Optimizing Waterflood Management in a Giant UAE Carbonate Oil Field Using Simulation-Based Streamlines

Khan, Sameer A.; Zaabi, Noura Al; Jani, Zankar; Tariq, Syed M.; Tee, Aaron

doi:10.2118/171777-ms

Abu Dhabi International Petroleum Exhibition and Conference 2014

DOI: 10.2118/171777-ms

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Optimizing Waterflood Management in a Giant UAE Carbonate Oil Field Using Simulation-Based Streamlines

Sameer A. Khan¹,

Noura Al Zaabi²,

Zankar Jani

et al.

Abstract: Streamlines have been acknowledged as a powerful tool for modeling and optimizing waterfloods in oil reservoirs. Streamlines provide visualization of reservoir fluid flow and a unique way to conceptualize and quantify injector-producer well connectivity. Well allocation factors (WAFs) between injectors and producers as well as injection efficiency can be calculated and used to optimize water injection and reduce injection water cycling while focusing on maximizing oil recovery. The objective of this study was … Show more

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Cited by 11 publications

References 9 publications

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Advances in Reservoir Management and Surveillance for a Giant Carbonate Reservoir

Al-Marzouqi

Owens²,

Tee³

et al. 2015

Day 4 Thu, November 12, 2015

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Significant advances in reservoir management have been achieved in recent years to address the many challenges in managing giant carbonate reservoirs. The advances are made possible due to culmination of three key elements working in harmony: Work Processes, Technology and People. Three major advances mentioned in this paper underpin this all important truth in reservoir management and surveillance. First is the development and implementation of a framework of recommended Integrated Reservoir Management Practices with detailed and structured multi-disciplinary workflows. Information Technology plays a key role in all these workflows via automation, data integration and visualization. Second is a new generation data integration and analysis tool facilitating data and work flow integration and providing a common platform for intelligent and interactive display, thus promoting collaboration to achieve synergistic benefits. Third is the application of advanced simulation-based streamline techniques whereby new technology and workflows are deployed, with full collaboration among stakeholders.The Integrated Reservoir Management Practices include a set of highly interactive workflows set in a continuous improvement loop: Data Gathering Requirements, Data QC/QA, Data Analysis, Integration and Visualization, Opportunity Generation, Execution and Monitoring. ZADCO is following these workflows with significant improvement in work efficiency and results. In the collaborative environment, open communication and sharing of knowledge is strongly encouraged among stakeholders to assess the problem from different perspectives. This often results in creative solutions being developed. The new generation integration tool further facilitates collaboration as it retrieves data from reservoir static and dynamic models, surveillance data such as cased-hole logs and pressure data, and displays them for interactive work sessions, including animated display to give extra insight on time dependent data. The streamlines enable model-based well allocation factors (WAFs) to be calculated to supplement analytically derived WAFs, guiding injection optimization and thus resulting in improved reservoir management.These advanced workflows and tools have helped ZADCO to make timely and informed decisions, resulting in significant savings to the company, and at the same time improving understanding of reservoir behavior and facilitating optimization of ongoing development plans. The advanced workflows and tools have been recognized by Shareholders as game changers greatly needed to better manage the complex giant carbonate reservoir.

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Advances in Reservoir Management and Surveillance for a Giant Carbonate Reservoir

Al-Marzouqi

Owens²,

Tee³

et al. 2015

Day 4 Thu, November 12, 2015

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Optimizing Water Flood Performance to Improve Injector Efficiency in Fractured low-Permeability Reservoirs Using Streamline Simulation

