Volume 47 Issue 6
Dec.  2019
Turn off MathJax
Article Contents
Abstract
References
Related Articles
HUAN Hengfei, GAO Tie, ZHAO Haiqing, ZHAO Weijun, GUO Canwen, SHI Bin. Application of high precision gravity survey in detecting mined-out areas of Fushun coal mine[J]. COAL GEOLOGY & EXPLORATION, 2019, 47(6): 194-200. DOI: 10.3969/j.issn.1001-1986.2019.06.029
Citation: HUAN Hengfei, GAO Tie, ZHAO Haiqing, ZHAO Weijun, GUO Canwen, SHI Bin. Application of high precision gravity survey in detecting mined-out areas of Fushun coal mine[J]. COAL GEOLOGY & EXPLORATION, 2019, 47(6): 194-200. DOI: 10.3969/j.issn.1001-1986.2019.06.029
shu

Application of high precision gravity survey in detecting mined-out areas of Fushun coal mine

  • Shenyang Geological Survey Center, CGS, Shenyang 110034, China;National Marine Data and Information Service, Tianjin 300171, China;Liaoning Institute of Geology and Mineral Survey, Shenyang 110031, China

Funds: 

National Key Research and Development Plan(2016YFC0600108)

More Information
  • Received Date: March 11, 2019
  • Published Date: December 24, 2019
    Graphical Abstract
    • Abstract
  • In order to find out the location, depth and distribution range of the mined-out areas in Fushun coal mine, and comprehensively considering the factors affecting the geophysical methods in the cities, the method of high-precision gravity survey was firstly used to study the mined-out areas in the area. Firstly, by analyzing the physical differences of the mined-out areas, a theoretical model was established for forward calculation and preliminarily studied on applicability of the gravity method. Then, a large-scale work of high-precision gravity survey was arranged in the study area, and through potential field separation,3D apparent density inversion and boundary identification calculation of the Bouguer gravity anomaly, the location, depth, boundary and tectonic distribution of the mined-out areas were inferred. The research results show that the method of high-precision gravity survey combined with effective data processing method can play an important role in the detection of mined-out areas in urban coal mines.
    • FullText(HTML)
    • References (18)
  • [1]
    樊杰. 我国煤矿城市产业结构转换问题研究[J]. 地理学报,1993,48(3):218-226.

    FAN Jie. A study on the industrial structure transformation of coal-mine cities in China[J]. Acta Geographica Sinica,1993,48(3):218-226.
    [2]
    GENG Hong,ZHANG Kai,ZHANG Hanwen. Research on sustainable development of resource-based small industrial and mining cities:A case study ofyangquanqu town,Xiaoyi,Shanxi Province,China[J]. Procedia Engineering,2011,21:633-640.
    [3]
    NAN Shiqing,ZHANG Juanxia,GUO Xianzhang. Study of safety mining technology on ore body adjacent to water-bearing crushed zone and fault[J]. Disaster Advances,2010,3(4):428-431.
    [4]
    杨建军,吴汉宁,冯兵,等. 煤矿采空区探测效果研究[J]. 煤田地质与勘探,2006,34(1):67-70.

    YANG Jianjun,WU Hanning,FENG Bing,et al. Research on prospecting effect for gob area of coal mines[J]. Coal Geology & Exploration,2006,34(1):67-70.
    [5]
    石刚,屈战辉,唐汉平,等. 探地雷达技术在煤矿采空区探测中的应用[J]. 煤田地质与勘探,2012,40(5):82-85.

    SHI Gang,QU Zhanhui,TANG Hanping,et al. Gob detection based on ground penetrating radar technique[J]. Coal Geology & Exploration,2012,40(5):82-85.
    [6]
    郭恩惠,刘玉忠,赵炯,等. 综合物探探测煤矿采空塌陷区[J]. 煤田地质与勘探,1997,25(5):8-10.

    GUO Enhui,LIU Yuzhong,ZHAO Jiong,et al. Mine goaf subsidence trough prospected by comprehensive geophysical exploration[J]. Coal Geology & Exploration,1997,25(5):8-10.
    [7]
    程建远,孙洪星,赵庆彪,等. 老窑采空区的探测技术与实例研究[J]. 煤炭学报,2008,33(3):251-255.

