All-Element Dataset of Combined Exploration of Urban Underground Spaces with Strong Interference

ZHANG Maosheng; WANG Yimin; ZHANG Ge; DONG Ying; SUN Pingping; JIA Jun

doi:10.12029/gc2019Z204

2019 Vol. 46, No. S2

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Article navigation > Geology in China > 2019 > 46(S2): 30-49

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ZHANG Maosheng, WANG Yimin, ZHANG Ge, DONG Ying, SUN Pingping, JIA Jun. 2019. All-Element Dataset of Combined Exploration of Urban Underground Spaces with Strong Interference[J]. Geology in China, 46(S2): 30-49. doi: 10.12029/gc2019Z204

Citation:

ZHANG Maosheng, WANG Yimin, ZHANG Ge, DONG Ying, SUN Pingping, JIA Jun. 2019. All-Element Dataset of Combined Exploration of Urban Underground Spaces with Strong Interference[J]. Geology in China, 46(S2): 30-49. doi: 10.12029/gc2019Z204

All-Element Dataset of Combined Exploration of Urban Underground Spaces with Strong Interference

1.
Xi’an Center, China Geological Survey, Xi’an 710054, China
2.
Shaanxi Engineering Technical Research Center of Water Resources and Environment, Xi’an 710054, China

Fund Project: China Geological Survey projects titled “Risk Assessment of Geologic Disasters in Important Towns in Shaanxi” (DD20160261) and “Comprehensive Geological Survey in Guanzhong – Tianshui Economic Region” (DD20189220) and “Multi-element Urban Geological Survey in Xi’an and Comprehensive Geological Survey in Yan’an, a Former Base of the Communist Party of China” (DD20189270).

More Information

Author Bio: ZHANG Maosheng, male, born in 1962, professor, engages in hydrogeological, engineering geological, and environmental geological survey and related research; E-mail: zmaosheng@cgs.cn
Corresponding author: WANG Yimin, male, born in 1990, Ph.D, engages in application of geophysical method and technology; E-mail: yi_min_w@163.com

Received Date: 23 October 2019

Revised Date: 08 November 2019

Publish Date: 25 December 2019

Abstract

Abstract

The utilization of underground space has become a major means of solving the problems plaguing cities, and the precise exploration of underground space is fundamental to its development and utilization. However, the theories, method combination, elements to be acquired and data application regarding the exploration of urban underground space with strong interference are yet to be determined in a united manner. The all-element dataset of combined exploration of urban underground space with strong interference (also referred to as the Dataset) relies on these four projects initiated by the China Geological Survey: Risk Assessment of Geologic Disasters in Important Towns in Shaanxi Province (2013—2016), Comprehensive Geological Survey in Guanzhong – Tianshui Economic Region (2016—2018), Multi-element Urban Geological Survey in Xi’an (2018—2021) and Comprehensive Geological Survey in Yan’an, a Former Base of the Communist Party of China (2018—2021). The aim of these projects were to meet the demand for quality assessment of rock and soil masses and also the assessment, development and utilization of urban underground space. During the development of the Dataset, monitoring-while-drilling (MWD) technology was introduced based on regular geophysical prospecting, drilling and testing. Furthermore, a total of 13 parameters was logged, a combined method of underground space exploration was established and the all-element data required for quality assessment of rock and soil masses and urban underground space were obtained. The data in the Dataset were obtained from the urban area of Shanyang County, in the Qinba Mountains of Shaanxi Province, the urban area of Xi’an City in the Guangzhong Basin and the urban area of Yan’an City in the Loess Plateau. It consists of five types of data, i.e., engineering geological drilling, testing, multi-parameter logging, MWD and ground geophysical prospecting. In detail, the data were acquired from 144 engineering geological boreholes, 672 testing samples, 111 boreholes for the logging of 13 parameters by geophysical prospecting, 36 MWD boreholes and 5 profiles of ground geophysical prospecting obtained via 4 methods. In total, the Dataset consists of 968 sets of data and 3 664 files in the formats of .jpg, .xls, .doc, .mpj and .dwg. It can be applied to the quality assessment of rock and soil masses, the establishment of 3D urban geological all-element models, the assessment of underground space resources, the research on the coupling relationship between the quality and physical properties of rock and soil masses and the scientific research of urban geology.
- drilling /
- monitoring while drilling (MWD) /
- ground geophysical prospecting /
- multi-parameter logging /
- underground space /
- urban geological survey engineering /
- Xi’an

