|Table of Contents|

Research progress of flow-induced vibration of bellows(PDF)

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:
2014年02期
Page:
16-21
Research Field:
专论与综述
Publishing date:

Info

Title:
Research progress of flow-induced vibration of bellows
Author(s):
YAN Song1 TAN Yong-hua2 CHEN Jian-hua1
1. Xi’an Aerospace Propulsion Institute, Xi’an 710100, China; 2. Academy of Aerospace Propulsion Technology, Xi’an 710100, China
Keywords:
bellows fluid-induced vibration vortex shedding whistling
PACS:
V434-34
DOI:
-
Abstract:
Fatigue failure of bellows occurs quite often when they carry fluids at high speed. Fluid-induced vibration is one of the important factors of the fatigue failure. In China, there is less research on this problem at present. The relevant research achievements abroad are summarized in this paper. The mechanism of flow-induced vibration is introduced. The liquid-induced vibration of bellows belongs to the vortex shedding induced vibration, while the gas-induced vibration of bellows belongs to acoustic and elastic coupling vibration. The vibration suppression measures are proposed in this paper on the basis of the research achievements.

References:

[1]ECKARD T D. Liquid rocket lines, bellows, flexible hoses, and filters, NASA-SP-8123[R]. USA: NASA, 1978.
[2]GERLACH C R. Study of minimum pressure loss in high velocity duct systems, NASA-CR-91525[R]. USA: NASA, 1967.
[3]GERLACH C R. Flow-induced vibrations of metal bellows, ASME PAPER 69-VIBR-5[R]. USA: ASME, 1969.
[4]GERLACH C R, SCHROEDER E C. Study of minimum pressure loss in high velocity duct systems, NASA-CR- 102499[R]. USA: NASA, 1970.
[5]BASS R L, HOLSTER J L. Bellows vibration with internal cryogenic fluid flows, ASME PAPER 71-VIBR-14[R]. USA: ASME, 1971.
[6]GERLACH C R. Vortex excitation of metal bellows, ASME PAPER 71-VIBR-22[R]. USA: ASME, 1971.
[7]MARRIS A W. A review of vortex streets, periodic wakes, and induced vibration phenomena[J]. Journal of Basic Engineering, 1964 (86): 165-196.
[8]DANIEL C M, FARGO C G. Fatigue failure in metal bellows due to flow-induced vibrations, MFS-18383[R]. USA: NASA, 1969.
[9]SACK L E, NELSON R L, MASON D R, et al. Prediction of flow-induced failure of braided hoses and bellows, MFS-19004[R], USA: NASA, 1972.
[10]罗宏瀚. 借助有限元分析对输流波纹管元件的减振研究[J]. 矿山机械, 2008, 36(3): 52-56.
[11]GOYDER H. On the modeling of noise generation in corrugated pipes[J]. Journal of Pressure Vessel Techno- logy, 2010 (132): 1-7.
[12]DEBUT V, ANTUNES J, MOREIRA M. Experimental study of the flow-excited acoustical lock-in in a corrugated pipe[C]// Proceedings of 14th International Con- gress on Sound Vibration. Cairns, Australia: ICSV, 2007: 123-133.
[13]KRISTIANSEN U R, MATTEI P, PINHDE C, et al. Measurements on tones generated in a corrugated flow pipe with special attention to the influence of a low frequency oscillation[C]// 34th Scandinavian Symposium on Physical Acoustics. Geilo, Norway: [s.n.], 2011: 1-7.
[14]BELFROID S P C, SHATTO D P, PETERS R M C A M. Flow induced pulsations caused by corrugated tubes [C]// 2007 ASME Pressure Vessels and Piping Division Conference. San Antonio, Texas: ASME, 2007:1-9.
[15]CADWELL L H. Singing corrugated pipes revisited[J]. American Journal of Physics, 1994, 62(3): 224-227.
[16]CERMARK P. On the sound generation in flexible metal hoses with spiraling grooves[J]. Phys Z, 1922 (23): 394-397.
[17]GOLLIARD J, TONON D, BELFROID S. Experimental investigation of the source locations for whistling short corrugated pipes[C]//Proceedings of the ASME 2010 3rd Joint US-European Fluids Engineering Summer Meeting and 8th International Conference on Nanochannels, Microchannels, and Minichannels. Montreal, Canada: ASME, 2010: 11-20.
[18]KRISTIANSEN U R, WIIK G A. Experiments on sound generation in corrugated pipes with flow[J]. J Acoust Soc Am, 2007, 121 (3): 1337-1344.
[19]NAKAMURA Y, FUKAMACHI N. Sound generation in corrugated tubes [J]. Fluid Dyn Res, 1991 (7): 255-261.
[20]WEAVE D S, AINSWORTH P. Flow induced vibration in bellows[C]// International Symposium on Flow-induced Vibration and Noise. Chicago:[s.n.], 1998: 205-214.
[21]KOP'EV V F, MIRONOV M A, SOLNTSEVA V S. Sound generation, amplification and absorption by air flow through waveguide with periodically corrugated boundary [C]// Forum Acoustic 2005 Conference. [S.l.]: [s.n.], 2005: 111-114.
[22]DEBUT V, ANTUNES J, MOREIRA J. Flow-acoustic interaction in corrugated pipes: time-domain simulation of experimental phenomena[C]// 9th International Conference on Flow-Induced Vibration. Prague: Czech Republic, 2008: 113-123.
[23]POPESCU M, JOHANSEN S, SHYY W. A Model for flow-induced acoustics in corrugated pipes[C]// 47th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition. Orlando, Florida: AIAA, 2009: 1-14.
[24]TONON D, LANDRY B J T, BELFROID S P C, et al. Whistling of a pipe system with multiple side branches: Comparison with corrugated pipes[J]. Journal of Sound and Vibration, 2010 (329): 1007-1024.
[25]POPESCU M, JOHANSEN S, SHYY W. Flow-induced acoustics in corrugated pipes[J]. Commun Comput Phys, 2011, 10(1):120-139.
[26]POPESCU M, JOHANSEN S. Acoustic wave propagation in low Mach flow pipe, AIAA2008-0063[R]. USA: AIAA, 2008.

Memo

Memo:
-
Last Update: 1900-01-01