基于应力监测的煤层水力造穴效果检验技术研究

doi:10.11799/ce202011016

煤炭工程 ›› 2020, Vol. 52 ›› Issue (11): 79-82.doi: 10.11799/ce202011016

基于应力监测的煤层水力造穴效果检验技术研究

沈润生

河南神火煤电股份有限公司

收稿日期:2019-05-07 修回日期:2020-01-02 出版日期:2020-11-16 发布日期:2020-12-16
通讯作者: 沈润生 E-mail:2260950464@qq.com

Testing Technology of Hydraulic Caving Effect in Coal Seam Based on Stress

Runsheng .Shen

Received:2019-05-07 Revised:2020-01-02 Online:2020-11-16 Published:2020-12-16
Contact: Runsheng .Shen E-mail:2260950464@qq.com

摘要/Abstract

摘要： 针对薛湖煤矿煤层瓦斯含量高、透气性低，存在瓦斯抽采工程量大、抽采时间长、钻孔抽采效果差、回采接续紧张等难题，通过布置应力监测仪，监测并分析薛湖煤矿25040机巷高瓦斯低渗透煤层水力造穴过程煤层应力演化规律，研究确定顺层线造穴有效影响半径及卸压增透范围。研究结果表明：顺层线造穴期间，距离钻孔越近，煤层应力变化越明显，距离钻孔越远，煤层应力越稳定|线造穴后，钻孔周围不同煤体的应力变化在时间和空间上均不同，距离钻孔越近，煤层应力变化越早，变化趋势越单一，变化幅度越大|距离钻孔越远，煤层应力变化越滞后，变化趋势越复杂，变化幅度越小|根据煤体应力变化可知，顺层线造穴有效影响半径为24m。研究结果对薛湖煤矿顺层线造穴安全高效的实施具有重要的指导作用。

关键词: 煤与瓦斯突出, 水力造穴, 应力, 演化规律

Abstract: In order to eliminate the outburst risk of high gas and low permeability coal seam, the stress field monitoring technology is used to monitor and test the effect of coal seam hydraulic cave building, and the stress evolution law of coal seam before and after hydraulic cave building is analyzed. The research results show that the stress changes of coal seam around the borehole are different in space. The closer the borehole is to the borehole, the more obvious the stress changes of coal seam are; after the completion of the construction of the borehole, the earlier the stress changes of the position near the borehole, the more single the change trend, the greater the pressure relief amplitude; the farther the borehole is to the borehole, the later the stress changes, and the more complex the change trend compared with the results of gas pressure measurement, the monitoring results of stress field can fully reflect the implementation effect and influence range of hydraulic hole making.

中图分类号:

TD712+.62

沈润生. 基于应力监测的煤层水力造穴效果检验技术研究[J]. 煤炭工程, 2020, 52(11): 79-82.

Runsheng .Shen. Testing Technology of Hydraulic Caving Effect in Coal Seam Based on Stress [J]. Coal Engineering, 2020, 52(11): 79-82.

参考文献 26

[1]	诸利一, 吕文生, 杨鹏, 等.年全国煤矿事故统计及发生规律研究[J].煤矿安全, 2018, 49(07):237-240
[2]	ZHU Liyi, LYU Wensheng, YANG Peng, et al.Statistical Analysis and Occurrence Laws of Coal Mine Accidents of China from 2007 to 2016[J].Safety in Coal Mines, 2018, 49(7):237-240
[3]	赵云平, 施龙青, 高卫富, 等.我国煤矿转型发展期内煤矿事故统计分析[J].煤炭技术, 2016, 35(09):321-324
[4]	ZHAO Yunping, SHI Longqing, GAO Weifu, et al.Statistic Analysis of Coal Mine Accidents in Chinese Coal Mine Transformation and Development Period[J].Coal Technology, 2016, 35(09):321-324
[5]	孙继平, 钱晓红.年全国煤矿事故分析[J].工矿自动化, 2016, 42(11):1-5
[6]	SUN Jiping, QIAN Xiaohong.Analysis of coal mine accidents in China during 2004–2015[J].Industry and Mine Automation, 2016, 42(11):1-5
[7]	冯丹，许江，陶云奇，等.水力冲孔物理模拟试验系统研制及其应用[J].采矿与安全工程学报, 2017, 34(4):782-788
[8]	FENG Dan, XU Jiang, TAO Yunming, et al.Development of hydraulic punching test system and its application[J]. [J].Journal of Mining & Safety Engineering, 2017, 34(4):782-788
[9]	袁亮, 林柏泉, 杨威.我国煤矿水力化技术瓦斯治理研究进展及发展方向[J].煤炭科学技术, 2015, 43(01):45-49
[10]	YUAN Liang, LIN Baiquan, YANG Wei.Research progress and devel? opment direction of gas control with mine hydraulic technology in China coal mine[J].Coal Science and Technology, 2015, 43(1):45-49
[11]	杨腾龙, 王兆丰, 刘海.下向钻孔水力冲孔工艺优化试验研究[J].煤矿安全, 2019, 50(03):13-16
[12]	YANG Tenglong, WANG Zhaofeng, LIU Hai.Experimental Study on Process Optimization of Hydraulic Flushing in Downward Holes[J].Safety in Coal Mines, 2019, 50(03):13-16
[13]	魏缘, 邢玉忠.水力冲孔有效影响半径数值模拟及现场应用[J].煤炭技术, 2017, 36(09):183-185
[14]	WEI Yuan, Xing Yuzhong.Numerical Simulation on Effective Influence Radius of Hydraulic Flushing and Field Application[J].Coal Technology, 2017, 36(09):183-185
[15]	宝坤, 张明杰, 魏国营.薛湖煤矿穿层水力冲孔周围煤体变形规律研究[J].煤矿安全, 2018, 49(03):17-20
[16]	BAO Kun, ZHANG Mingjie, WEI Guoying.Study on Coal Deformation Law of Hydraulic Flushing Passing Through Layer in Xuehu Coal Mine[J].Safety in Coal Mines, 2018, 49(03):17-20
[17]	郑雷.气体示踪法测定低透气性高瓦斯煤层瓦斯抽放半径[J].煤田地质与勘探, 2015, 43(03):122-124
[18]	ZHENG Lei.Determination of the gas drainage radius of low permeability and high gas coal seam by SF_6 gas tracer[J].Coal Geology & Exploration, 2015, 43(03):122-124
[19]	辛明.利用示踪技术测试煤层瓦斯抽采半径[J].安徽理工大学学报自然科学版, 2012, 32(1):64-66
[20]	XIN Ming.Determination of Gas Extraction Radius in Coal Seams by Tracer Technique with SF_6[J].Journal of Anhui University of Science & Technology, 2012, 32(1):64-66
[21]	郝富昌，刘明举，孙丽娟.瓦斯抽采半径确定方法的比较及存在问题研究[J].煤炭科学技术, 2012, 40(12):55-58
[22]	HAO Fuchang, LIU Mingju, SUN Lijuan.Study on Comparison of Methods to Determine Gas Drainage Radius and Existed Problems[J].Coal Science and Technology, 2012, 40(12):55-58
[23]	刘华锋，陈辉.顺层钻孔瓦斯抽采半径确定及抽采效果考察研究[J].中国煤炭, 2013, 39(6):83-86
[24]	LIU Huafeng, CHEN Hui.Research on gas drainage radius and effect of bedding borehole[J].China Coal, 2013, 39(6):83-86
[25]	韩增强, 王川婴, 邹先坚, 等.孔内立体像对成像技术在孔壁崩落法地应力测量中的应用探讨[J].岩石力学与工程学报, 2018, 37(S2):4177-4183
[26]	HAN Zengqiang, WANG Chuanying, ZOU Xianjian, et al.Discussion for application of stereo pair imaging technique in borehole breakout method[J].Chinese Journal of Rock Mechanics and Engineering, 2018, 37(S2):4177-4183