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References

[1]	Bobylev N. 2009. Mainstreaming sustainable development into a city’s master plan: a case of urban underground space use[J]. Land Use Policy, 26(4): 1128−1137. doi: 10.1016/j.landusepol.2009.02.003 CrossRef Google Scholar
[2]	Broere W. 2016. Urban underground space: Solving the problems of today’s cities[J]. Tunnelling and Underground Space Technology, 55: 245−248. doi: 10.1016/j.tust.2015.11.012 CrossRef Google Scholar
[3]	Yue ZQ, Lee CF, Law KT, et al. 2004. Automatic monitoring of rotary-percussive drilling for ground characterization –illustrated by a case example in Hong Kong[J]. International Journal of Rock Mechanics & Mining Science, 41: 573−612. Google Scholar
[4]	陈伟. 2006. 城市地下空间开挖对环境的影响与试验研究[D]. 中南大学. Google Scholar
[5]	何静, 何晗晗, 郑桂森, 刘予, 周圆心, 肖景泽, 王纯君. 2019. 北京五环城区浅部沉积层的三维地质结构建模[J]. 中国地质, 46(2): 244−254. Google Scholar
[6]	戚帮申, 丰成君, 谭成轩, 张鹏, 孟静, 张春山, 杨为民, 杨肖肖, 雷晓东. 2019. 京张地区延矾盆地北缘活动断裂带桑园镇隐伏段综合地球物理及钻孔地层剖面研究[J]. 中国地质, 46(3): 468−481. Google Scholar
[7]	钱七虎. 1998. 城市可持续发展与地下空间开发利用[J]. 地下空间, 18(2): 69−74. Google Scholar
[8]	乔永康, 张明洋, 刘洋, 彭芳乐. 2017. 古都型历史文化名城地下空间总体规划策略研究[J]. 地下空间与工程学报, 13(4): 859−867. Google Scholar
[9]	田中英, 张茂省, 冯立, 孙萍萍, 于锋丹. 2019. 基于综合物探的黄土滑坡优势通道探测[J]. 西北地质, 52(2): 172−180. Google Scholar
[10]	王化齐, 董英, 张茂省. 2019. 西安市地下空间开发利用现状与对策建议[J]. 西北地质, 52(2): 46−52. Google Scholar
[11]	王亚辉, 张茂省, 师云超, 董英, 王锋, 于峰丹. 2019. 基于综合物探的城市地下空间探测与建模[J]. 西北地质, 52(2): 83−94. Google Scholar
[12]	杨文采, 田钢, 夏江海, 杨波. 2019. 华南丘陵地区城市地下空间开发利用前景[J]. 中国地质, 46(3): 447−454. Google Scholar
[13]	岳中琦. 2014. 钻孔过程监测(DPM)对工程岩体质量评价方法的完善与提升[J]. 岩石力学与工程学报, 33(10): 1977−1996. Google Scholar
[14]	张茂省, 董英, 刘洁. 2014. 论新型城镇化中的城市地质工作[J]. 兰州大学学报(自然科学版), 50(5): 581−587. Google Scholar
[15]	张茂省, 董英, 张新社, 刘洁, 曾庆铭. 2013. 地面沉降预测及其风险防控对策—以大西安西咸新区为例[J]. 中国地质灾害与防治学报, 24(4): 115−118. Google Scholar
[16]	张茂省, 李同录, 程秀娟, 孙萍萍, 李强, 乔志甜, 赵权利. 2019. 山区城市地下空间资源评价与开发利用模式—以延安市为例[J]. 山地学报, 37(3): 303−315. Google Scholar
[17]	张茂省, 王化齐, 王尧, 董英, 孙萍萍. 2018. 中国城市地质调查进展与展望[J]. 西北地质, 51(4): 1−8. doi: 10.3969/j.issn.1009-6248.2018.04.001 CrossRef Google Scholar
[18]	张珊珊, 张茂省, 孙萍萍, 董英, 冯立. 2019. 面向黄土地质灾害的优势流研究[J]. 兰州大学学报(自然科学版), 55(2): 274−280. Google Scholar
[19]	赵镨, 姜杰, 王秀荣. 2017. 城市地下空间探测关键技术及发展趋势[J]. 中国煤炭地质, 29(9): 61−66. doi: 10.3969/j.issn.1674-1803.2017.09.12 CrossRef Google Scholar
[20]	周圆心, 郑桂森, 何静, 李超, 刘予, 何晗晗, 肖景泽. 2019. 北京平原区地下空间建设地质安全监测问题探讨[J]. 中国地质, 46(3): 455−467. Google Scholar
[1]	Bobylev N. 2009. Mainstreaming sustainable development into a city’s master plan: a case of urban underground space use[J]. Land Use Policy, 26(4): 1128−1137. doi: 10.1016/j.landusepol.2009.02.003 CrossRef Google Scholar
[2]	Broere W. 2016. Urban underground space: Solving the problems of today’s cities[J]. Tunnelling and Underground Space Technology, 55: 245−248. doi: 10.1016/j.tust.2015.11.012 CrossRef Google Scholar
[3]	Yue ZQ, Lee CF, Law KT, et al. 2004. Automatic monitoring of rotary-percussive drilling for ground characterization–illustrated by a case example in Hong Kong[J]. International Journal of Rock Mechanics & Mining Science, 41: 573−612. Google Scholar
[4]	Chen Wei. 2006. Environmental impact and experimental study of urban underground space excavation [D]. Central South University (in Chinese with English abstract). Google Scholar
[5]	He Jing, He Hanhan, Zheng Guisen, Liu Yu, Zhou Yuanxin, Xiao Jingze, Wang Chunjun. 2019. 3D geological modelling of superficial deposits in Beijing City[J]. Geology in China, 46(2): 244−254. Google Scholar
[6]	Qi Bangshen, Feng Chengjun, Tan Chengxuan, Zhang Peng, Meng Jing, Zhang Chunshan, Yang Weimin, Yang Xiaoxiao, Lei Xiaodong. 2019. Application of comprehensive geophysical-drilling exploration to detect the buried North Boundary active Fault Belt of Yanqing-Fanshan Basin in Sangyuan town, Beijing-Zhangjiakou area[J]. Geology in China, 46(3): 468−481. Google Scholar
