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Chemistry and Technology of Fuels and Oils
Erschienen in: Chemistry and Technology of Fuels and Oils 2/2024

17.05.2024 | INNOVATIVE TECHNOLOGIES OF OIL AND GAS

Study on the Division of Remaining Recoverable Reserves Abundance in Specific Reservoirs

verfasst von: Le Qu, Xiaolei Zheng, Weigang Zhang, Jianping Liu, Yanan Zhu, Zhenzhen Nian, Kexiang Ning, Zhe Zhang

Erschienen in: Chemistry and Technology of Fuels and Oils | Ausgabe 2/2024

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Abstract

The Yanchang group Chang 6 reservoir in the Tiebiancheng area, after decades of exploitation, exhibits localized zones of relatively high permeability but is predominantly characterized as an extra-low permeability oil reservoir with minimal natural productivity. The reservoir’s strong heterogeneity poses challenges in achieving production targets, resulting in significant variations in well yields. Therefore, a scientific division of potential zones within the blocks, targeted exploitation strategies are necessary. This study classifies the recoverable reserves abundance of the Chang 6 reservoir in the Tiebiancheng area into four distinct types, based on the analysis of two oilfield indicators: material potential field and flow state field. These types are categorized as follows: high velocity and high abundance (Type I), low velocity and high abundance (Type II), high velocity and low abundance (Type III), and low velocity and low abundance (Type IV). Moreover, tailored exploitation strategies are proposed, considering the characteristics of different favorable target zones. A computational simulation of regional oil production, with zoning exploitation strategies taken into account, indicates an anticipated cumulative oil production of 1463·104 m3 by 2027, whereas the cumulative oil production of the control group is projected to reach 1387·104 m3, resulting in a notable difference of 76·104 m3, signifying a considerable improvement in the recovery rate.
Vorheriger Artikel Characterization and Application of Quartz from Different Sources in Typical Shale Reservoirs
Nächster Artikel Seismic Sequence and Source Analysis of Typical Sandstone Reservoirs

