Field-Wide Interference Test For Understanding The Hydraulic Communication Between Two Stacked Reservoirs

Al-Quaimi, Bandar Ibrahim; Ansah, Joseph; Al-Shehab, Mahdi Abdulla; Al-Ajmi, Fahad

doi:10.4043/20571-ms

All Days 2010

DOI: 10.4043/20571-ms

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Field-Wide Interference Test For Understanding The Hydraulic Communication Between Two Stacked Reservoirs

Bandar Ibrahim Al-Quaimi

Joseph Ansah

Mahdi Abdulla Al-Shehab

et al.

Abstract: A field-wide interference test was recently conducted to delineate the hydraulic communication between two large carbonate reservoirs separated by a thick non-reservoir formation. The reservoirs were newly developed with peripheral water injection for pressure support. This initial development stage provided an opportunity to take advantage of the undisturbed state of the two reservoirs during field commissioning to conduct this interference test prior to production. The injection start-up was, therefore, desi… Show more

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Cited by 6 publications

References 5 publications

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Enhancement of Vorwata Field Reservoir Model by Integration of Pressure Transient Analysis with Real-Time Downhole Pressure Data

Setiawan¹,

Hird²,

Bennett³

2011

SPE Asia Pacific Oil and Gas Conference and Exhibition

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Vorwata is a giant gas field located in Bintuni Bay, Papua Barat Province, Indonesia. The field was discovered in 1997 and currently produces approximately 1.3 bcf/d of dry gas from the Roabiba sandstone reservoir. Initial development consists of 14 wells drilled from two platforms. The wells produce through 7-inch tubing and have been tested up to 240 mmscf/d. A Permanent Downhole Pressure Sensor (PDPS) is installed in each well to continuously monitor downhole pressure and temperature.Vorwata field is a faulted, high sand quality reservoir. The impact of faults on reservoir performance was very uncertain prior to startup. There was great concern the field could be compartmentalized, or at least strongly influenced by flow baffles and barriers. One of the primary subsurface objectives during pre-startup testing was to assess lateral and vertical reservoir connectivity within the development area.Pressure build-up tests (PBU) were conducted in each well as part of the initial clean up and testing procedure. The initial tests were very helpful in characterizing offset faults. PBUs obtained once the field was put on production are influenced by interference from offset wells, masking any boundary effects. Interpretation of the PBUs is enhanced by applying deconvolution. A pre-startup interference test successfully identified lateral and vertical pressure communication within the development area. The well/fault geometries and reservoir connectivity characteristics obtained from the PBUs and interference test have been used to condition the static and dynamic models.This paper describes the well testing program that has been implemented to reduce reservoir uncertainty in the Vorwata reservoir during the early phase of field development. Well test and pressure interference results have been integrated into full-field models to better assess future field performance and development decisions.

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Enhancement of Vorwata Field Reservoir Model by Integration of Pressure Transient Analysis with Real-Time Downhole Pressure Data

Setiawan¹,

Hird²,

Bennett³

2011

SPE Asia Pacific Oil and Gas Conference and Exhibition

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Detecting and Managing Inter-Reservoir Communication between Two Stacked Reservoirs

et al. 2012

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractThe challenge of how to effectively manage a field with multiple reservoirs that are in hydraulic communication comes up routinely when the field is under waterflood. Conventional management of such fields can result in many undesired outcomes such as a premature water production caused by cross-channeling from different reservoirs, inefficient pressure support to some of the individual reservoirs, or large volumes of bypassed oil. The main challenge that leads to such outcomes is the ability to identify the medium and magnitude of the inter-reservoir communication within the field. This paper addresses a field practice to pinpoint the communication between two reservoirs while the field is on production, along with its capability to further improve the effective reservoir management.The field consists of two large carbonate reservoirs separated by thick non-reservoir formation. Historical data proved the inter-reservoir communication in the field. I-Field technology was a primary component in the development of this field. This technology has become a tool for an effective day-to-day reservoir management. This enables pro-active management rather than the traditional, re-active, management with respect to field life due to its added advantage of early detection of anomalies and subsequently enhances characterization. In this field, i-field facilitated a field-wide interference test that was conducted prior to field production start-up to help with field characterization including inter-reservoir communication between the two reservoirs.Field cases describing the integration of static and dynamic data that led to better understanding of the field are presented. Results of this study will play a major role in building a robust dynamic model that can capture the fluids exchange between the two reservoirs. Such model will become an important tool for managing both reservoirs in order to maximize ultimate recovery from the field.

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Interpretation of Well Test Data from Two Hydraulically Communicating Reservoirs

Quaimi

Ibrahim

2012

All Days

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Naturally fractured reservoirs (NFR) have been receiving more attention than ever since the beginning of the last decade due to various reasons. The current understanding is not sufficient to achieve a favorable recovery factor, due to the lack of effective characterization and the complex dynamic nature of the fractured system. The fact that NFR are found in many countries around the globe in almost every lithology is another justification for more interest. The majority of the fractured reservoirs around the world are developed. Therefore, before proceeding into secondary or possibly tertiary recovery processes a thorough understanding must be accomplished to avoid undesirable results. The fracture characterization is the first building block in any NFR study. This study utilized well test data to detect fractures between two communicating reservoirs. The study was inspired by a real field example in which two reservoirs, separated by a thick non-reservoir formation, are in hydraulic communication with each other. A refined simulation model was constructed to predict the type of response that would be observed in such communicating reservoirs during a well test. This paper presents the result of this study, which showed a unique shape on the derivative due to the communication through fractures. The investigation was taken further to study the impact of the first and the third layer permeabilities on the observed shape of the derivative. The impact of fracture length, fracture permeability, fracture distance from the well, and the existence of multiple fractures were also investigated.

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Field-Wide Interference Test For Understanding The Hydraulic Communication Between Two Stacked Reservoirs

Cited by 6 publications

References 5 publications

Enhancement of Vorwata Field Reservoir Model by Integration of Pressure Transient Analysis with Real-Time Downhole Pressure Data

Enhancement of Vorwata Field Reservoir Model by Integration of Pressure Transient Analysis with Real-Time Downhole Pressure Data

Detecting and Managing Inter-Reservoir Communication between Two Stacked Reservoirs

Interpretation of Well Test Data from Two Hydraulically Communicating Reservoirs

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