Maximizing Production Recovery Through Autonomous Inflow Device AICD Configuration in Challenging Long Horizontal Open-Hole Oil Producer with High Gas-Oil-Ratio and Un-Even Fluid Contacts

Sapian, Nik Fazril Ain; Tusimin, Fuziana; Mei, Stefanie Chuah Mei; Wang, Arthur Goh Jin; Ali, Nurul Athirah Wahid; Naupa, Nagarajan AL; Madzidah, Asba; Ghonim, Elsayed Ouda; Awid, Abdurrezagh; Hasbullah, Nurathirah; Nazim, Nik Omar Md

doi:10.2118/209871-ms

Cited by 4 publications

References 5 publications

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Field B Oil Recovery Improvement Through Autonomous Inflow Control Device (AICD), A Case Study

Ariffin,

Mansor,

Marimuthu

et al. 2023

SPE/IATMI Asia Pacific Oil &Amp; Gas Conference and Exhibition

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In a thin oil column environment, the team needs to look for a way to monetize this oil with optimized cost and reduce the risk of unwanted fluid (gas and oil). To make matter worse, the reservoir drive mechanism is mainly gas-cap expansion with moderate aquifer support. The team has looked at several methods to delay this water breakthrough i.e., standoff from Oil Water Contact (OWC) and Gas Oil Contact (GOC), and Autonomous Inflow Control Device (AICD). There are two AICD types considered during the preliminary design stage which are the Fluid Diode Type and Rate-Control-Production (RCP) type. The team performed a cost-benefit analysis on these two types of AICD. AICD RCP type was selected to be the best way forward for this kind of reservoir. AICD RCP type should be able to control the horizontal drawdown thus reducing the unwanted fluid production. With this type of AICD, the viscosity contrast between oil and the unwanted fluid is important. With the viscosity contrast of 0.6 cp for oil and 0.5 cp for water, the viscosity contrast is considered low. The AICD does not work effectively to reduce water production. Thus, it is important to have a good OWC standoff to delay water production. Coupled with the reservoir dynamic model, sensitivity analysis was performed with several cases to improve the team's understanding of the AICD impact on the oil recovery. Below are cases run to ensure the best configuration were applied for each completion. Gas Oil Ratio (GOR) impact on the oil recovery with and without AICDWater Cut impact on the oil recovery with and without AICD.OWC and GOC standoff impact on the oil recovery with and without AICDNumber of AICD joints impact on the oil recovery with and without AICD The utilization of AICD technology is predicted to significantly improve oil recovery with the expected reserve to increase around 10-25% while delaying the unwanted fluid production. The field has an existing Inflow Control Device (ICD) well and 2 AICD wells just completed in 2022. With this, the team may analyze the benefit of the AICD compared to ICD. In addition, to ensure good recovery from the reservoir, a mud breaker was pumped to reduce the drilling mud damage in the open-hole section. Furthermore, oil and water tracers were installed to ensure water production location on the AICD open hole section.

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Field B Oil Recovery Improvement Through Autonomous Inflow Control Device (AICD), A Case Study

Ariffin,

Mansor,

Marimuthu

et al. 2023

SPE/IATMI Asia Pacific Oil &Amp; Gas Conference and Exhibition

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Increasing Recovery and Lowering CO2 Intensity Through Use of Autonomous Inflow Control – A Case Study from the Norwegian Continental Shelf

