微气泡气-液-固流化床流动特性

石油炼制与化工 ›› 2026, Vol. 57 ›› Issue (2): 112-123.

微气泡气-液-固流化床流动特性

杨捷¹,马永丽¹,宋敬阔¹,刘明言^1,2

1. 天津大学化工学院
2. 化学工程与低碳技术全国重点实验室

收稿日期:2025-09-16 修回日期:2025-10-30 出版日期:2026-02-12 发布日期:2026-01-27
通讯作者: 杨捷 E-mail:jieyang56@tju.edu.cn

HYDRODYNAMIC CHARACTERISTICS OF MICROBUBBLES IN GAS-LIQUID-SOLID FLUDIZED BED

Received:2025-09-16 Revised:2025-10-30 Online:2026-02-12 Published:2026-01-27

摘要/Abstract

摘要： 气-液-固流化床（GLSFB）因相间混合好、传质传热优，在化工等领域应用广泛。但是，毫米级气泡的气液相界面积小，限制了传递效率的进一步提高。相比之下，微米级气泡可使比表面积呈数量级的增加。将微气泡引入到GLSFB，可显著提高传质传热速率、延长停留时间。本研究聚焦新型微气泡GLSFB的流动特性，基于远心摄像技术，探究了操作参数对微气泡三相流动行为的影响规律，并基于Python 编程，结合远心摄像技术与人工校正算法，实现了三相流动参数的快速测量计算。结果表明：微气泡Sauter直径与局部气含率随表观气速增加而增大，随主水流表观液速增大先增后减；大颗粒体系固含率随气速增大而减小，小颗粒体系无显著变化。

关键词: 汽-液-固流化床, 三相流, 微气泡, 气含率, 远心光学系统

Abstract: Gas-liquid-solid fluidized beds (GLSFB) are widely used in various fields due to their excellent interphase mixing and superior mass and heat transfer. However, the gas-liquid phase interface area of millimeter-scale bubbles is small, resulting in low transfer efficiency. In contrast, the specific surface area of microbubbles has the advantage of a significant increase of several orders of magnitude. Introducing microbubbles into GLSFB can significantly enhance the mass and heat transfer rates and prolong the residence time. Focusing on the hydrodynamic characteristics of the microbubble-liquid-solid three-phase fluidized bed, and based on telecentric imaging technology, the influence law of operating parameters on the multiphase flow behavior is explored. Based on Python programming, combined with telecentric camera and manual correction algorithms, the rapid measurement and calculation of three-phase flow parameters were achieved. The results show that the Sauter diameter of microbubbles and the local gas holdup increase with the increase of the apparent gas velocity, and first increase and then decrease with the increase of the apparent liquid velocity of the main water flow. The solid content rate of the large particle system decreases with the increase of gas velocity, while the change in the small particle system is not obvious.

Key words: gas-liquid-solid fluidized bed, multiphase flow, microbubbles, gas holdup, telecentric optical system

杨捷马永丽宋敬阔刘明言. 微气泡气-液-固流化床流动特性[J]. 石油炼制与化工, 2026, 57(2): 112-123.

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