Optimization of directional drilling path design method in complex formation
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摘要: 金泰煤矿M6煤层具有顶底板破碎、视倾角由双倾角控制(XZ视图倾角17°、YZ视图倾角3°)、煤层厚度薄且厚度变化差异大(1.08~1.68 m)的复杂产状特征,在顺层定向钻孔施工中,钻孔平面拐弯段采用原有的轨迹设计方法存在轨迹实控难度大、易偏离煤层进入不稳定顶底板而无法钻进、多分支孔施工降低施工效率和无效进尺的难题。本文基于视倾角计算公式,引入钻孔沿工作面走向倾角参数,针对钻孔平面拐弯段优化轨迹设计方法,并在金泰煤矿开展验证试验。结果表明:优化的钻孔平面拐弯段轨迹设计方法相对于原有轨迹设计方法,能够保持钻孔沿煤层中部钻进,克服煤层厚度变化干扰,实现钻孔平面拐弯段精确沿煤层钻进,有效进尺率分别为48.82%、76.72%和100%。8~10号试验钻孔瓦斯监测数据均呈现出较好的瓦斯抽采效果。Abstract: The M6 coal seam in Jintai Coal Mine has complex occurrence characteristics such as roof and floor breakage, apparent dip angle controlled by double dip angle(XZ view inclination 17°, YZ view inclination 3°), thin seam thickness(1.08~1.68m) and large variation in thickness. In the construction of directional drilling along strata,there are some problems such as difficulty of actual control, easy deviation from coal seam into unstable roof and floor,lower construction efficiency and ineffective penetration in multi-branch hole construction. Based on the calculation formula of apparent dip angle, this paper introduces the dip angle parameter of borehole along the working face to optimize the trajectory design method for the plane turning section of borehole, and carries out the verification test in Jintai Coal mine. The results show that: Compared with the original trajectory design method, the optimized trajectory design method can keep the borehole drilling along the middle of the coal seam, overcome the interference of the thickness change of the coal seam, and realize the accurate drilling along the coal seam of the plane turning section of the borehole, and the effective footage rates are 48.82%, 76.72% and 100%, respectively. The gas monitoring data of test borehole No. 8~10 show good gas extraction effect.
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[1] 程亮.薄及中厚软煤层水力压裂煤岩损伤机理及瓦斯运移规律[D].重庆:重庆大学,2016.CHENG Liang. Coal and rock damage mechanism and methane migration law in thin and medium thick soft coal seams by hydraulic fracturing[D]. Chongqing: Chongqing University, 2016.
[2] 王永文,姚宁平,王海龙,等.高位定向钻孔分层布置与瓦斯抽采效果分析[J].钻探工程,2022,49(4):117-123.
SUN Yongwen, YAO Ningping, WANG Hailong, et al. Layered layout of high-level directional boreholes and analysis of gas drainage effect[J]. Drilling Engineering, 2022,49(4):117-123.
[3] 姚宁平,姚亚峰,方鹏,等.我国煤矿坑道钻探装备技术进展与展望[J].钻探工程,2021,48(1):81-87.
YAO Ningping, YAO Yafeng, FANG Peng, et al. Advances and outlook of coal mine tunnel drilling equipment and technology[J]. Drilling Engineering, 2021,48(1):81-87.
[4] 曹建明.复杂地层梳状定向长钻孔在区域瓦斯治理中的应用[J].钻探工程,2021,48(12):20-25.
CAO Jianming. Application of comb directional long boreholes to regional gas contral in complex formation[J]. Drilling Engineering, 2021,48(12):20-25.
[5] 曹小军.复杂工况下顺煤层空气定向钻进应用研究[J].钻探工程,2023,50(2):151-155.
CAO Xiaojun. Research on application of in-seam air directional drilling under complex working conditions[J]. Drilling Engineering, 2023,50(2):151-155.
[6] 石智军,董书宁,杨俊哲,等.煤矿井下3000 m顺煤层定向钻孔钻进关键技术[J].煤田地质与勘探,2019,47(6):1-7.
SHI Zhijun, DONG Shuning, YANG Junzhe, et al. Key technology of drilling in-seam directional borehole of 3000m in underground coal mine[J]. Coal Geology & Exploration, 2019,47(6):1-7.
[7] 方鹏,姚克,王龙鹏,等.ZDY25000LDK智能化定向钻进装备关键技术研究[J].煤田地质与勘探,2022,50(1):72-79.
