Abstract
Optimal transfer of two-phase solid-liquid flow (slurry flow) has long been a major industrial challenge. Slurry pumps are among the most common types of centrifugal pumps used to deal with this transfer issue. The approach of improving slurry pumps and consequently increasing the efficiency of a flow transmission system requires overcoming the effects of slurry flow such as the reduction in head, efficiency, and wear. This study attempts to investigate the changes in the pump head by modifying the slip factor distribution in the impeller channel. For this purpose, the effect of splitter blades on slip factor distribution to improve the pump head was investigated using numerical simulation tools and validated based on experimental test data. Next, an optimization process was used to determine the characteristics of the splitter (i.e., length, number, and environmental position of the splitter) based on a combination of experimental design methods, surface response, and genetic algorithm. The optimization results indicate that the splitters were in a relative circumferential position of 67.2% to the suction surface of the main blade. Also, the optimal number and length of splitter blades were 6 and 62.8% of the length of the main blades, respectively. Because of adding splitter blades and the reduction in the flow passage, the best efficiency point (BEP) of the slurry pump moved toward lower flow rates. The result of splitter optimization was the increase in pump head from 29.7 m to 31.7 m and the upkeep of efficiency in the initial values.
Highlights
Centrifugal pumps are among the most widely used turbomachines for transferring fluid in various industries
Optimizing the impeller geometry using a combination of artificial neural networks (ANNs) and artificial bee colony (ABC) algorithm was accomplished by Derakhshan et al (2013) on a centrifugal pump
2- Optimization methodology This research aims at improving the head in a centrifugal pump by focusing on correcting the slip factor distribution in the impeller channel by adding splitter blades
Summary
Centrifugal pumps are among the most widely used turbomachines for transferring fluid in various industries. Kergourlay et al (2007) investigated the effect of splitter blades on the flow field of a centrifugal pump in a comparative experimental analysis They studied the slip factor as a parameter affected by flow direction and showed that adding splitter blades improves the head. Zhang et al (2018) investigated the peripheral position of the splitter blades and its effect on the pump head and efficiency According to their results, such a system effectively improves the mentioned characteristics. Based on the research background, most of the related studies have been carried out on splitter blades for water fluid to investigate changes in the pump head and efficiency as research objectives. 2- Optimization methodology This research aims at improving the head in a centrifugal pump by focusing on correcting the slip factor distribution in the impeller channel by adding splitter blades. Sampling with DOE(LHS) Latin Hypercube Sampling Input variables Response Surface Method
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