提高地下储气库工作气量的压力相关渗透率综合地球动力学建模与研究

Lin Qu, Huijuan Yu, Chuanqin Mao, T. Salter, F. Ning, Roderick Floris Matthijs Van Der Kroef, C. Cranfield, A. Kshirsagar, Limin Li, S. Randazzo
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引用次数: 0

摘要

未来几十年,天然气消费量将大幅增长,以响应清洁能源倡议。地下储气库(UGS)将是解决能源转型期间短期供需动态的关键。本文对中国陆上相国司碳酸盐岩裂缝性气藏进行了改造研究。重点是如何围绕共享地下模型(包括耦合模拟)进行综合研究,以最大限度地提高工作储气能力,从而提高产能,以满足未来的天然气峰值需求。重要的是,这项研究的强大整合提高了人们的信心,足以提出在未来的天然气储存周期中,储层压力可能会高于原始(生产前)压力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Integrated Geo-Dynamic Modelling and Investigation of Pressure-Dependent Permeability to Increase Working Gas Capacity of a Reservoir Repurposed for Underground Gas Storage
Natural gas consumption will grow significantly in coming decades in response to cleaner energy initiatives. Underground gas storage (UGS) will be key to addressing short term supply and demand dynamics during this energy transition. This paper presents a study on the XiangGuoSi (XGS) fractured carbonate, gas reservoir onshore China which had been converted to UGS. The focus is on how integrated studies around a shared subsurface model including coupled simulation can be used to maximise working gas storage capacity and hence increase deliverability to meet future peak gas demand. Critically, the robust integration of this study raised confidence sufficiently to propose that reservoir pressure during future gas storage cycles could be increased above the original (pre-production) pressure.
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