Parameters optimization of seismic data acquisition for deep buried karst geothermal reservoir in sedimentary basin: A case study of the Niutuo geothermal field in Xiongan New Area

LONG Hui; LI Shengtao; MU Jianqiang; LIU Donglin; YUE Dongdong; YAN Guoyu

doi:10.16030/j.cnki.issn.1000-3665.202301017

2023 Vol. 50, No. 4

Article Contents

Article navigation > Hydrogeology & Engineering Geology > 2023 > 50(4): 14-25

Next Article Previous Article

LONG Hui, LI Shengtao, MU Jianqiang, LIU Donglin, YUE Dongdong, YAN Guoyu. Parameters optimization of seismic data acquisition for deep buried karst geothermal reservoir in sedimentary basin: A case study of the Niutuo geothermal field in Xiongan New Area[J]. Hydrogeology & Engineering Geology, 2023, 50(4): 14-25. doi: 10.16030/j.cnki.issn.1000-3665.202301017

Citation:

LONG Hui, LI Shengtao, MU Jianqiang, LIU Donglin, YUE Dongdong, YAN Guoyu. Parameters optimization of seismic data acquisition for deep buried karst geothermal reservoir in sedimentary basin: A case study of the Niutuo geothermal field in Xiongan New Area[J]. Hydrogeology & Engineering Geology, 2023, 50(4): 14-25. doi: 10.16030/j.cnki.issn.1000-3665.202301017

Parameters optimization of seismic data acquisition for deep buried karst geothermal reservoir in sedimentary basin: A case study of the Niutuo geothermal field in Xiongan New Area

1.
Center for Hydrogeology and Environmental Geology Survey, China Geological Survey, Tianjin 300309, China
2.
Tianjin Engineering Center of Geothermal Resources Exploration and Development, Tianjin　300309, China
3.
Geological Exploration Academy of China Metallurgical Geology Bureau, Baoding, Hebei,　071052, China

More Information

Corresponding author: LI Shengtao, lishengtao@mail.cgs.gov.cn

Received Date: 11 January 2023

Revised Date: 04 May 2023

Publish Date: 15 July 2023

Abstract

Abstract

Deep heterogeneous carbonate reservoirs have become more and more important in the deep exploration of geothermal resources in China. The essential seismic exploration technology has many difficulties, such as serious attenuation of deep energy, low signal-to-noise ratio, difficult imaging of inner basement in tectonic uplift areas. In order to acquire high-quality deep seismic exploration data, a large number of vibroseis excitation parameters and geophone receiving parameters experiments have been received in a typical areas of the Central Hebei Plain in North China. On the basis of a large number of field experimental data, a qualitative analysis of the original single-shot records is carried out, and quantitative analysis is also carried out from the aspects of frequency band energy, inter-channel frequency, signal-to-noise ratio, etc., to study the parameter selection such as the number of vibroseis, sweep frequency, sweep length, vibration times, driving amplitude and geophone combination mode, which can affect the quality of the seismic data. In this paper, the field construction parameters for 2D seismic exploration of deep carbonate reservoirs in the North China Plain are optimized as follows: 4 sets of 28 tons vibrate 4–6 times, 75% driving amplitude, non-linear sweep (slope –3), 6–84 Hz sweep frequency, and 12 s sweep length. The quality of the single-shot records and data processing profiles are greatly improved after parameter optimization, which can be more clearly divided into the bottom interface of the Gaoyuzhuang Formation of the Jixian System and the top interface of the Archean Erathern in the Niutuozhen uplift tectonic area. The optimized seismic acquisition parameters are of certain reference and guiding significance for deep seismic exploration in sedimentary basins.
- sedimentary basin /
- deep buried karst geothermal reservoir /
- seismic exploration /
- data acquisition /
- parameters optimization

FullText(HTML)