Halvorsen,

Martiniussen,

Nilsen

et al. 2024

SPE Annual Technical Conference and Exhibition

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The aim of this paper is to demonstrate how the adoption of autonomous inflow control (AICD) can lower water production and CO2 intensity in a field situated on the Norwegian continental shelf. The study outlines the process starting from device qualification and testing in a flow loop, followed by evaluation through modelling and reservoir simulations, then well planning to optimize AICD implementation, and finally the measurement of the effect in several wells. Breidablikk is an oilfield located on the Norwegian continental shelf that commenced oil production in October 2023. The oil reserves are at a depth of about 1750 meters, forming a thin layer that sits atop a strong water aquifer. Prior to production, a range of AICD solutions aimed at water reduction were evaluated, including qualification, and testing of the devices in a flow loop to obtain their flow performance data. This data was subsequently used as input in multiple reservoir simulations to determine the optimal distribution of AICDs in the wells. The wells are closely monitored to confirm that the expected AICD behavior has been achieved. The Breidablikk wells consist of long horizontal sections, both single and multilaterals, with lengths of up to 1600 meters. They are equipped with screens, various inflow control devices, blank sections, and swell packers. Following implementation and production start-up, measured flow rates and pressures are compared against the expected AICD performance. The lower completion design is optimized using a steady-state well simulator and the use of a dynamic reservoir simulator to provide expected production profiles. During the stepwise clean-up of the wells and branches, differential pressure and oil rates are used to measure well clean-up and AICD efficiency. The pressure drop across the AICDs is determined based on down hole pressure, plotted versus initial well test rates, and is consistent with laboratory tests under similar conditions. Chemical tracers have also been used to verify clean-up during flow performance evaluation. Based on the successful implementation, there is a good basis for planning and optimizing use of AICDs in future wells at Breidablikk. The reservoir drainage strategy for Breidablikk depends upon implementing artificial lift and utilizing the well designs mentioned earlier. Production of the wells at minimal gas lift rates, in combination with on/off well production, allows for higher NPV and recovery to be attained throughout the anticipated field lifetime. To ensure a successful implementation, step rate tests are performed to affirm the AICD flow characteristics determined through lab testing and simulations.

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Maximizing Production Recovery in Challenging Reservoirs: Insights from Autonomous Inflow Control Device (AICD) Implementation in Offshore Malaysia

Mohd Jeffry,

Ye Lin,

Mappanyompa

et al. 2024

Adipec

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Field B is an offshore brown field in Malaysia which has faced significant challenges due to the presence of a thin oil rim amidst complex reservoir conditions characterized by massive gas cap, uneven contacts, strong water drive and high sand production. Historically, early gas and water breakthroughs have been observed, leading to elevated gas-oil ratio (GOR) and high water cut. Autonomous Inflow Control Devices (AICDs) were incorporated in new horizontal infill wells since 2018 to allow production control and mitigate high GOR issues. AICDs have enabled autonomous regulation of unwanted production fluids, leveraging Bernoulli's Principle. The deployment was meticulously assessed based on reservoir characteristics, production objectives, and economic viability. This study thoroughly examines the performance of the horizontal wells equipped with AICDs integrated with openhole standalone screens (OHSAS) completion in Field B. The performance of the wells with AICDs were also compared with similar wells without AICDs to evaluate the value of this technology. Through comprehensive analysis, the investigation addressed the challenges encountered, outlined the best practices, and formulated the effective well production and monitoring strategies to ensure sustained functionality and reliability of AICDs over the production lifecycle. Various factors influencing well performance were explored, providing insights into the role of AICDs in optimizing production amidst challenging reservoir conditions. Since AICDs were adopted in recent infill wells, it was observed that the technology managed to control the gas-oil ratio (GOR) in wells that were located closer to the current gas-oil contact (GOC) and maximized the productivity. This paper features a comprehensive summary of the reservoir management, production strategy and resulting production improvement in Field B with the application of AICDs. Moreover, this paper also highlights on the effectiveness of AICDs in Field B, offering valuable insights for oil and gas operators navigating similar challenging reservoir conditions, ultimately aiming to optimize overall production efficiency.

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Maximizing Production Recovery Through Autonomous Inflow Device AICD Configuration in Challenging Long Horizontal Open-Hole Oil Producer with High Gas-Oil-Ratio and Un-Even Fluid Contacts

Cited by 4 publications

References 5 publications

Field B Oil Recovery Improvement Through Autonomous Inflow Control Device (AICD), A Case Study

Field B Oil Recovery Improvement Through Autonomous Inflow Control Device (AICD), A Case Study

Increasing Recovery and Lowering CO2 Intensity Through Use of Autonomous Inflow Control – A Case Study from the Norwegian Continental Shelf

Maximizing Production Recovery in Challenging Reservoirs: Insights from Autonomous Inflow Control Device (AICD) Implementation in Offshore Malaysia

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