    CHENG Jianyuan,SUN Hongxing,ZHAO Qingbiao,et al. Detection technology of excavated region in coal mine and case study[J]. Journal of China Coal Society,2008,33(3):251-255.
    [8]
    韩术合,张寿庭,郭宇飞,等. 多种物探方法在采空区勘查中的应用[J]. 有色金属工程,2017,7(1):76-81.

    HAN Shuhe,ZHAN Shouting,GUO Yufei,et al. Application research of integrated geophysical techniques on detecting the mine goaf[J]. Nonferrous metals engineering,2017,7(1):76-81.
    [9]
    温来福,郝海强,刘志远,等. 综合物探在山西省某煤矿采空区探测中的应用[J]. 工程地球物理学报,2014,11(1):112-117.

    WEN Laifu,HAO Haiqiang,LIU Zhiyuan,et al. Application of comprehensive geophysical prospecting method in the detection of coal mined-out areas in Lingshi,Shanxi[J]. Chinese Journal of Engineering Geophysics,2014,11(1):112-117.
    [10]
    张善法,孟令顺,杜晓娟,等. 高精度重力测量在金矿采空区探测中的应用研究[J]. 地球物理学进展,2009,24(2):590-595.

    ZHAN Shanfa,MENG Lingshun,DU Xiaojuan,et al. Study on the application of high precision gravity survey in detectingmined-out areas of gold mines[J]. Progress in Geophysics,2009,24(2):590-595.
    [11]
    张旭,杜晓娟,苏超,等. 辽源煤矿采空区重力异常解释研究[J]. 工程地球物理学报,2015,12(6):755-759.

    ZHANG Xu,DU Xiaojuan,SU Chao,et al. Gravity anomaly interpretation of mined-out area in Liaoyuan coal[J]. Chinese Journal of Engineering Geophysics,2015,12(6):755-759.
    [12]
    王延涛,潘瑞林. 微重力法在采空区勘查中的应用[J]. 物探与化探,2012,36(增刊1):61-64.

    WANG Yantao,PAN Ruilin. Application of micro-gravity method in survey of goaf[J]. Goephysical & Geochemical Exploration,2012,36(S1):61-64.
    [13]
    明圆圆,王春辉,牛雪,等. 重力勘探在阳泉煤炭采空区中的应用[J]. 煤炭技术,2018,37(9):136-139.

    MING Yuanyuan,WANG Chunhui,NIU Xue,et al. Ap-plication of gravity exploration in detection of coal goafs in Yangquan[J]. Coal Technology,2018,37(9):136-139.
    [14]
    罗孝宽,郭绍雍. 应用地球物理教程-重磁勘探[M]. 北京:地质出版社,1991.
    [15]
    常耀广,赵广信,苏顺强. 抚顺煤田矿震现状及其城市地质环境效应初探[J]. 辽宁工程技术大学学报,2002,21(5):579-583.

    CHANG Yaoguang,ZHAO Guangxin,SU Shunqiang. Present mining tremors in Fushun coal bed and preliminary study on behavior of urban geologic environment[J]. Journal of Liaoning Technical University,2002,21(5):579-583.
    [16]
    周建军,郑天涯,王思敬. 辽宁省抚顺矿区宏观地质结构及其工程效应分析[J]. 中国地质灾害与防治学报,2010,21(4):86-90.

    ZHOU Jianjun,ZHENG Tianya,WANG Sijing. Analysis of the geological structures in Fushun Mine area and its engineering effects[J]. The Chinese Journal of Geological Hazard and Control,2010,21(4):86-90.
    [17]
    陈召曦,孟小红,郭良辉. 重磁数据三维物性反演方法进展[J]. 地球物理学进展,2012,27(2):503-511.

    CHEN Zhaoxi,MENG Xiaohong,GUO Lianghui. Review of 3D property inversion of gravity and magnetic data[J]. Progress in Geophysics,2012,27(2):503-511.
    [18]
    王彦国,张凤旭,王祝文,等. 位场归一化差分法的边界检测技术[J]. 吉林大学学报(地球科学版),2013,43(2):592-602.

