,38(6):1161-1166. 被引量：4
7杨勇,李晶,朱作付,邓艾东.基于模态理论和改进GMM的声发射源识别研究[J].电子器件,2024,47(1):128-133.

1José A.Moríigo,José Hermida Quesada.Analysis of Viscous Heating in a Micro-Rocket Flow and Performance[J].Journal of Thermal Science,2008,17(2):116-124. 被引量：1
2张华良,饶柱石,傅志方.Study on Theoretical Modeling of Semi-Active Electro-Rheological Fluid Damper[J].Journal of Shanghai University(English Edition),2003,7(3):275-279.
3Yu Junyi Zhang YongliangWang Maohua Zhou XiaoqinFaculty of Mechanical Scienceand Engineering,Jilin University,Changchun 130025, China.STUDY ON ELECTRORHEOLOGICAL FLUID DAMPER FOR APPLICATION IN MACHINING CHATTER CONTROL[J].Chinese Journal of Mechanical Engineering,2003,16(1):13-16. 被引量：5
4祝长生.A disc-type magneto-rheologic fluid damper[J].Journal of Zhejiang University Science,2003,4(5):514-519. 被引量：3

Chinese Journal of Mechanical Engineering

2008年第3期

浏览历史

内容加载中请稍等...

THEORY AND EXPERIMENT ON THE VISCOUS HEATING OF FLUID DAMPER UNDER SHOCK ENVIRONMENT 被引量：2

参考文献15

同被引文献21

引证文献2

二级引证文献7

相关作者

相关机构

相关主题

浏览历史