多域效应和热效应影响下煤层气模拟开采

Wai Li, Jishan Liu, J. Zeng, Y. Leong, D. Elsworth, Jianwei Tian
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引用次数: 0

摘要

煤层气开采过程不仅对非常规能源供应具有重要意义,而且对矿井安全也具有重要意义。压裂技术的最新进展,如二氧化碳(CO2)压裂,加剧了受激煤层的复杂性。这项工作的重点是开发一个完全耦合的多域模型,以描述和深入了解煤层气开采过程,特别是那些复合裂缝煤层。导出了一组偏微分方程(PDEs)来描述气体从基质到裂缝和井眼的输运。煤层气被定义为三种相互作用的多孔介质的组合:基质、连续裂缝(CF)和径向原生水力裂缝(RF)。基质和CF构成双孔隙度-双渗透率体系,RF简化为一维裂缝介质。这些介质进一步形成了三个不同的区域:非增产储层区域(NSRD)、增产储层区域(SRD)和RF。将煤体变形、换热和非热吸附的影响耦合到模型中,以反映煤层气抽采过程的多过程。采用有限元法对其进行数值求解。通过与山西沁水盆地南部一组井的生产数据对比,验证了该模型的有效性。结果表明,该模型具有较好的煤层气提取精度。在此基础上,通过对不同煤层气开采模式的模拟分析,得出了不同煤层气开采模式之间的差异。(2)双翼断裂+ NSRD;(3)多个RFs + NSRD;(4) SRD + NSRD和(5)多个RFs + SRD + NSRD。结果表明,模式(5)(通常由CO2压裂形成)既增加了径向裂缝数量,又激活了煤块内的微裂缝,形成了不同尺度的复杂裂缝网络,从而提高了煤层气开采效率。通过敏感性分析,了解了多域煤层气开采过程中关键因素对煤层气开采的影响。研究发现,不同结构域的不同性质导致不同的演化,进而影响煤层气的产生。忽略煤层气开采过程中的热效应将高估或低估煤层气的产量,这是热应变和非等温吸附的净效应。该模型考虑了煤层性质的复杂演变以及不同组分和区域之间的相互作用,为准确评价煤层气开采提供了一种有用的方法。强调了多域效应和热效应对煤层气储层模拟的重要性。
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Modelling Methane Extraction from Stimulated Coalbed Influenced by Multidomain and Thermal Effects
The process of extracting coalbed methane (CBM) is not only of significance for unconventional energy supply but also important in mine safety. The recent advance in fracking techniques, such as carbon dioxide (CO2) fracking, intensifies the complexity of stimulated coalbeds. This work focuses on developing a fully coupled multidomain model to describe and get insight into the process of CBM extraction, particularly from those compound-fractured coalbeds. A group of partial differential equations (PDEs) are derived to characterize gas transport from matrix to fractures and borehole. A stimulated coalbed is defined as an assembly of three interacting porous media: matrix, continuous fractures (CF) and radial primary hydraulic fracture (RF). Matrix and CF constitute a dual-porosity-dual-permeability system, while RF is simplified as an 1-D cracked medium. These media further form three distinct domains: non-stimulated reservoir domain (NSRD), stimulated reservoir domain (SRD) and RF. The effects of coal deformation, heat transfer, and non-thermal sorption are coupled into the model to reflect the multiple processes in CBM extraction. The finite element method is employed to numerically solve the PDEs. The proposed model is verified by comparing its simulation results to a set of well production data from Southern Qinshui Basin in Shanxi Province, China. Great consistency is observed, showing the satisfactory accuracy of the model for CBM extraction. After that, the difference between various stimulation patterns is presented by simulating the CBM extraction process with different stimulation patterns including (1) unstimulated coalbed; (2) double-wing fracture + NSRD; (3) multiple RFs + NSRD; (4) SRD + NSRD and (5) multiple RFs + SRD + NSRD. The results suggest that Pattern (5) (often formed by CO2 fracking) boosts the efficiency of CBM extraction because it generates a complex fracture network at various scales by both increasing the number of radial fractures and activating the micro-fractures in coal blocks. Sensitivity analysis is also performed to understand the influences of key factors on gas extraction from a stimulated coalbed with multiple domains. It is found that the distinct properties of different domains originate various evolutions, which in turn influences the CBM production. Ignoring thermal effects in CBM extraction will either overestimate or underestimate the production, which is the net effect of thermal strain and non-isothermal sorption. The proposed model provides a useful approach to accurately evaluate CBM extraction by taking the complex evolutions of coalbed properties and the interactions between different components and domains into account. The importance of multidomain and thermal effects for CBM reservoir simulation is also highlighted.
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