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Simulation of gasâ€“liquid two-phase flow in a flow-focusing microchannel with the lattice Boltzmann method

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ã€Authorã€‘ Kai Feng;Gang Yang;Huichen Zhang;Naval Architecture and Ocean Engineering College, Dalian Maritime University;

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ã€æœºæž„ã€‘ Naval Architecture and Ocean Engineering College, Dalian Maritime Universityï¼›

ã€æ‘˜è¦ã€‘ A lattice Boltzmann method for gasâ€“liquid two-phase flow involving non-Newtonian fluids is developed. Bubble formation in a flow-focusing microchannel is simulated by the method. The influences of flow rate ratio, surface tension,wetting properties, and rheological characteristics of the fluid on the two-phase flow are analyzed. The results indicate that the flow pattern transfers from slug flow to dry-plug flow with a sufficiently small capillary number. Due to the presence of three-phase contact lines, the contact angle has a more significant effect on the dry-plug flow pattern than on the slug flow pattern. The deformation of the front and rear meniscus of a bubble in the shear-thinning fluid can be explained by the variation of the capillary number. The reduced viscosity and increased contact angle are beneficial for the drag reduction in a microchannel. It also demonstrates the effectiveness of the current method to simulate the gasâ€“liquid two-phase flow in a microchannel.æ›´å¤š è¿˜åŽŸ

ã€Abstractã€‘ A lattice Boltzmann method for gasâ€“liquid two-phase flow involving non-Newtonian fluids is developed. Bubble formation in a flow-focusing microchannel is simulated by the method. The influences of flow rate ratio, surface tension,wetting properties, and rheological characteristics of the fluid on the two-phase flow are analyzed. The results indicate that the flow pattern transfers from slug flow to dry-plug flow with a sufficiently small capillary number. Due to the presence of three-phase contact lines, the contact angle has a more significant effect on the dry-plug flow pattern than on the slug flow pattern. The deformation of the front and rear meniscus of a bubble in the shear-thinning fluid can be explained by the variation of the capillary number. The reduced viscosity and increased contact angle are beneficial for the drag reduction in a microchannel. It also demonstrates the effectiveness of the current method to simulate the gasâ€“liquid two-phase flow in a microchannel.æ›´å¤š è¿˜åŽŸ

ã€å…³é”®è¯ã€‘ two-phase flowï¼› lattice Boltzmann methodï¼› pressure dropï¼› flow-focusing microchannelï¼›
ã€Key wordsã€‘ two-phase flowï¼› lattice Boltzmann methodï¼› pressure dropï¼› flow-focusing microchannelï¼›

ã€åŸºé‡‘ã€‘ Project supported by the National Natural Science Foundation of China (Grant No. 51775077)

ã€æ–‡çŒ®å‡ºå¤„ã€‘ Chinese Physics B ,ä¸å›½ç‰©ç†B , ç¼–è¾‘éƒ¨é‚®ç®± ,2023å¹´11æœŸ

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