Impact of Interbedded Structure of Sand and Clay Layers on Geomechanical Responses of Hydrate-Bearing Sediments During Depressurization

Y. Sohn, J. Lee, K. Song, T. Kwon
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Abstract

This study investigates how the variation in sediment layer geometry of hydrate-bearing sediments (HBS) affects geomechanical behaviors of HBS under depressurization. Two reservoir models with different layering structures but with the same hydrate quantity were constructed and the reservoir responses were numerically investigated during gradual depressurization process. To simulate thermo-hydro-mechanically coupled multiphysics processes occurring in HBS, a series of governing equations were discretized based on a finite volume concept, and coded into an explicit finite difference numerical simulator. An explicitly coupled, time-marching algorithm was used to couple thermo-hydro-mechanical responses associated with depressurization-driven hydrate dissociation. We herein modelded a hydrate deposit in Ulleung Basin, Korea for the sediment properties and geological setting. The simulation results clearly demonstrate that the "densely" layered HBS structure, composed of thin and interbedded clay-sand layers, is more prone to geomechanical instability though it led to more gas production. It is attributed to various mechanisms, including (i) the rapid water drainage from neighboring thin clay layers, (ii) the unique hydrate dissociation pattern in interbedded HBS, and (iii) the transfer of shear stress from hydrate-bearing, "stiff" sandy layers into adjacent thin "soft" clay layers. The layer geometry substantially affects not only the gas production but also the geomechanical stability of a hydrate reservoir. High-resolution sediment profiling appears to play an important role in numerical HBS simulations to reliably predict the feasibility of safe exploitation from layered HBS systems.
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砂土层互层结构对降压过程中含水沉积物地质力学响应的影响
研究了含水沉积层几何形状的变化对含水沉积层在降压条件下的地质力学行为的影响。建立了两种层状结构不同但水合物含量相同的储层模型,并对逐渐降压过程中的储层响应进行了数值研究。为了模拟HBS中发生的热-水-力耦合多物理场过程,基于有限体积概念对一系列控制方程进行离散化,并将其编码为显式有限差分数值模拟器。一种显式耦合的时间推进算法用于耦合与减压驱动的水合物解离相关的热-水-力学响应。本文模拟了韩国郁陵盆地的一个水合物矿床的沉积性质和地质背景。模拟结果清楚地表明,由薄层互层粘土-砂层组成的“致密”层状HBS结构虽然产气量大,但更容易发生地质力学失稳。这可归因于多种机制,包括(i)相邻薄粘土层的快速排水,(ii)互层HBS中独特的水合物解离模式,以及(iii)从含水合物的“硬”砂质层向相邻薄“软”粘土层传递剪切应力。地层的几何形状不仅对天然气产量有很大影响,而且对水合物储层的地质力学稳定性也有很大影响。高分辨率沉积物剖面在HBS数值模拟中发挥着重要作用,可以可靠地预测分层HBS系统安全开采的可行性。
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