CAJ | 학술논문

为了研究导叶时序效应对离心泵性能的影响，采用CFD方法对设计流量工况下导叶不同时序位置时离心泵内部流动进行了数值计算，定义导叶叶片尾缘与隔舌夹角为0时为时序位置0，每增加10°增加一个时序位置。得到了泵内外特性随时序位置不同的变化规律，并分析了不同时序位置对隔舌处压力脉动及叶轮径向力非定常特性的影响。结果表明：随着导叶时序位置的增加，泵扬程和效率呈先上升后下降的趋势，导叶与隔舌相对位置在20°时达到最大值，扬程较最低值提高0.6 m；时序效应对隔舌处1倍和2倍叶片通过频率影响最大，且随时序位置的增加，主频和压力脉动幅值呈先减小后增加的趋势，时序位置1时幅值为4时的70%；导叶时序位置的改变主要影响泵底座-出口方向叶轮径向力分量。研究结果为离心泵径向导叶设计提供参考。
위료연구도협시서효응대리심빙성능적영향，채용CFD방법대설계류량공황하도협불동시서위치시리심빙내부류동진행료수치계산，정의도협협편미연여격설협각위0시위시서위치0，매증가10°증가일개시서위치。득도료빙내외특성수시서위치불동적변화규률，병분석료불동시서위치대격설처압력맥동급협륜경향력비정상특성적영향。결과표명：수착도협시서위치적증가，빙양정화효솔정선상승후하강적추세，도협여격설상대위치재20°시체도최대치，양정교최저치제고0.6 m；시서효응대격설처1배화2배협편통과빈솔영향최대，차수시서위치적증가，주빈화압력맥동폭치정선감소후증가적추세，시서위치1시폭치위4시적70%；도협시서위치적개변주요영향빙저좌-출구방향협륜경향력분량。연구결과위리심빙경향도협설계제공삼고。
In order to study the influence of clocking effect on the centrifugal pump, the CFD method was applied to simulate the inner flow in the centrifugal pump at its design flow rate under different guide vane clocking positions. The centrifugal pump mainly consisted of volute, guide vane and impeller. The physical model was made of transparent organic glass. The clocking positions were changed by changing the circumferential connection between guide vane and volute. First, we defined the position at which the angle between guide vane blade trailing edge and volute tongue was 0° as Clocking0, and the clocking position number increases by 1 every increase of 10° clockwise. The calculation result at Clocking1 position was compared with its experimental value. The experiment was conducted in a closed test platform. The pump head and efficiency error between experimental and calculated results were less than 3%, which indicated the CFD calculation method predicted the performance of centrifugal pump relatively well such that it can be used for predicting the characteristics of other clocking positions. The external characteristics and internal flow features variations of the pump versus clocking positions were obtained. The pressure fluctuation at the tongue region and the radial hydraulic force on the impeller at different clocking positions were analyzed as well. The results indicated that with the increase of clocking position, the pump head and efficiency increased and then decreased, reaching the maximum value near Clocking2. The minimum value of pump head and efficiency was at Clocking0. The pump head at Clocking2 was 0.6m greater than that of Clocking0, and the efficiency was about 5% greater. The average relative pressure differences on each cross section of pump volute were analyzed, which indicated that the pressure variations were within 20%with the increase of clocking positions. The analysis on frequency fluctuations and frequency spectra of pressure fluctuations at locations around tongue for different clocking positions revealed that clocking effect mainly affected one and two times the blade passing frequency at the tongue region. When the clocking position number increased, both the dominant frequency and the amplitude of the pressure fluctuation increased and then decreased. The minimum value of the pressure fluctuation amplitude was at Clocking1, the maximum value of pressure fluctuation amplitude was at Clocking4, and the minimum value was 70%of the maximum. In addition, the structures of pressure fluctuation translate periodically with the sequence of clocking positions. The analysis of unsteady radial hydraulic force on the impeller showed that with increasing clocking position, the value of radial hydraulic force first decreased and then increased, the maximum value was at Clocking4, and the minimum was at Clocking1. The study demonstrates that the guide vane clocking position has the very important impact on centrifugal pump and it provides a reference for the guide vane design in centrifugal pumps.