Two-Zone Commingled Production using Intelligent Well Completion Coupled with ESP through a Hydraulic Disconnect Tool

Ansah, Joseph; Al-Shehab, Mahdi Abdulla; Al-Bani, Fahad Abdullah; Al-Quaimi, Bandar Ibrahim; Jacob, Suresh

doi:10.2118/120303-ms

“…Reservoir-A has excellent reservoir qualities and is laterally homogeneous in terms of petro-physical properties across the entire field. (Ansah, 2009) Collected cores along the field were utilized for fracture modeling along with dynamic flow data, pressure transient analysis and drilling information. Reservoir B is located below Reservoir-A, and is separated by a 300' impermeable carbonate mudstone formation.…”

Section: Field Characterizationmentioning

confidence: 99%

“…Crude oil fingerprint tests were also conducted and results showed that both reservoirs shared the same fluid properties (Ansah, 2009). Crude oil fingerprint tests were also conducted and results showed that both reservoirs shared the same fluid properties (Ansah, 2009).…”

Section: Historic Datamentioning

confidence: 99%

Detecting and Managing Inter-Reservoir Communication between Two Stacked Reservoirs

SayedAkram

¹

,

Tubayyeb

²

,

Ansah

³

et al. 2012

All Days

2

0

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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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“…The need to control fluid production from each reservoir was critical, especially in the areas of proven inter-reservoir communication. 3 Recall that fractures have been identified in both reservoirs and are suspected to be conduits for the communication between the reservoirs. It is only the application of smart wells equipped with ICVs (Figure 4), that will provide the capability to control and optimize fluid production, from separate laterals in the separate reservoirs, without a major workover operation,.…”

Section: Field Development and I-fieldmentioning

confidence: 99%

Field-wide Interference Test for Understanding the Hydraulic Communication between Two Stacked Reservoirs

Al-quaimi¹,

Ansah²,

Al-Shehab³

et al. 2010

Proceedings of Offshore Technology Conference

2

0

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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, designed to inject into one reservoir while monitoring pressures at various parts of the other reservoir. Several observation wells across the field were designated to record the pressure changes during the initial water injection stage to provide the field coverage. The injection rates were also closely monitored and modified throughout the test period to record the rate of pressure change in the observation wells.The field was developed with the state-of-the-art permanent downhole monitoring systems (PDHMS) which provided the means for comprehensive monitoring of this field-wide interference test. The test showed some interesting findings within the reservoirs themselves, areas of communication were indentified and the extent of the lateral connectivity was observed. Additionally, the dynamic data acquired during this interference test will complement the static data for building improved geological and engineering models.This paper describes the test design, implementation and presents the results and findings. The test was concluded but monitoring is continuing utilizing the intelligent field (I-field) infrastructure and the results will, in future, be incorporated into reservoir simulation models for production/injection strategy optimization and accurate field performance forecasting. OTC 20571opportunity of the undisturbed state of the reservoirs, utilizing the readily available injection system, to conduct the test. The enabler was the leading-edge technologies implemented in the development.The following conclusions are drawn from the results of this field-wide test:• In addition to the central part of the field where the communication was discovered in the past, pressure communication between these two reservoirs was also seen at the southern end of the field, as this could be detected during the relatively short period of this test. • No significant pressure increase was seen in the east side suggesting no communication or very weak channels of communication in that area. • The degree of inter-reservoir communication at various parts of the field was assessed using the interference test results.With the conclusion of this field-wide interference test, the results will be used to adjust production/injection plans in both reservoirs in order to maximize hydrocarbon recovery. The potential risk of water encroachment from Reservoir B into Reservoir A will be minimized by this knowledge of more areas of communication.

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“…3 Recall that fractures have been identified in both reservoirs and are suspected to be conduits for the communication between the reservoirs. This multiple-pay environment called for commingling production from these reservoirs, to reduce development costs and optimize field development.…”

Section: Field Development and I-fieldmentioning

confidence: 99%

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

Al-Quaimi

¹

,

Ansah

²

,

Al-Shehab

³

et al. 2010

All Days

6

0

View full text Add to dashboard Cite

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, designed to inject into one reservoir while monitoring pressures at various parts of the other reservoir. Several observation wells across the field were designated to record the pressure changes during the initial water injection stage to provide the field coverage. The injection rates were also closely monitored and modified throughout the test period to record the rate of pressure change in the observation wells.The field was developed with the state-of-the-art permanent downhole monitoring systems (PDHMS) which provided the means for comprehensive monitoring of this field-wide interference test. The test showed some interesting findings within the reservoirs themselves, areas of communication were indentified and the extent of the lateral connectivity was observed. Additionally, the dynamic data acquired during this interference test will complement the static data for building improved geological and engineering models.This paper describes the test design, implementation and presents the results and findings. The test was concluded but monitoring is continuing utilizing the intelligent field (I-field) infrastructure and the results will, in future, be incorporated into reservoir simulation models for production/injection strategy optimization and accurate field performance forecasting. OTC 20571opportunity of the undisturbed state of the reservoirs, utilizing the readily available injection system, to conduct the test. The enabler was the leading-edge technologies implemented in the development.The following conclusions are drawn from the results of this field-wide test:• In addition to the central part of the field where the communication was discovered in the past, pressure communication between these two reservoirs was also seen at the southern end of the field, as this could be detected during the relatively short period of this test. • No significant pressure increase was seen in the east side suggesting no communication or very weak channels of communication in that area. • The degree of inter-reservoir communication at various parts of the field was assessed using the interference test results.With the conclusion of this field-wide interference test, the results will be used to adjust production/injection plans in both reservoirs in order to maximize hydrocarbon recovery. The potential risk of water encroachment from Reservoir B into Reservoir A will be minimized by this knowledge of more areas of communication.

show abstract

Two-Zone Commingled Production using Intelligent Well Completion Coupled with ESP through a Hydraulic Disconnect Tool

Cited by 12 publications

References 6 publications

Detecting and Managing Inter-Reservoir Communication between Two Stacked Reservoirs

Detecting and Managing Inter-Reservoir Communication between Two Stacked Reservoirs

Field-wide Interference Test for Understanding the Hydraulic Communication between Two Stacked Reservoirs

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

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