深部厚硬岩层定向水力压裂弱化减灾机理及效果检验分析

doi:10. 11799/ ce202503012

摘要/Abstract

摘要：

为了给工作面的安全生产创造有利条件，采用了理论分析、现场实测、数据分析等方法对深部厚硬岩层定向水力压裂的弱化减灾机理展开研究。研究结果表明：基于理论分析，发现压裂层位厚硬岩体不同破裂形式，均能减小厚硬岩层的破断步距，有效破坏大能量事件的发生条件。通过现场钻孔窥视，观测到水力压裂后的目标岩层发育了多种不同形态的裂隙，目标岩层的完整性以及连续性遭到了破坏。对比分析未压裂区与压裂区微震频次及能量分布，发现压裂区大能量微震事件（ >10000 J）数量为1次，相较于未压裂区的大能量微震事件个数（44次）减少了97.7%。压裂区能量峰值相较于压裂前降低了2个数量级。研究成果充分证明，定向水力压裂在厚硬岩层弱化减灾方面发挥着极其显著的作用。

关键词:

厚硬岩层 , 水力压裂 , 冲击地压 , 减灾机理 , 效果检验

Abstract:

In order to create favorable conditions for the safety production of the working face, this study adopted theoretical analysis, on-site measurement, data analysis and other methods to study the weakening and disaster reduction mechanism of directional hydraulic fracturing in deep thick and hard rock layers. The research results indicate that: ① Based on theoretical analysis, it has been found that different fracture forms of thick and hard rock formations in fractured layers can reduce the fracture step distance of thick and hard rock formations, effectively destroying the conditions for the occurrence of high-energy events. ② Through on-site drilling and observation, it was observed that the target rock layer developed various types of fractures after hydraulic fracturing, and the integrity and continuity of the target rock layer were damaged. ③ Comparing and analyzing the frequency and energy distribution of microseismic events in the unfractured and fractured areas, it was found that the number of high-energy microseismic events (>10000J) in the fractured area was 1, which was a 97.7% decrease compared to the number of high-energy microseismic events (44) in the unfractured area. The peak energy in the fracturing zone decreased by two orders of magnitude compared to before fracturing. The research results fully demonstrate that directional hydraulic fracturing plays an extremely significant role in the weakening and disaster reduction of thick and hard rock layers.

中图分类号:

TD324

张帝, 韩刚, 刘虎, 等.

深部厚硬岩层定向水力压裂弱化减灾机理及效果检验分析 [J]. 煤炭工程, 2025, 57(3): 80-88.

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