微观混合
文丘里效应
微型反应器
计算流体力学
湍流
机械
迷惑
材料科学
消散
压力降
湍流动能
流体力学
微流控
体积流量
流量(数学)
化学
航程(航空)
流体体积法
空化
动能
机械工程
传质
流体学
下降(电信)
作者
Yongzhi Ning,Bo Wang,Runci Wang,Taihong Yan
出处
期刊:Micromachines
[Multidisciplinary Digital Publishing Institute]
日期:2026-02-11
卷期号:17 (2): 234-234
摘要
Microreactors offer remarkable advantages in intensifying mixing/mass transfer and hold promising prospects for industrial applications. In this study, T-shaped microreactors (TMRs) integrated with baffle, orifice-plate, and venturi structures (featuring different contraction angles) were designed. Based on the Villermaux-Dushman reaction system, three-dimensional computational fluid dynamics (CFD) models were established to simulate the fluid flow and mixing-reaction processes in these microreactors. The results demonstrate that peaks in velocity, turbulent kinetic energy, and turbulent dissipation rate consistently emerge in the confluence region of the two fluid streams. In the operating range of this study, the baffle configuration exhibits the highest micromixing performance but also induces the largest pressure drop, followed by the orifice-plate structure. Notably, the venturi structure not only enhances micromixing efficiency but also results in a minimal increase in pressure drop and eliminates flow dead zones. Specifically, the venturi structure with a 45° contraction angle achieves a balance between energy consumption and micromixing efficiency. Using the agglomeration model, the micromixing times of the microreactors with various structures were determined to range from 0.025 to 0.234 ms.
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