The Influence of Different Working Fluid Temperatures on the Hydraulic Performance of Magnetic Vortex Pumps
Author:
Cheng Yijia1,
Li Wei1ORCID,
Ma Sizhuo12,
Ji Leilei1ORCID,
Xiao Cui1,
Li Yongkang1
Affiliation:
1. Fluid Machinery Engineering Technology Research Center, Jiangsu University, Zhenjiang 212013, China
2. Three Gorges Renewables Offshore Wind Power Operation and Maintenance Jiangsu Co., Ltd., Yancheng 224000, China
Abstract
Magnetic vortex pumps are characterized by their high performance and zero leakage, and in recent years, they have been applied for the transportation of antifreeze coolant in varying-temperature environments. This paper combines Computational Fluid Dynamics (CFD) with experimental verification to study the external and internal flow characteristics of magnetic vortex pumps when transporting working fluid at different temperatures, considering radial clearance flow. The results indicate that as the temperature of the medium increases, both the pump head and efficiency improve. Specifically, under the design flow rate condition, the pump head increases by 16.7% when transporting a medium at 90 °C compared to ambient-temperature conditions. Conversely, the pump head is only 16.8% of that observed under ambient-temperature conditions when transporting a medium at −30 °C. Analysis of the internal flow field reveals that the changes in pump hydraulic performance at different working fluid temperatures are primarily due to variations in the vorticity of the internal flow field.
Funder
National Natural Science Foundation of China
China Postdoctoral Science Foundation
Key International Cooperative research project of the National Natural Science Foundation of China
Sixth “333 High Level Talented Person Cultivating Project” of Jiangsu Province
“Blue Project” within Jiangsu Colleges and Universities
Wenling Fluid Machinery Technology Institute of Jiangsu University
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