Experimental study of the effect of blade tip clearance and blade angle error on the performance of mixed-flow pump 被引量：13

Experimental study of the effect of blade tip clearance and blade angle error on the performance of mixed-flow pump

导出

摘要 The hydraulic performance test of the mixed-flow pump has been carried out through selecting different blade tip clearances and various blade angle errors.The ratio of the mixed-flow pump efficiency reduction and the blade tip clearance variation(η/δ) varies with the flow rate coefficient revealing a parabolic trend.An empirical equation has been developed for the mixed-flow pump model by parabolic fitting.For the same blade tip clearance variation δ,the mixed-flow pump efficiency reduction η increases rapidly as the flow rate rises.For any given flow rate,the efficiency,the head and the shaft power of the mixed-flow pump all decrease with the increase of the blade tip clearance.Among them,the efficiency reduction η varies approximately linearly with the blade tip clearance variation δ.When the angle of an individual blade of the mixed-flow pump has a deviation,the performance curves will move and change.These curves have consistent change directions with the performance curves under the condition of all the blades rotated at the same time,but have smaller offset and lower range of variation.When an individual blade angle error changes to ±2°,the optimal efficiency of the mixed-flow pump will have no significant difference.When the individual blade angle error increases to ±4°,the optimal efficiency will decrease by 1%.

作者 BING Hao CAO ShuLiang HE ChengLian LU Li

机构地区 State Key Laboratory of Hydroscience and Engineering Beifang Investigation Hydraulic Machinery Department

出处《Science China(Technological Sciences)》 SCIE EI CAS 2013年第2期293-298,共6页 中国科学（技术科学英文版）

基金 supported by the National Natural Science Foundation of China (Grant No. 51176088)

关键词 mixed-flow pump model test hydraulic performance blade tip clearance blade angle 叶尖间隙角度误差混流泵性能测试叶片实验性能曲线刀片式服务器

分类号 TH313 [机械工程—机械制造及自动化]

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