«Previous Article|Table of Contents|Next Article»

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

Issue:

2023年05期

Page:

73-80

Research Field:

目次

Publishing date:

Info

Title:

Multi-parameter hydraulic optimization of inducer based on response surface method

Author(s):

HUANG Xilong;  YANG Baofeng;  YAN Junfeng;  LI Chunle;  XU Kaifu

(Xi'an Aerospace Propulsion Institute, Xi'an 710100, China)

Keywords:

inducer;  multi-parameter;  response surface method;  penalty function method;  hydraulic optimization

PACS:

V434.21

DOI:

-

Abstract:

In order to improve the hydraulic performance of prepressurizing turbopumps, the multi-parameter hydraulic optimization of the inducer was carried out by the response surface method. Six inducer's structural parameters including blade inclination angle, inlet blade angle, outlet blade angle, axial position of splitting vanes, inlet and outlet hub diameters were selected as influencing factors. 78 sets of inducer schemes were designed according to the principle of central composite inscribed design. The head and efficiency of 78 sets of inducers were obtained by numerical simulation. The effects of influence factors on the head and efficiency of inducers were obtained by range analysis of calculation results. The results show that outlet blade angle and outlet hub diameter have more influence on the head of the inducer. Axial position of splitting vanes and inlet hub diameter have little influence on the head. Inlet blade angle has the greatest influence on the efficiency of inducer. Outlet hub diameter has the least influence on the efficiency. The response surface models of head coefficient and efficiency were obtained respectively by linear regression. With the efficiency greater than 60% as the constraint condition, the penalty function method was used to optimize the head of inducer. The results show that the head of the optimized inducer is improved by 15.4%.

References:

[1] 廖懂华,林奇燕,叶小明.预压涡轮泵轴流式液力涡轮的流动结构研究[J].导弹与航天运载技术,2018(6):49-54.
[2] 袁伟为,王晓锋,张聃,等.液体火箭发动机预压泵性能优化研究[C]//陕西省宇航学会2018年学术交流会.汉中:陕西省宇航学会,2018.
[3] 陈聿晨,安阳,沈文金.220吨补燃循环发动机氢预压泵诱导轮技术方案研究[C]//第二届中国空天推进技术论坛.西宁:[s.n.],2019.
[4] 王伟,施卫东,蒋小平,等.基于正交试验及 CFD 的多级离心泵叶轮优化设计[J].排灌机械工程学报,2016,34(3):191-197.
[5] 冷洪飞,郝开元.基于权矩阵分析法的微型离心泵多目标正交优化设计[J].流体机械,2018,46(5):35-39.
[6] 童哲铭,陈尧,童水光,等.基于NSGA-Ⅲ算法的低比转速离心泵多目标优化设计[J].中国机械工程,2020,31(18):2239-2246.
[7] 方杰,朱荣生,王秀礼,等.基于二次回归正交组合设计低比转速离心泵叶轮的优化设计[J].水泵技术,2019(1):14-20.
[8] 李惠敏,李向阳,蒋建园,等.诱导轮出口参数对高速离心泵性能的影响[J].火箭推进,2020,46(1):69-75.
LI H M,LI X Y,JIANG J Y,et al.Influence of outlet parameters of inducer on performance of high speed centrifugal pump[J].Journal of Rocket Propulsion,2020,46(1):69-75.
[9] 张亚太,陈晖,项乐,等.基于正交优化设计的诱导轮空化性能研究[J].推进技术,2020,41(2):343-352.
[10] 余璐,张皓晨,陈晖,等.考虑空化不稳定性的诱导轮水力正交优化设计[C]//2018年工程热物理学会西安年会.西安:中国工程热物理学会,2018.
[11] 黄锡龙,陈炜,王文廷,等.前置不同诱导轮的高速离心泵性能[J].火箭推进,2020,46(2):64-70.
HUANG X L,CHEN W,WANG W T,et al.Performance of high-speed centrifugal pump with different pre-positioned inducer[J].Journal of Rocket Propulsion,2020,46(2):64-70.
[12] DERAKHSHAN S,MOHAMMADI B,NOURBAKHSH A.Efficiency improvement of centrifugal reverse pumps[J].Journal of Fluids Engineering,2009,131(2):1-9.
[13] BELLARY S A I,HUSAIN A,SAMAD A.Effectiveness of meta-models for multi-objective optimization of centrifugal impeller[J].Journal of Mechanical Science and Technology,2014,28(12):4947-4957.
[14] PARK H S,MIAO F.Simulation and modeling methodologies,technologies and applications[EB/OL].https://link.springer.com/book/10.1007/978-3-319-11457-6,2015.
[15] 袁寿其,王文杰,裴吉,等.低比转数离心泵的多目标优化设计[J].农业工程学报,2015,31(5):46-52.
[16] 薛城,祝宝山,刘小兵,等.基于叶片载荷分布的离心泵正交优化设计[J].工程热物理学报,2019,40(5):1065-1071.
[17] 张人会,樊家成,杨军虎,等.基于自由曲面变形方法的离心泵叶片载荷优化[J].农业机械学报,2015,46(10):38-43.
[18] 张德胜,梅剑,赵睿杰,等.基于响应曲面法的氟塑料两相流泵优化设计[J].排灌机械工程学报,2020,38(9):898-903.
[19] ZHANG X D,YU S M,GONG Y,et al.Optimization design for turbodrill blades based on response surface method[J].Advances in Mechanical Engineering,2016,8(2):168781401562483.
[20] 方俊涛.响应曲面方法中试验设计与模型估计的比较研究[D].天津:天津大学,2011.
[21] 熊俊涛,乔志德.基于响应面法的跨声速翼型气动优化设计[J].实验流体力学,2005,19(1):104-108.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01