APPLICATION OF BOTH CSAMT AND CYT ELECTROMAGNETIC METHOD TO DETECTION OF DEEP SALT CAVES

WANG Zhirong; WANG Quangeng; ZHANG Limin

doi:10.13544/j.cnki.jeg.2016.01.018

Volume 24 Issue 1

Feb. 2016

Turn off MathJax

Article Contents

Article Navigation > JOURNAL OF ENGINEERING GEOLOGY > 2016 > 24(1): 142-149

WANG Zhirong, WANG Quangeng, ZHANG Limin. 2016: APPLICATION OF BOTH CSAMT AND CYT ELECTROMAGNETIC METHOD TO DETECTION OF DEEP SALT CAVES. JOURNAL OF ENGINEERING GEOLOGY, 24(1): 142-149. doi: 10.13544/j.cnki.jeg.2016.01.018

Citation:

WANG Zhirong, WANG Quangeng, ZHANG Limin. 2016: APPLICATION OF BOTH CSAMT AND CYT ELECTROMAGNETIC METHOD TO DETECTION OF DEEP SALT CAVES. JOURNAL OF ENGINEERING GEOLOGY, 24(1): 142-149. doi: 10.13544/j.cnki.jeg.2016.01.018

Citation:

PDF( 4396 KB)

APPLICATION OF BOTH CSAMT AND CYT ELECTROMAGNETIC METHOD TO DETECTION OF DEEP SALT CAVES

doi: 10.13544/j.cnki.jeg.2016.01.018

1.
School of Water Conservancy and Environment Engineering, Zhengzhou University, Zhengzhou 450001;
2.
Investigation Center of Resource and Environment of Henan Bureau of Coal Geology, Zhengzhou 450053

Received Date: 2014-11-26
Rev Recd Date: 2015-09-01
Publish Date: 2016-02-25

Abstract

Abstract

This paper is based on the particularity in exploration of deep salt caves. The theoretical foundation, detection principle and interpretation methods of earth electric field lithology detection(CYT) and Controlled source audio magnetic telluric(CSAMT) are discussed using the Yexian salt field gas storage project in Pingdignshan. The geometry, space distribution and feedback physical information of salt caves are studied as well. Firstly, the spatial range of target body is confirme-droughly with CSAMT method. Then the spatial form is determined in detail with CYT method on the basis of CSAMT results in favorable area. Exploration results show that the spatial form of salt cave is complex. The irregular holes appear on the geological section with depth of-1000～-1400m. But the single cavern is small and the radius is about 8～60m. The research results can be used to guide the site selection and construction of underground salt cavern gas storage, and provide some reference for deep salt caves detection and interpretation of lithology electric fields.
- Pingdingshan salt field,
- CYT and CSAMT detection,
- Salt rock cavity detection,
- Application example

FullText(HTML)

References(1)

References

Ban F S,Xiao L Z,Yuan G G,et al. 2012. Preparation of large size salt rock solution mining model and its application[J]. Natural Gas Geoscience, 23 (4): 804～806.

Chen W Z,Tan X J,Wu G J,et al. 2009. Research on gas seepage law in laminated salt rock gas storage[J]. Chinese Journal of Rock Mechanics and Engineering, 28 (7): 1297～1304.

Chen Z P,Chen D J,Zhang Z X,et al. 2010. Application of high frequency magnetotelluric method in Chimushan tunnels[J]. Chinese Journal of Underground Space and Engineering, 6 (S2): 1726～1730.

Deng J Z,Mo H,Liu Q C. 2001. The application of ground-penetrating radar to karst detection[J]. Geophysical and Geochemical Exploration, 25 (6): 474～476.

Ding G S,Ran L N,Dong Y. 2010. Feasibility of Pingdingshan salt cavern gas storage for the 2nd west-east gas pipeline[J]. Oil & Gas Storage and Transportation, 29 (4): 255～257.

Ge C P,Kang Z Q,Lai S Q,et al. 2007. The utilization of controlled source audio-frequency magnetotellurics in hydro-geological investigating of complex karst mine——A case in Makeng iron mine, Fujian province[J]. China Water Transport, 7 (10): 82～84.

Huang L J,Meng Y S,Lu G F. 2007a. An application of CSAMT sounding to exploration of deep geothermal resources[J]. Computing Techniques for Geophysical and Geochemical exploration,(S1): 60～63.

Huang L J,Zhang W,Liu R D. 2007b. Function of geological routing about CSAMT exploration in prospecting for concealed metallic ore deposits[J]. Computing Techniques for Geophysical and Geochemical exploration,(S1): 55～59.

Li J,Deng H K,Zhang J D,et al. 2009. Application of geological routing about CSAMT exploration in Gaoligong Mountain tunnel of Dali-Ruili Railway[J]. Hydrogeology & Engineering Geology,(2): 72～76.

Li J P,Li T L,Zhang H,et al. 2005. Study and application of the TEM forward and inversion problem of irregular loop source over the layered medium[J]. Journal of Jilin University(Earth Science Edition), 35 (6): 790～795.

