Investigation of Microscopic Pore Structure and Permeability Prediction in Sand-Conglomerate Reservoirs

You Zhou; Songtao Wu; Zhiping Li; Rukai Zhu; Shuyun Xie; Xiufen Zhai; Lei Lei

doi:10.1007/s12583-020-1082-7

Journal of Earth Science ›› 2021, Vol. 32 ›› Issue (4) : 818 -827. DOI: 10.1007/s12583-020-1082-7

Article

Investigation of Microscopic Pore Structure and Permeability Prediction in Sand-Conglomerate Reservoirs

You Zhou ¹^,²^,³^,⁴
, Songtao Wu ¹^,²^,³^,^b
, Zhiping Li ⁵
, Rukai Zhu ¹^,²^,³
, Shuyun Xie ⁶
, Xiufen Zhai ¹^,²^,³
, Lei Lei ⁶

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Abstract

The microscopic pore structure of sand-conglomerate rocks plays a decisive role in its exploration and development of such reservoirs. Due to complex gravels-cements configurations and resultant high heterogeneity in sand-conglomerate rocks, the conventional fractal dimensions are inadequate to fully characterize the pore space. Based on the Pia Intermingled Fractal Units (IFU) model, this paper presents a new variable-ratio factor IFU model, which takes tortuosity and boundary layer thickness into consideration, to characterize the Triassic Karamay Formation conglomerate reservoirs in the Mahu region of the Junggar Basin, Northwest China. The modified model has a more powerful and flexible ability to simulate pore structures of porous media, and the simulation results are closer to the real conditions of pore space in low-porosity and low-permeability reservoirs than the conventional Pia IFU model. The geometric construction of the model is simplified to allow for an easing of computation. Porosity and spectral distribution of pore diameter, constructed using the modified model, are generally consistent with actual core data. Also, the model-computed permeability correlates well with experimental results, with a relative error of less than 15%. The modified IFU model performs well in quantitatively characterizing the heterogeneity of sand-conglomerate pore structures, and provides a methodology for the study of other similar types of heterogeneous reservoirs.

Keywords

sand-conglomerate / intermingled fractal units / pore structure / quantitative characterization / permeability

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You Zhou, Songtao Wu, Zhiping Li, Rukai Zhu, Shuyun Xie, Xiufen Zhai, Lei Lei. Investigation of Microscopic Pore Structure and Permeability Prediction in Sand-Conglomerate Reservoirs. Journal of Earth Science, 2021, 32(4): 818-827 DOI:10.1007/s12583-020-1082-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Atzeni C, Pia G, Sanna U. Fractal Modelling of Medium-High Porosity SiC Ceramics. Journal of the European Ceramic Society, 2008, 28(14): 2809-2814.

[2]

Chen H Q, Liang S X, Shu Z R, . Characteristics of Conglomerate Reservoir Architecture of Alluvial Fan and Its Controlling Effects to Reservoir Development: Taking Alluvial Fan Reservoir in Some Area of Northwest Margin of Junggar Basin as an Example. Journal of Jilin University (Earth Science Edition), 2015, 45(1): 13-24. (in Chinese with English Abstract)

[3]	Erol S, Fowler S J, Harcouët-Menou V, . An Analytical Model of Porosity-Permeability for Porous and Fractured Media. Transport in Porous Media, 2017, 120(2): 327-358.

[4]	Gao S S. Research on Seepage Theory and Use of Petroleum Reservoir Engineering of Sang-Conglomerate Reservoir Formation in Mobei Oilfield, Xinjiang, 2012, Beijing: China University of Geosciences (in Chinese with English Abstract)

[5]	He C Z, Hua M Q. Fractal Geometry Description of Reservoir Pore Structure. Oil and Gas Geology, 1998, 19(1): 15-23. (in Chinese with English Abstract)

[6]	Ju Y, Zheng J T, Epstein M, . 3D Numerical Reconstruction of Well-Connected Porous Structure of Rock Using Fractal Algorithms. Computer Methods in Applied Mechanics and Engineering, 2014, 279: 212-226.

[7]	Kuang Y, Sima L Q, Qu J H, . Influencing Factors and Quantitative Evaluation for Pore Structure of Tight Glutenite Reservoir: A Case of the Triassic Baikouquan Formation in Ma 131 Well Field, Mahu Sag. Lithologic Reservoirs, 2017, 29(4): 91-100. (in Chinese with English Abstract)

[8]	Li C X, Lin M, Ji L L, . Investigation of Intermingled Fractal Model for Organic-Rich Shale. Energy & Fuels, 2017, 31(9): 8896-8909.

[9]	Li C X, Lin M, Ji L L, . Rapid Evaluation of the Permeability of Organic-Rich Shale Using the 3D Intermingled-Fractal Model. SPE Journal, 2018, 23(6): 2175-2187.

[10]	Liu Z X, Yan D T, Niu X. Insights into Pore Structure and Fractal Characteristics of the Lower Cambrian Niutitang Formation Shale on the Yangtze Platform, South China. Journal of Earth Science, 2020, 31(1): 169-180.

[11]	Lou Y, Zhu W Y, Song H Q, . Apparent Permeability Model for Fractal Porous Media Considering the Effect of Solid-Liquid Interface. Journal of Northeast Petroleum University, 2014, 38(2): 69-73. (in Chinese with English Abstract)

[12]	Lyu C, Cheng Q M, Zuo R G, . Mapping Spatial Distribution Characteristics of Lineaments Extracted from Remote Sensing Image Using Fractal and Multifractal Models. Journal of Earth Science, 2017, 28(3): 507-515.

