The prediction of condensation flow patterns by using artificial intelligence (AI) techniques

Multiphase flow provides a solution to the high heat flux and precision required by modern-day gadgets and heat transfer devices as phase change processes make high heat transfer rates achievable at moderate temperature differences. An application of multiphase flow commonly used in industry is the...

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Main Author: Seal, Michael Kevin
Other Authors: Mehrabi, Mehdi
Language:en
Published: University of Pretoria 2021
Subjects:
Online Access:http://hdl.handle.net/2263/78303
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-up-oai-repository.up.ac.za-2263-783032021-12-15T05:22:33Z The prediction of condensation flow patterns by using artificial intelligence (AI) techniques Seal, Michael Kevin Mehrabi, Mehdi Meyer, Josua P. u15225250@tuks.co.za convolutional neural network condensation flow pattern machine learning UCTD Multiphase flow provides a solution to the high heat flux and precision required by modern-day gadgets and heat transfer devices as phase change processes make high heat transfer rates achievable at moderate temperature differences. An application of multiphase flow commonly used in industry is the condensation of refrigerants in inclined tubes. The identification of two-phase flow patterns, or flow regimes, is fundamental to the successful design and subsequent optimisation given that the heat transfer efficiency and pressure gradient are dependent on the flow structure of the working fluid. This study showed that with visualisation data and artificial neural networks (ANN), a machine could learn, and subsequently classify the separate flow patterns of condensation of R-134a refrigerant in inclined smooth tubes with more than 98% accuracy. The study considered 10 classes of flow pattern images acquired from previous experimental works that cover a wide range of flow conditions and the full range of tube inclination angles. Two types of classifiers were considered, namely multilayer perceptron (MLP) and convolutional neural networks (CNN). Although not the focus of this study, the use of a principal component analysis (PCA) allowed feature dimensionality reduction, dataset visualisation, and decreased associated computational cost when used together with multilayer perceptron neural networks. The superior two-dimensional spatial learning capability of convolutional neural networks allowed improved image classification and generalisation performance across all 10 flow pattern classes. In both cases, the classification was done sufficiently fast to enable real-time implementation in two-phase flow systems. The analysis sequence led to the development of a predictive tool for the classification of multiphase flow patterns in inclined tubes, with the goal that the features learnt through visualisation would apply to a broad range of flow conditions, fluids, tube geometries and orientations, and would even generalise well to identify adiabatic and boiling two-phase flow patterns. The method was validated by the prediction of flow pattern images found in the existing literature. Dissertation (MEng)--University of Pretoria, 2021. NRF Mechanical and Aeronautical Engineering MEng Restricted 2021-02-08T11:00:31Z 2021-02-08T11:00:31Z 2021-04 2021 Dissertation http://hdl.handle.net/2263/78303 * S2021 en © 2019 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria. University of Pretoria
collection NDLTD
language en
sources NDLTD
topic convolutional neural network
condensation flow pattern
machine learning
UCTD
spellingShingle convolutional neural network
condensation flow pattern
machine learning
UCTD
Seal, Michael Kevin
The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
description Multiphase flow provides a solution to the high heat flux and precision required by modern-day gadgets and heat transfer devices as phase change processes make high heat transfer rates achievable at moderate temperature differences. An application of multiphase flow commonly used in industry is the condensation of refrigerants in inclined tubes. The identification of two-phase flow patterns, or flow regimes, is fundamental to the successful design and subsequent optimisation given that the heat transfer efficiency and pressure gradient are dependent on the flow structure of the working fluid. This study showed that with visualisation data and artificial neural networks (ANN), a machine could learn, and subsequently classify the separate flow patterns of condensation of R-134a refrigerant in inclined smooth tubes with more than 98% accuracy. The study considered 10 classes of flow pattern images acquired from previous experimental works that cover a wide range of flow conditions and the full range of tube inclination angles. Two types of classifiers were considered, namely multilayer perceptron (MLP) and convolutional neural networks (CNN). Although not the focus of this study, the use of a principal component analysis (PCA) allowed feature dimensionality reduction, dataset visualisation, and decreased associated computational cost when used together with multilayer perceptron neural networks. The superior two-dimensional spatial learning capability of convolutional neural networks allowed improved image classification and generalisation performance across all 10 flow pattern classes. In both cases, the classification was done sufficiently fast to enable real-time implementation in two-phase flow systems. The analysis sequence led to the development of a predictive tool for the classification of multiphase flow patterns in inclined tubes, with the goal that the features learnt through visualisation would apply to a broad range of flow conditions, fluids, tube geometries and orientations, and would even generalise well to identify adiabatic and boiling two-phase flow patterns. The method was validated by the prediction of flow pattern images found in the existing literature. === Dissertation (MEng)--University of Pretoria, 2021. === NRF === Mechanical and Aeronautical Engineering === MEng === Restricted
author2 Mehrabi, Mehdi
author_facet Mehrabi, Mehdi
Seal, Michael Kevin
author Seal, Michael Kevin
author_sort Seal, Michael Kevin
title The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
title_short The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
title_full The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
title_fullStr The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
title_full_unstemmed The prediction of condensation flow patterns by using artificial intelligence (AI) techniques
title_sort prediction of condensation flow patterns by using artificial intelligence (ai) techniques
publisher University of Pretoria
publishDate 2021
url http://hdl.handle.net/2263/78303
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