Araştırma Makalesi
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KAMBRİYEN KİREÇTAŞININ KARSTLAŞMA SÜRECİNİN FARKLI ARAŞTIRMA TEKNOLOJİLERİ İLE ANALİZİ

Yıl 2021, , 115 - 123, 01.06.2021
https://doi.org/10.30797/madencilik.950069

Öz

Kaynakça

  • Dai, G.L. 2010. The effect of geology structure on hydrogeology characteristics of Hancheng mining area. Journal of Arid Land Resources and Environment. vol. 24, no. 7, pp. 62-67.
  • Dai, Q.H., Peng, X.D., Yang, Z., Zhao, L.S. 2017. Runoff and erosion processes on bare slopes in the Karst Rocky Desertification Area. Catena. vol. 152, pp. 218-226.
  • Dong, S.N. 2010. Some key scientific problems on water hazards frequently happened in China’s coal mines. Journal of China Coal Society. vol. 35, no. 1, pp. 66-71.
  • Hao, B.Y., Guo, Y.H., Wang, F., Zhang, H. 2013. Study on development features and major control factors of Ordovician limestone karst in Gujiao mining area. Coal Science and Technology. vol. 41, no. 2, pp. 91-95.
  • Hu. W.Y., Zheng, G., Yan, L.Y. 2010. Study on detecting deep karst developing features by chemical tracing. Carsologica Sinica. vol. 29, no. 2, pp.205-211.
  • Kovács A, Perrochet P, Darabos E, et al. 2017. Well hydrograph analysis for the characterisation of flow dynamics and conduit network geometry in a karst aquifer, Bükk Mountains, Hungary. Journal of Hydrology. vol. 530, no. 2, pp.484-499.
  • Lipar, M., Webb, J A. 2015. The formation of the pinnacle karst in Pleistocene aeolian calcarenites (Tamala Limestone) in southwestern Australia. Earth-Science Reviews. vol. 42, no.4, pp.182-202.
  • Liu, B., Liu, Z.Y., Li, S.C., Nie, L.C., Su, M.X., Sun, H.F., Fan, K.R., Zhang, X.X., Pang, Y.H. 2017. Comprehensive surface geophysical investigation of karst caves ahead of the tunnel face: A case study in the Xiaoheyan section of the Water Supply Project from Songhua River, Jilin, China. Journal of Applied Geophysics. vol. 144, pp.37-39.
  • Qiao, W., Li, W.P., Zhang, X. 2014. Characteristic of water chemistry and hydrodynamics of deep karst and its influence on deep coal mining. Arabian Journal of Geosciences. vol. 7, no. 4, pp. 1261- 1275.
  • Soulsby, C., Bradford, J, Dick, J, McNamara, J. P., Geris, J., Lessels, J., Blumstock, M., Tetzlaff, D. 2016. Using geophysical surveys to test tracer-based storage estimates in headwater catchments. Hydrological Processes. vol. 30, no.23, pp. 4434-4445.
  • Sun, L.L., Wang, Z.H., Wang, H.J., Wang, Y.H., Sun, Y.Q. 2013. Detection research on water abundance of floor aquifers. Mining Safety & Environmental Protection. vol. 40, no.1, pp.61-64.
  • Wang, Q., Wang, X.Y., Hou, Q.L. 2016a. Geothermal water at a coal mine: from risk to resource. Mine Water and the Environment. vol. 35, no. 3, pp. 294-301.
  • Wang, Q., Wang, X.Y., Liu, X.M., Zhen, X.G., Chen, G.S., Zhang, B. 2018. Prevention of groundwater disasters in coal seam floors based on TEM of cambrian limestone. Mine Water & the Environment. vol. 7, no. 2, pp. 300-311.
  • Wang, W.J. 2015. Research on water control effect of Xiatuanbai fault. Mining Safety & Environmental Protection. vol. 42, no.4, pp. 72- 75.
  • Wang, X.Y., Ji, H.Y., Wang, Q., Liu, X.M., Huang, D., Yao, X.P., Chen, G.S. 2016b. Divisions based on groundwater chemical characteristics and discrimination of water inrush sources in the Pingdingshan coalfield. Environmental Earth Sciences. vol. 75, no. 10, pp. 1 -11.
  • Wang, X.Y., Zhao, W, Liu, X.M., Wang, T.T., Zhang, J.G., Guo, J.W., Cheng, G.S., Zhang, B. 2017. Identification of water inrush source from coalfield based on entropy weight-fuzzy variable set theory. Journal of China Coal Society, vol. 42, no. 9, pp. 2433-2439.
  • Wu, Q., Jia, X, Cao, D.T., Liang, Y.P. 2014. Impermeability evaluation method and its application on the ancient weathering crust of carbonatite in Middle Ordovician system in North China coalfield. Journal of China Coal Society. vol. 39, no. 8, pp. 1735-1741.
  • Wu, Q., Zhang, B., Zhao, W.D., Liu, S.Q. 2013. A new practical methodology of coal seam floor water burst evaluation: the comparison study among ANN, the weight of evidence and the logistic regression vulnerable index method based on GIS. Journal of China Coal Society. vol. 38, no. 1, pp. 21-26.
  • Yang, B.B., Yuan, J.H, Duan, L.H. 2018. Development of a system to assess vulnerability of flooding from water in karst aquifers induced by mining. Environmental Earth Sciences. vol. 77, no. 3, pp. 91
  • Yu, X.l., Xu, G.q. 2013. Connected experiment study on explore hydraulic connection between limestones in Panbei mine. Coal Science and Technology. vol. 41, no.10, pp. 105-107.
  • Zhao, L.J., Xia, R.Y., Yi, L.X., Yang, Y., Wang, Z., Liu, H.P. 2016. Quantitative analysis of the source and the effect of turbidity in karst river on tracer test. Acta Geoscientia Sinica. vol. 37, no.2, pp. 241-246.
  • Zhao, Q.B. 2014. Ordovician limestone karst water disaster regional advanced governance technology study and application. Journal of China Coal Society. vol. 39, no.6, pp. 1112-1117.
  • Zhou, C.X., Jiang, J.J., Dong, S.B., Yan, S.X., Chen, Y.M., Song, Y.X., Bian, J.M. 2011. Groundwater tracer test in Sanguikou Ore District, Wulate Houqi,Inner Mongolia. Journal of Jilin University (Earth Science Edition). vol. 41, pp. 285-292.

ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE

Yıl 2021, , 115 - 123, 01.06.2021
https://doi.org/10.30797/madencilik.950069

Öz

Coal mine floor limestone aquifers are a major source of water inrush from the coal seam floor and a serious threat to the safety of coal mining. In order to
reduce and avoid the occurrence of water inrush within the coal mine, we use multiple detection techniques, which are geophysical exploration technology,
drilling technology, water inrush accidents and tracer test, to develop a multi-faceted exploration of karst development and analyze its development
characteristics in the Chaochuan mine No. 1 well. The results show that, the Cambrian limestone (CL) karst water is poor; there is a certain hydraulic
connection. Near faults F5, F1, F125, and SF28, the area is less water-rich area, and the deep karst water forms a closed area; 61.54 % of shallow water inrush
accidents in the Taiyuan limestone and CL karsts were caused by large tectonic and nearby shallow faults. The karst vertical zonation is shallow; the shallow
water level decreased more in the West Wing of the No. 1 well than in the East Wing.

Kaynakça

  • Dai, G.L. 2010. The effect of geology structure on hydrogeology characteristics of Hancheng mining area. Journal of Arid Land Resources and Environment. vol. 24, no. 7, pp. 62-67.
  • Dai, Q.H., Peng, X.D., Yang, Z., Zhao, L.S. 2017. Runoff and erosion processes on bare slopes in the Karst Rocky Desertification Area. Catena. vol. 152, pp. 218-226.
  • Dong, S.N. 2010. Some key scientific problems on water hazards frequently happened in China’s coal mines. Journal of China Coal Society. vol. 35, no. 1, pp. 66-71.
  • Hao, B.Y., Guo, Y.H., Wang, F., Zhang, H. 2013. Study on development features and major control factors of Ordovician limestone karst in Gujiao mining area. Coal Science and Technology. vol. 41, no. 2, pp. 91-95.
  • Hu. W.Y., Zheng, G., Yan, L.Y. 2010. Study on detecting deep karst developing features by chemical tracing. Carsologica Sinica. vol. 29, no. 2, pp.205-211.
  • Kovács A, Perrochet P, Darabos E, et al. 2017. Well hydrograph analysis for the characterisation of flow dynamics and conduit network geometry in a karst aquifer, Bükk Mountains, Hungary. Journal of Hydrology. vol. 530, no. 2, pp.484-499.
  • Lipar, M., Webb, J A. 2015. The formation of the pinnacle karst in Pleistocene aeolian calcarenites (Tamala Limestone) in southwestern Australia. Earth-Science Reviews. vol. 42, no.4, pp.182-202.
  • Liu, B., Liu, Z.Y., Li, S.C., Nie, L.C., Su, M.X., Sun, H.F., Fan, K.R., Zhang, X.X., Pang, Y.H. 2017. Comprehensive surface geophysical investigation of karst caves ahead of the tunnel face: A case study in the Xiaoheyan section of the Water Supply Project from Songhua River, Jilin, China. Journal of Applied Geophysics. vol. 144, pp.37-39.
  • Qiao, W., Li, W.P., Zhang, X. 2014. Characteristic of water chemistry and hydrodynamics of deep karst and its influence on deep coal mining. Arabian Journal of Geosciences. vol. 7, no. 4, pp. 1261- 1275.
  • Soulsby, C., Bradford, J, Dick, J, McNamara, J. P., Geris, J., Lessels, J., Blumstock, M., Tetzlaff, D. 2016. Using geophysical surveys to test tracer-based storage estimates in headwater catchments. Hydrological Processes. vol. 30, no.23, pp. 4434-4445.
  • Sun, L.L., Wang, Z.H., Wang, H.J., Wang, Y.H., Sun, Y.Q. 2013. Detection research on water abundance of floor aquifers. Mining Safety & Environmental Protection. vol. 40, no.1, pp.61-64.
  • Wang, Q., Wang, X.Y., Hou, Q.L. 2016a. Geothermal water at a coal mine: from risk to resource. Mine Water and the Environment. vol. 35, no. 3, pp. 294-301.