FANG Peng, YAO Ke, WANG Longpeng, et al. Research on key technologies of the ZDY25000LDK intelligent directional drilling equipment[J]. Coal Geology & Exploration, 2022,50(1):72-79.
[8] 李泉新,方俊,褚志伟,等.青龙煤矿碎软煤层顺层定向钻孔钻进试验研究[J].工矿自动化,2018,44(11):1-6.
LI Quanxin, FANG Jun, CHU Zhiwei, et al. Drilling experiment research on bedding directional drilling of soft-fragmentized coal seam of Qinglong Coal Mine[J]. Industry and Mine Automation, 2018,44(11):1-6.
[9] 陈万勇,潘自滔,刘政.贵州金泰煤矿龙潭组煤层发育特征与煤质分析[J].企业技术开发,2019,38(5):87-88,91.
CHEN Wanyong, PAN Zitao, LIU Zheng. Coal seam development characteristics and coal quality analysis of Longtan formation in Jingtai Coal Mine, Guizhou Province[J]. Technological Development of Enterprise, 2019,38(5):87-88,91.
[10] 张垒,韩洪强.顺煤层随钻测量定向钻进技术在金泰煤矿的应用[J].内蒙古煤炭经济,2021(24):156-158.
ZHANG Lei, HAN Hongqiang. Application of measurement-while-drilling directional drilling technology along coal seam in Jintai Coal Mine[J]. Inner Mongolia Coal Economy, 2021(24):156-158.
[11] 焦聚博,侯红,孙凯.煤矿井下保直钻进技术现状及展望[J].钻探工程,2021,48(7):14-19.
JIAO Jubo, HOU Hong, SUN Kai. State and prospect of underground straight drilling technology in coal mines[J]. Drilling Engineering, 2021,48(7):14-19.
[12] 费振邦.浅谈煤层真倾角与视倾角相互换算的方法[J].科技展望,2016,26(10):184.FEI Zhenbang. The method of converting the true dip angle and apparent dip angle of coal seam to each other[J]. Technology Outlook, 2016,26(10):184.
[13] 姚宁平,张杰,李泉新,等.煤矿井下定向钻孔轨迹设计与控制技术[J].煤炭科学技术,2013,41(3):7-11,46.
YAO Ningping, ZHANG Jie, LI Quanxin, et al. Tracing design and control technology of directional drilling borehole in underground mine[J]. Coal Science and Technology, 2013,41(3):7-11,46.
[14] 白家祉,苏义脑.定向钻井过程中的三维井身随钻修正设计与计算[J].石油钻采工艺,1991(6):1-4.
BAI Jiazhi, SU Yinao. Design and calculation of 3D borehole correction during directional drilling[J]. Oil Drilling & Production Technology,1991(6):1-4.
[15] 董小明,褚志伟,张垒,等.顺煤层随钻测量定向钻进技术在金泰煤矿的应用研究[J].煤炭技术,2022,41(1):92-96.
DONG Xiaoming, CHU Zhiwei, ZHANG Lei, et al. Application of directional drilling technology with measurement while drilling along coal seam in Jintai Coal Mine[J]. Coal Technology, 2022,41(1): 92-96.
[16] 褚志祥.水峪煤矿孤岛工作面强矿压机理及顶板控制研究[D].徐州:中国矿业大学,2021.CHU Zhixiang. Research on the mechanism of strong rock pressure and roof control in island wording face of Shuiyu Coal Mine[D]. Xuzhou: China University of Mining and Technology,2021.
[17] 豆旭谦,王力,王毅,等.张集煤矿灰岩顺层定向钻进托压效应及影响因素分析[J].煤矿安全,2020,51(3):168-172,177.
DOU Xuqian, WANG Li, WANG Yi, et al. Back pressure effect of limestone consequent landslide directional drilling and analysis of influencing factors in Zhangji Coal Mine[J]. Safety in Coal Mines, 2020,51(3):168-172,177.
[18] 姚宁平,王毅,姚亚峰,等.我国煤矿井下复杂地质条件下钻探技术与装备进展[J].煤田地质与勘探,2020,48(2):1-7.
YAO Ningping, WANG Yi, YAO Yafeng, et al. Progress of drilling technologies and equipment for complicated geological conditions in underground coal mines in China [J]. Coal Geology & Exploration,2020,48(2):1-7.
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