Journal of Jilin University(Earth Science Edition) ›› 2021, Vol. 51 ›› Issue (6): 1801-1810.doi: 10.13278/j.cnki.jjuese.20200054

Previous Articles     Next Articles

Hydraulic Connection Coefficient and Quantitative Evaluation of Hydraulic Connection Between Aquifers

Li Chaofeng1,2   

  1. 1. Xi'an Research Institute, China Coal Technology and Engineering Group Corp, Xi'an 710077, China;
    2. Shaanxi Key Laboratory of Coal Mine Hazard Prevention and Control Technology, Xi'an 710077, China
  • Received:2020-03-05 Online:2021-11-26 Published:2021-11-24
  • Supported by:
    Supported by National Key R&D Program of China (2016YFC0501104)

Abstract: In order to quantitatively evaluate the degree of groundwater hydraulic connection between aquifers, the concept of "hydraulic connection coefficient" C is first proposed. Based on the drawdown of groundwater level in full penetrating wells during the steady-state pumping test when the groundwater level is stable, the hydraulic connection coefficient C is defined as the ratio of the drawdown of groundwater level of the target aquifer to the drawdown of groundwater level of the pumping/dewatering aquifer in the observation borehole. The hydraulic connection coefficient can be used to quantitatively evaluate the degree of hydraulic connection between two points in different directions and different distances on the aquifer plan, and also between different aquifers in the vertical direction. According to the hydraulic connection coefficient C value of the aquifers in Luohe Formation in Ordos basin, the degree of groundwater hydraulic connection between the aquifers is divided into five grades:Among them, 0.000 0 ≤ C<0.062 5, the hydraulic connection is very weak; 0.062 5 ≤ C<0.125 0, the hydraulic connection is weak; 0.125 0 ≤ C<0.250 0, the hydraulic connection is medium; 0.250 0 ≤ C<0.500 0, the hydraulic connection is strong; C ≥ 0.500 0, the hydraulic connection is very strong. Taking the data of pumping test and dewatering test in Gaojiabu mine field as an example, the hydraulic connection coefficient and the response time of groundwater level in the observation borehole beginning to fall are used to quantitatively evaluate the internal groundwater hydraulic connection of the thick and layered Luohe Formation. Among them, when the hydraulic connection coefficient of the middle-upper layers in Luohe Formation is 0.373 0 and 0.413 8 respectively, and the response time of groundwater level in the observation borehole beginning to fall is very short (about 5 min), the groundwater hydraulic connection is strong; The hydraulic connection coefficient of the lower layers in Luohe Formation is 0.440 1 and 0.491 1, respectively, and the response time of groundwater level in observation borehole beginning to fall is short (9-20 min), the groundwater hydraulic connection is strong; When the hydraulic connection coefficient between the middle-upper and lower layers in Luohe Formation is 0.000 2, 0.007 2 and 0.089 7, respectively, and the response time of groundwater level in the observation borehole is longer (more than 60 min), the groundwater hydraulic connection is weak or very weak.

Key words: Luohe Formation aquifer, vertical layered aquifers, hydraulic connection coefficient, pumping (or dewatering) test, groundwater

CLC Number: 

