分体式不提钻钻孔压水试验孔口装置的研发与应用
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摘要
在钻探施工过程中,由于工程要求,必须对钻孔做孔口压水试验,根据钻孔吸水量、压力数据,检验钻孔的漏失及其他情况。传统孔口压水试验使用的孔口装置,必须把孔内钻具提出孔外,严重地影响工程施工进度。分体式不提钻钻孔压水试验孔口装置的研发,可在不提钻的情况下完成孔口压水试验作业,大幅度缩短施工工期,减轻工人的劳动强度,减少安全事故的发生,对钻探工程施工具有一定的经济价值和现实意义。本文详细介绍了研制的分体式不提钻钻孔压水试验孔口装置的结构、工作原理及使用方法,并与传统孔口压水装置进行了试验对比,验证了分体式不提钻孔口压水试验孔口装置工作的可靠性及优势。
According to the project requirements, wellhead water injection tests need to be conducted in the drilling process to detect its leakage and other failures based on the water absorption of boreholes and the pressure data. In the conventional way of wellhead water injection tests, drilling tools should be lifted out of the borehole, which severely affects the construction schedule. The development of the split type wellhead device allows the test to be done without lifting the drill string up, which is of great economic value and practical significance as it saves time, reduces labor intensity and safety accidents. This paper introduces the structure, working principle and application of the split type wellhead device developed for water injection tests without tripping the drilling string, and compares it with the conventional wellhead water injection devices through tests to verify its reliability and advantages.
According to the project requirements, wellhead water injection tests need to be conducted in the drilling process to detect its leakage and other failures based on the water absorption of boreholes and the pressure data. In the conventional way of wellhead water injection tests, drilling tools should be lifted out of the borehole, which severely affects the construction schedule. The development of the split type wellhead device allows the test to be done without lifting the drill string up, which is of great economic value and practical significance as it saves time, reduces labor intensity and safety accidents. This paper introduces the structure, working principle and application of the split type wellhead device developed for water injection tests without tripping the drilling string, and compares it with the conventional wellhead water injection devices through tests to verify its reliability and advantages.
引文
[1] 王宗有,乔生贵,陈刚,等.大雪山煤矿有线随钻定向钻进技术应用[J].探矿工程(岩土钻掘工程),2018,45(1):4-8. WANG Zongyou, QIAO Shenggui, CHEN Gang, et al. Application of cabled directional drilling technology in Daxueshan Coal Mine[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2018,45(1):4-8.
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[5] 杨志斌,董书宁.压水试验定量评价注浆效果研究[J].煤炭学报,2018,43(7):2021-2028. YANG Zhibin, DONG Shuning. Study on quantitative evaluation of grouting effect by water pressure test[J]. Journal of China Coal Society, 2018,43(7):2021-2028.
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[7] 刘明明,胡少华,陈益峰,等.基于高压压水试验的裂隙岩体非线性渗流参数解析模型[J].水利学报,2016,47(6):752-762. LIU Mingming, HU Shaohua, CHEN Yifeng, et al. An analytical model for nonlinear flow parameters of fractured rock masses based on high pressure packer tests[J]. Journal of Hydraulic Engineering, 2016,47(6):752-762.
[8] 黄震,姜振泉,曹丁涛,等.基于钻孔压水试验的岩层阻渗能力研究[J].岩石力学与工程学报,2014,33(S2):3573-3580. HUANG Zhen, JIANG Zhenquan, CAO Dingtao, et al. Study of impermeability of rock stratum based on water injection test[J]. Chinese Journal of Rock Mechanics and Engineering, 2014,33(S2):3573-3580.
[9] 黄震,姜振泉,孙强,等.深部巷道底板岩体渗透性高压压水试验研究[J].岩土工程学报,2014,36(8):1535-1543. HUANG Zhen, JIANG Zhenquan, SUN Qiang, et al. High-pressure water injection tests on permeability of deep rock mass under tunnels[J]. Chinese Journal of Geotechnical Engineering, 2014,36(8):1535-1543.
[10] 王锦国,周志芳,黄勇.基于压水试验资料的岩体透水性分形特征研究[J].岩石力学与工程学报,2003,(4):562-565. WANG Jinguo, ZHOU Zhifang, HUANG Yong. Study on permeability of rock mass based on water pressure test data by using fractal theory[J]. Chinese Journal of Rock Mechanics and Engineering, 2003,(4):562-565.
[11] 陶士先,纪卫军,胡继良,等.一种地质钻探用可调孔口密封装置:中国,CN201220163706.6[P].2012-12-05. TAO Shixian, JI Weijun, HU Jiliang, et al. A kind of geological drilling with adjustable orifice sealing device: China, CN201220163706.6[P]. 2012-12-05.
[12] 田玮,张杰,罗元斌,等.一种井下注浆孔口装置:中国,CN201720506435.2[P].2017-12-05. TIAN Wei, ZHANG Jie, LUO Yuanbin, et al. A borehole grouting orifice device: China, CN201720506435.2[P]. 2017-12-05.
[13] 李光宏.东庞煤矿DB2-E5井侧钻水平钻进技术[J].探矿工程(岩土钻掘工程),2018,45(7):52-55,69. LI Guanghong. Sidetracking horizontal drilling technology in Well DB2-E5 of Dongpang Coal Mine[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2018,45(7):52-55,69.
