Quantification of Fluid Production Distribution in Deviated Wells with High Gas-Liquid Ratio Using a Flow Array Sensing Tool

Gonzalez, J.; Linares, Alejandro Jose; Rodriguez, Diego Armando; Rivera, Gerson Orlando; Schoepf, Virginie; Abbassi, Linda

doi:10.2118/205803-ms

Cited by 3 publications

(1 citation statement)

References 3 publications

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“…By establishing a cut-off demarcating water from hydrocarbon, the mechanism functions as a miniaturized, quick-response conductivity gauge, imparting improved measurement reliability and fidelity [29]. Optical probe technologies have spawned a novel breed of fluid recognition schemes deviating from traditional optically based bubble detection methodologies [30], featuring an exclusive biconical architecture leveraging sensitivity towards optical fluid indices. Reflective indexes across diverse fluid species fall within a finite range, where gaseous substances exhibit values near unity, waters average around 1.35, and crude oils approxi-mate closer to 1.5.…”

Section: Fsi and Fast Monitoring Of Key Parametersmentioning

confidence: 99%

Application and Analysis of Array Production Logging Technology for Multiphase Flow in Horizontal Wells

Luo,

Liu,

Yang

et al. 2023

Processes

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Production logging (PL) instruments play a pivotal role in the comprehensive management and monitoring of oil and gas reservoirs. These devices facilitate the resolution of complex flow diagnosis challenges throughout the life cycle of hydrocarbon field exploitation. However, the advent of highly deviated well drilling technology has exposed certain limitations inherent in conventional centralized logging sensing techniques. When fluid flow within horizontal wells becomes segregated or even laminar, these traditional methods struggle to accurately decipher the zonal productions of oil, gas, and water. To address this challenge, multi-array production logging tools were developed in the late 1990s. Historically, these tools were characterized by considerable lengths, reaching up to 30 feet for an entire suite incorporating flow speed and holdup sensors that were not always collocated. Despite the integration of multiple sensors, uncertainties in determining flow profiles persisted. In this paper, we propose a novel integrated multi-parameter evaluation method based on measurements from a recently developed ultracompact flow array sensing tool, aimed at enhancing the accuracy of reservoir evaluation. The validity of the multi-parameter method is substantiated through a comparison of the new tool with an industry benchmark array PL tool on the same well. By combining the monitoring results, an optimization strategy for oil and gas extraction is presented, which is expected to improve the oil and gas recovery rate, thereby providing guidance for subsequent extraction endeavors. Moreover, we demonstrate how this innovative integrated workflow significantly enhances energy savings and efficiency, further underlining its value in modern oil and gas field management.

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Section: Fsi and Fast Monitoring Of Key Parametersmentioning

confidence: 99%

Application and Analysis of Array Production Logging Technology for Multiphase Flow in Horizontal Wells

Luo,

Liu,

Yang

et al. 2023

Processes

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Determining a Flow Zone Indicator in Conventional and Unconventional Reservoirs Using Resistivity Logs

Gonzalez¹,

Linares²,

Rodriguez³

et al. 2023

Day 2 Tue, March 21, 2023

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The Flow Zone Indicator (FZI) depends on permeability and porosity. The permeability of a reservoir is one of the most difficult properties to determine, since the models to calculate permeability use input from several logs (gamma ray, density-neutron, sonic, etc.). Permeability modeling is done using complex methodologies such as: matching learning, fuzzy logic, cluster, multiple linear regression, etc., and at the end, permeability models end up being unique for each reservoir. The objective of this work is to determine a flow zone indicator (FZI) from the deep (Rt) and shallow resistivity (Rs) logs in conventional and unconventional reservoirs. Basically, the methodology consisted of studying the phenomenon of the invasion of mud filtration during the drilling of the wells, and the behavior of resistivity logs. Invasion affects some properties of porous and permeable formations in the vicinity of a well. In general, the invasion is small in very porous and permeable reservoirs, the opposite is in poorly permeable reservoirs, tight, vuggy carbonates or fractured formations. Based on the above, a mathematical model was proposed to determine the FZI, as a logarithmic function which is applicable in both water and oil-based muds. If the resistivities are equal, then there is no mud filtration invasion, and the permeability is zero. If the difference in resistivity is different from zero, there is invasion of the sludge filtrate and therefore the permeability is greater than zero, indicating flow zones in the reservoir. There are other borehole, formation and tool conditions that may generate difference between RT and RS which are not related to invasion. These will be explained briefly below. The FZI model identified the flow zones in the reservoir. FZI from core and Nuclear Magnetic Resonance (NMRI) log data correlated with the FZI calculated with the model. The mobility data of formation testers agreed with the calculated FZI. Also, spectral noise and PLT logs inflow zones showed excellent correlation with the FZI. This methodology can be applied in any type of reservoir. In exploration wells the methodology allows to define and propose the best zones to set the formation testers, thus optimizing operational time. Before performing a petrophysical assessment, FZI results can identify prospective zones of the reservoir based on rock quality. Also, the production and injection behavior of the wells can be monitored with the obtained results. And finally, the FZI as an independent variable decreases the uncertainty of a permeability model, because the FZI is intimately related to the texture of the rock and the facies. The simplest expression of this is the resistivity variation with changes of porosity. Therefore, if porosity is related to facies, so is the formation factor (F), and then the resistivity log becomes an excellent facies discriminator.

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Completion Diagnostic Tools, Production Logging Technology Delivers Accurate Flow Contributions Vertical & Horizontal Wellbores

Heddleston

2023

Day 3 Wed, April 19, 2023

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Over the past 18 years, the industry has focused on drilling and completing horizontal producing wells, in order to develop better deliverability and UER across the reservoir. These types of wells are drilled with various inclinations, trajectories which porpoise across the reservoir interval. Horizontal lateral sections consist of numerous selectively stimulated stages containing greater than 20 stages spread out across 2,000 ft to 25,000 ft of horizontal interval. (Heddleston, 2017). Many indirect measurements such as chemical tracing or fiber optic sensing have been trialed, but the only direct measurement of real production contributing across a producing lateral is acquired using production logging measurements with production data analysis. This true measurement of production contribution is the best method which allow oil companies to understand and acknowledge which portions of the hydraulically stimulated reservoir is contributing the production and the value of their properties.

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Quantification of Fluid Production Distribution in Deviated Wells with High Gas-Liquid Ratio Using a Flow Array Sensing Tool

Cited by 3 publications

References 3 publications

Application and Analysis of Array Production Logging Technology for Multiphase Flow in Horizontal Wells

Application and Analysis of Array Production Logging Technology for Multiphase Flow in Horizontal Wells

Determining a Flow Zone Indicator in Conventional and Unconventional Reservoirs Using Resistivity Logs

Completion Diagnostic Tools, Production Logging Technology Delivers Accurate Flow Contributions Vertical & Horizontal Wellbores

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