    WANG Yanguo,ZHANG Fengxu,WANG Zhuwen,et al. Edge detection of potential field using normalized differential[J]. Journal of University(Earth Science Edition),2013,43(2):592-602.
    • Related Articles

  • Related Articles

    [1]ZOU Jun, GUO Yan, GUI Herong, WANG Weimin, CHEN Zhenlin, LIU Faming, Dai Yanan, HU Yang, CHEN Zengbao, LI Jun, GAO Chuan, LI Heng. An experimental study on the yield strength of cement grout for grouting in the limestone area of a coal seam floor[J]. COAL GEOLOGY & EXPLORATION, 2025, 53(4): 1-9. DOI: 10.12363/issn.1001-1986.24.11.0695
    [2]LIU Zhaoxing, ZHANG Qi. PFC numerical analysis on crack initiation mechanism of fracture grouting in top of Ordovician limestone[J]. COAL GEOLOGY & EXPLORATION, 2023, 51(10): 72-85. DOI: 10.12363/issn.1001-1986.23.01.0019
    [3]XING Maolin, ZHENG Shitian, SHI Zhiyuan, ZHAO Shaolei, DU Botao, CUI Siyuan. Technology of raising upper limit of mining by grouting reconstruction in thick water-bearing sand layer and its application[J]. COAL GEOLOGY & EXPLORATION, 2023, 51(5): 113-122. DOI: 10.12363/issn.1001-1986.22.07.0583
    [4]DONG Shuning, LIU Qisheng, WANG Hao, GUO Xiaoming, LIU Zhaoxing, ZHENG Shitian, NAN Shenghui, LIU Jianlin, ZHAO Zhao, SHI Zhiyuan. Theoretical framework and key technology of advance regional control of water inrush in coal seam floor[J]. COAL GEOLOGY & EXPLORATION, 2023, 51(1): 185-195. DOI: 10.12363/issn.1001-1986.22.10.0813
    [5]HU Weiyue, ZHAO Chunhu, LYU Hanjiang. Main influencing factors for regional pre-grouting technology of water hazard treatment in coal seam floor and efficient hole arrangement[J]. COAL GEOLOGY & EXPLORATION, 2022, 50(11): 134-143. DOI: 10.12363/issn.1001-1986.22.04.0279
    [6]ZHENG Shitian, MA Hewen, JI Yadong. Optimization of regional advanced coal floor water hazard prevention and control technology and its application[J]. COAL GEOLOGY & EXPLORATION, 2021, 49(5): 167-173. DOI: 10.3969/j.issn.1001-1986.2021.05.018
    [7]ZHAO Chunhu, WANG Hao, JIN Dewu. Discussion on roof water loss control method of coal seam based on pre-splitting grouting reformation(P-G)[J]. COAL GEOLOGY & EXPLORATION, 2021, 49(2): 159-167. DOI: 10.3969/j.issn.1001-1986.2021.02.020
    [8]ZHENG Shitian. Advanced exploration and control technology of limestone water hazard in coal seam floor in Huainan and Huaibei coalfields[J]. COAL GEOLOGY & EXPLORATION, 2018, 46(4): 142-146,153. DOI: 10.3969/j.issn.1001-1986.2018.04.023
    [9]NAN Shenghui. Technical feasibility of grouting reform for upper part of Ordovician limestone in Xingtai and Handan coal mining areas[J]. COAL GEOLOGY & EXPLORATION, 2010, 38(3): 37-40. DOI: 10.3969/j.issn.1001-1986.2010.03.009
    [10]GUO Chun, XING Wen-ping, LI Wen-jun. Application of transient electromagnetic techniques to grouting reconstruction of lower confining bed[J]. COAL GEOLOGY & EXPLORATION, 2006, 34(4): 74-76.