References

[1]	杨海. 中国陆域居里面特征研究[D]. 成都: 成都理工大学, 2015 Google Scholar YANG Hai. Characteristics of Chinese continental Curie point isotherm[D]. Chengdu: Chengdu University of Technology, 2015. （in Chinese with English abstract） Google Scholar
[2]	康玉柱. 中国古生代碳酸盐岩古岩溶储集特征与油气分布[J]. 天然气工业,2008,28(6):1 − 12. [KANG Yuzhu. Characteristics and distribution laws of paleokarst hydrocarbon reservoirs in palaeozoic carbonate formations in China[J]. Natural Gas Industry,2008,28(6):1 − 12. (in Chinese with English abstract) Google Scholar KANG Yuzhu. Characteristics and distribution laws of paleokarst hydrocarbon reservoirs in palaeozoic carbonate formations in China[J]. Natural Gas Industry, 2008, 28（6）: 1-12. （in Chinese with English abstract） Google Scholar
[3]	姜光政,高堋,饶松,等. 中国大陆地区大地热流数据汇编(第四版)[J]. 地球物理学报,2016,59(8):2892 − 2910. [JIANG Guangzheng,GAO Peng,RAO Song,et al. Compilation of heat flow data in the continental area of China(4th edition)[J]. Chinese Journal of Geophysics,2016,59(8):2892 − 2910. (in Chinese with English abstract) Google Scholar JIANG Guangzheng, GAO Peng, RAO Song, et al. Compilation of heat flow data in the continental area of China（4th edition）[J]. Chinese Journal of Geophysics, 2016, 59（8）: 2892-2910. （in Chinese with English abstract） Google Scholar
[4]	庞宏磊. 车镇凹陷沙四上亚段低坡折带湖相碳酸盐岩地震识别及沉积特征[J]. 油气地球物理,2017,15(1):6 − 11. [PANG Honglei. Seismic identification and sedimentary features of lacustrine facies carbonate rock in low slope-breaks of the upper of ES4 in Chezhen Depression[J]. Petroleum Geophysics,2017,15(1):6 − 11. (in Chinese with English abstract) Google Scholar PANG Honglei. Seismic identification and sedimentary features of lacustrine facies carbonate rock in low slope-breaks of the upper of ES4 in Chezhen Depression[J]. Petroleum Geophysics, 2017, 15（1）: 6-11. （in Chinese with English abstract） Google Scholar
[5]	张薇,王贵玲,刘峰,等. 中国沉积盆地型地热资源特征[J]. 中国地质,2019,46(2):255 − 268. [ZHANG Wei,WANG Guiling,LIU Feng,et al. Characteristics of geothermal resources in sedimentary basins[J]. Geology in China,2019,46(2):255 − 268. (in Chinese with English abstract) Google Scholar ZHANG Wei, WANG Guiling, LIU Feng, et al. Characteristics of geothermal resources in sedimentary basins[J]. Geology in China, 2019, 46（2）: 255-268. （in Chinese with English abstract） Google Scholar
[6]	张军林,田世澄. 缝洞型碳酸盐岩储层反射波法地震勘探技术的现状与趋势[J]. 石油天然气学报,2013,35(12):62 − 66. [ZHANG Junlin,TIAN Shicheng. Current situation and trend of seismic exploration technique of reflection wave method of fracturevuggy carbonatite reservoirs[J]. Journal of Oil and Gas Technology,2013,35(12):62 − 66. (in Chinese with English abstract) Google Scholar ZHANG Junlin, TIAN Shicheng. Current situation and trend of seismic exploration technique of reflection wave method of fracturevuggy carbonatite reservoirs[J]. Journal of Oil and Gas Technology, 2013, 35（12）: 62-66. （in Chinese with English abstract） Google Scholar
[7]	柴绪兵. 古城地区中下奥陶统碳酸盐岩储层地震预测技术研究[D]. 大庆: 东北石油大学, 2017 Google Scholar CHAI Xubing. Study on seismic prediction technology of carbonate reservoir in Gucheng area[D]. Daqing: Northeast Petroleum University, 2017. （in Chinese with English abstract） Google Scholar