[14] 王永全,周兢.钻探技术在煤矿水害防治工作中的应用[J].探矿工程(岩土钻掘工程),2017,44(11):35-41. WANG Yongquan, ZHOU Jing. Application of drilling technology in coal mine water hazard control[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2017,44(11):35-41.
[15] 刘伟,李海伟.动水注浆技术在奥陶系灰岩含水层的应用[J].西部探矿工程,2014,26(2):110-112. LIU Wei, LI Haiwei. Application of dynamic water grouting technique in Ordovician limestone aquifer[J]. West-China Exploration Engineering, 2014,26(2):110-112.
[2] 邹道全.受控定向钻井技术在福建马坑矿区的应用[J].探矿工程(岩土钻掘工程),2016,43(1):75-79. ZOU Daoquan. Application of controlled directional drilling technology in Makeng Mining Area[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2016,43(1):75-79.
[3] 赵庆彪.奥灰岩溶水上带压开采区域超前治理防治水技术[J].中国安全生产科学技术,2014,10(S1):232-236. ZHAO Qingbiao. Technology of regional advance water prevention and control applied to pressurized coal mining above Ordovician limestone karst water[J]. Journal of Safety Science and Technology, 2014,10(S1):232-236.
[4] 赵鹏飞,赵章.地面水平分支孔注浆超前治理奥灰底板突水技术[J].煤炭科学技术,2015,43(6):122-125. ZHAO Pengfei, ZHAO Zhang. Ordovician limestone floor inrush water advance treatment technology with surface horizontal branch borehole grouting[J]. Coal Science and Technology, 2015,43(6):122-125.
[5] 杨志斌,董书宁.压水试验定量评价注浆效果研究[J].煤炭学报,2018,43(7):2021-2028. YANG Zhibin, DONG Shuning. Study on quantitative evaluation of grouting effect by water pressure test[J]. Journal of China Coal Society, 2018,43(7):2021-2028.
[6] 杨志斌,董书宁.压水试验定量评价单孔注浆效果影响因素分析[J].煤矿安全,2018,49(6):187-194. YANG Zhibin, DONG Shuning. Influence factors analysis of quantitative evaluation of single borehole grouting effect by water pressure test[J]. Safety in Coal Mines, 2018,49(6):187-194.
[7] 刘明明,胡少华,陈益峰,等.基于高压压水试验的裂隙岩体非线性渗流参数解析模型[J].水利学报,2016,47(6):752-762. LIU Mingming, HU Shaohua, CHEN Yifeng, et al. An analytical model for nonlinear flow parameters of fractured rock masses based on high pressure packer tests[J]. Journal of Hydraulic Engineering, 2016,47(6):752-762.
[8] 黄震,姜振泉,曹丁涛,等.基于钻孔压水试验的岩层阻渗能力研究[J].岩石力学与工程学报,2014,33(S2):3573-3580. HUANG Zhen, JIANG Zhenquan, CAO Dingtao, et al. Study of impermeability of rock stratum based on water injection test[J]. Chinese Journal of Rock Mechanics and Engineering, 2014,33(S2):3573-3580.
[9] 黄震,姜振泉,孙强,等.深部巷道底板岩体渗透性高压压水试验研究[J].岩土工程学报,2014,36(8):1535-1543. HUANG Zhen, JIANG Zhenquan, SUN Qiang, et al. High-pressure water injection tests on permeability of deep rock mass under tunnels[J]. Chinese Journal of Geotechnical Engineering, 2014,36(8):1535-1543.
[10] 王锦国,周志芳,黄勇.基于压水试验资料的岩体透水性分形特征研究[J].岩石力学与工程学报,2003,(4):562-565. WANG Jinguo, ZHOU Zhifang, HUANG Yong. Study on permeability of rock mass based on water pressure test data by using fractal theory[J]. Chinese Journal of Rock Mechanics and Engineering, 2003,(4):562-565.
[11] 陶士先,纪卫军,胡继良,等.一种地质钻探用可调孔口密封装置:中国,CN201220163706.6[P].2012-12-05. TAO Shixian, JI Weijun, HU Jiliang, et al. A kind of geological drilling with adjustable orifice sealing device: China, CN201220163706.6[P]. 2012-12-05.
[12] 田玮,张杰,罗元斌,等.一种井下注浆孔口装置:中国,CN201720506435.2[P].2017-12-05. TIAN Wei, ZHANG Jie, LUO Yuanbin, et al. A borehole grouting orifice device: China, CN201720506435.2[P]. 2017-12-05.
[13] 李光宏.东庞煤矿DB2-E5井侧钻水平钻进技术[J].探矿工程(岩土钻掘工程),2018,45(7):52-55,69. LI Guanghong. Sidetracking horizontal drilling technology in Well DB2-E5 of Dongpang Coal Mine[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2018,45(7):52-55,69.
[14] 王永全,周兢.钻探技术在煤矿水害防治工作中的应用[J].探矿工程(岩土钻掘工程),2017,44(11):35-41. WANG Yongquan, ZHOU Jing. Application of drilling technology in coal mine water hazard control[J]. Exploration Engineering (Rock & Soil Drilling and Tunneling), 2017,44(11):35-41.
[15] 刘伟,李海伟.动水注浆技术在奥陶系灰岩含水层的应用[J].西部探矿工程,2014,26(2):110-112. LIU Wei, LI Haiwei. Application of dynamic water grouting technique in Ordovician limestone aquifer[J]. West-China Exploration Engineering, 2014,26(2):110-112.
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