Li S C,Xue Y G,Zhang Q S,et al. 2008. Key technology study on comprehensive prediction and early-warning of geological hazards during tunnel construction in high-risk karst areas[J]. Chinese Journal of Rock Mechanics and Engineering, 27 (7): 1297～1307.

Li T B,Meng L B,Zhu J,et al. 2009. Comprehensive analysis method for advanced forecast of geology in tunnels[J]. Chinese Journal of Rock Mechanics and Engineering, 28 (12): 2429～2436.

Song G Y,Liu G Z. 2009. Application of CSAMT in tunnel exploration [J]. Coal Technology, 28 (9): 147～148.

Wang Z R,Li Y K,Zhang L M,et al. 2015. Analysis of the feasibility and engineering geology condition of underground gas storage in thin salt rock[J]. Journal of Engineering Geology, 23 (1): 148～154.

Xi B P,Zhao Y S,Zhao Y L,et al. 2008. Investigation on rheodestruction and permeability of surrounding rock for long-term running storage cavern in bedded rock salt[J]. Rock and Soil Mechanics, 29 (S1): 241～246.

Xue G Q,Li X. 2008a. The technology of TEM tunnel prediction imaging[J]. Chinese Journal of Geophysics, 51 (3): 894～900.

Xue G Q,LI X,Di Q Y. 2008b. Research progress in TEM forward modeling and inversioncal culation[J]. Progress in Geophysics, 23 (4): 1165～1172.

Yang Q J,Wang Z X. 1999. Probing into the principle and the technology of electrotelluric lithology sound[J]. Progress in Geophysics, 14 (3): 79～88.

Zhao Z C,Zhu W Y,Shan W W,et al. 2004. Mathematical model of chamber building with water solution for gas storages in salt beds[J]. Natural Gas Industry, 24 (9): 126～129.

班凡生,肖立志,袁光杰,等. 2012. 大尺寸盐岩溶腔模型制备研究及应用[J]. 天然气地球科学, 23 (4): 804～806.

陈卫忠,谭贤君,伍国军,等. 2009. 含夹层盐岩储气库气体渗透规律研究[J]. 岩石力学与工程学报, 28 (7): 1297～1304.

陈志平,陈德玖,张照秀,等. 2010. 高频大地电磁法在慈母山隧道勘察中的应用[J]. 地下空间与工程学报, 6 (增2):1726～1730.

邓居智,莫撼,刘庆成. 2001. 探地雷达在岩溶探测中的应用[J]. 物探与化探, 25 (6): 474～476.

丁国生,冉莉娜,董颖. 2010. 西气东输二线平顶山盐穴储气库建设可行性[J]. 油气储运, 29 (4): 255～257.

葛纯朴,康志强,赖树钦,等. 2007. 可控源音频大地电磁法(CSAMT)在复杂岩溶矿山水文地质勘探中的应用——以福建马坑铁矿为例[J]. 中国水运, 7 (10): 82～84.

黄力军,孟银生,陆桂福. 2007a. 可控源音频大地电磁测深在深部地热资源勘查中的应用[J]. 物探化探计算技术,(增1): 60～63.

黄力军,张威,刘瑞德. 2007b. 可控源音频大地电磁测深法寻找隐伏金属矿的作用[J]. 物探化探计算技术,(增刊): 55～59.

李坚,邓宏科,张家德,等. 2009. 可控源音频大地电磁勘探在大瑞铁路高黎贡山隧道地质选线中的应用[J]. 水文地质工程地质,(2): 72～76.

李建平,李桐林,张辉,等. 2005. 不规则回线源层状介质瞬变电磁场正反演研究及应用[J]. 吉林大学学报(地球科学版), 35 (6): 790～795.

李术才,薛翊国,张庆松,等. 2008. 高风险岩溶地区隧道施工地质灾害综合预报预警关键技术研究[J]. 岩石力学与工程学报, 27 (7): 1297～1307.

李天斌,孟陆波,朱劲,等. 2009. 隧道超前地质预报综合分析方法[J]. 岩石力学与工程学报, 28 (12): 2429～2436.

宋国阳,刘国争. 2009. 可控源音频大地电磁法在工程隧道勘查中的应用[J]. 煤炭技术, 29 (9): 147～148.

王志荣,李亚坤,张利民,等. 2015. 薄层状盐岩地下储气库工程地质条件及可行性分析[J]. 工程地质学报, 23 (1): 148～154.

郤宝平,赵阳升,赵延林,等. 2008. 层状盐岩储库长期运行腔体围岩流变破坏及渗透现象研究[J]. 岩土力学, 29 (增1): 241～246.

薛国强,李貅.2008a.瞬变电磁隧道超前预报成像技术[J]. 地球物理学报, 51 (3): 894～900.

薛国强,李貅,底青云.2008b.瞬变电磁法正反演问题研究进展[J]. 地球物理学进展, 23 (4): 1165～1172.

杨庆锦,王招香. 1999. 大地电场岩性测深原理及方法技术的探讨[J]. 地球物理学进展, 14 (3): 79～88.

赵志成,朱维耀,单文文,等. 2004. 盐岩储气库水溶建腔数学模型研究[J]. 天然气工业, 24 (9): 126～129.

Relative Articles

Supplements(0)

Cited By

Proportional views