[8]	黄锐. 川东北碳酸盐岩地区地震勘探技术难点与对策[J]. 石油物探,2008,47(5):476 − 482. [HUANG Rui. Technical difficulties in and countermeasures for seismic exploration in the carbonate area of northeast Sichuan Basin[J]. Geophysical Prospecting for Petroleum,2008,47(5):476 − 482. (in Chinese with English abstract) Google Scholar HUANG Rui. Technical difficulties in and countermeasures for seismic exploration in the carbonate area of northeast Sichuan Basin[J]. Geophysical Prospecting for Petroleum, 2008, 47（5）: 476-482. （in Chinese with English abstract） Google Scholar
[9]	李博. ZG15区块奥陶系碳酸盐岩地震资料精细解释[J]. 甘肃科技,2018,34(10):16 − 17. [LI Bo. Seismic data interpretation of Ordovician carbonate rocks in ZG15 block[J]. Gansu Science and Technology,2018,34(10):16 − 17. (in Chinese) Google Scholar LI Bo. Seismic data interpretation of Ordovician carbonate rocks in ZG15 block[J]. Gansu Science and Technology, 2018, 34（10）: 16-17. （in Chinese） Google Scholar
[10]	李鹏飞, 崔德育, 黄诚. 地震资料处理解释一体化技术在塔北碳酸盐岩储层识别中的应用[J]. 石油地球物理勘探, 2018, 53（增刊2）: 306 – 313 Google Scholar LI Pengfei, CUI Deyu, HUANG Cheng. Carbonate reservoir identification in Tabei Area, Tarim Basin with integrated seismic data processing and interpretation[J]. Oil Geophysical Prospecting, 2018, 53（Sup 2）: 306 – 313. （in Chinese with English abstract） Google Scholar
[11]	常少英,李昌,陈娅娜,等. 海相碳酸盐岩储层地震预测技术进展及应用实效[J]. 海相油气地质,2020,25(1):22 − 34. [CHANG Shaoying,LI Chang,CHEN Yana,et al. Progress and application of seismic prediction technology for marine carbonate reservoir[J]. Marine Origin Petroleum Geology,2020,25(1):22 − 34. (in Chinese with English abstract) Google Scholar CHANG Shaoying, LI Chang, CHEN Yana, et al. Progress and application of seismic prediction technology for marine carbonate reservoir[J]. Marine Origin Petroleum Geology, 2020, 25（1）: 22-34. （in Chinese with English abstract） Google Scholar
[12]	杜伟. K1地区地震数据目标处理技术及效果[J]. 石油地质与工程,2018,32(2):43 − 46. [DU Wei. Seismic data processing technology and its effect in K1 area[J]. Petroleum Geology and Engineering,2018,32(2):43 − 46. (in Chinese with English abstract) Google Scholar DU Wei. Seismic data processing technology and its effect in K1 area[J]. Petroleum Geology and Engineering, 2018, 32（2）: 43-46. （in Chinese with English abstract） Google Scholar
[13]	龙姣. FG地区二维地震资料采集技术研究[D]. 成都: 成都理工大学, 2017 Google Scholar LONG Jiao. Research on 2D seismic acquisition technology in FG area[D]. Chengdu: Chengdu University of Technology, 2017. （in Chinese with English abstract） Google Scholar
[14]	高俊,李燕燕,王贵玲,等. 雄安新区高阳地热田蓟县系热储特征及资源量评估[J]. 地球学报,2023,44(1):133 − 144. [GAO Jun,LI Yanyan,WANG Guiling,et al. Geothermal reservoirs characteristics and resource assessment of Jixian system in Gaoyang geothermal field,Xiongan New Area[J]. Acta Geoscientica Sinica,2023,44(1):133 − 144. (in Chinese with English abstract) Google Scholar GAO Jun, LI Yanyan, WANG Guiling, et al. Geothermal reservoirs characteristics and resource assessment of Jixian system in Gaoyang geothermal field, Xiongan New Area[J]. Acta Geoscientica Sinica, 2023, 44（1）: 133-144. （in Chinese with English abstract） Google Scholar