  • Cited by

    Periodical cited type(64)

    1. 刘少伟,郭泽政,冯超,牛帅. 防隔水煤柱定向爆破应力转移机理及参数优化设计. 河南理工大学学报(自然科学版). 2025(01): 1-9 .
    2. 王占礼. 羊东矿8472工作面综合物探与区域治理验证. 煤炭与化工. 2025(01): 73-77+83 .
    3. 任志祥. 地面注浆防治水设备选型及工艺优化. 煤矿机械. 2025(03): 116-119 .
    4. 丁华忠,王力,景慎怀,黄寒静,陈洪岩,程合玉,李明强,曾庆辉,聂超. 松软煤层条带预抽底板梳状孔成孔及飞管完孔技术研究. 煤炭技术. 2025(03): 141-145 .
    5. 薛杨,李建林,郭水涛,徐博博. 基于定向钻探技术的深部矿井突水点封堵方案优化. 煤矿安全. 2024(01): 192-199 .
    6. 赵睿,刘磊. 瞬变电磁技术在注浆效果检测的试验研究. 煤矿机械. 2024(03): 31-33 .
    7. 钟蜜. 城郊煤矿薄层灰岩水害治理技术研究与实践. 山东煤炭科技. 2024(02): 126-131 .
    8. 桂和荣,李俊,陈永青,余浩,王浩,叶爽,陈大星,梁展,胡洋,郭艳,许继影. 基于主量元素地球化学的岩屑层位源解析. 煤炭学报. 2024(02): 929-940 .
    9. 董书宁,樊敏,郭小铭,刘英锋,郭康,姬中奎,李超峰,薛小渊. 陕西省煤矿典型水灾隐患特征及治理技术. 煤炭学报. 2024(02): 902-916 .
    10. 王琦. 煤层底板含水层注浆巷道跑浆风险及防范措施. 煤炭技术. 2024(07): 125-129 .
    11. 高保彬,任闯难,李兵兵,程磊,宋少鹏,齐治虎,徐影. 韧性视角下华北型煤田底板承压灰岩水原位保护技术研究. 河南理工大学学报(自然科学版). 2024(04): 12-20 .
    12. 李建林,薛杨,王心义,徐博博,郭水涛. 基于模糊综合评价的导水通道超前探查判识技术. 煤炭科学技术. 2024(07): 178-186 .
    13. 曾一凡,于超,武强,赵菱尔,尹尚先,张博成,刘泽洋,崔雅帅,阚雪冬,黄浩. 煤矿防治水“三区”划分方法及其水害防治意义. 煤炭学报. 2024(08): 3605-3618 .
    14. 纪伟,陈志坚,赵仲珩. 边坡地下水渗透压力数据时序分解方法研究. 中国煤炭地质. 2024(11): 32-39 .
    15. 闫鑫,丁湘,蒲治国,纪卓辰,李哲,刘凯祥,张寅. 基于AHP-CRITIC奥灰突水危险性评价的工作面水害分区防控. 中国矿业. 2024(12): 217-225 .
    16. 刘文武,刘杰,芮学来. 淮南张集矿东-1煤上采区多分支水平注浆井钻井技术. 矿产勘查. 2024(12): 2329-2336 .
    17. 唐道增,王永宝,陈建刚,陈军涛,云明,刘磊,郭洪运,傅子群. 黄河北煤田定向钻孔注浆效果的全周期评价方法. 煤炭技术. 2023(01): 151-156 .
    18. 武强,郭小铭,边凯,杜鑫,许珂,卜文扬,曾一凡. 开展水害致灾因素普查 防范煤矿水害事故发生. 中国煤炭. 2023(01): 3-15 .
    19. 董书宁,刘其声,王皓,郭小铭,柳昭星,郑士田,南生辉,刘建林,赵兆,石志远. 煤层底板水害超前区域治理理论框架与关键技术. 煤田地质与勘探. 2023(01): 185-195 . 本站查看
    20. 樊鑫,赵晓光,唐胜利,解海军,程建远,王云宏,王盼. WSD-SVM在工作面底板破坏深度微震事件自动识别中的应用. 西安科技大学学报. 2023(01): 160-166 .
    21. 许峰. 阶梯式导水断层带探查及水害防治技术. 矿业安全与环保. 2023(01): 82-85+91 .
    22. 邢茂林. 煤层底板区域治理后断层突水原因及探讨. 煤矿安全. 2023(03): 204-211 .
    23. 魏廷双,许光泉,高宇航,党保全,孙贵,丁庆和,杨婷婷. 潘二矿奥陶系岩溶地下水数值模拟及疏放性分析. 地下水. 2023(02): 13-16 .
