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

Issue:

2015年05期

Page:

29-33

Research Field:

研究与设计

Publishing date:

Info

Title:

Analysis on characteristics of self-excited cavitation oscillation in pump-piping system

Author(s):

YAN Junfeng;  CHEN Hui;  LU Wanruo

Xi’an Aerospace Propulsion Institute, Xi’an 710100, China

Keywords:

centrifugal pump;  piping system;  self-excited cavitation oscillation;  dynamic characteristic;  limit cycle

PACS:

V434-34

DOI:

-

Abstract:

The low frequency oscillation of inlet pressure and outlet pressure occurred in an inducer-centrifugal pump test when flow in the pump was small, which contrasts with the frequency characteristics of high speed centrifugal pump. This indicates that the self-excited oscillation occurs in the pump-piping system. When the pump is operating at off-design conditions, the backflow zone intensively interacting with main flow zone may appear. This backflow is rotated with the inducer, which will decrease the static pressure of the mainstream liquid and result in a periodical change of the physalides volume, and then the self-excited cavitation oscillation occurs. In order to analyze the characteristics of the self-excited cavitation oscillation, a novel cavitation dynamic model is presented to simulate the dynamic characteristic to capture the oscillation frequency in the pump-piping system, the dynamic characteristics of inlet pressure and flow rate, and the limit cycle of flow rate versus inlet pressure. The results of numerical experiments indicate that the calculated characteristics of self-excited cavitation oscillation is consistent with experimental result, this cavitation self-excited mathematic model is suitable to simulate the characteristics of the self-excited cavitation oscillation. The oscillation frequency increases with decrease of the pump speed and the length of inlet piping, while the oscillation frequency decreases with decrease of the inlet pressure and the flow rate.

References:

[1]严俊峰, 陈炜.基于遗传算法的低比转速高速泵优化设计[J].火箭推进, 2006, 32(3): 1-7. YAN Junfeng, CHEN Wei. Optimum design of low- specific-speed high speed centrifugal pump based on genetic algorithm[J]. Journal of Rocket Propulsion, 2006, 32(3):1-7.
[2]BRENNEN C E. Hydrodynamics of pumps[M]. Califor- nia: California Institute of Technology, 1994.
[3]ПИЛИПЕНКО В В. КΑΒИТАЦИОННЫЕ АВТОКО- ЛЕБАНИЯ [M]. КИЕВ: Наукова Думка, 1989.
[4]RAPPOSELLI E, CERVONE A, DAGOSTINO L. A new cavitating pump rotordynamic test facility, AIAA 2002- 4285[R]. Reston, USA: AIAA, 2002.

[5]程勉. 非线性振动[M]. 北京: 北京航空学院出版社, 1984.

[6]靳治礼. 低比转速泵的设计研究[J]. 水泵技术, 1985(3):1-7.
[7]刘占生, 张云峰, 田新. 冲压发动机超声速进气道流动自激振荡研究[J]. 航空动力学报, 2008, 12(9): 49-56.
[8]孙建.低汽蚀余量泵诱导轮的研究[D]. 镇江: 江苏大学, 2006.
[9]YANG M G, SUN X K, GAO B, et al. Numerical analysis of unsteady cavitating flow characteristic in centrifugal pump[J]. Journal of Jiangsu University (Natural Science Edition), 2012, 33(4): 408-413.

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