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Literatur
1.
Yao, X. T., Su, X. K., Zheng, X., et al. 3D physical simulation experiments of development effects after well pattern adjustment in extra-high water cut reservoirs. Petroleum Geology and Recovery Efficiency, 2023, 30(01), 139-145.
2.
Fan, T. E., Du, X., Fan, P. J., et al. Fault-Landform Double Controlled Archean Buried-Hill Reservoir Integrated Prediction for BZ26-6 Oil Field, Bohai Bay. Earth Science, 2023, 48(2), 429-438.
3.
Yin, S., Mei, H., Xu, X. Experimental Study on Dynamic and Static Rock Mechanical Properties of Tight Sandstone Gas Reservoir. Chem Technol Fuels Oils, 2023, 59, 561-568.CrossRef
4.
Chai, R. K., Liu, Y. T., He, Y. T. et al. Low-salinity waterflooding laws in the tight sandstone oil reservoirs of Yanchang Formation in Ordos Basin. Daqing Petroleum Geology and Development, 2022, 41(2), 67-74.
5.
Li, M., Liao, J., Wang, S., et al. Imbibition characteristics and influencing factors of reservoirs with ultra-low permeability of Ordos Basin:a case study of third memThassic Yanchang: in Weibei Oil Field. Petroleum Geology Experiment, 2022, 44(6), 971-980.
6.
Zhao, D. L., Bai, Y. B., Zhang, H. Characteristics and Reservoir-Forming Model of Yan 9 Reservoir in Jingbian Oilfield, Ordos Basin. Xinjiang Geology, 2022, 40(3), 388-393.
7.
Liu, C. C., Yang, Y. X., Fang, T. Y., et al. Evaluation method of highquality shale oil reservoir in Ordos Basin. Well Logging Technology, 2023, 34(03), 49-54+62.
8.
Zhang, X. L., Tang, Y., Li, Z.Y., et al. Hydrocarbon Accumul-ation Patterns of Chang 8 Low-Charging Oil Reservoirs in Southwestern Margin of Ordos Basin: Taking Huanxi-Pengyang Area as an Example. Journal of Xi’an Shiyou University, 2023, 38(1), 31-44.
9.
Zhang, X. M., Huang, M., Li, K., et al. Reservoir forming model and main controlling factors of Jurassic reservoir in Tiebiancheng area. Application of Petrochemical Technology, 2022, 41(7), 81-85.
10.
Ji, B.Y., Xu, T., Gao, X.J., et al. Production evolution patterns and development stage division of waterflooding oilfields. Petroleum Exploration and Development, 2023, 50(2), 433-441.CrossRef
11.
Cui, C. Z., Li, S., Yang, Y., et al. Planar zoning regulation and control method of reservoir at ultra-high water cut stage. Petroleum Exploration and Development, 2018, 39(10), 1155-1161.
12.
Naderi, M., Khamehchi, E. Well placement optimization using metaheuristic bat algorithm. Journal of Petroleum Science & Engineering, 2016, 150(13), 348-354.
13.
Lyons, J., Nasrabadi, H. Well placement optimization under time-dependent uncertainty using an ensemble Kalman filter and a genetic algorithm. Journal of Petroleum Science & Engineering, 2013, 109(9), 70-79.CrossRef
14.
Jia, H.Z., Li, B.Y., Lyu, Z., et al. Experimental study on the interaction between CO2 and Jimsar reservoir rocks. Chemical Engineering of Oil & Gas, 2021, 50(1), 76-80.
15.
Li, J.X., Liu, Y., Wu, D., et al. The Synergistic Effects of Alkaline, Surfactant, and Polymer on the Emulsification and Destabilization of Oil-in-water Crude Oil Emulsion Produced by Alkaline-surfactant-polymer Flooding. Petroleum Science & Technology, 2013, 31(4), 399-407.CrossRef
16.
Supee, A., Idris, A. K. Effects of Surfactant-Polymer Formulation and Salinities Variation Towards Oil Recovery. Arabian Journal for Science and Engineering, 2014, 39(5), 4251-4260.CrossRef
17.
Wang, G. F., Song, L. Z., Wei, Z. L., et al. A Laboratory Study of Polymer and Surfactant Binary Combination Flooding in Reservoirs with Low to Medium Permeability. Advanced Materials Research, 2013, 718-720.
18.
Guan, X.W., Meng, Q., Wang, B.B., et al. Description of Formations Fault Activity Characteristics and Genesis Mechanism Using of Paleogeomorphic Restoration Techniques. Chem Technol Fuels Oils, 2023, 59, 647-660.CrossRef
19.
Lyu, X., Zhu, G., Liu, Z. Well-controlled dynamic hydrocarbon reserves calculation of fracture–cavity karst carbonate reservoirs based on production data analysis. Journal of Petroleum Exploration and Production Technology, 2020,10, 2401-2410..CrossRef
20.
Ren, M. Y., Shi, Q., Xin, H. Z., et al. Characteristics of Remaining Oil Distribution in Conglomerate Reservoirs after Water Flooding and Technical Countermeasures. Special Oil & Gas Reservoirs, 2023, 30(1), 147-153.
21.
Dong, Y. W., Wang, R., Wang, S. Y., et al. Evaluation of Oil Displac-ement Effect and Microscopic Oil Displacement Mechanism of Viscoelastic Fluid with Low Interfacial Tension. Science Technology and Engineering, 2023, 23(3),1017-1023.
Metadaten
Titel
Study on the Division of Remaining Recoverable Reserves Abundance in Specific Reservoirs
verfasst von
Le Qu
Xiaolei Zheng
Weigang Zhang
Jianping Liu
Yanan Zhu
Zhenzhen Nian
Kexiang Ning
Zhe Zhang
Publikationsdatum
17.05.2024
Verlag
Springer US
Erschienen in
Chemistry and Technology of Fuels and Oils / Ausgabe 2/2024
Print ISSN: 0009-3092
Elektronische ISSN: 1573-8310
DOI
https://doi.org/10.1007/s10553-024-01699-6

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