    24. 李晓龙. 整合矿井复采条件下老空水防治技术体系研究. 煤矿安全. 2023(04): 184-193 .
    25. 陈陆望,胡永胜,张杰,张苗,郑剑,郑忻,张媛媛,蔡欣悦,武明辉. 华北型煤田水文地球化学勘探关键技术研究进展. 煤田地质与勘探. 2023(02): 207-219 . 本站查看
    26. 谢治刚,孙贵,随峰堂,许光泉,张海涛,卜军,詹润. 基于层次分析法的地面区域治理目的层位优化选择. 煤炭科学技术. 2023(03): 201-211 .
    27. 曹栋. 羊东矿8472工作面区域治理与分析. 煤炭与化工. 2023(04): 82-86 .
    28. 刘艺芳. 新型多泵高压注浆混合装置的设计及应用. 矿山机械. 2023(06): 46-49 .
    29. 马强,崔岩波. 定向长钻孔在煤矿工作面防治水中的应用. 价值工程. 2023(17): 124-126 .
    30. 李博,罗玉岚,樊娟,郭小铭,李梦华. 煤层底板突水多源信息综合评价系统设计开发与实现. 煤田地质与勘探. 2023(06): 1-12 . 本站查看
    31. 尚慧. 晋城西北矿区底板隔水层采动影响模拟研究. 重庆科技学院学报(自然科学版). 2023(04): 13-20 .
    32. 董书宁,李智,郑士田,郭小铭,王宇航. 煤层底板导水通道钻孔超前探查与多元信息识别技术. 煤炭科学技术. 2023(07): 15-23 .
    33. 王震. 地面区域治理技术在隐伏断层超前探查中的应用. 中国煤炭地质. 2023(07): 47-50 .
    34. 吕红莉,童传霞,郝卫光. 带压开采煤层底板奥灰岩溶水害区域超前治理技术与应用. 煤炭技术. 2023(10): 163-166 .
    35. 毛怀勇,王正,刘凯祥,邹宏,贺晓浪,苏文,冯洁. 井下近水平定向钻进技术在煤矿奥灰水害防治中的应用. 中国煤炭地质. 2023(08): 38-44 .
    36. 薛小勇,南晶晶,胡晓亮,王兴明. 西卓煤矿首采工作面底板水害超前区域治理分析. 科学技术创新. 2023(24): 190-193 .
    37. 许光泉,鲍慧,刘星,贾娒,谢治刚,孙贵. 底板岩溶水害治理效果综合评价模型及应用. 安徽理工大学学报(自然科学版). 2023(05): 76-82 .
    38. 李杰,刘兆峰,唐佳伟,王霄. 矿井水处理技术研究进展. 中国煤炭. 2023(S2): 310-314 .
    39. 张智聪. 带压开采技术体系研究及应用. 内蒙古煤炭经济. 2023(21): 120-122 .
    40. 赵晨德,王心义,任君豪,郝建卿,孟建勇. 基于深度学习理论的煤层底板突水危险性预测. 地下空间与工程学报. 2023(06): 2090-2100 .
    41. 吴铁卫,高磊,程振雨. 山西介休青云煤矿底板奥灰水区域治理目的层位研究. 中国煤炭地质. 2023(12): 43-46 .
    42. 丁亚恒,李少华,陈卫. 地面定向顺层钻孔注浆改造技术在新桥煤矿水害治理中的应用. 能源与环保. 2023(12): 108-114+120 .
    43. 孙亚军,张莉,徐智敏,陈歌,赵先鸣,李鑫,高雅婷,张尚国,朱璐璐. 煤矿区矿井水水质形成与演化的多场作用机制及研究进展. 煤炭学报. 2022(01): 423-437 .
    44. 任君豪,王心义,王麒,王俊智,张波,郭水涛. 基于多方法的煤层底板突水危险性评价. 煤田地质与勘探. 2022(02): 89-97 . 本站查看
    45. 高银贵,孔皖军,安士凯,薛贤明,郑刘根,常成林,姜春露,国伟,雷锋,王刚,杨成超. 唐家会矿奥灰水害区域治理试验工程及防控技术. 煤矿安全. 2022(03): 91-95+103 .
    46. 杨忠,李晓龙. 带压开采煤层底板破坏深度研究. 能源与环保. 2022(05): 306-310 .
    47. 李凯,李晓龙. 基于改进型突水系数法治理底板奥灰水害技术. 煤田地质与勘探. 2022(06): 125-131 . 本站查看
