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Auteurs principaux: Carvalho, Felipe de Castro Teixeira, Nath, Kamaljyoti, Serpa, Alberto Luiz, Karniadakis, George Em
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2310.03001
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author Carvalho, Felipe de Castro Teixeira
Nath, Kamaljyoti
Serpa, Alberto Luiz
Karniadakis, George Em
author_facet Carvalho, Felipe de Castro Teixeira
Nath, Kamaljyoti
Serpa, Alberto Luiz
Karniadakis, George Em
contents Electrical submersible pumps (ESPs) are prevalently utilized as artificial lift systems in the oil and gas industry. These pumps frequently encounter multiphase flows comprising a complex mixture of hydrocarbons, water, and sediments. Such mixtures lead to the formation of emulsions, characterized by an effective viscosity distinct from that of the individual phases. Traditional multiphase flow meters, employed to assess these conditions, are burdened by high operational costs and susceptibility to degradation. To this end, this study introduces a physics-informed neural network (PINN) model designed to indirectly estimate the fluid properties, dynamic states, and crucial parameters of an ESP system. A comprehensive structural and practical identifiability analysis was performed to delineate the subset of parameters that can be reliably estimated through the use of intake and discharge pressure measurements from the pump. The efficacy of the PINN model was validated by estimating the unknown states and parameters using these pressure measurements as input data. Furthermore, the performance of the PINN model was benchmarked against the particle filter method utilizing both simulated and experimental data across varying water content scenarios. The comparative analysis suggests that the PINN model holds significant potential as a viable alternative to conventional multiphase flow meters, offering a promising avenue for enhancing operational efficiency and reducing costs in ESP applications.
format Preprint
id arxiv_https___arxiv_org_abs_2310_03001
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Learning characteristic parameters and dynamics of centrifugal pumps under multiphase flow using physics-informed neural networks
Carvalho, Felipe de Castro Teixeira
Nath, Kamaljyoti
Serpa, Alberto Luiz
Karniadakis, George Em
Machine Learning
Electrical submersible pumps (ESPs) are prevalently utilized as artificial lift systems in the oil and gas industry. These pumps frequently encounter multiphase flows comprising a complex mixture of hydrocarbons, water, and sediments. Such mixtures lead to the formation of emulsions, characterized by an effective viscosity distinct from that of the individual phases. Traditional multiphase flow meters, employed to assess these conditions, are burdened by high operational costs and susceptibility to degradation. To this end, this study introduces a physics-informed neural network (PINN) model designed to indirectly estimate the fluid properties, dynamic states, and crucial parameters of an ESP system. A comprehensive structural and practical identifiability analysis was performed to delineate the subset of parameters that can be reliably estimated through the use of intake and discharge pressure measurements from the pump. The efficacy of the PINN model was validated by estimating the unknown states and parameters using these pressure measurements as input data. Furthermore, the performance of the PINN model was benchmarked against the particle filter method utilizing both simulated and experimental data across varying water content scenarios. The comparative analysis suggests that the PINN model holds significant potential as a viable alternative to conventional multiphase flow meters, offering a promising avenue for enhancing operational efficiency and reducing costs in ESP applications.
title Learning characteristic parameters and dynamics of centrifugal pumps under multiphase flow using physics-informed neural networks
topic Machine Learning
url https://arxiv.org/abs/2310.03001