Gas-liquid mass transfer in rotating perforated-disc contactors

Letters in Heat and Mass Transfer Pub Date : 1982-03-01 DOI:10.1016/0094-4548(82)90028-5

Wen-Jei Yang

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引用次数: 6

Abstract

This paper presents a numerical model for predicting the performance of liquid-gas mass transfer in a rotating perforated-disc type contactor. The device consists of a cylindrical section situated between two 45-degree conical sections. A liquid flows downward by gravity while a stream of air moves upward by buoyancy thus forming a counter-current flow situation in the contactor. A gas dissolved in the liquid transfers into air bubbles which are sheared to a tiny size as they rise through the perforations on the rotating disc. Both laminar and turbulent flows are treated. Utilizing the velocity distribution [10,11] and bubble trajectory [12] as the basis, the interphase mass transfer performance of carbon dioxide in the water-air system is numerically determined. It is disclosed that in both laminar and turbulent flow cases, the rate of interphase mass transfer increases significantly with a reduction in bubble size. Rotational speed does not affect mass transfer in laminar flow but causes an exponential mass transfer enhancement in higher turbulent flows. There exists an optimum through-flow rate of the liquid for the best mass transfer performance depending on the initial bubble size and disc speed. Test results [9] provide a qualitative confirmation of the theory.

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旋转穿孔盘式接触器的气液传质

本文提出了一种预测旋转穿孔圆盘式接触器液气传质性能的数值模型。该装置由位于两个45度圆锥形部分之间的圆柱形部分组成。液体在重力作用下向下流动，而气流在浮力作用下向上流动，从而在接触器中形成逆流流动。溶解在液体中的气体转化为气泡，这些气泡在通过旋转圆盘上的孔上升时被剪成很小的尺寸。层流和湍流都进行了处理。以速度分布[10,11]和气泡轨迹[12]为基础，数值确定了二氧化碳在水气系统中的相间传质性能。揭示了在层流和湍流两种情况下，随着气泡尺寸的减小，相间传质速率显著增加。在层流中，转速对传质没有影响，但在高湍流中，转速对传质有指数增强作用。根据初始气泡大小和圆盘速度的不同，存在最佳传质速率。测试结果[9]为该理论提供了定性的证实。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Letters in Heat and Mass Transfer

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