致密气成藏动力学机制及数值模拟方法——缩小理论与现场应用的差距

IF 9 1区 地球科学 Q1 ENERGY & FUELS Advances in Geo-Energy Research Pub Date : 2023-05-31 DOI:10.46690/ager.2023.06.02
Wenfeng Zhao, C. Jia, Yan Song, Xiangfang Li, L. Hou, Lin Jiang
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引用次数: 3

摘要

引为:赵,W.,贾,C.,宋,Y.,李,X.,侯,L.,江,L.致密气成藏动力学机制及数值模拟方法:缩小理论与现场应用的差距。地球能源研究进展,2023,8(3):146-158。https://doi.org/10.46690/ager.2023.06.02摘要:尽管近年来致密气勘探开发取得了重大进展,但对致密气成藏动力学机制的认识仍然有限,缺乏数值模拟方法。事实上,理论与现场应用之间的差距已经成为致密气勘探开发发展的障碍。本文通过将压力和温度相关毛细管力的计算嵌入孔隙网络模型,从毛细管自封闭理论的角度揭示了致密地层中油气聚集的动力学机制。通过地质模拟将微观动力机制放大到水库水位,实现了基于真实地质剖面的储量定量评价。从结果中,我们考虑了一些因素来帮助进行资源评估和最佳点预测。首先,微纳孔喉系统中毛细管的自封闭作用是致密砂岩气藏理论的核心;碳氢化合物产生的膨胀力是驱动力,毛细管力包括阻力。此外,微观毛细管力研究可以嵌入孔隙网络模型中,并使用相对渗透率曲线和毛细管力曲线放大为地质模型。现场应用可以通过油藏规模的地质数值模拟来实现。最后,高温高压可以降低毛细管压力,从而增加天然气饱和度和储量。
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Dynamic mechanisms of tight gas accumulation and numerical simulation methods: Narrowing the gap between theory and field application
Cited as: Zhao, W., Jia, C., Song, Y., Li, X., Hou, L., Jiang, L. Dynamic mechanisms of tight gas accumulation and numerical simulation methods: Narrowing the gap between theory and field application. Advances in Geo-Energy Research, 2023, 8(3): 146-158. https://doi.org/10.46690/ager.2023.06.02 Abstract: Despite the significant progress made in tight gas exploration and development in recent years, the understanding of the dynamic mechanisms of tight gas accumulation is still limited, and numerical simulation methods are lacking. In fact, the gap between theory and field application has become an obstacle to the development of tight gas exploration and development. This work sheds light on the dynamic mechanisms of hydrocarbon accumulation in tight formations from the aspect of capillary self-sealing theory by embedding calculation of pressureand temperature-dependent capillary force in a pore network model. The microscale dynamic mechanisms are scaled up to the reservoir level by geological simulation, and the quantitative evaluation of reserves based on real geological sections is realized. From the results, several considerations are made to assist with resource assessment and sweet spot prediction. Firstly, the self-sealing effect of capillary in the micro-nano pore-throat system is at the core of tight sandstone gas accumulation theory; the hydrocarbon-generated expansion force is the driving force, and capillary force comprises the resistance. Furthermore, microscopic capillary force studies can be embedded into a pore network model and scaled up to a geological model using relative permeability curve and capillary force curve. Field application can be achieved by geological numerical simulations at the reservoir scale. Finally, high temperature and high pressure can reduce capillary pressure, which increases gas saturation and reserves.
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来源期刊
Advances in Geo-Energy Research
Advances in Geo-Energy Research natural geo-energy (oil, gas, coal geothermal, and gas hydrate)-Geotechnical Engineering and Engineering Geology
CiteScore
12.30
自引率
8.50%
发文量
63
审稿时长
2~3 weeks
期刊介绍: Advances in Geo-Energy Research is an interdisciplinary and international periodical committed to fostering interaction and multidisciplinary collaboration among scientific communities worldwide, spanning both industry and academia. Our journal serves as a platform for researchers actively engaged in the diverse fields of geo-energy systems, providing an academic medium for the exchange of knowledge and ideas. Join us in advancing the frontiers of geo-energy research through collaboration and shared expertise.
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