天然气水合物矿床产气过程中地质力学性质的变化

J. Lee, J. Lee, G. Cho, T. Kwon
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摘要

天然气水合物分布广泛,存在于永久冻土和深海沉积物中。天然气水合物储层的大面积估计表明,如果开发出经济上可行的生产方法,天然气水合物作为一种能源的潜力很大。从天然气水合物矿床中开采天然气带来了诸多挑战,如根据水合物储层的物理性质和地质结构评估水合物的采收率,确保特定资源产出天然气的经济可行性,以及保证开采过程不受水合物分离产生的地质力学影响。在水合物解离和解离天然气水合物随后的产气过程中,由于沉积物变形、水合物饱和度变化和精细运移等因素,地质力学性质发生了变化。在这项研究中,进行了广泛的实验室研究,以量化这些问题,并调查了这些变化对天然气水合物矿床天然气产量的影响。在高压测量系统和三轴测量系统中测试了天然气水合物饱和度对强度、刚度和渗透率的影响。用许多不同的实验系统研究了细迁移特性和随后的性质变化。实验系统包括带x线CT监测的岩心驱替系统、测径系统、三轴系统和一维精细运移实验系统。本研究使用的沉积物为含天然气水合物的合成沉积物,平均粒径为细砂。水合物饱和度从10%到50%不等。细馏分也从10%到50%不等。压应力集中引起的沉积物变形通常会增加刚度,降低渗透性。天然气水合物开采引起的水合物饱和度降低一般会降低强度和刚度,增加渗透率。天然气水合物的性质变化与水合物的饱和度没有线性关系,其关系因矿床性质的不同而不同。天然气水合物开采引起的细颗粒运移改变了产层中的细颗粒含量,也改变了地质力学性质。运动颗粒一般集中在井眼附近,但集中的位置取决于生产层段的特征,如粒度分布和流量。即使一小部分细颗粒也能引起物理性质的显著变化。在细粒集中带,刚度普遍增大,渗透率普遍减小。在系统而广泛的实验研究基础上对这些现象进行量化是开发天然气水合物生产THM数值模拟程序的必要步骤。在不久的将来,本研究中的定量关系将应用于天然气水合物生产的THM模拟程序中。
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The Production-Induced Geomechanical Property Changes during Gas Production from Gas Hydrate Deposits
Gas hydrates are widespread, occurring in both permafrost and deep sea sediments. The large estimated areas of gas hydrate reservoirs suggest that the high potential of gas hydrates as an energy resource if economically viable production methods were developed. The production of natural gas from gas hydrate deposits poses challenges such as assessing hydrate recovery rates from physical properties and geological structure of the hydrate reservoir, securing the economic viability of produced gas from a particular resource, and keeping process safe from geomechanical impacts from hydrate dissociation. During the hydrate dissociation and the subsequent gas production from dissociated gas hydrate, geomechanical property changes due to the sediment deformation, the changes in hydrate saturations, and fine migrations. In this study, extensive laboratory studies have been conducted to quantify these issues and the implications of these changes to the gas production from gas hydrate deposits have been investigated. Strength, stiffness, permeability changes due to gas hydrate saturations were examined in high-pressure oedometric system and tri-axial system. Fine migrations characteristics and the subsequent property changes were examined with many different experimental systems. The experimental system includes core-flooding system with X-ray CT monitoring, oedometric system, triaxial system, and one-dimensional fine migration experiment system. The sediment used in this study is synthesized gas hydrate-bearing sediments and the mean grain size of the sediments lies in fine sands. Hydrate saturation ranges from 10 to 50%. Fine fraction ranges also from 10 to 50%. Sediment deformation from compressive stress concentration generally increases stiffness and decreases permeability. Hydrate saturation decrease induced from gas hydrate production generally decrease strength and stiffness and increase permeability. The property changes are not linearly related to gas hydrate saturations and the relations differ depending on the character of deposits. Fine migrations induced by gas hydrate production alter fine contents in producing intervals and also would change geomechanical properties. Moving particles generally concentrates near well-bore but the locus of concentration depends on the character of the producing interval, such as grain size distributions and flow rate. Even a small fraction of fine particles can induce significant changes in physical properties. In fine-concentrated zones, stiffness generally increases and permeability generally decreases. The quantifications of these phenomena based on the systematic and extensive experimental studies are the essential steps before the development of THM numerical simulation code for gas hydrate production. For near future the quantitative relations in this study will be implemented to THM simulation code for gas hydrate production.
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