  • P641
[1] Bear J. Hydraulics of Groundwater[M]. New York:Dover Publications,INC,1979.
[2] 陈崇希,林敏,成建梅.地下水动力学[M].5版.北京:地质出版社,2011. Chen Chongxi,Lin Min,Cheng Jianmei. Hydraulics of Groundwater[M]. 5th ed. Beijing:Geological Publishing House,2011.
[3] 郭东屏,宋焱勋,钱会,等.地下水动力学[M].西安:陕西科学技术出版社,1994. Guo Dongping,Song Yanxun,Qian Hui, et al. Hydraulics of Groundwater[M]. Xi'an:Shaanxi Science and Technology Press,1994.
[4] Bear J.多孔介质流体动力学[M].李竞生,陈崇希,译.北京:中国建筑工业出版社,1983. Bear J. Dynamics of Fluids in Porous Media[M]. Translated by Li Jingsheng,Chen Chongxi. Beijing:China Architecture & Building Press,1983.
[5] 王明明,解伟,安永会,等.封隔注浆分层成井技术在水文地质勘查中的应用研究[J].水文地质工程地质,2019,46(1):50-55. Wang Mingming,Xie Wei,An Yonghui,et al. Application of the Technology of Injecting Cement for the Stratified Well Completion to Hydrogeological Exploration[J]. Hydrogeology & Engineering Geology,2019,46(1):50-55.
[6] 邵红旗,曹祖宝,李建文,等.一种放水试验分析方法及其应用[J].水文地质工程地质,2014,41(2):7-12,43. Shao Hongqi,Cao Zubao,Li Jianwen,et al. A Method of Analysis of Dewatering Test and Application[J]. Hydrogeology & Engineering Geology,2014,41(2):7-12,43.
[7] 张海涛,许光泉.基于Visual Basic 6.0的含水层水文地质参数求取软件的开发及应用[J].煤田地质与勘探,2018,46(2):105-110. Zhang Haitao,Xu Guangquan. The Development and Application of Aquifer Hydrogeological Parameter Calculation Software Based on Visual Basic 6.0[J]. Coal Geology & Exploration,2018,46(2):105-110.
[8] 方刚,梁向阳,黄浩,等.巴拉素井田煤层富水机理与注浆堵水技术[J].煤炭学报,2019,44(8):2470-2483. Fang Gang,Liang Xiangyang,Huang Hao,et al. Water-Rich Mechanism of Coal Seam and Grouting and Blocking Water Technology in Balasu Mine Field[J].Journal of China Coal Society,2019,44(8):2470-2483.
[9] 徐智敏,高尚,孙亚军,等.西部典型侏罗系富煤区含水介质条件与水动力学特征[J].煤炭学报,2017,42(2):444-451. Xu Zhimin,Gao Shang,Sun Yajun,et al. A Study of Conditions of Water Bearing Media and Water Dynamics in Typical Jurassic Coal Rich Regions in Western China[J]. Journal of China Coal Society,2017,42(2):444-451.
[10] 李超峰,虎维岳,刘英锋.洛河组含水层垂向差异性研究及保水采煤意义[J].煤炭学报,2019,44(3):848-857. Li Chaofeng,Hu Weiyue,Liu Yingfeng. Vertical Hydrogeological Characteristics of Luohe Aquifer and Its Significance of Water-Preserved Coal Mining[J]. Journal of China Coal Society,2019,44(3):848-857.
[11] 李超峰.彬长矿区巨厚洛河组垂向差异性研究[J].煤炭技术,2018,37(4):131-133. Li Chaofeng. Vertical Differences of Thick Luohe Formation in Binchang Mining Area[J]. Coal Technology,2018,37(4):131-133.
[12] 刘英锋,郭小铭.导水裂缝带部分波及顶板含水层条件下涌水量预测[J].煤田地质与勘探,2016,44(5):97-101,107. Liu Yingfeng,Guo Xiaoming. Prediction of Water Inflow in Roof Aquifer Affected by Water-Flowing Fracture Zone[J]. Coal Geology & Exploration,2016,44(5):97-101,107.
[13] 周建军.崔木煤矿顶板涌突水类型及其判别研究[J].煤矿安全,2019,50(4):205-207,212. Zhou Jianjun. Study on Roof Water Inrush Type and Its Discrimination in Cuimu Coal Mine[J]. Safety in Coal Mines,2019,50(4):205-207,212.
[14] 国家煤矿安全监察局. 煤矿防治水细则[M]. 北京:煤炭工业出版社,2018. The National Coal Mine Safety Administration of China. Handbook of Mine Water Hazard Prevention and Control[M]. Beijing:China Coal Industry Publishing House,2018.
[15] 李超峰.采煤工作面顶板巨厚层状含水层涌水量预测研究[D].北京:煤炭科学研究总院,2019. Li Chaofeng. Prediction Theory and Method of Water Inflow from Roof Thick Layered Aquifer of Coal Mining Face[D]. Beijing:China Coal Research Institute, 2019.
[16] 李云峰,冯建国,王玮,等.鄂尔多斯盆地白垩系含水层系统分析[J].西北地质,2004,37(1):90-96. Li Yunfeng,Feng Jianguo,Wang Wei,et al. The Groundwater System Analysis of Cretaceous System of Ordos Basin[J]. Northwestern Geology,2004,37(1):90-96.
[17] 方刚,刘柏根.基于巴拉素井田多孔抽水试验的含水层特征及水力联系研究[J].水文,2019,39(3):36-40,67. Fang Gang,Liu Baigen. Research on Aquifers Characteristics and Hydraulic Connection Based on Multiple Drilling Pumping Tests in Balasu Well Field[J]. Journal of China Hydrology,2019,39(3):36-40,67.
