Gas Effect in Electrical-Submersible-Pump-System Stage-by-Stage Analysis

Oliva, G. B. F. F.; Galvão, Hannah Lícia Cruz; Santos, Diogo Pereira dos; Silva, Raphael E.; Maitelli, André Laurindo; Costa, Rafael F. S.; Maitelli, C. W. S. P.

doi:10.2118/173969-pa

Cited by 6 publications

(2 citation statements)

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“…The multiphase mixed transportation technology (red line in Figure 1) is superior to traditional separated phase transportation technology (blue line in Figure 1) in overcoming longdistance resistance losses, improving flow safety, saving separation equipment costs, improving production and transportation efficiency, and improving marginal oilfield economy [2,3]. Therefore, the mixed oil and gas transportation process has become the preferred solution for deep-sea oil and gas production and transportation systems [4]. This technology uses a gas-liquid two-phase flow pump to directly extract well fluid, and a pressurized system to transport oil and gas over long distances.…”

Section: Introductionmentioning

confidence: 99%

Investigation on the operation and gas-liquid two phase flow characteristics of vane type deep-sea pump

Luo,

Yan,

Feng

et al. 2024

J. Phys.: Conf. Ser.

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The development of oil and gas resources towards the deep sea is an inevitable trend in international energy development. Due to its advantages of high production and transportation efficiency, good flow safety and low investment cost, oil and gas mixed transportation technology has become the preferred technology for deep-sea oil and gas production and transportation system. The core device of the oil-gas mixed transportation system is the gas-liquid two-phase flow pump. Under the gas-liquid two-phase condition, the pressure surging will occur with the increase of the inlet gas volume fraction (IGVF) in the pump. At this time, the pressurization capacity of the pump decreases significantly, accompanied by violent vibration, resulting in extremely unstable operation. To solve this problem, the numerical simulation and experiment of the two-phase operation characteristics of a centrifugal pump and a semi-open mixed-flow pump were carried out in this study. The influence of operating parameters on its pressurization capacity was clarified, and the internal gas-liquid distribution was visually tested, revealing the distribution and its spatiotemporal evolution of gas-phase in the impeller. Finally, the unsteady characteristics of pressure surging were analyzed in detail.

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Section: Introductionmentioning

confidence: 99%

Investigation on the operation and gas-liquid two phase flow characteristics of vane type deep-sea pump

Luo,

Yan,

Feng

et al. 2024

J. Phys.: Conf. Ser.

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“…ESPs excel in producing crude oils at very high flow rate, but they have to be operated within a narrow application window. Gas involvement, changing production rate and high oil viscosity can greatly affect the ESP performance [3,4].…”

Section: Introductionmentioning

confidence: 99%

A Review of Experiments and Modeling of Gas-Liquid Flow in Electrical Submersible Pumps

Zhu

Zhang

2018

Energies

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As the second most widely used artificial lift method in petroleum production (and first in produced amount), electrical submersible pump (ESP) maintains or increases flow rate by converting kinetic energy to hydraulic pressure of hydrocarbon fluids. To facilitate its optimal working conditions, an ESP has to be operated within a narrow application window. Issues like gas involvement, changing production rate and high oil viscosity, greatly impede ESP boosting pressure. Previous experimental studies showed that the presence of gas would cause ESP hydraulic head degradation. The flow behaviors inside ESPs under gassy conditions, such as pressure surging and gas pockets, further deteriorate ESP pressure boosting ability. Therefore, it is important to know what parameters govern the gas-liquid flow structure inside a rotating ESP and how it can be modeled. This paper presents a comprehensive review on the key factors that affect ESP performance under gassy flow conditions. Furthermore, the empirical and mechanistic models for predicting ESP pressure increment are discussed. The computational fluid dynamics (CFD)-based modeling approach for studying the multiphase flow in a rotating ESP is explained as well. The closure relationships that are critical to both mechanistic and numerical models are reviewed, which are helpful for further development of more accurate models for predicting ESP gas-liquid flow behaviors.

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Predicting Non-Newtonian Fluid Electric Submersible Pump failure using Deep Learning and Artificial Neural Network

Okoro

Sanni

Okigbo

et al. 2021

IOP Conf. Ser.: Earth Environ. Sci.

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The monitoring of electric submersible pumps (ESPs) is essential for optimal petroleum artificial lifting operations. Most ESP research are aimed at operation improvement and optimization of the centrifuge multi-stage pump motor and the load that the pump has to discharge which is a function of the pumps mechanical properties and characteristics, liquid compositions, pressure and temperature. ESPs failure often lead to oil production losses or “oil deferment” which affects revenue for all the parties involved. Also, pulling the ESP out of the wellbore of interest, requires mobilization of a rig because it is installed several hundred meters down the wellbore. To prevent these loses, a predictive approach is needed to avert these scenarios. In the current decade, machine learning algorithms studies have spurred real- time technologies research interest due to their abilities to predict future outcomes using already existing data sets. This study presents a predictive approach for Electric Submersible Pump failure during artificial lift operations. The study creates an “algorithm” that helps to predict via Machine learning, the failure of an ESP with the assumption that failure is usually caused by pressure build-ups. A deep learning model for predicting ESP failure was proposed and artificial neural network was used in developing the suggested model. Based on the outcomes of this study, it can be concluded that the selected AI algorithm and its characteristics, are suitable for applications in detecting ESP failure before it happens using upstream-data.

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Gas Effect in Electrical-Submersible-Pump-System Stage-by-Stage Analysis

Cited by 6 publications

References 0 publications

Investigation on the operation and gas-liquid two phase flow characteristics of vane type deep-sea pump

Investigation on the operation and gas-liquid two phase flow characteristics of vane type deep-sea pump

A Review of Experiments and Modeling of Gas-Liquid Flow in Electrical Submersible Pumps

Predicting Non-Newtonian Fluid Electric Submersible Pump failure using Deep Learning and Artificial Neural Network

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