Hydraulic Fracturing-induced Seismicity at the Hot Dry Rock Site of the Gonghe Basin in China附视频

被引：0

作者：

CHEN Zubin ^{[1
,2
]}

ZHAO Fa ^{[1
,2
]}

SUN Feng ^{[1
,2
]}

L Hao ^{[1
,2
]}

WANG Chunlu ^{[1
,2
]}

WU Haidong ^{[3
]}

ZHOU Xiaohua ^{[1
,2
]}

机构：

[1] College of Instrumentation & Electrical Engineering, Jilin University

[2] Key Lab of Geo-Exploration Instrumentation of the Ministry of Education, Jilin University

[3] Center for Hydrogeology and Environmental Geology,China Geological

来源：

Acta Geologica Sinica(English Edition) | 2021年 / 06期

关键词：

D O I：

暂无

中图分类号：

P314 [地热学]; P315.9 [工程地震];

学科分类号：

摘要：

Hot dry rock is becoming an important clean energy source. Enhanced geothermal systems(EGS) hold great promise for the potential to make a contribution to the energy inventory. However, one controversial issue associated with EGS is the impact of induced seismicity. In August 2019, a hydraulic stimulation experiment took place at the hot dry rock site of the Gonghe Basin in Qinghai, China. Earthquakes of different magnitudes of 2 or less occurred during the hydraulic stimulation. Correlations between hydraulic stimulation and seismic risk are still under discussion. Here, we analyze the hydraulic stimulation test and microseismic activity. We quantify the evolution of several parameters to explore the correlations between hydraulic stimulation and induced seismicity, including hydraulic parameters, microseismic events, bvalue and statistical forecasting of event magnitudes. The results show that large-magnitude microseismic events have an upward trend with an increase of the total fluid volume. The variation of the b-value with time indicates that the stimulation experiment induces small amounts of seismicity. Forecasted magnitudes of events can guide operational decisions with respect to induced seismicity during hydraulic fracturing operations, thus providing the basis for risk assessment of hot dry rock exploitation.

引用

页码：1835 / 1843

页数：9

共 26 条

[1] 青海共和及周边地区的地壳三维速度结构
罗仁昱
陈继锋
尹欣欣
李少华
[J]. 地震地质, 2021, 43 (01) : 232 - 248
[2] 青海共和盆地地热资源热源机制与聚热模式
唐显春
王贵玲
马岩
张代磊
刘忠
赵旭
程天君
[J]. 地质学报, 2020, 94 (07) : 2052 - 2065
[3] Holocene Moisture Variation Recorded by Aeolian Sand-Palaeosol Sequences of the Gonghe Basin; Northeastern Qinghai-Tibetan Plateau; China[J] LIU Bing;ZHAO Hui;JIN Heling;CHEN Fahu; Acta Geologica Sinica(English Edition) 2020, 03
[4] Velocity calibration for microseismic event location using surface data[J] Hai-Yu Jiang;Zu-Bin Chen;Xiao-Xian Zeng;Hao Lv;Xin Liu; Petroleum Science 2016, 02
[5] CO2化学刺激剂对增强地热系统热储层的改造作用
那金
冯波
兰乘宇
许天福
鲍新华
[J]. 中南大学学报(自然科学版), 2014, 45 (07) : 2447 - 2458
[6] A 3D thermo-hydro-mechanical coupling model for enhanced geothermal systems[J] Cui Xin;Wong Louis Ngai Yuen International Journal of Rock Mechanics and Mining Sciences 2021,
[7] Production capacity and mining plan optimization of fault/fracture‐controlled EGS model in Gonghe Basin[J] Jie Zhang;Jingxuan Xie;Han Zhang Energy Science & Engineering 2019,
[8] Real‐Time Imaging; Forecasting; and Management of Human‐Induced Seismicity at Preston New Road; Lancashire; England[J] Huw Clarke;James P. Verdon;Tom Kettlety;Alan F. Baird;J‐Michael Kendall Seismological Research Letters 2019,
[9] Managing injection-induced seismic risks.[J] Lee KangKun;Ellsworth William L;Giardini Domenico;Townend John;Ge Shemin;Shimamoto Toshihiko;Yeo InWook;Kang TaeSeob;Rhie Junkee;Sheen DongHoon;Chang Chandong;Woo JeongUng;Langenbruch Cornelius Science (New York; N.Y.) 2019,
[10] Induced seismicity at the UK ‘hot dry rock’ test site for geothermal energy production[J] Xun Li;Ian Main;Andrew Jupe Geophysical Journal International 2018,

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