叶片厚度对混流式核主泵叶轮能量性能影响研究Influence of Blade Thickness on Energy Performance of Mixed Flow Nuclear Main Pump
杨敏官,陆胜,高波,王达,王俊
YANG Min-guan,LU Sheng,GAO Bo,WANG Da,WANG Jun
摘要(Abstract):
基于三维不可压缩流体N-S方程和RNGκ-ε湍流模型,对混流式核主泵叶轮水力模型的能量性能进行了数值预测,研究了不同叶片厚度及其分布规律对混流叶轮模型水力性能的影响。通过分析叶轮叶片压力面、吸力面的静压分布,获得叶片表面的载荷分布及其变化规律。结果表明:随着叶轮叶片厚度减薄,最高效率值有所增大且高效点向大流量工况偏移;当叶片最厚处位置在靠近进口边约1/3处时,叶轮水力效率值最大;随着叶片最厚位置由进口向出口移动时,最高效率点向大流量工况偏移。
Based on the three dimensional incompressible Navier-Stokes equation and RNG κ- ε turbulent model,energy performance of mixed-flow nuclear main pump impeller hydraulic model was numerically predicted and the influence of the blade thickness and distribution of mixed-flow nuclear main pump impeller model on hydraulic performance was studied. Through analyzing the static pressure on impeller blade pressure surface and the suction side and the load distribution of mixed-flow pump impeller blade,the study revealed the main variation characteristics of the load on blade surface. The results show: with the impeller blade thickness being thin,the highest efficiency value gets increased and efficient points to offset heavy traffic conditions; When the thickest blade position locates at about 1 /3 part of imports edge,the values of impeller hydraulic efficiency is the highest; As the thickest blade's location moving from enter port to exit,the highest efficiency point offset to the heavy traffic conditions.
关键词(KeyWords):
核主泵;混流叶轮;水力性能;叶片厚度
nuclear main pump;mixed-flow impeller;hydraulic performance;blade thickness
基金项目(Foundation): 国家自然科学基金资助项目(51106066)
作者(Author):
杨敏官,陆胜,高波,王达,王俊
YANG Min-guan,LU Sheng,GAO Bo,WANG Da,WANG Jun
参考文献(References):
- [1]秦杰.核主泵过流部件水力设计与内部流场数值模拟[D].大连:大连理工大学,2010.
- [2]吴治将,赵万勇.混流泵内流场的数值模拟[J].流体机械,2005,33(10):20-24.
- [3]马希金,张化川,张克危.核电站三级循环给水混流泵的数值模拟与试验分析[J].流体机械,2009,37(9):6-9.
- [4]Jidong Li,Yongzhong Zeng.Optimum design on impeller blade of mixed-flow pump based on CFD[J].Procedia Engineering,2012,31:187-195.
- [5]KIM Jin-Hyuk,AHN Hyung-Jin.High-efficiency design of a mixed-flow pump[J].SCIENCE CHINA:Technological Sciences,2010,53(1):24-27.
- [6]常书平,王永生,苏永生.若干因素对导叶式混流泵水力性能的影响[J].排灌机械工程学报,2012,(6):646-649.
- [7]刘国辉.叶片厚度对混流泵性能的影响研究[J].船电技术,2013,33(2):26-29.
- [8]谢蓉,单玉姣,王晓放.混流泵叶轮流动性能数值模拟和叶型优化设计[J].排灌机械工程学报,2010,(4):295-299.
- [9]李靖,王晓放,周方明,等.非均布导叶对核主泵模型泵性能及压力脉动的影响[J].流体机械,2014,42(9):30-35.
- [10]刘建瑞,郑俊峰,付登鹏,等.混流泵径向间隙对内部非定常流场影响的分析[J].流体机械,2014,42(3):27-31.
- [11]朱瑞松.高温下螺栓-法兰-垫片系统密封性能研究[J].压力容器,2013,30(6):43-46.
- [12]黎义斌,李仁年,王秀勇,等.混流泵内部流动不稳定特性的数值模拟[J]排灌机械工程学报,2013,(5):22-27.
- [13]王福军.计算流体动力学分析[M].北京:清华大学出版社,2004:74-125.
- [14]吴达人,陈胜利.离心泵叶轮的载荷分布和性能关系的研究[J].农业机械学报,1988,(2):58-65.