3D Modelling of Coal Deformation under Fluid Pressure using COMSOL Multiphysics

Energy & Economic Geology eJournal Pub Date : 2017-12-01 DOI:10.2139/ssrn.3923859

D. H. Kumar, M. Mishra, S. Mishra

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引用次数: 1

Abstract

Gas transportation in coal bed is a complex physical process. The Adsorption/desorption process is associated with the migration of gas in coal. Adsorption/desorption of CO2/CH4 in coal bed includes diffusion of gas from coal matrix and its flow through natural fractures. Therefore, it is necessary to have a clear concept of the flow behavior of gas in coal beds for successful coal bed methane (CBM) production and carbon dioxide sequestration. The flow of gas through natural cracks results in the deformation of the coal bed. Injection of CO2 in enhanced coal bed methane (ECBM) depends on the permeability and fluid flow behavior. Deformation in solid coal induced by fluid pressure during CBM and ECBM process is still not clearly understood. Numerical models and Multiphysics are dominant in the modeling of a complex study of flow-induced deformation. Such modeling is required for a detailed understanding of deformation as well as flow parameters. In this study 3D model of fractured coal, the core was developed. The deformation in the coal core at multiple injected fluid pressures was analyzed. Geo-mechanical parameters (Stress, Strain, Deformation, Pore pressure, and Darcy’s Velocity, etc.) were determined at varying injection pressures. The relations between different Geo-mechanical parameters were established using a statistical approach.y]

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基于COMSOL Multiphysics的流体压力下煤体变形三维建模

煤层气输运是一个复杂的物理过程。煤的吸附/解吸过程与煤中气体的运移有关。CO2/CH4在煤层中的吸附/解吸包括煤基质中气体的扩散及其通过天然裂缝的流动。因此，要想成功地开采煤层气和封存二氧化碳，有必要对煤层中气体的流动特性有一个清晰的认识。瓦斯通过天然裂缝的流动导致煤层变形。加强型煤层气中CO2的注入取决于其渗透率和流体流动特性。在煤层气和ECBM过程中，流体压力对固体煤变形的影响尚不清楚。数值模型和多物理场在模拟复杂的流致变形研究中占主导地位。这样的建模是详细了解变形和流动参数所必需的。本研究建立了裂隙煤岩心三维模型。分析了多种注入流体压力下煤芯的变形。在不同的注入压力下，确定了地力学参数(应力、应变、变形、孔隙压力和达西速度等)。利用统计方法建立了不同地力学参数之间的关系。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Energy & Economic Geology eJournal

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