An Application Case of Transferring Intelligent Well System Triple-Gauge Data into Real-Time Flow Allocation Results

Sun, Kai; Omole, Oluwole Ayodotun; Saputelli, Luigi; González, Fabio

doi:10.2118/144259-ms

Cited by 7 publications

(1 citation statement)

References 15 publications

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“…They are often installed in two-zone I-wells. Sun et al (2011) proposed a "triple-gauge-and-valve" numerical simulator to upgrade the two-zone, I-well triple-gauge P/T data into a real-time, flow-allocation data stream. The simulator provided continuous multi-zone flow rate estimation based on choke pressure drops (position of ICV).…”

Section: Introductionmentioning

confidence: 99%

Flow Control Optimisation to Maximise the Accuracy of Multi-phase Flow Rate Allocation

Malakooti¹,

Muradov²,

Davies³

et al. 2015

All Days

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The value added by intelligent wells (I-wells) derives from real-time, reservoir and production performance monitoring together with zonal, downhole flow control. Unfortunately, downhole sensors that directly measure the flow rates and phase cuts required for optimal control of the well's producing zones are not normally installed. Instead, Multi-zone, Multi-phase Flow Metering (MFM) parameters are calculated from indirect measurements (e.g. from zonal pressures, temperatures, and well flow rates).To-date all published techniques of zonal flow rate allocation in multi-zone I-wells are "passive" in that they calculate the MFM parameters for a fixed given configuration of the completion. These techniques are subject to model error, but also to errors stemming from measurement noise when there is insufficient data duplication for accurate parameter estimation. This paper describes an "active" monitoring technique which uses a direct search method based on Deformed Configurations to optimise the sequence of Interval Control Valve (ICV) positions during a routine multi-rate test in a "intelligent" well. This novel approach maximises the accuracy of the calculated reservoir properties and MFM parameters.Four "active monitoring" levels are available. Each one uses a particular combination of down-hole and surface measurements depending on the available well performance monitoring systems. Level one is the simplest, requiring a minimal amount of well data. The higher levels require more data; but provide, in return, a greater understanding of the in-flow performance, the volumes of produced fluids and the reservoir's properties at both a well and a zonal level.Our "active monitoring" workflow can be extended to a wide range of production and injection allocation problems for any well completion type. The workflow may also be used to improve the accuracy of production flow rate measurements and, ultimately, to maximise oil production rate and recovery.

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Section: Introductionmentioning

confidence: 99%

Flow Control Optimisation to Maximise the Accuracy of Multi-phase Flow Rate Allocation

Malakooti¹,

Muradov²,

Davies³

et al. 2015

All Days

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Study of the Intelligent Completion System for Liaohe Oil Field

Huang

Peng

et al. 2011

Procedia Engineering

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Inflow Performance Identification and Zonal Rate Allocation from Commingled Production Tests in Intelligent Wells—Offshore West Africa

et al. 2011

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The main objective of a production well test is to assist in the identification of reservoir and well parameters needed for regulatory accounting, well surveillance, and asset management purposes. Interpreted information is used to drive decisions on production enhancement, operations optimization, and field-development plans. However, uncertain results may occur when wells are produced from multiple reservoirs. Currently, the industry approach is to allocate well and reservoir parameters based on known petrophysical data, offset well information, and zonal well tests. When possible, testing by difference is commonly performed to control one or more zones; however, this process may result in significant production losses with poor concluding results, especially when zonal interference is vital to a well's operating point (e.g., intelligent wells in a waterflood field). A methodology was developed to consistently identify reservoir and well-performance parameters from wells produced under commingle conditions from multiple reservoir zones by leveraging available real-time data. This methodology was successfully applied in a field located in offshore West Africa, a waterflooded field with nine intelligent wells. The methodology integrates surface well-test rates, pressures, and downhole triple-gauge data. Collected data is validated via a rigorous history calibration process of an integrated production model consisting of an analytical reservoir, well, downhole and surface chokes, and pipeline models. The calculated parameters (e.g., zonal rates, productivity index, reservoir pressure, gasoil ratio, and water cut) are the result of an error minimization between calculated variables and measured field data. This paper presents applications of this methodology for two production tests of a single dry-tree well with individually controlled reservoir zones. Benefits of the above application include a 90% reduction of the time required to perform a similar analysis, reduced uncertainty in rate allocation and reservoir parameters, and better understanding of the likely production from every reservoir zone. Because well and reservoir parameters are allocated to individual layers, the resulting rate allocation satisfies all sensor data and physical models, and therefore the uncertainty of the allocation is reduced. In addition, the application provides the basis for rate allocation to multiple zones in real time when well tests are not available.

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An Application Case of Transferring Intelligent Well System Triple-Gauge Data into Real-Time Flow Allocation Results

Cited by 7 publications

References 15 publications

Flow Control Optimisation to Maximise the Accuracy of Multi-phase Flow Rate Allocation

Flow Control Optimisation to Maximise the Accuracy of Multi-phase Flow Rate Allocation

Study of the Intelligent Completion System for Liaohe Oil Field

Inflow Performance Identification and Zonal Rate Allocation from Commingled Production Tests in Intelligent Wells—Offshore West Africa

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