[7]	Qian Qihu. 1998. Urban sustainable development and exploitation of underground space[J]. Chinese Journal of Underground Space and Engineering, 18(2): 69−74 (in Chinese). Google Scholar
[8]	Qiao Yongkang, Zhang Mingyang, Liu Yang, Peng Fangle. 2017. Strategy Research on the Master Planning for Underground Space Utilization in Historical and Cultural City of Ancient Capital Type[J]. Chinese Journal of Underground Space and Engineering, 13(4): 859−867 (in Chinese with English abstract). Google Scholar
[9]	Tian Zhongying, Zhang Maosheng, Feng Li, Yu Fengdan. 2019. Preferential passage detectionof loess landslide based on integrated geophysical exploration[J]. Northwestern Geology, 52(2): 172−180 (in Chinese with English abstract). Google Scholar
[10]	Wang Huaqi, Dong Ying, Zhang Maosheng. 2019. Present situation and countermeasures for the underground space utilization in Xi’an city[J]. Northwestern Geology, 52(2): 46−52 (in Chinese with English abstract). Google Scholar
[11]	Wang Yahui, Zhang Maosheng, Shi Yunchao, Dong Ying, Wang Feng, Yu Fengdan. 2019. Precise detection and modeling of urban underground space based on integrated geophysical exploration[J]. Northwestern Geology, 52(2): 83−94 (in Chinese with English abstract). Google Scholar
[12]	Yang Wencai, Tian Gang, Xia Jianghai, Yang Bo. 2019. The prospect of exploitation and utilization of urban underground space in hilly areas of South China[J]. Geology in China, 46(3): 447−454. Google Scholar
[13]	Yue Zhongqi. 2014. Drilling process monitoring for refining and upgrading rock mass quality classification methods[J]. Chinese Journal of Rock Mechanics and Engineering, 33(10): 1977−1996 (in Chinese with English abstract). Google Scholar
[14]	Zhang Maosheng, Dong Ying, Liu Jie. 2014. Discussion of urban geological work in new urbanization[J]. Journal of Lanzhou University(Natural Science), 50(5): 581−587 (in Chinese with English abstract). Google Scholar
[15]	Zhang Maosheng, Dong Ying, Zhang Xinshe, Liu Jie. 2013. Zeng Qingming. Prediction of land subsidence and its mitigation methods—a case study in the new urban district of Xi’an-Xianyang[J]. The Chinese Journal of Geological Hazard and Control, 24(4): 115−118 (in Chinese with English abstract). Google Scholar
[16]	Zhang Maosheng, Li Tonglu, Cheng Xiujuan, Sun Pingping, Li Qiang, Qiao Zhitian, Zhao Quanli. 2019. Evaluation of underground space resources in mountain cities and their development models-taking Yan’an city as an example[J]. Mountain Research, 37(3): 303−315 (in Chinese with English abstract). Google Scholar
[17]	Zhang Maosheng, Wang Huaqi, Wang Yao, Dong Ying, Sun Pingping. 2018. Progress and prospect of urban geological survey in China[J]. Northwestern Geology, 51(4): 1−8 (in Chinese with English abstract) Google Scholar
[18]	Zhang Shanshan, Zhang Maosheng, Sun Pingping, Dong Ying, Feng Li. 2019. Advances in and outlooks of preferential flow study in unsaturated soils[J]. Journal of Lanzhou University (Natural Science), 55(2): 274−280 (in Chinese with English abstract). Google Scholar
[19]	Zhao Pu, Jiang Jie, Wang Xiurong. 2017. Urban Underground Space Exploration Key Technologies and Development Trend[J]. Coal Geology of China, 29(9): 61−66 (in Chinese with English abstract). Google Scholar
[20]	Zhou Yuanxin, Zheng Guisen, He Jing, Li Chao, Liu Yu, He Hanhan, Xiao Jingze. 2019. Research on geological safety monitoring of urban underground space resource utilization in Beijing[J]. Geology in China, 46(3): 455−467 (in Chinese). Google Scholar