[13]	Meng Q B, Liu H Q, Wang J. A Critical Review on Fundamental Mechanisms of Spontaneous Imbibition and the Impact of Boundary Condition, Fluid Viscosity and Wettability. Advances in Geo-Energy Research, 2017, 1(1): 1-17.

[14]	Pia G. High Porous Yttria-Stabilized Zirconia with Aligned Pore Channels: Morphology Directionality Influence on Heat Transfer. Ceramics International, 2016, 42(10): 11674-11681.

[15]	Pia G, Casnedi L. Heat Transfer in High Porous Alumina: Experimental Data Interpretation by Different Modelling Approaches. Ceramics International, 2017, 43(12): 9184-9190.

[16]	Pia G, Casnedi L, Ionta M, . On the Elastic Deformation Properties of Porous Ceramic Materials Obtained by Pore-Forming Agent Method. Ceramics International, 2015, 41(9): 11097-11105.

[17]	Pia G, Casnedi L, Sanna U. Porosity and Pore Size Distribution Influence on Thermal Conductivity of Yttria-Stabilized Zirconia: Experimental Findings and Model Predictions. Ceramics International, 2016, 42(5): 5802-5809.

[18]	Pia G, Siligardi C, Casnedi L, . Pore Size Distribution and Porosity Influence on Sorptivity of Ceramic Tiles: From Experimental Data to Fractal Modelling. Ceramics International, 2016, 42(8): 9583-9590.

[19]	Pia G, Sanna U. An Intermingled Fractal Units Model and Method to Predict Permeability in Porous Rock. International Journal of Engineering Science, 2014, 75: 31-39.

[20]	Pia G, Sanna U. An Intermingled Fractal Units Model to Evaluate Pore Size Distribution Influence on Thermal Conductivity Values in Porous Materials. Applied Thermal Engineering, 2014, 65(1/2): 330-336.

[21]	Pia G, Sanna U. A Geometrical Fractal Model for the Porosity and Thermal Conductivity of Insulating Concrete. Construction and Building Materials, 2013, 44: 551-556.

[22]	Qian G B, Xu C F, Chen Y K, . Microscopic Mechanism of Polymer Flooding in Glutenite Reservoir of Lower Karamay Formation in East District-7(1), Karamay Oilfield. Xinjiang Petroleum Geology, 2016, 37(1): 56-61. (in Chinese with English Abstract)

[23]	Sergeyev Y D. Evaluating the Exact Infinitesimal Values of Area of Sierpinski’s Carpet and Volume of Menger’s Sponge. Chaos, Solitons & Fractals, 2009, 42(5): 3042-3046.

[24]	Shan X, Zou Z W, Meng X C, . Provenance Analysis of Triassic Baikouquan Formation in the Area around Mahu Depression, Junggar Basin. Acta Sedimentologica Sinica, 2016, 34(5): 930-939. (in Chinese with English Abstract)

[25]	Shi Y, Yang Z M, Yang W Y. Study of Non-Linear Relative Permeability in Low Permeability Reservoir. Journal of Southwest Petroleum University (Science & Technology Edition), 2011, 33(1): 78-82. (in Chinese with English Abstract)

[26]	Tian X F, Cheng L S, Li X L, . A New Method to Calculate Relative Permeability Considering the Effect of Pore-Throat Distribution. Journal of Shaanxi University of Science and Technology (Natural Science Edition), 2014, 32(6): 100-104. (in Chinese with English Abstract)

[27]	Vita M C, De Bartolo S, Fallico C, . Usage of Infinitesimals in the Menger’s Sponge Model of Porosity. Applied Mathematics and Computation, 2012, 218(16): 8187-8195.

[28]	Wan L, Dai L M, Tang G M, . Multi-Scale Characterization and Evaluation of Pore-Throat Combination Characteristics of Lacustrine Mixed Rock Reservoir. Earth Science, 2020, 45(10): 3841-3852. (in Chinese with English Abstract)

[29]	Wu Z X, Yang Z C, Ding C, . Characteristics of Fan Delta in Triassic Karamay Formation, Northwest Margin of Junggar Basin: Taking W16 Well Area as an Example. Natural Gas Geoscience, 2011, 22(4): 602-609. (in Chinese with English Abstract)

[30]	Xu Y H, Yang X H, Mei L F. Reservoir Characteristics and Main Control Factors of Conglomerate Reservoir of El ₃ in the Northwest Steep Slope Zone of Weixinan Depression. Earth Science, 2020, 45(5): 1706-1721. (in Chinese with English Abstract)

[31]	Xu Z H, Hu S Y, Wang L, . Seismic Sedimentologic Study of Facies and Reservoir in Middle Triassic Karamay Formation of the Mahu Sag, Junggar Basin, China. Marine and Petroleum Geology, 2019, 107: 222-236.

[32]	Yang Y Q, Qiu L W, Cao Y C, . Reservoir Quality and Diagenesis of the Permian Lucaogou Formation Tight Carbonates in Jimsar Sag, Junggar Basin, West China. Journal of Earth Science, 2017, 28(6): 1032-1046.

[33]	Yu B M, Li J H. A Geometry Model for Tortuosity of Flow Path in Porous Media. Chinese Physics Letters, 2004, 21(8): 1569-1571.

[34]	Yun M J, Yu B M, Xu P, . Geometrical Models for Tortuosity of Streamlines in Three-Dimensional Porous Media. The Canadian Journal of Chemical Engineering, 2008, 84(3): 301-309.

[35]	Zhang J Z. Fractal, 2011, 2nd Edition, Beijing: Tsinghua University Press, 262-263 (in Chinese)

[36]	Zhou Y, Wu S T, Li Z P, . Multifractal Study of Three-Dimensional Pore Structure of Sand-Conglomerate Reservoir Based on CT Images. Energy and Fuels, 2018, 32(4): 4797-4807.