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The pilot Chemical EOR project in Sabriyah Field, Kuwait is implemented applying a five-spot pattern: four injectors and one producer. The results of base-line logging campaign performed in EOR area with the purpose of appraising the current state of the reservoir before EOR implementation have been addressed earlier in [1]. The objective of this paper is to demonstrate the results and value of reservoir-oriented noise and temperature logging campaign carried out during the water injection stage, before chemical injection. To investigate the reservoir and well parameters in EOR area, an integrated logging suite consisting of High Precision Temperature (HPT) and Spectral Noise Logging (SNL) tools was run. High-definition broadband SNL tool with a large scanning radius successfully located the active flow units including low-rate ones and differentiated between reservoir flows, behind-casing channelling and leaks in well completion components, even behind multiple barriers. HPT data were analysed to quantify flow/injection profiles by matching the simulated reservoir temperature logs with field measurements under flowing/injection and static conditions, riglessly. The main objectives of the extensive logging campaign during water injection phase before chemical EOR were to determine the water injection profile in pilot injectors and estimate the effective thickness of the target reservoir zones being developed. It was found out that injection/flow profiles in injectors and producers drilled in a heterogeneous formation were non-uniform: the flow from injector to producer propagated mostly through highly-permeable layers. This resulted in a rapid injection water breakthrough: in the producer, water breakthrough occurred in a highly permeable zone only several feet thick. The least effective thickness (34-38% of the entire perforation zone) was found in the injectors situated to the west of the producer, while in the eastern part of the EOR area the effective thickness of the reservoir was 56-59%. It was also discovered that the underlying formation cooled off considerably after the pilot injection had started, which might be caused by water migration to the lower reservoir zones in offset injector, because no substantial water loss to the underlying formation was detected in the logged injectors. The information obtained during the surveys will be used for updating the Chemical EOR Project to ensure injection water flow control by injecting chemicals and chart the de-risking and mitigation plan for implementing and testing during EOR pilot. The results confirmed the possibility of using polymers during development of such kind of a heterogeneous reservoir, and requirements of more due diligence prior to the implementation of EOR pilot.
The pilot Chemical EOR project in Sabriyah Field, Kuwait is implemented applying a five-spot pattern: four injectors and one producer. The results of base-line logging campaign performed in EOR area with the purpose of appraising the current state of the reservoir before EOR implementation have been addressed earlier in [1]. The objective of this paper is to demonstrate the results and value of reservoir-oriented noise and temperature logging campaign carried out during the water injection stage, before chemical injection. To investigate the reservoir and well parameters in EOR area, an integrated logging suite consisting of High Precision Temperature (HPT) and Spectral Noise Logging (SNL) tools was run. High-definition broadband SNL tool with a large scanning radius successfully located the active flow units including low-rate ones and differentiated between reservoir flows, behind-casing channelling and leaks in well completion components, even behind multiple barriers. HPT data were analysed to quantify flow/injection profiles by matching the simulated reservoir temperature logs with field measurements under flowing/injection and static conditions, riglessly. The main objectives of the extensive logging campaign during water injection phase before chemical EOR were to determine the water injection profile in pilot injectors and estimate the effective thickness of the target reservoir zones being developed. It was found out that injection/flow profiles in injectors and producers drilled in a heterogeneous formation were non-uniform: the flow from injector to producer propagated mostly through highly-permeable layers. This resulted in a rapid injection water breakthrough: in the producer, water breakthrough occurred in a highly permeable zone only several feet thick. The least effective thickness (34-38% of the entire perforation zone) was found in the injectors situated to the west of the producer, while in the eastern part of the EOR area the effective thickness of the reservoir was 56-59%. It was also discovered that the underlying formation cooled off considerably after the pilot injection had started, which might be caused by water migration to the lower reservoir zones in offset injector, because no substantial water loss to the underlying formation was detected in the logged injectors. The information obtained during the surveys will be used for updating the Chemical EOR Project to ensure injection water flow control by injecting chemicals and chart the de-risking and mitigation plan for implementing and testing during EOR pilot. The results confirmed the possibility of using polymers during development of such kind of a heterogeneous reservoir, and requirements of more due diligence prior to the implementation of EOR pilot.
EOR pilot initiatives, integral to the company's strategy, are conducted within limited areas, typically less than ∼5 acres, to assess the commercial feasibility of selected EOR methodologies for specific reservoirs. This study examines subsurface challenges encountered throughout the execution of EOR projects, focusing on geological uncertainties. It proposes pragmatic remedies by addressing constraints in geological data and devising risk mitigation strategies during the pilot implementation phase. Drawing upon insights gleaned from EOR pilot initiatives, various strategies are employed to mitigate geological uncertainties within and surrounding the pilot zone. These encompass the acquisition of directional surveys in pilot and adjacent monitoring wells, as well as the collection of core samples, RFT data, fluid specimens, CBL logs, FMI, and VIT data in a minimum of two pilot wells to facilitate correlation. Additionally, comprehensive analyses such as complete core CT scans, sedimentological assessments, XRD analyses, and petrographic studies are conducted. Surveillance during the pilot phase involves obtaining baseline and time-lapse data through methods like HPT-SNL, PLT, induction resistivity, and pulse neutron logging. Furthermore, interwell tracer data is acquired at least twice and integrated with geological correlations. In the first case study, a three-well pilot comprising two injectors and one producer, alongside an existing central producer, was initially designed. The first injector well was drilled based on the predetermined plan. Subsequent analysis of the most recent deviation surveys revealed alterations in the target subsurface distances between the injector and central producer wells, prompting adjustments to the design to align with the updated surveys. In the second case study, the acquisition of cores from multiple wells within a conventional five-spot chemical EOR pilot proved instrumental in accurately determining the depths and widths of highly permeable zones in each well. This core data was then correlated with HPT-SNL logs to delineate the extension of permeable layers within the pilot area. Furthermore, insights derived from formation mineralogy aided in understanding issues related to siderite precipitation resulting from chemical injection, particularly in zones with large perforation intervals. The third case study involved a miscible gas EOR pilot, cores from pilot wells aided in avoiding weathered zones for perforation. VIT, guided by FMI and openhole logs, identified six lithological barriers; unexpectedly, only two were leak-free. These findings shed light on gas breakthroughs and guided perforation strategies. The study focus lies on tackling geological uncertainties and suggesting solutions like thorough data acquisition. Adaptation of pilot designs using deviation surveys, accurate zone identification through core data, and employing Vertical Interference Testing (VIT) for lithological barrier assessment in miscible gas EOR projects are highlighted as essential insights.
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