Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models

With diminishing light crude oil reserves, the focus shifts to heavy and extra-heavy crude oil, posing challenges with high viscosity impeding flow. Water-lubricated technology addresses this issue in oil transmission lines. This study introduces a novel method integrating response surface methodolo...

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Published in:FUEL
Main Authors: Alsehli, Mishal; Basem, Ali; Jasim, Dheyaa J.; Mausam, Kuwar; Alshamrani, Ali; Sultan, Abbas J.; Kassim, Murizah; Rajab, Husam; Musa, Veyan A.; Maleki, Hamid
Format: Article
Language:English
Published: ELSEVIER SCI LTD 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001268270300001
author Alsehli
Mishal; Basem
Ali; Jasim
Dheyaa J.; Mausam
Kuwar; Alshamrani
Ali; Sultan
Abbas J.; Kassim
Murizah; Rajab
Husam; Musa
Veyan A.; Maleki
Hamid
spellingShingle Alsehli
Mishal; Basem
Ali; Jasim
Dheyaa J.; Mausam
Kuwar; Alshamrani
Ali; Sultan
Abbas J.; Kassim
Murizah; Rajab
Husam; Musa
Veyan A.; Maleki
Hamid
Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
Energy & Fuels; Engineering
author_facet Alsehli
Mishal; Basem
Ali; Jasim
Dheyaa J.; Mausam
Kuwar; Alshamrani
Ali; Sultan
Abbas J.; Kassim
Murizah; Rajab
Husam; Musa
Veyan A.; Maleki
Hamid
author_sort Alsehli
spelling Alsehli, Mishal; Basem, Ali; Jasim, Dheyaa J.; Mausam, Kuwar; Alshamrani, Ali; Sultan, Abbas J.; Kassim, Murizah; Rajab, Husam; Musa, Veyan A.; Maleki, Hamid
Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
FUEL
English
Article
With diminishing light crude oil reserves, the focus shifts to heavy and extra-heavy crude oil, posing challenges with high viscosity impeding flow. Water-lubricated technology addresses this issue in oil transmission lines. This study introduces a novel method integrating response surface methodology (RSM), computational fluid dynamics (CFD), and optimized machine learning (ML) models to analyze pipeline pressure gradients (PG) in oil-water two-phase flows downstream of T-junctions. The present study uses the D-optimal technique for simulation design to optimize CFD computational demands efficiently. This study breaks new ground by proposing a framework that leverages support vector machines (SVMs). The proposed framework incorporates metaheuristic optimization algorithms (genetic algorithm (GA) and particle swarm optimization (PSO)) to achieve superior PG prediction accuracy. The optimized ML models outperformed RSM models for predicting PG. Results indicated that oil-to-water viscosity ratio and oil inlet velocity significantly affect PG, followed by water inlet velocity and surface tension between phases. In contrast, the oil-to-water density ratio, oil entry angle at the T-junction, and wall contact angle have minimal impact. Furthermore, statistical metrics and visual comparison tools identified the PSO-optimized SVM model based on linear kernel function as the most effective (MAPE = 13.2 % and R = 0.9949). The hybrid methodology presented in this research holds significant promise for optimizing heavy oil transfer efficiency in applications involving water-lubricated technologies.
ELSEVIER SCI LTD
0016-2361
1873-7153
2024
374

10.1016/j.fuel.2024.132431
Energy & Fuels; Engineering

WOS:001268270300001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001268270300001
title Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
title_short Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
title_full Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
title_fullStr Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
title_full_unstemmed Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
title_sort Insights into water-lubricated transport of heavy and extra-heavy oils: Application of CFD, RSM, and metaheuristic optimized machine learning models
container_title FUEL
language English
format Article
description With diminishing light crude oil reserves, the focus shifts to heavy and extra-heavy crude oil, posing challenges with high viscosity impeding flow. Water-lubricated technology addresses this issue in oil transmission lines. This study introduces a novel method integrating response surface methodology (RSM), computational fluid dynamics (CFD), and optimized machine learning (ML) models to analyze pipeline pressure gradients (PG) in oil-water two-phase flows downstream of T-junctions. The present study uses the D-optimal technique for simulation design to optimize CFD computational demands efficiently. This study breaks new ground by proposing a framework that leverages support vector machines (SVMs). The proposed framework incorporates metaheuristic optimization algorithms (genetic algorithm (GA) and particle swarm optimization (PSO)) to achieve superior PG prediction accuracy. The optimized ML models outperformed RSM models for predicting PG. Results indicated that oil-to-water viscosity ratio and oil inlet velocity significantly affect PG, followed by water inlet velocity and surface tension between phases. In contrast, the oil-to-water density ratio, oil entry angle at the T-junction, and wall contact angle have minimal impact. Furthermore, statistical metrics and visual comparison tools identified the PSO-optimized SVM model based on linear kernel function as the most effective (MAPE = 13.2 % and R = 0.9949). The hybrid methodology presented in this research holds significant promise for optimizing heavy oil transfer efficiency in applications involving water-lubricated technologies.
publisher ELSEVIER SCI LTD
issn 0016-2361
1873-7153
publishDate 2024
container_volume 374
container_issue
doi_str_mv 10.1016/j.fuel.2024.132431
topic Energy & Fuels; Engineering
topic_facet Energy & Fuels; Engineering
accesstype
id WOS:001268270300001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001268270300001
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collection Web of Science (WoS)
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