Lei

Li³

et al. 2016

All Days

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Objectives/Scope Waterflooding has been the main development method for maintaining the formation energy in low-permeability reservoirs. Often these reservoirs are characterized by poor sweep and high water cut of oil wells due to natural fractures. Streamline technology is an ideal tool for optimization of waterflooding operations. One of the main advantages of streamline simulation is to display paths of fluid flow and to calculate rate allocation factors. However, describing fluid transport in fractured low-permeability reservoirs entails additional challenge because of the complicated physics arising from matrix-fracture interactions. Methods, Procedures, Process In this paper we demonstrate a straightforward workflow for optimizing injection rate based on a comprehensive analysis of injector efficiency (IE). First, the streamline model including improved transfer function and non-Darcy flow of matrix is generalized to describe fluid transport. In particular, the streamline time of flight concept is utilized to develop a general dual porosity dual permeability system of equations for water injection in naturally fractured reservoirs. The streamlines can be derived from the flux field of this model that represent a snapshot of the flow pattern within the reservoir, well drainage region information and fluid allocation changes with the flood progression. Second, using an analytical calculation to compute weighting factors for injection/production rate targets from a derived ranking of the wells (IE). Finally, reallocation of injected fluid volumes from low-efficiency to high-efficiency injectors improves volumetric displacement and sweep efficiency in the less swept areas of the reservoir. The application of this workflow is demonstrated with a real-field example of an fractured low-permeability sandstone reservoir in Chang Qing oilfield in China where the pattern balancing has led to incremental production over the 5 years forecast in which the IE average of the field is the benchmark while obeying facility constraints. Results, Observations, Conclusions The results indicate that water cycling was quantified by streamline simulation and water injection with a decrease of 30-40% on the maximum principal stress direction causes in a reduction in the produced water volumes. A new water injection strategy was implemented, and a decrease in water cut on this challenge sector was achieved in the targeted producers. Novel/Additive Information This work provides a comprehensive case study and useful method for better understanding the fractures on waterflooding performance and optimizing production plan of maximizing oil recovery on the fractured low-permeability reservoir.

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A Novel Holistic Workflow for Field Development Planning in Green Field Environment: A Case Study

Alkhatib¹,

Ali²,

Mukhtār³

et al. 2018

Day 1 Mon, November 12, 2018

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A novel workflow was developed to select the optimal field development plan (FDP) accounting for the associated uncertainties in a green onshore oil field with a limited number of wells and no production data. The FDP was then revisited in view of the performance of wells drilled during the execution phase and updated as needed based on the acquired data . Comprehensive uncertainty analysis was performed resulting in multiple subsurface realizations. A broad set of development scenarios and options were screened under uncertainty. The viable scenarios were then economically evaluated, resulting in an optimal FDP that is robust to uncertainty and the least risk prone from an economical point of view. The used workflow was specifically suitable to test many development concepts and explore various options including horizontal well orientation, well pattern concept, pattern acreage and spacing, length of the horizontal sections, and landing of the horizontal sections. Following an extensive techno-economic analysis of all possible combinations (900 in total), the most robust development concept was selected and analyzed considering the viable development strategies pertaining to plateau rate, drilling schedule, phasing, water injection timing and artificial lift timings. A phased development approach was adopted enabling acquiring necessary data to mitigate the remaining uncertainty and avoid costly consequences of significant over- or under-capacity. Data acquired in one development phase were assessed and used to update the following planned phases, if necessary. The study demonstrated that the field development could accommodate a delay in either water injection or artificial lift implementation. Although it was not recommended at this stage to delay either of them, it is noteworthy that the long lead time that may be incurred in the implementation of artificial lift or the risk of lower injectivity would not impact the field performance or ultimate recovery if contained to a few years during initial production. These results further reinforced the robustness of the proposed development plan. Large subsurface uncertainty combined with an extensive set of possible development scenarios and options required cutting-edge uncertainty analysis and screening workflows to select the optimal FDP. These unique workflows can be readily used in similar green fields to help arrive at the final FDP.

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Optimizing Waterflood Management in a Giant UAE Carbonate Oil Field Using Simulation-Based Streamlines

Cited by 11 publications

References 9 publications

Advances in Reservoir Management and Surveillance for a Giant Carbonate Reservoir

Advances in Reservoir Management and Surveillance for a Giant Carbonate Reservoir

Optimizing Water Flood Performance to Improve Injector Efficiency in Fractured low-Permeability Reservoirs Using Streamline Simulation

A Novel Holistic Workflow for Field Development Planning in Green Field Environment: A Case Study

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