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

Issue:

2020年02期

Page:

64-70

Research Field:

研究与设计

Publishing date:

Info

Title:

Performance of high-speed centrifugal pump with different pre-positioned inducer

Author(s):

HUANG Xilong;  CHEN Wei;  WANG Wenting;  YAN Junfeng;  XU Kaifu

(Science and Technology on Liquid Rocket Engine Laboratory,Xi’an Aerospace Propulsion Institute, Xi’an 710100, China)

Keywords:

centrifugal pump;  high-speed;  splitter blade inducer;  variable pitch inducer

PACS:

V434.21

DOI:

-

Abstract:

To investigate the effect of splitter blade inducer and variable pitch inducer on the hydraulic performance and anti-cavitation performance of the centrifugal pump, experiment and numerical simulation were carried out for the high-speed centrifugal pump with pre-positioned inducer.External characteristics experiments reveal that pre-positioned splitter blade inducer or variable pitch inducer has little influence on the efficiency of a high-speed centrifugal pump.Compared with the pre-positioned variable pitch inducer, the head of the centrifugal pump with the pre-positioned splitter blade inducer is decreased significantly.The results of the cavitation experiments show that, under the small flow condition, the anti-cavitation performance of the centrifugal pump with pre-positioned splitter blade inducer is improved.Under the large flow condition, the anti-cavitation performance with a pre-positioned variable pitch inducer is improved, and they are similar under other conditions.The numerical simulation results show that, under the large flow condition, the head of the splitter blade inducer is lower observably, which cannot meet the inlet energy requirement of centrifugal impeller, so the anti-cavitation performance of the centrifugal pump with pre-positioned splitter blade inducer is deteriorated.

References:

[1] 颜子初.液体火箭发动机涡轮泵技术的发展[J].推进技术, 1991, 12(6):23-30.
[2] 陈晖, 张恩昭, 谭永华, 等.高速平板诱导轮的结构设计与分析[J].火箭推进, 2009, 35(3):1-5.CHEN H, ZHANG E Z, TAN Y H, et al.Geometry design and analysis of the high-speed rotational plate inducer[J].Journal of Rocket Propulsion, 2009,35(3):1-5.
[3] 赵瑞.高速诱导轮离心泵的数值模拟与试验研究[D].杭州:浙江理工大学, 2010.
[4] 程效锐, 符丽, 包文瑞.等螺距诱导轮的螺距变化对离心泵汽蚀性能的影响[J].兰州理工大学学报, 2018, 44(2):48-53.
[5] 杨从新, 刘洋.诱导轮叶片数对超高速泵性能影响的研究[J].甘肃科学学报, 2017, 29(5):147-152.
[6] HASHIMOTO T, YOSHIDA M, WATANABE M, et al.Experimental study on rotating cavitation of rocket propellant pump inducers[J].Journal of Propulsion and Power, 1997, 13(4):488-494.
[7] HASHIMOTO T, YAMADA H, FUNATSU S, et al.Rotating cavitation in three and four-bladed inducers[C]//33rd Joint Propulsion Conference and Exhibit.Seattle, WA, USA.Reston, Virigina:AIAA, 1997.
[8] KIMURA T, YOSHIDA Y, HASHIMOTO T, et al.Numerical simulation for vortex structure in a turbopump inducer:close relationship with appearance of cavitation instabilities[J].Journal of Fluids Engineering,2008,130(5):051104-1-051104-9.
[9] 宋沛原, 李家文, 唐飞.轮毂形状对诱导轮性能的影响[J].火箭推进, 2012, 38(2):38-43.SONG P Y, LI J W, TANG F.Effect of hub shape on performance of inducer[J].Journal of Rocket Propulsion, 2012,38(2):38-43.
[10] 郭晓梅, 朱祖超, 崔宝玲, 等.诱导轮长短叶片位置对高速离心泵汽蚀性能的影响[J].工程热物理学报, 2012, 33(10):1695-1698.
[11] 张召磊,张楠,窦唯等.基于正交试验的诱导轮前置孔板的参数化研究[J].工程热物理学报,2011,32(8):1319-1322.
[12] 李晓俊, 袁寿其, 潘中永, 等.诱导轮离心泵空化条件下扬程下降分析[J].农业机械学报, 2011, 42(9):89-93.
[13] 孔繁余, 黄建军, 吕毅, 等.离心泵变螺距诱导轮的开发[J].排灌机械, 2008, 26(3):10-14.
[14] 朱祖超, 王乐勤, 汪希萱.高速泵变螺距诱导轮的设计分析[J].农业机械学报, 1997, 28(4):102-104.
[15] 朱祖超,王乐勤.变螺距诱导轮结构设计与理论分析[J].浙江大学学报,1998,32(3):197-200.
[16] 颜子初.高性能螺旋轮设计的探讨[J].导弹与航天运载技术, 1998(5):12-20.
[17] 林慧超, 张玉良, 陈通励, 等.带分流叶片的变螺距诱导轮的设计与实验[J].石油化工设计, 2014, 31(4):35-37.
[18] 李永鹏, 陈晖, 王文廷, 等.多工况高抗汽蚀性能的诱导轮设计[J].排灌机械工程学报, 2014, 32(11):948-954.
[19] 张翠儒, 宋勇, 毋杰, 等.一种平板螺旋式诱导轮的扬程计算法[J].火箭推进, 2013, 39(5):51-54.ZHANG C R, SONG Y, WU J, et al.A calculation method of delivery lift of flat-plate helical inducer[J].Journal of Rocket Propulsion, 2013,39(5):51-54.
[20] 孙建, 孔繁余, 焦其斌.变螺距诱导轮的设计步骤及参数选择[J].流体机械, 2006, 34(4):19-22.
[21] 郭晓梅, 李昳, 崔宝玲, 等.前置不同诱导轮高速离心泵旋转空化特性研究[J].航空学报, 2013, 34(7):1572-1581.

Memo

Memo:

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Common functions

Last Update: 2020-04-25