Intermittent two-phase flow study by NMR

Comptes Rendus de l'Académie des Sciences - Series IIC - Chemistry Pub Date : 2001-11-01 DOI:10.1016/S1387-1609(01)01344-5

Fabien Barberon, Jacques Leblond

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引用次数: 7

Abstract

Co-circulation of gas and liquid in a pipe can generate, depending on inlet conditions, various kinds of flow patterns. Few investigations have been performed on intermittent two-phase flows (slug flows) using classical techniques (optical probe, hot-wire anemonetry, etc.), because these techniques are difficult to apply in this flow regime. Here we show that nuclear magnetic resonance is a powerful technique to study such flows. The presented results deal with controlled isolated Taylor bubbles. In addition to a classical Pulsed Field Gradient Spin Echo (PFGSE), a magnetic field gradient was applied during the π/2)_X radio frequency pulse, which produces a selective irradiation. Thus, cutting up of the flow into slices provides the longitudinal evolution of the liquid fraction and of the velocity probability distribution in the entire region perturbed by the Taylor bubble. The existence of a recirculatory flow under the Taylor bubble is clearly demonstrated.

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间歇两相流的核磁共振研究

管道内气体和液体的共循环，根据进口条件的不同，可以产生各种流动模式。使用经典技术(光学探针、热线风速等)对间歇两相流(段塞流)进行的研究很少，因为这些技术很难应用于这种流动状态。在这里，我们表明核磁共振是一种强有力的技术来研究这种流动。给出的结果处理了受控的孤立泰勒气泡。除了经典的脉冲场梯度自旋回波(PFGSE)外，在π/2)X射频脉冲期间施加磁场梯度，产生选择性辐照。因此，将流动切割成薄片提供了液体分数的纵向演化和受泰勒气泡扰动的整个区域的速度概率分布。本文清楚地证明了泰勒气泡下循环流动的存在。

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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Comptes Rendus de l'Académie des Sciences - Series IIC - Chemistry

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