Characteristics of High Flow Zones and a Balanced Development Strategy of a Thick Bioclastic Limestone Reservoir in the Mishrif Formation in X Oilfield, Iraq

The Mishrif Formation in X Oilfield in Iraq is heterogeneous and has prominent development contradictions, and the development plan required urgent adjustment. Based on data regarding the core, cast thin sections, physical property, mercury injection experiments, and development performance, the main geological factors causing the unbalanced development of the Mishrif Formation are identified, and the corresponding development strategy is proposed. The results show that the High Flow Zones (HFZs) are the main geological factors causing unbalanced production in the thick bioclastic limestone reservoir. There are three kinds of HFZs in MA, MB1, and MB2 intervals, namely, the point shoal type, the tidal channel type, and the platform margin shoal type. All HFZs have different scales and distribution patterns. HFZs have ultra-high permeability and large permeability differences with the surrounding reservoir. During development, the oil mainly comes from HFZs, and the considerable reserves in the low permeability reservoir surrounding the HFZs are difficult to develop. The size of the pore throat of the HFZs greatly varies, and permeability is mainly dominated by the mega-pore throat (>10 μm) and the macro-pore throat (2.5~10 μm). In water flood development, the injected water rapidly advances along the mega-pore throat and the macro-pore throat, and the oil in the micro-pore or medium-pore throats are difficult to be displace. It can be concluded that the Mishrif Formation is vertically heterogeneous. The connectivity of HFZs in different intervals greatly varies. As a result, the Mishrif Formation is divided into three development units, MA, MB1, and MB2 + MC, and production wells are deployed in HFZs. The MA adopts a reverse nine-point injection-production pattern, for which the well spacing is 900 m using a vertical well, and the injection well should avoid the HFZs near the faults. The MB1 adopts an irregular five-point injection-production pattern using a vertical well, and the injection wells are deployed at the edge of the tidal channel or in the lagoon. MB2_1 deploys horizontal production wells, for which the well spacing is 900 m. Horizontal production wells, for which the well spacing is 300 m, are deployed in the lower MB2, and the lateral horizontal production wells are converted into injection wells after water breakthrough, and the horizontal wells deployed in the lower part of MC should moderately inject water.

[1]  Meiyan Fu,et al.  The Nonuniform Distribution of Stylolite in Bioclastic Limestones and Its Influence on Reservoir Petro-Physical Properties—A Case Study of the Mishrif Formation from the Ah Oilfield , 2022, Energies.

[2]  Bo Liu,et al.  Control of depositional and diagenetic processes on the reservoir properties of the Mishrif Formation in the AD oilfield, Central Mesopotamian Basin, Iraq , 2021 .

[3]  Ahmed N. Al-Dujaili,et al.  Characterization of flow units, rock and pore types for Mishrif Reservoir in West Qurna oilfield, Southern Iraq by using lithofacies data , 2021, Journal of Petroleum Exploration and Production Technology.

[4]  Y. Tong,et al.  Karstification characteristics of the Cenomanian-Turonian Mishrif Formation in the Missan Oil Fields, southeastern Iraq, and their effects on reservoirs , 2021, Frontiers of Earth Science.

[5]  Bo Liu,et al.  The characteristics and origins of thief zones in the Cretaceous limestone reservoirs of Central and southern Mesopotamian Basin , 2021 .

[6]  Xiaobo Guo,et al.  Quantitative evaluation of the carbonate reservoir heterogeneity based on production dynamic data: A case study from Cretaceous Mishrif formation in Halfaya oilfield, Iraq , 2021 .

[7]  K. Ahmad,et al.  Facies Architecture, Diagenesis and Paleoceanography of Mishrif (Late Cretaceous) in Selected Wells of West Qurna Oil Field, Southern Iraq , 2020, Journal of Physics: Conference Series.

[8]  Amani L. M. Salih,et al.  Reservoir characterization, Facies distribution, and sequence stratigraphy of Mishrif Formation in a selected oilfield, South of Iraq , 2020, Journal of Physics: Conference Series.

[9]  Yan Wang,et al.  Characterization of paleo-karst reservoir and faulted karst reservoir in Tahe Oilfield, Tarim Basin, China , 2020 .

[10]  J. Ou,et al.  Depositional and diagenetic controls on reservoir quality: Example from the upper Cretaceous Mishrif Formation of Iraq , 2020 .

[11]  Hussein A. Chafeet,et al.  Diagenesis processes impact on the carbonate Mishrif quality in Ratawi oilfield, southern Iraq , 2020, Modeling Earth Systems and Environment.

[12]  Guoyin Zhang,et al.  Grid density overlapping hierarchical algorithm for clustering of carbonate reservoir rock types: A case from Mishrif Formation of West Qurna-1 oilfield, Iraq , 2019, Journal of Petroleum Science and Engineering.

[13]  Y. Rafiei,et al.  Improved reservoir characterization by employing hydraulic flow unit classification in one of Iranian carbonate reservoirs , 2019, Advances in Geo-Energy Research.

[14]  Bo Liu,et al.  Pore types, origins and control on reservoir heterogeneity of carbonate rocks in Middle Cretaceous Mishrif Formation of the West Qurna oilfield, Iraq , 2018, Journal of Petroleum Science and Engineering.

[15]  Li Yong,et al.  Optimum development options and strategies for water injection development of carbonate reservoirs in the Middle East , 2018 .

[16]  Hongfu Shi,et al.  Mechanisms of reservoir pore/throat characteristics evolution during long-term waterflooding , 2017 .

[17]  A. Aqrawi,et al.  Role of facies diversity and cyclicity on the reservoir quality of the mid-Cretaceous Mishrif Formation in the southern Mesopotamian Basin, Iraq , 2017, Special Publications.

[18]  J. Powell,et al.  Cenomanian–turonian stable isotope signatures and depositional sequences in northeast Egypt and central Jordan , 2017 .

[19]  Anjiang Shen,et al.  Characteristics, origin and distribution of dolomite reservoirs in Lower-Middle Cambrian, Tarim Basin, NW China , 2016 .

[20]  Cong Xiao,et al.  Geologic features and genesis of the barriers and intercalations in carbonates: A case study of the Cretaceous Mishrif Formation, West Qurna oil field, Iraq , 2016 .

[21]  A. Aqrawi,et al.  SEQUENCE STRATIGRAPHIC ANALYSIS OF THE MID‐CRETACEOUS MISHRIF FORMATION, SOUTHERN MESOPOTAMIAN BASIN, IRAQ , 2014 .

[22]  Bingjian Li,et al.  Detecting Thief Zones in Carbonate Reservoirs by Integrating Borehole Images With Dynamic Measurements: Case Study From the Mauddud Reservoir, North Kuwait , 2010 .

[23]  F. Meyer,et al.  Stratigraphic and Petrophysical Characteristics of Cored Arab-D Super-k Intervals, Hawiyah Area, Ghawar Field, Saudi Arabia , 2000, GeoArabia.