[15]	姚亚辉, 贾小丰, 李胜涛, 等. 雄安新区D01井岩溶热储下伏太古界中热流测定研究[J]. 中国地质, 2022, 49（6）: 1723 – 1731. Google Scholar YAO Yahui, JIA Xiaofeng, LI Shengtao, et al. Heat flow determination of Archean strata under the karst thermal reservoir of D01 well in Xiongan New Area[J]. Geology in China, 2022, 49（6）: 1723 – 1731.（in Chinese with English abstract） Google Scholar
[16]	邢一飞, 王慧群, 李捷, 等. 雄安新区地热水的化学场特征及影响因素分析[J]. 中国地质, 2022, 49（6）: 1711 – 1722. Google Scholar XING Yifei, WANG Huiqun, LI Jie, et al. Chemical field of geothermal water in Xiongan New Area and analysis of influencing factors[J]. Geology in China, 2022, 49（6）: 1711 – 1722.（in Chinese with English abstract） Google Scholar
[17]	杨海盟,戴俊生,汪必峰,等. 牛驼镇凸起发育过程[J]. 东北石油大学学报,2014,38(6):22 − 29. [YANG Haimeng,DAI Junsheng,WANG Bifeng,et al. Development process of Niutuozhen uplift[J]. Journal of Northeast Petroleum University,2014,38(6):22 − 29. (in Chinese with English abstract) Google Scholar YANG Haimeng, DAI Junsheng, WANG Bifeng, et al. Development process of Niutuozhen uplift[J]. Journal of Northeast Petroleum University, 2014, 38（6）: 22-29. （in Chinese with English abstract） Google Scholar
[18]	王凯,张杰,白大为,等. 雄安新区地热地质模型探究:来自地球物理的证据[J]. 中国地质,2021,48(5):1453 − 1468. [WANG Kai,ZHANG Jie,BAI Dawei,et al. Geothermal-geological model of Xiongan New Area:Evidence from geophysics[J]. Geology in China,2021,48(5):1453 − 1468. (in Chinese with English abstract) Google Scholar WANG Kai, ZHANG Jie, BAI Dawei, et al. Geothermal-geological model of Xiongan New Area: Evidence from geophysics[J]. Geology in China, 2021, 48（5）: 1453-1468. （in Chinese with English abstract） Google Scholar
[19]	岳航羽,王凯,张杰,等. 雄安新区及周边深反射地震高精度成像技术[J]. 石油地球物理勘探,2022,57(4):855 − 869. [YUE Hangyu,WANG Kai,ZHANG Jie,et al. High-precision imaging technology of deep reflection seismic in Xiongan New Area and its surroundings[J]. Oil Geophysical Prospecting,2022,57(4):855 − 869. (in Chinese with English abstract) Google Scholar YUE Hangyu, WANG Kai, ZHANG Jie, et al. High-precision imaging technology of deep reflection seismic in Xiongan New Area and its surroundings[J]. Oil Geophysical Prospecting, 2022, 57（4）: 855-869. （in Chinese with English abstract） Google Scholar
[20]	陈鹏,于常青,韩建光,等. 低频可控震源在哈拉湖冻土区二维地震勘探试验研究[J]. 地球物理学进展,2018,33(2):562 − 570. [CHEN Peng,YU Changqing,HAN Jianguang,et al. Low-frequency vibroseis experimental study of 2D seismic exploration for Hala Lake’s permafrost region[J]. Progress in Geophysics,2018,33(2):562 − 570. (in Chinese with English abstract) Google Scholar CHEN Peng, YU Changqing, HAN Jianguang, et al. Low-frequency vibroseis experimental study of 2D seismic exploration for Hala Lake’s permafrost region[J]. Progress in Geophysics, 2018, 33（2）: 562-570. （in Chinese with English abstract） Google Scholar
[21]	陈玉达,林君,邢雪峰. 可控震源技术发展与应用[J]. 石油物探,2020,59(5):666 − 682. [CHEN Yuda,LIN Jun,XING Xuefeng. Development and application of vibroseis technology[J]. Geophysical Prospecting for Petroleum,2020,59(5):666 − 682. (in Chinese with English abstract) Google Scholar CHEN Yuda, LIN Jun, XING Xuefeng. Development and application of vibroseis technology[J]. Geophysical Prospecting for Petroleum, 2020, 59（5）: 666-682. （in Chinese with English abstract） Google Scholar
