Volume 46 Issue S1
Jul.  2018
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ZHOU Hengxin, ZHOU Yuhua, JIANG Xiyin. Analysis and practice of the hydrogeological situation in the construction of the vertical holes across Balipu fault[J]. COAL GEOLOGY & EXPLORATION, 2018, 46(S1): 23-26. DOI: 10.3969/j.issn.1001-1986.2018.S1.005
Citation: ZHOU Hengxin, ZHOU Yuhua, JIANG Xiyin. Analysis and practice of the hydrogeological situation in the construction of the vertical holes across Balipu fault[J]. COAL GEOLOGY & EXPLORATION, 2018, 46(S1): 23-26. DOI: 10.3969/j.issn.1001-1986.2018.S1.005
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Analysis and practice of the hydrogeological situation in the construction of the vertical holes across Balipu fault

  • Yanzhou Mining Group, Jining No. Second coal Mine, Jining 272000, China

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  • Received Date: May 14, 2018
  • Published Date: July 24, 2018
    Graphical Abstract
    • Abstract
  • The underground construction across a large fault area faces problems such as fault conductivity analysis, water abundance analysis of strata under construction and construction process control. This paper discusses the choice of engineering measures under the conditions of a specific geological body. According to the results of the hydrogeological properties analysis and exploration of fault, the scheme of vertical hole position was chosen, the technical measures to safely cross the fault was proposed and finally the safe construction of the project was ensure. This paper provides some practical reference for the selection and implementation of this kind of engineering scheme through the example of the vertical holes in air return roadway.
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    • References (10)
  • [1]
    杨孟达,刘新华,王瑛,等. 煤矿地质学[M]. 北京:煤炭工业出版社,2003.
    [2]
    魏久传,朱鲁,尹会永. 八里铺断层的含、导水性及煤柱合理留设研究[R]. 山东:山东科技大学,2006.
    [3]
    李振鲁,张文泉. 巷道防隔水煤(岩)柱留设研究[J]. 煤炭技术,2017,36(4):71-73.

    LI Zhenlu,ZHANG Wenquan. Study on the retention of coal(rock) pillars in roadways[J]. Coal Technology,2017,36(4):71-73.
    [4]
    杨建,梁向阳,丁湘. 蒙陕接壤区深埋煤层开发过程中矿井涌水量变化特征[J]. 煤田地质与勘探,2017,45(4):97-100.

    YANG Jian,LIANG Xiangyang,DING Xiang. The characteristics of mine water inflow during the development of deep buried coal seams in the border area[J]. Coal Geology & Exploration,2017,45(4):97-100.
    [5]
    褚程程,杨滨滨. 灰色理论在矿井涌水量预测中的应用[J]. 煤田地质与勘探,2012,40(2):55-58.

    CHU Chengcheng,YANG Binbin. Application of grey theory in prediction of mine water inflow[J]. Coal Geology & Exploration,2012,40(2):55-58.
    [6]
    奚砚涛,冯春莉,郭英海,等. 钻孔单位涌水量换算的理论与实践[J]. 煤田地质与勘探,2015,43(1):48-51.

    XI Yantao,FENG Chunli,GUO Yinghai,et al. Theory and practice of water inrush conversion for drilling units[J]. Coal Geology & Exploration,2015,43(1):48-51.
    [7]
    王慧明,张成银,李荣学. 三河尖煤矿高压奥灰突水原因及机理分析[J]. 煤炭科技,2004(1):41-42.

    WANG Huiming,ZHANG Chengyin,LI Rongxue. Analysis of the causes and mechanism of high pressure Ordovician limestone water inrush in Sanhejian Coal Mine[J]. Coal Technology,2004(1):41-42.
    [8]
    赵玉琳,尹世才,王海泉. 奥陶系灰岩富水区带划分的综合水文地质研究[J]. 煤炭技术,2008,27(11):114-116.

    ZHAO Yulin,YIN Shicai,WANG Haiquan. Comprehensive hydrogeological study of the division of the water-rich zone of the Ordovician limestone[J]. Coal Technology,2008,27(11):114-116.
    [9]
    钟声. 地面与井下瞬变电磁法联合探测煤矿富水区域[J]. 山东国土资源,2016,32(7):71-74.

    ZHONG Sheng. Ground and underground transient electromagnetic methods jointly detect water-rich areas in coal mines[J]. Shandong Land and Resources,2016,32(7):71-74.
    [10]
    刘树才,刘志新,姜志海. 瞬变电磁法在煤矿采区水文勘探中的应用[J]. 中国矿业大学学报,2005,34(4):414-417.

    LIU Shucai,LIU Zhixin,JIANG Zhihai. The application of transient electromagnetic method in hydrologic exploration of coal mining area[J]. Journal of China University of Mining,2005,34(4):414-417.
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