基于流体压力波动的地震发射层析成像基础研究

A. Watanabe, H. Mikada, J. Takekawa
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摘要

近年来,利用裂缝内流体流动引起的地震振荡进行地震发射层析成像的研究越来越受到人们的关注。然而,观测到的地震数据与储层流体行为之间的关系尚未揭示。在本研究中,我们通过数值实验来理解诱发微震发射的机制,以便从观测到的地震数据中提取更多关于流体行为的信息。本文采用晶格玻尔兹曼方法(LBM)模拟裂缝中的流体流动。我们采用两种数值模型,1)平行板模型,2)孔喉模型。计算了非定常流场和多相流场对断口壁面应力的影响。非定常流是由流入边界的循环压力变化产生的。在这种情况下,裂缝的内部只充满水或油。在多相流中,我们考虑了喉道充水的裂缝中油滴的运移。在平行板模型中,有油的情况下剪切应力变化较大。这是因为靠近裂缝壁的流体速度变化更快,这是由于油的高粘度造成的。在孔喉多相流模型中,当直径为1 mm的油滴通过孔喉时,在裂缝壁上观察到约8 Pa的剪应力和28 Pa的正应力。我们利用来自应力的地震波来估计流体流动的位置。研究结果表明,流体流动诱发的微震发射强烈依赖于流体粘度、裂缝网络几何形状等因素,这些因素影响着流体的流动模式和流量。
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Fundamental study of seismic emission tomography in terms of fluid pressure fluctuations
Recent years, seismic emission tomography which utilizes seismic oscillation due to fluid flow inside fractures has drawn more attention. However, the relationship between observed seismic data and fluid behavior in a reservoir has not been revealed yet. In the present study, we conduct numerical experiments for understanding the mechanism of the induced microseismic emission in order to extract more information about fluid behavior from observed seismic data. We simulate fluid flow in a fracture using the lattice Boltzmann method (LBM). We adopt two numerical models, i) parallel plate model, and ii) pore throat model. We calculate stress changes at the fracture wall induced by unsteady flow and multi-phase flow fields. The unsteady flow is generated by cyclic pressure change at the inflow boundary. In this case, inner portion of the fracture is filled only water or oil. In the multi-phase flow, we consider migration of oil droplet in a fracture with a throat filled by water. In the parallel plate model, larger shear stress change can be observed in the case of oil. This stems from more rapid change in fluid velocity close to the fracture wall due to the high viscosity of oil. In the case of the multi-phase flow in the pore throat model, about 8 Pa of shear stress and 28 Pa of normal stress are observed at the fracture wall when an oil droplet whose diameter is 1 mm passes through the pore throat. We estimate where fluid flowing using seismic wave from that stress changes. Our results show that the induced microseismic emission by fluid flow is strongly dependent on the fluid viscosity, geometry of fracture network, etc., which influences the pattern and the flux of the flow.
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