【摘要】 微流体系统通常具备极大的比表面积、易于控制等优势,在气-液相传质、传热、反应等方面具有良好的应用前景。本文考察了6个气液相体系在矩形截面蛇形微通道中的气液两相泰勒流流动情况以及气泡和液弹的动态行为,以气泡截面形状的几何模型为基础,得到了微通道中净泄漏流的量化方程。同时发现在较大的操作区间内,蛇形微通道对泄漏流的可控性优于直形微通道。并且详细分析了不同气液相流量、液相物性(表面张力和黏度)和气泡长度对蛇形微通道主通道净泄漏流的具体影响。更多还原

【Abstract】 Microfluidic platforms have promising applications in gas-liquid mass transfer, heat transfer and chemical reaction, due to its great specific surface area, precise control of residence time, and stability of transport process. The Taylor flow for six different gas-liquid systems with different surface tensions and viscosities were systematically investigated in rectangular cross-section serpentine microchannels, aiming at dynamic behavior of bubbles and liquid slugs. Based on geometric model of bubble cross-sectional shape, quantitative equation of the net leakage flow was successfully obtained. It was simultaneously found that the controllability of the serpentine microchannel on the leakage flow is better than that of the straight microchannel in a larger operating range. And the effects of different gasliquid flow rates, liquid physical properties(surface tension and viscosity) and bubble length on the net leakage flow of the main channel for the serpentine microchannel were respectively analyzed in detail.更多还原