Yifan Xuan, Guojun Zhu, Xingqi Luo, Zhenbo Tang, Yang Wang
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引用次数: 0
Abstract
The rotating speed conversion strategy has a significant impact on the stability of the variable speed operation of the mixed flow pump. Taking a mixed-flow pump as the research object, this paper collects the shaft vibration, pressure pulsation, and external characteristic parameters under different conversion times based on the synchronous acquisition system, and analyzes the influence of conversion time on these parameters. Finally, based on the improved TOPSIS evaluation method, the influence of different conversion time on the stability of the mixed-flow pump is evaluated. The results indicate that the conversion time is positively correlated with the amplitude of shaft vibration and pressure pulsation in the pump during the transition of rotating speed reduction. The local rubbing of the shaft can induce the vibration component corresponding to the high harmonics frequencies such as 2 f n, 3 f n, and 4 f n. The high correlation frequency band of the impeller outlet pressure pulsation and shaft vibration is located between 64 Hz and 120 Hz. And this frequency band is not affected by the conversion time. According to the TOPSIS evaluation results, in the transition process of speed reduction, the longer the rotating speed conversion time, the worse the stability of the mixed-flow pump during the conversion process.
转速转换策略对混流泵变速运行的稳定性有重要影响。本文以混流泵为研究对象,基于同步采集系统采集了不同转换时间下的轴振动、压力脉动和外部特性参数,并分析了转换时间对这些参数的影响。最后,基于改进的 TOPSIS 评价方法,评价了不同转换时间对混流泵稳定性的影响。结果表明,在转速降低的过渡阶段,转换时间与泵的轴振动幅度和压力脉动呈正相关。轴的局部摩擦会引起与 2 f n、3 f n 和 4 f n 等高次谐波频率相对应的振动分量。叶轮出口压力脉动与轴振动的高相关频段位于 64 Hz 至 120 Hz 之间。该频段不受转换时间的影响。根据 TOPSIS 评估结果,在降速过渡过程中,转速转换时间越长,混流泵在转换过程中的稳定性越差。
期刊介绍:
The Journal of Vibration and Control is a peer-reviewed journal of analytical, computational and experimental studies of vibration phenomena and their control. The scope encompasses all linear and nonlinear vibration phenomena and covers topics such as: vibration and control of structures and machinery, signal analysis, aeroelasticity, neural networks, structural control and acoustics, noise and noise control, waves in solids and fluids and shock waves.