基于应力监测的煤层水力造穴效果检验技术研究

Testing Technology of Hydraulic Caving Effect in Coal Seam Based on Stress

PDF (Mobile)

可视化

摘要/Abstract

引用本文

使用本文

参考文献 26

相关文章 15

编辑推荐

Metrics

本文评价

[1]	孙立田, 孔贺, 张立明, 田国庆, 李登月. 多因素应力叠加冲击危险性评价应力增量取值实测分析[J]. 煤炭工程, 2020, 52(9): 94-98.
[2]	刘宜平, 朱恒忠, 殷帅峰. 煤柱影响下被保护层开采应力演化特征数值模拟研究[J]. 煤炭工程, 2020, 52(9): 99-105.
[3]	冉星仕 . 隆德煤矿浅埋上下煤层协调同采技术研究[J]. 煤炭工程, 2020, 52(8): 1-5.
[4]	孟宪志, 刘阳军, 王业征. 高应力超大断面硐室围岩控制对策研究[J]. 煤炭工程, 2020, 52(8): 64-67.
[5]	刘金广, 刘建庄. 密集锚注支护技术在孤岛区石门套修中的应用[J]. 煤炭工程, 2020, 52(7): 24-27.
[6]	吴波. 综放开采多煤柱扰动致冲危险性分析及监测防控技术[J]. 煤炭工程, 2020, 52(7): 68-73.
[7]	周连春, 李望, 王琰. 上覆煤层煤柱下采掘工作面应力分布规律研究[J]. 煤炭工程, 2020, 52(5): 121-125.
[8]	李爱军, 王䶮. 高地应力切顶留巷围岩快速控制技术研究[J]. 煤炭工程, 2020, 52(4): 28-32.
[9]	王文林, 马赛. 大采高工作面复杂应力扰动下切顶卸压沿空留巷技术[J]. 煤炭工程, 2020, 52(4): 33-37.
[10]	韦庆亮, 李彦斌, 谷攀, 张博. 综采工作面过断层顶板破坏机理及控制技术[J]. 煤炭工程, 2020, 52(4): 52-57.
[11]	王天禄, 王维国, 刘啸, 刘帅. 高地应力软岩下山非对称变形机理与控制研究[J]. 煤炭工程, 2020, 52(4): 78-83.
[12]	李生舟. 地应力主导型突出危险煤巷水力扩孔卸压防突技术研究[J]. 煤炭工程, 2020, 52(4): 97-102.
[13]	夏方迁, 魏全德, 郭延淼, 张立明. 柔性钻孔应力计设计及实验应用研究[J]. 煤炭工程, 2020, 52(4): 161-165.
[14]	魏大勇, 孙亚楠, 闫奋前, 吴俊达. 承压水上含隐伏构造底板突水机理研究[J]. 煤炭工程, 2020, 52(3): 93-97.
[15]	高厚, 陈卫忠, 邢天海, 郑有雷, 贾晓东, 程文武. 定向水力致裂对煤层顶板三向应力的影响研究[J]. 煤炭工程, 2020, 52(3): 113-117.