Unsteady flow and excitation characteristics in a vortex pump

IF 2.3 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Xianfang Wu , Chen Shao , Minggao Tan , Houlin Liu , Runan Hua , Honggang Li
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Abstract

The impeller in vortex pumps is installed at the side of the volute, which causes the flow instability and vibration. This study employs the Renormalization Group k-epsilon (RNG k-ε) turbulence model to investigate the unsteady flow and excitation characteristics within a vortex pump under various flow rates. The results show that increasing the flow rate reduces the low-pressure area in the vaneless chamber, with flow instability primarily occurring in the middle of the vaneless chamber and intensifying with higher flow rate. Pressure pulsation within the vaneless chamber at nominal flow rate is driven by periodic changes in the vortex structure, occurring at approximately twice the shaft frequency (96Hz). As the impeller rotates, pulsation energy propagates from the vaneless chamber to the tongue and outlet. With increasing flow rates, variations of inlet axial flow velocity cause the rise in pressure pulsation in the vaneless chamber. At high flow rate, pressure pulsation in the vaneless chamber increases tenfold compared to low flow rate. The pressure pulsation at the tongue is significantly smaller than that in the vaneless chamber. The rise in pressure pulsation with increasing flow rates is attributed to the displacement of the circulation flow position towards the tongue.
旋涡泵中的非稳态流动和激励特性
旋涡泵的叶轮安装在涡槽的一侧,这就造成了流动的不稳定性和振动。本研究采用归一化组 k-epsilon (RNG k-ε) 湍流模型研究了不同流速下旋涡泵内的不稳定流动和激振特性。结果表明,增加流速会减小无蜗壳腔内的低压区,流动不稳定性主要发生在无蜗壳腔中部,并随着流速的增加而加剧。在额定流量下,无叶片腔内的压力脉动是由涡流结构的周期性变化驱动的,发生频率约为轴频率的两倍(96Hz)。随着叶轮的旋转,脉动能量从无叶片腔传播到叶舌和出口。随着流量的增加,入口轴向流速的变化会导致无叶室内压力脉动的上升。在高流速下,无阀腔内的压力脉动比低流速下增加了十倍。舌部的压力脉动明显小于无阀腔的压力脉动。随着流速的增加,压力脉动也随之增加,这是因为循环流向舌部的位置发生了位移。
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来源期刊
Flow Measurement and Instrumentation
Flow Measurement and Instrumentation 工程技术-工程:机械
CiteScore
4.30
自引率
13.60%
发文量
123
审稿时长
6 months
期刊介绍: Flow Measurement and Instrumentation is dedicated to disseminating the latest research results on all aspects of flow measurement, in both closed conduits and open channels. The design of flow measurement systems involves a wide variety of multidisciplinary activities including modelling the flow sensor, the fluid flow and the sensor/fluid interactions through the use of computation techniques; the development of advanced transducer systems and their associated signal processing and the laboratory and field assessment of the overall system under ideal and disturbed conditions. FMI is the essential forum for critical information exchange, and contributions are particularly encouraged in the following areas of interest: Modelling: the application of mathematical and computational modelling to the interaction of fluid dynamics with flowmeters, including flowmeter behaviour, improved flowmeter design and installation problems. Application of CAD/CAE techniques to flowmeter modelling are eligible. Design and development: the detailed design of the flowmeter head and/or signal processing aspects of novel flowmeters. Emphasis is given to papers identifying new sensor configurations, multisensor flow measurement systems, non-intrusive flow metering techniques and the application of microelectronic techniques in smart or intelligent systems. Calibration techniques: including descriptions of new or existing calibration facilities and techniques, calibration data from different flowmeter types, and calibration intercomparison data from different laboratories. Installation effect data: dealing with the effects of non-ideal flow conditions on flowmeters. Papers combining a theoretical understanding of flowmeter behaviour with experimental work are particularly welcome.
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