[18] 彭涛,龙良良,刘凯祥,等.基于煤层顶板抽水试验的含水层水力联系研究[J].矿业安全与环保,2019,46(3):66-69,73. Peng Tao,Long Liangliang,Liu Kaixiang,et al. Study on Aquifer Hydraulic Connection Based on Pumping Test of Coal Seam Roof[J]. Mining Safety & Environmental Protection,2019,46(3):66-69,73.
[19] 穆鹏飞.示踪试验在煤层顶底板充水含水层水力联系探查中的应用[J].中国煤炭,2019,45(5):55-58. Mu Pengfei. Application of Tracer Test in Hydraulic Connection Exploration of Water-Filled Aquifer in Roof and Floor of Coal Seam[J]. China Coal,2019,45(5):55-58.
[20] 姬中奎,薛小渊,杨志斌,等.神府煤田张家峁煤矿烧变岩与水库水力联系研究[J].中国煤炭地质,2019,31(4):57-61. Ji Zhongkui, Xue Xiaoyuan, Yang Zhibin, et al. Study on Hydraulic Connection Between Burnt Rock and Reservoir in Zhangjiamao Coalmine, Shenfu Coalfield[J]. Coal Geology of China,2019,31(4):57-61.
[21] 郑刚,曹剑然,程雪松,等.考虑承压含水层间越流的地下水回灌现场试验研究[J].岩土工程学报,2019,41(9):1609-1618. Zheng Gang,Cao Jianran,Cheng Xuesong,et al. Field Tests on Groundwater Recharge Considering Leakage Between Semiconfined Aquifers[J]. Chinese Journal of Geotechnical Engineering,2019,41(9):1609-1618.
[22] 许蓬,王明.环境同位素技术在判定矿井含水层间水力联系的应用[J].煤炭科学技术,2018,46(增刊1):227-230. Xu Peng,Wang Ming. Application of Environmental Isotopes Technology in Determining Hydraulic Connection Between Mine Aquifer[J]. Coal Science and Technology,2018,46(Sup.1):227-230.
[23] 蒋瑞,张志才,陈喜,等.西南喀斯特峰丛- 洼地水力联系特征分析[J].地球与环境,2018,46(2):121-128. Jiang Rui,Zhang Zhicai,Chen Xi,et al. Hydrologic Connectivity in Peak-Cluster Depression of Karst Area in Southwestern China[J]. Earth and Environment,2018,46(2):121-128.
[24] 苏小四,高睿敏,袁文真,等.基于环境同位素技术的河水补给研究:以沈阳黄家傍河水源地为例[J].吉林大学学报(地球科学版),2019,49(3):762-772. Su Xiaosi,Gao Ruimin,Yuan Wenzhen,et al. Research on River Recharge Based on Environmental Isotope Technology:A Case Study of Huangjia Riverside Well Field in Shenyang City[J]. Journal of Jilin University(Earth Science Edition),2019,49(3):762-772.
[25] 束龙仓,王明昭,张惠潼,等.咸淡水界面位置确定的综合方法(TEcG)及其应用[J].吉林大学学报(地球科学版),2019,49(6):1706-1713. Shu Longcang,Wang Mingzhao,Zhang Huitong,et al. Comprehensive Method (TEcG) of Determination of the Location of Freshwater and Saltwater Interface and Its Application[J]. Journal of Jilin University(Earth Science Edition),2019,49(6):1706-1713.
[26] 地质矿产部水文地质工程技术方法研究队.水文地质手册[M].北京:地质出版社,1978. Research Team of Hydrogeological & Engineering Technology Methods, Ministry of Geology and Mineral Resources, China. Handbook of Hydrogeology[M]. Beijing:Geological Publishing House,1978.
[1] Liu Yuanqing, Zhou Le, Li Wei, Wang Xinfeng, Ma Xuemei, Lü Lin, Yin Kai, Meng Shunxiang. Controlling Effect of Mesozoic Tectonic Activities on Present Karst Groundwater Occurrence in Central Mountain Area of Shandong Province [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(6): 1811-1822.
[2] Pan Weiqiang, Zhang Liming, Cong Yu. Relationship Between Shaft Failure with Stress-Relief Groove and Groundwater Level in Thick Loose Strata [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(5): 1578-1586.
[3] Yan Baizhong, Sun Jian, Wang Xinzhou, Li Xiaomeng, Sun Fengbo, Fu Danping. Suitability Zoning of Groundwater Source Heat Pump in Shijiazhuang Based on GIS-FAHP [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(4): 1172-1181.
[4] Wang Zhe, Fu Yu, Zhu Jingsi, Cao Wengeng. Effect Assessment on Groundwater Recharge for Typical Rivers in North China [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(3): 843-853.
[5] Yan Baizhong, Sun Fengbo, Li Xiaomeng, Wang Yuqing, Fan Chengbo, Chen Jiaqi. Impact of Climate Change and Human Activities on Groundwater Depth of Gaocheng District in Shijiazhuang City [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(3): 854-863.
[6] Luo Yishan, Li Zhao. Statistical Evaluation of Impact of Coalbed Methane Exploitation on Groundwater Environment in Qinshui Basin [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(2): 516-525.
[7] Zhu Jun, Li Ting, Chen Chao, Xie Tian, Zhang Aiming. Model Calculation Method of Radionuclide Groundwater Release Flux of Offshore Nuclear Power Plants [J]. Journal of Jilin University(Earth Science Edition), 2021, 51(1): 201-211.
