In view of the problem that a single modeling method cannot predict the distribution of microfacies, a new idea of coupling modeling method to comprehensively predict the distribution of sedimentary microfacies was proposed, breaking the tradition that different sedimentary microfacies used the same modeling method in the past. Because different sedimentary microfacies have different distribution characteristics and geometric shapes, it is more accurate to select different simulation methods for prediction. In this paper, the coupling modeling method was to establish the distribution of sedimentary microfacies with simple geometry through the point indicating process simulation, and then predict the microfacies with complex spatial distribution through the sequential indicator simulation method. Taking the DC block of Bohai basin as an example, a high-precision reservoir sedimentary microfacies model was established by the above coupling modeling method, and the model verification results showed that the sedimentary microfacies model had a high consistency with the underground. The coupling microfacies modeling method had higher accuracy and reliability than the traditional modeling method, which provided a new idea for the prediction of sedimentary microfacies.
References
[1]
Zhao, B., Hou, J., et al. (2011) Modeling Method of Carbonate Fractured Reservoir Based on Point Indicating Process Simulation. Science and Technology Bulletin, 29, 39-43.
[2]
Hu, J., Feng, F., et al. (2015) Identification of Channel Sand in W Oilfield of Llanos Basin. Journal of Southwest Petroleum University (Science & Technology Edition), 37, 30-38.
[3]
Lv, Z.B., Zhao, C.M., Huo, C.L., et al. (2010) Application of Fine Facies-Constrained Geological Modeling Technology in Adjustment and Tapping Oil Potential of Old Oilfields: An Example from Suizhong 36-1 Oilfield. Lithologic Reservoirs, 22, 100-105.
[4]
Liu, Y. and Zhang, C. (2011) Petroleum Geology and Exploration in Colombia. Petroleum Geology & Experiment, 33, 226-232.
[5]
Feng, F., Wang, X., Hu, J., et al. (2015) Exploration and Development Technology for Lithologic-Structural Reservoir in Dorotea Block of Llanos Basin in South America. China Petroleum Exploration, 20, 79-88.
[6]
Zhu, Y.-X., Liu, L.-F. and Jin, J. (2004) Llarno Basin Oil and Gas Geological Characteristics and Predict Favorable Zones. Xinjiang Petroleum Geology, No. 1, 110.
[7]
Sun, Y., Guo, S.B. and Shao, Y. (2010) Application of Pre-Stack Inversion Technology to Tracing Sand Body: A Case Study from Huagang Formation in Pinghu Oil and Gas Field. Lithologic Reservoirs, 22, 27-30.
[8]
Chen, J.-Y., Yu, X.-H., Li, S.-L., et al. (2008) Multiple Seismic Attributes with a Synergy of Reservoir Geological Modeling Method. Xinjiang Petroleum Geology, 29, 106-108.
[9]
Wang, Z., Bi, J.-J. and Bao, F. (2009) The Application of Well Seismic Joint Stochastic Modeling in AoNa Region. Daqing Petroleum Geology and Development, 28, 37-39.
[10]
Li, G. and Sha, X.-M. (2011) Description of Devonian Oil Reservoirs in Algerian BEL Structure. Lithologic Reservoir, 23, 24-29.
[11]
Zhang, J., Yan, A., Liu, W., et al. (2019) Hydrocarbon Accumulation Characteristics of Cabiona Block in Llanos Basin. Petroleum Geology and Recovery Efficiency, 19, 24-26.
[12]
Thornton, J.M., Mariethoz, G. and Brunner, P. (2018) A 3D Geological Model of a Structurally Complex Alpine Region as a Basis for Interdisciplinary Research. Scientific Data, 5, Article No. 180238. https://doi.org/10.1038/sdata.2018.238
[13]
Kim, J., Lee, J.Y., Ahn, T.W., et al. (2021) Validation of Strongly Coupled Geomechanics and Gas Hydrate Reservoir Simulation with Multiscale Laboratory Tests. International Journal of Rock Mechanics and Mining Sciences, 149, Article ID: 104958. https://doi.org/10.1016/j.ijrmms.2021.104958
