Analysis of Conductance Probes for Two-Phase Flow and Holdup Applications

[EN] In this paper we perform an analysis of the conductance probes used in two-phase flow applications especially for two-phase flow tomography of annular flow, to measure the waves produced in the interface with different boundary conditions without perturbing the flow, and in addition we examine...

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Bibliographic Details
Authors: J. L. Muñoz-Cobo|||0000-0002-4512-7991, Berna-Escriche, César|||0000-0002-2097-5089, Escrivá, A.|||0000-0002-9670-068X, Rivera-Durán, Yago
Format: article
Publication Date:2020
Country:España
Institution:Ajuntament de Barcelona
Repository:RiuNet. Repositorio Institucional de la Universitat Politécnica de Valéncia
Language:English
OAI Identifier:oai:riunet.upv.es:10251/176255
Online Access:https://riunet.upv.es/handle/10251/176255
Access Level:Open access
Keyword:Conductance probes
Two-phase flow sensors
Liquid fraction determination from relative conductance
Two-phase flow tomography
ESTADISTICA E INVESTIGACION OPERATIVA
INGENIERIA NUCLEAR
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Summary:[EN] In this paper we perform an analysis of the conductance probes used in two-phase flow applications especially for two-phase flow tomography of annular flow, to measure the waves produced in the interface with different boundary conditions without perturbing the flow, and in addition we examine the holdup applications as measuring the average void fraction in a given region. The method used to obtain the detector conductance between the electrodes is to solve analytically the generalized Laplace equation in 3D with the boundary conditions of the problem, and then to obtain the average potential difference between the detector electrodes. Then, dividing the current intensity circulating between the emitter and the receiver electrodes by the average potential difference yields the probe conductance, which depends on the geometric and physical characteristics of the measured system and the probe. This conductance is then non-dimensionalized by dividing by the conductance of the pipe full of water. In this way a set of analytical expression have been obtained for the conductance of two-plate sensors with different geometries and locations. We have performed an exhaustive comparison of the results obtained using the equations deduced in this paper with the experimental data from several authors in different cases with very good agreement. In some cases when the distribution of bubbles is not homogeneous, we have explored the different alternatives of the effective medium theory (EMT) in terms of the self-consistent EMT and the non-consistent EMT.