Forward modeling of fracture parameters in coal reservoir

被引：0

作者：

Shi S. ^{[1
]}

Liu D. ^{[1
]}

Zhao T. ^{[1
]}

机构：

[1] State Key Laboratory of Coal Resources and Safe Mining, China University of Mining & Technology(Beijing), Beijing

来源：

Meitan Xuebao/Journal of the China Coal Society | 2018年 / 43卷 / 03期

关键词：

AVO forward modeling; Fissure filling; Fracture density; HTI coal seam;

D O I：

10.13225/j.cnki.jccs.2017.0980

中图分类号：

学科分类号：

摘要：

Based on the three components of TTI coal seam by two-dimensional anisotropic elastic wave equation, the finite difference scheme of Lebedev grid was derived, and the numerical simulation of TTI medium on different fracture parameters were carried out, the impact of fracture parameters on the seismic wave field was analyzed, the three layer model was established, and the different theoretical models of crack density and crack filling were obtained.Also, the AVO records were obtained by forward modeling.The simulation results show that ① When the coal seam medium is a dry fracture, the velocity anisotropy of the compressional wave is sensitive to the fracture.When the coal seam medium is fluid fracture, the velocity anisotropy of the shear wave is sensitive to the fracture; ② The reflection coefficient of coal seam roof is negative, the bottom plate is positive, and the reflection coefficient of coal seam is affected by many factors; ③ When the coal seam fracture medium is dry, the change of fracture density to intercept the reflection coefficient curve has a great influence and the effect on slope is small.When the fractured medium is saturated fluid, the fracture density has no influence on the reflection coefficient of coal seam; ④ With the increase of the fracture density, the influence of the filling material on the reflection coefficient is relatively larger. © 2018, Editorial Office of Journal of China Coal Society. All right reserved.

引用

页码：784 / 792

页数：8

共 18 条

[1] Zhu P., Wang J., Yu W., Et al., Inverting reservoir fracture density using P-wave AVO data, Geophysical Prospecting for Petroleum, 40, 2, pp. 1-12, (2001)
[2] Wang H., Peng S., Du W., Et al., Azimuthal AVO in HTI tectonic coal, Journal of Geophysical Research Atmospheres, 49, 6, pp. 1122-1130, (2014)
[3] Liu Z., Qu S., Sun J., Et al., Progress of seismic fracture characterization technology, Geophysical Prospecting for Petroleum, 51, 2, pp. 191-198, (2012)
[4] Deng X., Peng S., Lin Q., Et al., AVO forward method for thin seam based on anisotropy, Journal of China Coal Society, 35, 12, pp. 2053-2058, (2010)
[5] Chen T., Wang X., Cui R., The detectability analysis on HTI tectonic coal cracks by azimuthal AVO forward modeling, Journal of China Coal Society, 35, 4, pp. 640-644, (2010)
[6] Dong L., Ma Z., Cao J., A study on stability of the staggered-grid high-order diference method of first-order elastic wave equation, Chinese Journal of Geophysics, 43, 6, pp. 411-419, (2000)
[7] Pei Z., Numerical simulation of high order finite difference method for elastic wave equation in three-dimensional anisotropic medium, Journal of the University of Petroleum: Natural Science, 28, 5, pp. 23-29, (2004)
[8] Li D., Dong S., Zhao X., Et al., Seismic wave simulation of biphase EDA medium in coal-bed media, Progress in Geophys, 26, 2, pp. 654-663, (2011)
[9] Lisitsa V., Vishnevskiy D., Lebedev scheme for the numerical simulation of wave propagation in 3D anisotropic elasticity, Geophysical Prospecting, 58, 4, pp. 619-635, (2010)
[10] Bernth H., Chapman C., A comparison of the dispersion relations for anisotropic elastodynamic finite-difference grids, Geophysics, 76, 3, pp. WA43-WA50, (2011)

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