Application of Intelligent Completions To Optimize Waterflood Process on a Mature North Sea Field: A Case Study

Ajayi, Arashi; Konopczynski, Michael; Tesaker, Oeystein

doi:10.2118/101935-ms

Cited by 12 publications

(1 citation statement)

References 11 publications

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“…For the screening of ICVs, this study follows the same approach presented by Ajayi et al (2006) and Al-Khelaiwi et al (2008). For the screening of ICVs, this study follows the same approach presented by Ajayi et al (2006) and Al-Khelaiwi et al (2008).…”

Section: Fig 2-smart Completion Proposed For Kwidf Project Horizontmentioning

confidence: 99%

Optimizing the Waterflooding Performance of a Carbonate Reservoir with Internal Control Valves

et al. 2013

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Intelligent digital oilfield (iDOF) operations include the transfer, monitoring, visualization, analysis, and interpretation of real-time data. Enabling this process requires a significant investment to upgrade surface, subsurface, and well instrumentation and also the installation of a sophisticated infrastructure for data transmission and visualization. Once upgraded, the system is then capable of transferring massive quantities of data, converting it into real information at the right time.The transformation of raw data into information is achieved through intelligent, automated work processes, which are referred to here as "smart flows." Smart flows assist engineers in their daily well surveillance activities, helping make them more productive and improve decision making. A major oil and gas operator in the Middle East has invested in such an infrastructure and is developing a set of smart flows for key activities and workflows for its production operations, with the ultimate goal of improved asset performance.In response to early water breakthrough, a study was commissioned to investigate whether smart completions that use down-hole internal control valves (ICVs) could provide a range of fluid-flow control options to enhance reservoir sweep efficiency, reduce produced water, and increase well life. This paper describes the strategy and process to identify production and injection wells best suited for intelligent well completions in the Sabriyah field, Mauddud reservoir. The goal is to control zonal injection and production rates to reduce uneven water fronts, sweep and produce bypassed oil, postpone water breakthrough, and extend well life, thus boosting oil production while optimizing water handling at the surface. The study demonstrates excellent potential for down-hole control to significantly improve operations in the water injection areas.

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Section: Fig 2-smart Completion Proposed For Kwidf Project Horizontmentioning

confidence: 99%

Optimizing the Waterflooding Performance of a Carbonate Reservoir with Internal Control Valves

et al. 2013

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Chapter 12 Specialist Completions

Bellarby¹

2009

Developments in Petroleum Science

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Field Development Plans Optimization by Modeling Fluids Flow Impact and Assessing Intelligent Wells on Reservoir Performance

Elrafie

AlQahtani

Agil

et al. 2008

Abu Dhabi International Petroleum Exhibition and Conference

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The understanding and accuracy of modeling fluid flow behavior in naturally fractured carbonate reservoir is critical in predicting reservoir sweep efficiency, remaining drilling targets and evaluating field development alternatives. The use of appropriate complex wells design such as Horizontals, (H) Multi-laterals (ML) and completion technology such as equalizers (ICD) or Inflow Control Valves (ICV) are of equal importance. The approach presented in this paper is based on detailed integrated analysis of all available well data including logs, production, pressure transient analysis (PTA), fracture distributions, well flow profiles (PLT) etc, to provide a first-line insight of the fractured reservoir fluid flow mechanism. These first-line insights provide the basis to develop mechanistic or concept reservoir simulation models to fine-tune fluid movement understanding in fractures, reservoir matrix, well types (H, ML) and completion placement to field development strategies. Sector modeling provides further insight to well design in field areas of different rock quality and fracture density. Well type and completion strategy alternatives for each identified field area including intelligent smart well completions are developed and tested in each sector model. The combined developed understanding of fluid flow mechanisms, well type and completion strategy are rolled up and implemented into a full field simulation model, fine tuned through history match and prediction processes. This paper describes the methodology used to study a number of naturally fractured carbonate reservoirs through the integrated "Event Solution"1 study approach. The methodology presented in this paper was applied on a number of large Middle East carbonate fields. The fields studied have naturally fractured reservoirs with two distinct fracture systems. Namely, fracture corridors or clusters and diffuse or layer-bounded fractures. Diffuse fractures are typically horizontal (layer-bounded fractures) inter-connect with the fracture corridors which are normally vertical to sub-vertical. This fracture system combination forms a highly conductive fluid flow and pressure medium which is responsible for observed water movement as well as pressure propagation from the aquifer/injectors into the reservoirs. Background Literature presented some methodologies to numerically simulate fracture corridors and diffuse fractures systems in naturally fractured carbonate reservoirs. Halilu et al.2 presented a method for large fields dominated by clusters of sub-vertical fractures called fracture corridors. In this study, the effective Warren-Root and fracture parameters were adjusted to mimic explicit fracture modeling to represent fractures corridors. The study results showed that fluid flow in these fields is largely influenced by large scale fracture corridors. These large scale fracture corridors were lately named fracture fairways.

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Application of Intelligent Completions To Optimize Waterflood Process on a Mature North Sea Field: A Case Study

Cited by 12 publications

References 11 publications

Optimizing the Waterflooding Performance of a Carbonate Reservoir with Internal Control Valves

Optimizing the Waterflooding Performance of a Carbonate Reservoir with Internal Control Valves

Chapter 12 Specialist Completions

Field Development Plans Optimization by Modeling Fluids Flow Impact and Assessing Intelligent Wells on Reservoir Performance

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