Analysis of Flow Instabilities on a Three-Bladed Axial Inducer in Fixed and Rotating Frames

Pace, Giovanni; Valentini, Dario; Pasini, Angelo; Hadavandi, Ruzbeh; d’Agostino, Luca

doi:10.1115/1.4041731

Cited by 15 publications

(7 citation statements)

References 27 publications

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“…Therefore, the GFQ200-500 inducer with three blades can work normally at the designed flow value when it is matched with the pump. A comprehensive literature study about the pressure sensor location and pressure measurement method had been conducted, The outlet pressure sensor located about 1.5 times diameter downstream of the blade trailing edges 25 , while it located about one diameter downstream of the blade trailing edges 26 . Although the right pressure sensor location and pressure measurement method had been selected, 33 the inducer outlet whirl disturbed the pressure distribution of outlet pipe and enlarged the uncertainly of measurements.…”

Section: Resultsmentioning

confidence: 99%

“…The inlet pressure sensor located in 4 D t (which D t is tip diameter of inducer) upstream of the inducer blade leading edge, the outlet pressure sensor located in 2 D t downstream of the inducer blade trailing edge. 25,26,33 The pressure measuring method utilizes measurement points located on the circumference of the experimental pipe to attain accurate data, and the error associated with the head is ±1.5%. A control system software is used to obtain data on the rotating speed, torque, flow rate, and pressure, which is followed by calculating and exporting the results of shaft power and head.…”

Section: Experimental Facilitiesmentioning

confidence: 99%

“…An experiment was conducted at the fluid machinery test platform in Jiangsu University, Zhenjiang, China. 31–33 Considering the validation costs (the size of designed pump is very bigger) and particularity of submersible pump, 24–26,30 an independent experimental system of a high-speed inducer with great flow rate was built, and the cavitation performance was analyzed using high-speed photography. Moreover, hydraulic and cavitation curves were obtained, different cavitation development stages were classified, and distribution of the cavitation bubbles was analyzed.…”

Section: Introductionmentioning

confidence: 99%

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Experimental investigation of cavitation characteristics for a high-speed inducer with a great flow rate

Zhang

Xia

Kong

et al. 2022

Advances in Mechanical Engineering

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Cavitation performance is a key parameter for a mine high-speed rescue pump, which reduces the stability and reliability of the entire unit. In this study, an experimental method was used to investigate the cavitation characteristics of an inducer installed on the impeller upstream. Hydraulic performance without cavitation was determined along with the cavitation performance, and a visualization experiment was implemented. The inducer head slightly decreased when the cavitation number started to decline; however, it dropped significantly thereafter. At 4200 r/min, anti-cavitation ability of the inducer had no connection with the blade numbers. The anti-cavitation performance of the inducer with three blades was superior than that of the inducer with two blades. The law governing shaft power, cavitation number, and rotating speed disagreed with the similarity law theory. Moreover, the inducer efficiency was higher at greater speeds. The evolution of cavitation bubbles was categorized into the inception, developing, and developed stages. When the cavitation number decreased, vortex cavitation was induced along with the tip leakage vortex; subsequently, wedge-shaped sheet cavitation occurred, which was followed by back-flow vortex cavitation. The areas associated with wedge-shape sheet cavitation and back-flow vortex cavitation increased gradually, extending spirally along the axial direction until the entire flow passage was blocked. Overall, the heads declined by 1.1%–1.9% for the inducer with three and two blades, respectively.

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Section: Resultsmentioning

confidence: 99%

Section: Experimental Facilitiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Experimental investigation of cavitation characteristics for a high-speed inducer with a great flow rate

Zhang

Xia

Kong

et al. 2022

Advances in Mechanical Engineering

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“…The behavior of the cavitating volume was characterized via cavitation compliance and mass flow gain factor defined with respect to the upstream local pressure and incidence. Three different types of one-lobed azimuthal modes were estimated by the model and also observed in experiments: a super-synchronous forward rotating cavity [18][19][20][21][22][23][24][25][26], a backward rotating cavity [20][21][22][23] and subsynchronous rotating stall.…”

Section: Introductionmentioning

confidence: 98%

Dynamic Model-Based Identification of Cavitation Compliance and Mass Flow Gain Factor in Rocket Engine Turbopump Inducers

Wan

Manfredi

Pasini

et al. 2021

Journal of Engineering for Gas Turbines and Power

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Cavitation dynamics continue to pose a significant risk in the development and operation of launch vehicle (LV) propulsion systems. In addition to generating unsteady loads that can directly damage turbopump hardware, cavitation dynamics often couple with LV fluid feed systems, producing system wide POGO instability that can cause catastrophic failures. Despite its importance, the current understanding of cavitation dynamics, and especially pump transfer matrices, is limited. Given the relatively sparse amount of inducer transfer matrix data available, there is a critical need for more in-depth characterization of the cavitation dynamics in turbopump inducers to avoid POGO instability. This paper defines and validates a new reduced-order approach to infer key parameters such as cavitation compliance, K, and mass flow gain factor, M, from simple, single sensor unsteady pressure measurements during inducer inlet pressure ramps. The utility of this approach is demonstrated for a range of inducer geometries reported in the literature. The results are in agreement with experimental data and the paper provides a new capability supporting the assessment of launch vehicle POGO instability

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“…Inducer cavitation causes vibration and affects the operation stability of the pump unit. Researchers have used the combination of transient pressure signal measurements and visual experiments to study the cavitation instability of the inducer [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Research on Visualization of Inducer Cavitation of High-Speed Centrifugal Pump in Low Flow Conditions

Kong

Zhang

et al. 2021

JMSE

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Inducer is often used to improve the cavitation performance of pump. In order to study the cavitation characteristics of inducer under low flow condition of high-speed pump, high-speed photography technology was employed in this paper to carry out visual experiments on the inducer of a high-speed centrifugal pump. In low flow rates, Cavitation distribution and evolution among the inducer were captured. The experimental results revealed that a band-shaped backflow vortex in the inlet pipe would occur when the flow rate was less than 0.3 Qd. Moreover, the backflow vortex in the inlet pipe rotated with the inducer and the rotational speed of backflow vortex was approximately half of the inducer. The visualization test of 0.27 Qd was carried out: when the NPSH was greater than 6.72 m, the bubbles in the inlet pipe were asymmetrical; When the NPSH dropped to 5.41 m, the cavitation was becoming less asymmetrical; When NPSH dropped to 3.81 m, cavitation evolved to the deteriorating stage, plenty of bubbles entered into the main impeller, resulting in a rapid decline of pump performance. Furthermore, the cavitation performance was worse at an extreme flow rate, and the NPSH value of 0.27 Qd was 7.5% greater than that under design condition.

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Analysis of Flow Instabilities on a Three-Bladed Axial Inducer in Fixed and Rotating Frames

Cited by 15 publications

References 27 publications

Experimental investigation of cavitation characteristics for a high-speed inducer with a great flow rate

Experimental investigation of cavitation characteristics for a high-speed inducer with a great flow rate

Dynamic Model-Based Identification of Cavitation Compliance and Mass Flow Gain Factor in Rocket Engine Turbopump Inducers

Research on Visualization of Inducer Cavitation of High-Speed Centrifugal Pump in Low Flow Conditions

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