A numerical study of clogging analysis in submersible drainage pump

Erosion of material surface due to collisions with solid particles has become a challenge to several engineering fields. Therefore, it is necessary to effectively design radial flow pumps that mitigate the sediment particles’ clogging effect from the system performance. This study aims to analyse an...

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Bibliographic Details
Published in:Journal of physics. Conference series 2024-02, Vol.2707 (1), p.12014
Main Authors: Rakibuzzaman, Md, Suh, Sang-Ho, Song, Kwang Chul, Song, Kyung Hee, Zhou, Ling
Format: Article
Language:English
Subjects:
Cavitation erosion
Computational fluid dynamics
Density
Erosion rates
Flow velocity
Impact prediction
Mathematical models
Particle trajectories
Power factor
Radial flow
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Summary:Erosion of material surface due to collisions with solid particles has become a challenge to several engineering fields. Therefore, it is necessary to effectively design radial flow pumps that mitigate the sediment particles’ clogging effect from the system performance. This study aims to analyse and identify the clogging development of a newly designed submersible pump using computational fluid dynamics (CFD) techniques. The particle trajectory was accounted Tabakoff–Grant erosion model for predicting the clogging impact. The experimental pump performance results obtained by this study were used to validate the numerical results of the submersible pump. Pump results revealed a good agreement between the two marks, especially the head of the pump was obtained at a flow rate of 0.165 m 3 /min. When considering the motor power factor of 0.78, the pump efficiency was found to be 46%, and the test result was well-matched. Also, for combined cavitation-erosion, the performance characteristics of erosion rate density increase linearly. At a flow rate of 0.16 m 3 /min, the erosion rate density of the original model was more significant than the revised model. Furthermore, compared to the original model significantly reduced the adverse clogging effects on the impeller blades of the revised model.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/2707/1/012014