箱涵式进水流道的立式轴流泵装置水动力特性分析

    Analysis of hydraulic performance for vertical axial-flow pumping system with cube-type inlet passage

    • 摘要: 为了研究有涡时箱涵式进水流道的立式轴流泵装置水动力性能,该文采用CFD(computational fluid dynamic)和高速摄影技术对箱涵式进水流道的立式轴流泵装置进水流道内部附底涡流动特征及其对泵装置水动力性能的影响进行了分析。数值模拟和试验结果表明,基于CFD数值模拟技术,成功捕捉到各工况时箱涵式进水流道内部附底涡轨迹,与高速摄影捕捉到附底涡的运动轨迹较为一致,且均发生于喇叭管口下方,附底涡对泵装置的安全运行稳定性有直接影响。有、无消涡锥的箱涵式进水流道出口断面的轴向速度分布均匀度与速度加权平均角的差异性较小,但其水力损失值下降较大;叶轮所受轴向力相对比值m1在0~7.0%范围内波动,轴向力随流量系数的增大而减小,附底涡对叶轮所受径向力的影响较大,径向力相对比值m2在5.0%~110.0%范围内波动,涡带对叶轮受力有一定程度的影响,实际工程中应避免箱涵式进水流道内部涡带的出现。

       

      Abstract: Abstract: In order to better understand the effect of a submerged vortex on the hydraulic performance of a vertical axial-flow pumping system and the trajectory characteristics of a submerged vortex, a vertical axial-flow pumping system with a cube-type inlet passage was chosen as the research object, and CFD (computational fluid dynamic) technology and high-speed photography technology were used. The flow patterns in the cube-type inlet passage, calculated by a numerical simulation of CFD, can be classified into three types: the straight line adjustment stage, a flare tube contraction, and a flare tube adjustment pattern. The second and third stages of the flow pattern are especially important in the cube-type inlet passage. A submerged vortex occurs in the flare tube contraction stage under different conditions. A submerged vortex trajectory of an inlet passage was captured successfully based on a numerical simulation in different operating conditions, which was basically the same as the experimental results. A submerged vortex occurs first in the bottom of inlet passage, and then it flows into the flare tube. When a submerged vortex flows from the bottom of an inlet passage into the inlet of a flare tube, the position of maximum vorticity is closer to the center point of the bell-mouth than the initial position. A submerged vortex trajectory is oscillating. If it flows into the impeller chamber, it will affect the safe operation stability of the pumping system and the hydraulic efficiency of the pumping system. With the increase of flow coefficient KQ, the maximum vorticity magnitude of every measuring line increases gradually, and the increased amplitude of maximum vorticity magnitude decreases gradually. In the flow coefficient KQ range from 0.30-0.62, the hydraulic loss of an inlet passage with an anti-submerged vortex device (AVD) decreases, the maximum difference is 0.50 cm, the minimum difference is 0.34 cm. The uniformity of axial velocity distribution improves by 0.77%, the velocity-weighted average swirl angle improves by 0.22° for the outlet section of inlet passage, compared with the inlet passage without AVD. There is a little difference between the hydraulic performance of inlet passage with and without ADV, except for hydraulic loss. The variation range of the relative ratio value of the axial force is 0-7.0%, and the axial force decreases gradually with the increase of flow coefficient KQ. The variation range of the relative ratio value of radial force is 5.0%-110.0%, and the submerged vortex has a great influence on the radial force of the impeller. The submerged vortex should be suppressed by AVD installation on the bottom of an inlet passage for a pumping system.

       

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