A Coupled PIV PTV Technique for the Dispersed Oil-Water Two-Phase Flows Within a Centrifugal Pump Impeller

Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering Pub Date : 2022-08-01 DOI:10.11159/htff22.186

R. Cerqueira, R. Perissinotto, W. Fonseca, W. M. Verde, Biazussi J. L., Franklin E.J. L., M. Castro, A. Bannwart

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Abstract

- The current work presents a framework for the simultaneous characterization of different phases in a dispersed oil-water two-phase flow. The framework is based on the coupling of the PIV and PTV techniques in raw PIV acquisition images. The PIV technique computes the water velocity fields, while the PTV technique calculates the oil drop velocities. Thus, the proposed technique allows the simultaneous measurement of the water phase and dispersed oil drop velocity from the same image. In order to present the advantages of the coupled PIV/PTV technique, the flow within a centrifugal pump impeller is completely analyzed by computing the oil and water phase-ensembled velocities. the phase-averaged velocity fields of the oil drops are presented. The results show that the oil drops move slower than the continuous phase on the majority of the impeller channels, except close to the oil injection ports. These results may help the oil drop dynamics within centrifugal pump impellers, the of drag/lift/virtual mass closure models, typically used in Computational Fluid Dynamics (CFD) applications.

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离心泵叶轮内分散油水两相流的耦合PIV - PTV技术

目前的工作提出了一个同时表征分散油水两相流中不同相的框架。该框架基于原始PIV采集图像中PIV和PTV技术的耦合。PIV技术计算的是水速度场，PTV技术计算的是油滴速度场。因此，所提出的技术允许从同一图像同时测量水相和分散的油滴速度。为了展示PIV/PTV耦合技术的优势，通过计算油水相系速度，对离心泵叶轮内的流动进行了全面分析。给出了油滴的相平均速度场。结果表明:除喷油口附近外，大部分叶轮流道上的油滴运动速度比连续相慢;这些结果可能有助于离心泵叶轮内的油滴动力学，即通常用于计算流体动力学(CFD)应用的阻力/升力/虚拟质量闭合模型。

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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Proceedings of the 8th World Congress on Mechanical, Chemical, and Material Engineering

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