Research on the numerical simulation of the groundwater flow field in bedrock islands
XU Haoli1, WANG Daqing1, DENG Zhengdong1, DING Zhibin1, ZHAO Xiaolan1, LIU Zhixin2, XU Xingang2, SU Heyan2
1. Defense Engineering College, Army Engineering University, Nanjing 210007, China; 2. School of Resources and Geosciences, China University of Mining and Technology, Xuzhou 221116, China
Abstract:The island is an important part of our territory, and it is of great significance to our national security and national defense. Groundwater resources in islands are particularly valuable. Simulation of the groundwater flow field is an important method to study the distribution of groundwater. Due to the flexible hydrogeological condition of islands and a small number of observation wells, the accuracy of hydrogeological model generalization was not high and the initial conditions were difficult to obtain. In order to overcome these difficulties of the groundwater flow field simulation in bedrock islands, the authors chose Wailingding Island in Zhuhai as a study case to build the geological model of island using the digital elevation model data. The geological layers data of the island were acquired thraugh GPR method, DC method and hydrogeological means. The initial water level of the groundwater was determined to build the groundwater flow field model by remote sensing elevation and well data. Finally, the groundwater flow images of simulation results were mapped through the numerical simulation of groundwater flow of Wailingding Island. The actual water levels of the measured multiple points were well correlated with the simulated water levels, with R2 of 0.872 2. It can be seen that using integrated remote sensing, geophysical prospecting, hydrogeological means and other methods and technologies to obtain data, and using the methods of simulation softwares or programs to simulate data, were effective research methods in the field of island groundwater resource.
许颢砾, 王大庆, 邓正栋, 丁志斌, 赵小兰, 刘志新, 许新刚, 苏合岩. 基岩岛屿地下水流场数值模拟研究[J]. 中国地质调查, 2020, 7(4): 95-103.
XU Haoli, WANG Daqing, DENG Zhengdong, DING Zhibin, ZHAO Xiaolan, LIU Zhixin, XU Xingang, SU Heyan. Research on the numerical simulation of the groundwater flow field in bedrock islands. , 2020, 7(4): 95-103.
[1] McCartney M P,Houghton-Carr H A.An assessment of ground-water recharge on the Channel Island of Jersey[J].Water Environ J,1998,12(6):445-451. [2] Schneider J C,Kruse S E.Assessing selected natural and anthropogenic impacts on freshwater lens morphology on small barrier islands:Dog Island and St.George Island,Florida,USA[J].Hydrogeol J,2006,14(1/2):131-145. [3] 张保祥. 火山和珊瑚岛屿上的地下水勘探[J].国外地质勘探技术,1997(3):14-16. [4] 甄黎,周从直,束龙仓,等.海岛淡水透镜体演变规律的室内模拟实验[J].吉林大学学报(地球科学版),2008,38(1):81-85. [5] 周从直,何丽,杨琴,等.珊瑚岛礁淡水透镜体三维数值模拟研究[J].水利学报,2010,41(5):560-566. [6] 李国敏,陈崇希,沈照理,等.涠洲岛海水入侵模拟[J].水文地质工程地质,1995(5):1-5. [7] 庞忠和,高明.基岩海岛地下水资源与环境——以庙岛群岛为例[J].勘察科学技术,1988(3):27-30. [8] 庞忠和. 中国东部沿海基岩海岛地下水资源分布特点——以庙岛群岛为例[J].地质科学,1987(3):291-299. [9] 郑春苗,Bennett G D.地下水污染物迁移模拟[M].孙晋玉,卢国平,译.北京:高等教育出版社,2009. [10] 董贵明,田娟.地下水流运动及污染物迁移数值模拟Visual Modflow应用分析与实例[M].徐州:中国矿业大学出版社,2013. [11] 卢薇,刘卫平.珠江口东岸地区海水入侵三维溶质数值模拟研究[J].热带地理,2010,30(3):294-298. [12] 谭家华,雷宏武.基于GMS的三维TOUGH2模型及模拟[J].吉林大学学报(地球科学版),2017,47(4):1229-1235. [13] 王大庆,许颢砾,邓正栋,等.基岩岛屿地下水数值模拟发展研究现状[J].中国地质调查,2019,6(3):68-74. [14] 周鹏鹏,李国敏,卢耀东,等.大陆岛地下水动力学特征——以湛江东海岛为例[J].水文地质工程地质,2013,40(1):12-18. [15] 滕建标,刘蕴芳,周雯,等.冲蚀型大陆岛地下水数值模拟研究——以东海岛为例[J].环境影响评价,2015,37(1):59-63. [16] 温汉辉. 雷州半岛地下水循环规律及合理开发利用研究[D].武汉:中国地质大学(武汉),2013 [17] 许颢砾,王大庆,邓正栋,等.某岛屿GF-1-RS浅层地下水富集性评估[J].水文地质工程地质,2018,45(6):42-48. [18] 邓正栋,叶欣,龙凡,等.地下水遥感模糊评估指数的构建与研究[J].地球物理学报,2013,56(11):3908-3916. [19] Lee S,Song K Y,Kim Y S,et al.Regional groundwater productivity potential mapping using a geographic information system (GIS) based artificial neural network model[J].Hydrogeol J,2012,20(8):1511-1527. [20] 汪民,殷跃平,文冬光,等.水文地质手册[M].北京:地质出版社,2012. [21] 毛昶熙. 堤防工程手册[M]. 北京:中国水利水电出版社,2009.