    48. 丁同福,汪敏华,刘满才,朱昌淮,文东明,陈晓雷. 叠层多分支水平井精准建造陷落柱堵水塞技术. 煤炭科学技术. 2022(07): 244-251 .
    49. 张历峰. 采动影响下滨湖煤矿奥灰地下水流场数值模拟研究. 山东煤炭科技. 2022(08): 189-191+195+198 .
    50. 朱敬忠,刘启蒙,刘瑜,范佳俊,杨森. 断层活化特征及防隔水煤柱合理化留设研究. 煤炭科学技术. 2022(08): 166-171 .
    51. 姬中奎,疏义国,翟恩发,高银贵,程爱民,孔皖军,杨柳,罗安昆,薛小渊. 准格尔煤田奥灰水害区域超前治理技术研究. 煤炭技术. 2022(11): 109-112 .
    52. 贺炳伟. 煤矿奥灰水动态监测系统设计及应用. 陕西煤炭. 2022(06): 183-186+210 .
    53. 张培森,董宇航,张晓乐,许大强. 2008—2021年我国煤矿水害事故统计规律分析及预测研究. 煤炭工程. 2022(11): 131-137 .
    54. 虎维岳,赵春虎,吕汉江. 煤层底板水害区域注浆治理影响因素分析与高效布孔方式. 煤田地质与勘探. 2022(11): 134-143 . 本站查看
    55. 于小鸽,吕华东,张德明,吕昌兴,曲林燕. 霄云井田奥陶系灰岩岩溶发育规律研究. 煤矿安全. 2022(12): 22-27 .
    56. 董书宁,刘再斌,程建远,陈宝辉,代振华,李丹. 煤炭智能开采地质保障技术及展望. 煤田地质与勘探. 2021(01): 21-31 . 本站查看
    57. 王皓,董书宁,乔伟,姬亚东,朱开鹏,周振方,宁殿艳,尚宏波. 矿井水害防控远程服务云平台构建与应用. 煤田地质与勘探. 2021(01): 208-216 . 本站查看
    58. 尹尚先,连会青,徐斌,田午子,曹敏,姚辉,孟浩鹏. 深部带压开采:传承与创新. 煤田地质与勘探. 2021(01): 170-181 . 本站查看
    59. 高耀全,方刚,闫兴达. 邢东煤矿深部区域奥灰水害探查治理技术. 煤矿安全. 2021(05): 87-95 .
    60. 姜文浩. 联合注浆在工作面底板水害防治中的应用. 煤炭科技. 2021(04): 83-87 .
    61. 李晓龙. 煤矿井下水砂突涌钻孔封孔技术研发与应用. 煤田地质与勘探. 2021(04): 192-197 . 本站查看
    62. 孟凡丁,许光泉,孙贵,谢治刚. 深埋条件下水平分支孔注浆模拟分析. 绿色科技. 2021(14): 194-198+213 .
    63. 郑士田,马荷雯,姬亚东. 煤层底板水害区域超前治理技术优化及其应用. 煤田地质与勘探. 2021(05): 167-173 . 本站查看
    64. 董书宁. 煤矿安全高效生产地质保障的新技术新装备. 中国煤炭. 2020(09): 15-23 .

    Other cited types(17)

Catalog

    Get Citation
    PDF
    XML

    Article Metrics

    Article views (129) PDF downloads (29) Cited by(81)
    Related

    Copyright of website design © Editorial Office of Coal Geology & Exploration 陕ICP备05001372号-6 陕公网安备 61019002002193号

    Address: Editorial Office of Coal Geology & Exploration, No.82 Jinye 1st Rd, High-Tech Zone, Xi'an City, Shaanxi, China

    Tel: 029-81778075 E-mail: ccrimtdzykt@vip.163.com

    Supported by: Beijing Renhe Information Technology Co., Ltd. Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return