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离心式燃油泵复合叶轮的数字化设计及验证
引用本文:潘潇,王文平,李述林,肖若富,潘常春. 离心式燃油泵复合叶轮的数字化设计及验证[J]. 上海交通大学学报, 2014, 48(8): 1164-1169
作者姓名:潘潇  王文平  李述林  肖若富  潘常春
作者单位:(1. 航空机电系统综合科技重点实验室, 南京 211106; 2. 中航工业金城南京机电液压工程研究中心, 南京 211106; 3. 中国农业大学 水利与土木工程学院, 北京 100083;4. 上海交通大学 自动化系, 系统控制与信息处理教育部重点实验室, 上海 200240)
基金项目:国家自然科学基金资助项目(61203178,61304214)
摘    要:针对现有加油系统的燃油泵不足,采用复合长短叶轮对原有燃油泵进行改进.首先,采用数值模拟方法进行多次迭代设计,得到水力性能最优的复合叶轮模型.其次,对该模型进行了三维流场的数值模拟,分析其内部流动特性与外特性曲线.最后,根据优化设计结果生产试件,并进行试验验证.通过对比复合叶轮和原有叶轮的仿真及试验结果可知,复合叶轮的效率和扬程都高于普通形式的叶轮,特别是有效改善了小流量工况的稳定性,其有效运行区间由原先的1.3倍变流量工况增大到2倍变流量工况.该研究为其他航空高速宽工作区间燃油泵的优化设计提供了参考.

关 键 词:复合叶轮   燃油泵   数值模拟   性能优化  
收稿时间:2013-11-20

Digital Design and Validation of Fuel Pump with Complex Centrifugal Impeller
PAN Xiao;WANG Wen-ping;LI Shu-lin;XIAO Ruo-fu;PAN Chang-chun. Digital Design and Validation of Fuel Pump with Complex Centrifugal Impeller[J]. Journal of Shanghai Jiaotong University, 2014, 48(8): 1164-1169
Authors:PAN Xiao  WANG Wen-ping  LI Shu-lin  XIAO Ruo-fu  PAN Chang-chun
Affiliation:(1. Aviation Key Laboratory of Science and Technology on Aero Electromechanical System Integration,Nanjing 211106, China; 2. Nanjing Engineering Institute of Aircraft Systems, Jincheng, Aviation Industry Corporation of China, Nanjing 211106, China; 3. College of Water  Conservancy and Civil Engineering, China Agricultural University, Beijing 100083, China;4. Department of Automation, Shanghai Jiaotong University, Shanghai 200240, China)
Abstract:In order to meet the needs of the next generation refueling system , an optimizaed hydraulic model of a particular centrifugal fuel pump was developed with spiltter blade. First, the complex impeller model with best hydraulic performance was redesigned by using the CFD(computational fluid dynamics) method iteratively. Then, the full three dimensional numerical simulation was applied to the resulting model. The analysis of the internal flow shows that the splitter blade can depress the vortexes effectively. Based on optimization results, specimen products were made and tests were performed to verify the design. The comparison of test data and simulation results show that the performance of the optimized pump is superior to that of the current one. The complex impeller can improve instability of centrifugal pump at small flow and widen its range of working condition from 1.3 to 2 times of the design flow rate condition. The results of this paper can provide technical support for designing better fuel pumps for other applications.
Keywords:complex impeller  fuel pump  numerical simulation  performance optimization  
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