[22]	邸志欣. 哈拉阿拉特山山前构造带三维地震采集技术研究[D]. 青岛: 中国海洋大学, 2013 Google Scholar DI Zhixin. 3D seismic acquisition technology research for piedmont tectonic belt in Halaalate mountain[D]. Qingdao: Ocean University of China, 2013. （in Chinese with English abstract） Google Scholar
[23]	蓝加达. 可控震源非线性扫描在高分辨率地震采集中的应用[J]. 石油物探,2008,47(2):208 − 211. [LAN Jiada. Application of vibroseis nonlinear sweep in high resolution seismic data acquisition in S area[J]. Geophysical Prospecting for Petroleum,2008,47(2):208 − 211. (in Chinese with English abstract) Google Scholar LAN Jiada. Application of vibroseis nonlinear sweep in high resolution seismic data acquisition in S area, [J]. Geophysical Prospecting for Petroleum, 2008, 47（2）: 208-211. （in Chinese with English abstract） Google Scholar
[24]	吴华,张保卫,王凯,等. 哈拉湖地区浅层地震勘探可控震源激发参数对比试验[J]. 物探与化探,2018,42(5):1033 − 1041. [WU Hua,ZHANG Baowei,WANG Kai,et al. Comparative test of vibroseis excitation parameters for shallow seismic exploration in Har Hu area[J]. Geophysical and Geochemical Exploration,2018,42(5):1033 − 1041. (in Chinese with English abstract) Google Scholar WU Hua, ZHANG Baowei, WANG Kai, et al. Comparative test of vibroseis excitation parameters for shallow seismic exploration in Har Hu area[J]. Geophysical and Geochemical Exploration, 2018, 42（5）: 1033-1041. （in Chinese with English abstract） Google Scholar
[25]	孙海川. 可控震源地震采集技术在H探区煤炭勘查中的实验[J]. 物探与化探,2020,44(1):42 − 49. [SUN Haichuan. Experimental study of vibroseis seismic acquisition technology on coal exploration in H prospecting area[J]. Geophysical and Geochemical Exploration,2020,44(1):42 − 49. (in Chinese with English abstract) Google Scholar SUN Haichuan. Experimental study of vibroseis seismic acquisition technology on coal exploration in H prospecting area[J]. Geophysical and Geochemical Exploration, 2020, 44（1）: 42-49. （in Chinese with English abstract） Google Scholar
[26]	李忠雄,卫红伟,马龙,等. 羌塘盆地可控震源采集试验分析[J]. 石油地球物理勘探,2017,52(2):199 − 208. [LI Zhongxiong,WEI Hongwei,MA Long,et al. Vibroseis acquisition tests in Qiangtang Basin[J]. Oil Geophysical Prospecting,2017,52(2):199 − 208. (in Chinese with English abstract) Google Scholar LI Zhongxiong, WEI Hongwei, MA Long, et al. Vibroseis acquisition tests in Qiangtang Basin[J]. Oil Geophysical Prospecting, 2017, 52（2）: 199-208. （in Chinese with English abstract） Google Scholar
[27]	刘小峰,槐永军,刘会林,等. 根据工区地表条件确定合适的可控震源驱动幅度[J]. 物探装备,2018,28(6):399 − 403. [LIU Xiaofeng,HUAI Yongjun,LIU Huilin,et al. How to determine the appropriate driving level of vibroseis according to the surface conditions of the work area[J]. Equipment for Geophysical Prospecting,2018,28(6):399 − 403. (in Chinese with English abstract) Google Scholar LIU Xiaofeng, HUAI Yongjun, LIU Huilin, et al. How to determine the appropriate driving level of vibroseis according to the surface conditions of the work area[J]. Equipment for Geophysical Prospecting, 2018, 28（6）: 399-403. （in Chinese with English abstract） Google Scholar