Mutual feedback and fracturing effect of hydraulic fractures in composite coal−rock reservoirs under different fracturing layer sequence conditions

IF 7 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL
Bo Li , Yizheng He , Zhen Shi , Wang Jian , Nannan Wang , Yapeng Zhang
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Abstract

Multistage fractures in different reservoirs exhibit competitive extension and mutual feeding mechanisms under different fracturing sequence conditions. To better understand these mechanisms for a more efficient extraction of mine gases, a combination of true triaxial physical tests and numerical simulation was performed in this study. The expansion process of hydraulic fractures in different layers and the comprehensive effect of fracturing were analyzed. The directional deflection effect of the induced stress field on the hydraulic fractures can be summarized as follows. In terms of their behavioral pattern, the fractures in the rock seam extended “in the direction of maximum geo-stress and then deflected toward the interface.” The fracture behavior in the coal seams could be divided into two patterns: “deflection toward the interface and then extension along the direction of maximum geo-stress” and “deviation from the interface and then extension along the direction of maximum geo-stress.” The mutual feedback between the fractures manifested in the form of fracture “phase direction” in the case of stratified fracturing and “phase back” in the case of simultaneous fracturing, i.e., the fracture behaviors in the rock seams and in the first type of coal seams were promoted whereas the fracture behavior was inhibited in the second type of coal seams. In addition, the second fracturing process could be characterized by an increase in the fracture initiation pressure, a decrease in the rate of pressure drop, an increase in the fracture extension duration, and a decrease in the fracture width. When using a fracturing sequence of rock followed by coal, the formation of the seam network structure was found to be more favorable. When using a fracturing sequence of coal followed by rock, it was necessary to continue the injection of the hydraulic fluid into the first fracture during the second fracturing process, so as to obtain a higher fracturing yield. This research provides a certain theoretical support for the efficient co-exploitation of three gases, namely coalbed methane, tight gas, and shale gas, from coal composite reservoirs and in the prevention of gas disasters.
不同压裂层序条件下煤岩复合储层水力裂缝的互馈与压裂效应
在不同的压裂序列条件下,不同储层中的多级裂缝呈现出竞争延伸和相互充填机制。为了更好地理解这些机理,从而更有效地开采矿井气体,本研究结合了真实三轴物理试验和数值模拟。研究分析了水力压裂在不同层位的扩展过程以及压裂的综合效应。诱导应力场对水力压裂的定向变形效应可归纳如下。从行为模式上看,岩层中的裂缝 "向最大地应力方向延伸,然后向界面偏转"。煤层中的断裂行为可分为两种模式:"向界面偏转,然后沿最大地应力方向延伸 "和 "偏离界面,然后沿最大地应力方向延伸"。裂缝之间的相互反馈表现为分层压裂时的裂缝 "相向 "和同步压裂时的裂缝 "相背",即岩层和第一类煤层的裂缝行为得到促进,而第二类煤层的裂缝行为受到抑制。此外,第二次压裂过程的特点是压裂起始压力增大、压力下降速度减小、压裂延伸持续时间延长以及压裂宽度减小。当采用先岩后煤的压裂顺序时,发现煤层网络结构的形成更为有利。当采用先煤后岩的压裂顺序时,有必要在第二次压裂过程中继续向第一条裂缝注入液压油,以获得更高的压裂产量。该研究为煤复合储层中煤层气、致密气、页岩气三种气体的高效共采以及预防瓦斯灾害提供了一定的理论支持。
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来源期刊
CiteScore
14.00
自引率
5.60%
发文量
196
审稿时长
18 weeks
期刊介绍: The International Journal of Rock Mechanics and Mining Sciences focuses on original research, new developments, site measurements, and case studies within the fields of rock mechanics and rock engineering. Serving as an international platform, it showcases high-quality papers addressing rock mechanics and the application of its principles and techniques in mining and civil engineering projects situated on or within rock masses. These projects encompass a wide range, including slopes, open-pit mines, quarries, shafts, tunnels, caverns, underground mines, metro systems, dams, hydro-electric stations, geothermal energy, petroleum engineering, and radioactive waste disposal. The journal welcomes submissions on various topics, with particular interest in theoretical advancements, analytical and numerical methods, rock testing, site investigation, and case studies.
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