[8] Yan Baizhong, Sun Jian, Wang Xinzhou, Han Na, Liu Bo. Multivariable LSTM Neural Network Model for Groundwater Levels Prediction [J]. Journal of Jilin University(Earth Science Edition), 2020, 50(1): 208-216.
[9] Shen Haoyong, Liang Yongping, Zhao Chunhong, Tang Chunlei, Wang Zhiheng. Hydro-Geological Characteristics and Demarcation of Gudui Spring Karst Groundwater System [J]. Journal of Jilin University(Earth Science Edition), 2020, 50(1): 217-225.
[10] Feng Bo, Chen Mingtao, Yue Dongdong, Li Shengtao, Jia Xiaofeng, Song Dan. Comparison of 3D Geological Modeling Based on Two Different Interpolation Methods [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(4): 1200-1208.
[11] Dong Linyao, Ren Hongyu, Lei Junshan, Liu Jigen. Temperature Tracing Method for Groundwater Flux Under Surface Warming [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(3): 773-783.
[12] Fu Xiaogang, Tang Zhonghua, Liu Bintao, Lin Linlin, Bu Hua, Yan Baizhong. Study on Exploitable Groundwater Resources of Yangzhuang Basin in Shandong Province by Using Simulation-Optimization Model [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(3): 784-796.
[13] Yu Weijiang, Jia Chao, Di Shengtong, Li Kang, Yuan Han. Groundwater Quality Assessment Based on Comprehensive Weight and Improved Matter-Element Extension Evaluation Model [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(2): 539-547.
[14] Luo Zujiang, Ning Di, Du Jingjing, Lu Wei. Influence of Building Load and Groundwater Exploitation on Land Subsidence in Shengze,Wujiang [J]. Journal of Jilin University(Earth Science Edition), 2019, 49(2): 514-525.
[15] Liu Na, Ding Jiyang, Yu Qingmin, Zhang Sida, Zhao Hongjun, Lü Chunxin. Degradation of 1,4-Dioxane in Groundwater by Ultrasound Enhanced ZVI-Activated Persulfate Oxidation Process [J]. Journal of Jilin University(Earth Science Edition), 2018, 48(6): 1831-1837.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
[1] CHENG Li-ren, ZHANG Yu-jie, ZHANG Yi-chun. Ordovician Nautiloid Fossils of Xainza Region,Tibet[J]. J4, 2005, 35(03): 273 -0282 .
[2] LI Bing-cheng. Preliminary Studies on Holocene Climatic In Fuping,Shaanxi Province[J]. J4, 2005, 35(03): 291 -0295 .
[3] HE Zhong-hua,YANG De-ming,WANG Tian-wu,ZHENG Chang-qing. SHRIMP U[CD*2]Pb Dating of Zircons from Two-Mica Granite in Baga Area in Gangdise Belt[J]. J4, 2005, 35(03): 302 -0307 .
[4] CHEN Li, NIE Lei, WANG Xiu-fan, LI Jin. Seismic Risk Analysis of Some Electric Power Equipment Station in Suizhong[J]. J4, 2005, 35(05): 641 -645 .
[5] JI Hong-jin,SUN Feng-yue2,CHEN Man,HU Da-qian,SHI Yan-xiang,PAN Xiang-qing. Geochemical Evaluation for Uncovered GoldBearing Structures in Jiaodong Area[J]. J4, 2005, 35(03): 308 -0312 .
[6] CHU Feng-you, SUN Guo-sheng,LI Xiao-min,MA Wei-lin, ZHAO Hong-qiao. The Growth Habit and Controlling Factors of the CobaltRich Crusts in Seamount of the Central Pacific[J]. J4, 2005, 35(03): 320 -0325 .
[7] LI Bin, MENG Zi-fang, LI Xiang-bo, LU Hong-xuan, ZHENG Min. The Structural Features and Depositional Systems of the Early Tertiary in the Biyang Depression[J]. J4, 2005, 35(03): 332 -0339 .
[8] LI Tao, WU Sheng-jun, CAI Shu-ming, XUE Huai-ping, YASUNORI Nakayama. Simulation Analysis of the Storage Capacity Based on DEM Before and After Connecting to Yangtze River in Zhangdu Lake[J]. J4, 2005, 35(03): 351 -0355 .
[9] KUANG Li-xiong,GUO Jian-hua, MEI Lian-fu, TONG Xiao-lan, YANG Li. Study on the Upheaval of the Bogeda Mountain Block from Angle of Oil and Gas Exploration[J]. J4, 2005, 35(03): 346 -0350 .
[10] ZHANG Guang-xin, DENG Wei, HE Yan, RAMSIS Salama. An Application of Hydrological Response Units in Assessment of Soil Salinization Risks[J]. J4, 2005, 35(03): 356 -0360 .