Application of the thermoporoelasticity model in numerical modelling of underground coal gasification influence on the surrounding medium

IF 0.7 Q4 MECHANICS
Anna Uciechowska-Grakowicz, T. Strzelecki
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引用次数: 1

Abstract

Abstract The purpose of this paper was to present the thermoporoelasticity model adapted for application in modelling processes, where phase transition may occur, such as during underground coal gasification (UCG). The mathematical model of the medium (soil/rock with pores filled with liquid/gas) in non-isothermal conditions is based on Biot's poroelasticity model. The poroelasticity model is expanded here by the influence of temperature and adjusted to the case where both liquid and highly compressible fluid are present in pores by using the gas laws. This requires considering temperature-dependent physical quantities such as pore fluid density, heat transfer coefficient and viscosity as functions of temperature. Based on the proposed mathematical model and the finite element method, a numerical model was built for the purpose of computing processes occurring in the vicinity of the UCG generator. The result of the authors’ work is a three-dimensional (3D) model, which was not only modified, but derived straight from the laws of thermodynamics, where fields of displacement, temperature and fluid flow are coupled. The model makes it possible to determine results significant to modelling of the UCG process, the reach of the gaseous phase's presence in pores, subsidence values, temperature distribution and directions and rate of seepage, without losing the simplicity and elegance of Biot's original concept. Next, the results of simulations for a hypothetical deposit to estimate the environmental impact of UCG are presented. After applying specific geometry and parameters, the model can be useful for verifying if the chosen technology of UCG in specific conditions will be safe for the environment and infrastructure.
热孔弹性模型在煤地下气化对周围介质影响数值模拟中的应用
本文的目的是提出适用于模拟过程的热孔弹性模型,其中可能发生相变,如地下煤气化(UCG)过程。非等温条件下介质(孔隙中充满液体/气体的土壤/岩石)的数学模型基于Biot的孔隙弹性模型。本文将孔隙弹性模型扩展到温度的影响,并利用气体定律对孔隙中同时存在液体和高可压缩流体的情况进行了调整。这需要考虑与温度相关的物理量,如孔隙流体密度、传热系数和粘度作为温度的函数。基于所提出的数学模型和有限元方法,建立了数值模型,对UCG发电机附近发生的过程进行了计算。作者的工作结果是一个三维(3D)模型,它不仅是修改的,而且是直接从热力学定律推导出来的,其中位移场、温度场和流体流动场是耦合的。该模型可以确定对模拟UCG过程、气相在孔隙中存在的范围、沉降值、温度分布、方向和渗流速度具有重要意义的结果,而不会失去Biot原始概念的简单和优雅。接下来,给出了一个假设矿床的模拟结果,以估计UCG对环境的影响。在应用特定的几何形状和参数后,该模型可用于验证所选择的UCG技术在特定条件下对环境和基础设施是否安全。
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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来源期刊
CiteScore
1.30
自引率
16.70%
发文量
20
审稿时长
16 weeks
期刊介绍: An international journal ‘Studia Geotechnica et Mechanica’ covers new developments in the broad areas of geomechanics as well as structural mechanics. The journal welcomes contributions dealing with original theoretical, numerical as well as experimental work. The following topics are of special interest: Constitutive relations for geomaterials (soils, rocks, concrete, etc.) Modeling of mechanical behaviour of heterogeneous materials at different scales Analysis of coupled thermo-hydro-chemo-mechanical problems Modeling of instabilities and localized deformation Experimental investigations of material properties at different scales Numerical algorithms: formulation and performance Application of numerical techniques to analysis of problems involving foundations, underground structures, slopes and embankment Risk and reliability analysis Analysis of concrete and masonry structures Modeling of case histories
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