  • Wang, Q., Wang, X.Y., Liu, X.M., Zhen, X.G., Chen, G.S., Zhang, B. 2018. Prevention of groundwater disasters in coal seam floors based on TEM of cambrian limestone. Mine Water & the Environment. vol. 7, no. 2, pp. 300-311.
  • Wang, W.J. 2015. Research on water control effect of Xiatuanbai fault. Mining Safety & Environmental Protection. vol. 42, no.4, pp. 72- 75.
  • Wang, X.Y., Ji, H.Y., Wang, Q., Liu, X.M., Huang, D., Yao, X.P., Chen, G.S. 2016b. Divisions based on groundwater chemical characteristics and discrimination of water inrush sources in the Pingdingshan coalfield. Environmental Earth Sciences. vol. 75, no. 10, pp. 1 -11.
  • Wang, X.Y., Zhao, W, Liu, X.M., Wang, T.T., Zhang, J.G., Guo, J.W., Cheng, G.S., Zhang, B. 2017. Identification of water inrush source from coalfield based on entropy weight-fuzzy variable set theory. Journal of China Coal Society, vol. 42, no. 9, pp. 2433-2439.
  • Wu, Q., Jia, X, Cao, D.T., Liang, Y.P. 2014. Impermeability evaluation method and its application on the ancient weathering crust of carbonatite in Middle Ordovician system in North China coalfield. Journal of China Coal Society. vol. 39, no. 8, pp. 1735-1741.
  • Wu, Q., Zhang, B., Zhao, W.D., Liu, S.Q. 2013. A new practical methodology of coal seam floor water burst evaluation: the comparison study among ANN, the weight of evidence and the logistic regression vulnerable index method based on GIS. Journal of China Coal Society. vol. 38, no. 1, pp. 21-26.
  • Yang, B.B., Yuan, J.H, Duan, L.H. 2018. Development of a system to assess vulnerability of flooding from water in karst aquifers induced by mining. Environmental Earth Sciences. vol. 77, no. 3, pp. 91
  • Yu, X.l., Xu, G.q. 2013. Connected experiment study on explore hydraulic connection between limestones in Panbei mine. Coal Science and Technology. vol. 41, no.10, pp. 105-107.
  • Zhao, L.J., Xia, R.Y., Yi, L.X., Yang, Y., Wang, Z., Liu, H.P. 2016. Quantitative analysis of the source and the effect of turbidity in karst river on tracer test. Acta Geoscientia Sinica. vol. 37, no.2, pp. 241-246.
  • Zhao, Q.B. 2014. Ordovician limestone karst water disaster regional advanced governance technology study and application. Journal of China Coal Society. vol. 39, no.6, pp. 1112-1117.
  • Zhou, C.X., Jiang, J.J., Dong, S.B., Yan, S.X., Chen, Y.M., Song, Y.X., Bian, J.M. 2011. Groundwater tracer test in Sanguikou Ore District, Wulate Houqi,Inner Mongolia. Journal of Jilin University (Earth Science Edition). vol. 41, pp. 285-292.
Toplam 23 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Bölüm Araştırma Makalesi
Yazarlar

Xinyi Wang Bu kişi benim 0000-0002-5275-9209

Yayımlanma Tarihi 1 Haziran 2021
Gönderilme Tarihi 11 Ağustos 2020
Yayımlandığı Sayı Yıl 2021

Kaynak Göster

APA Wang, X. (2021). ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE. Bilimsel Madencilik Dergisi, 60(2), 115-123. https://doi.org/10.30797/madencilik.950069
AMA Wang X. ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE. Madencilik. Haziran 2021;60(2):115-123. doi:10.30797/madencilik.950069
Chicago Wang, Xinyi. “ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE”. Bilimsel Madencilik Dergisi 60, sy. 2 (Haziran 2021): 115-23. https://doi.org/10.30797/madencilik.950069.
EndNote Wang X (01 Haziran 2021) ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE. Bilimsel Madencilik Dergisi 60 2 115–123.
IEEE X. Wang, “ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE”, Madencilik, c. 60, sy. 2, ss. 115–123, 2021, doi: 10.30797/madencilik.950069.
ISNAD Wang, Xinyi. “ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE”. Bilimsel Madencilik Dergisi 60/2 (Haziran 2021), 115-123. https://doi.org/10.30797/madencilik.950069.
JAMA Wang X. ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE. Madencilik. 2021;60:115–123.
MLA Wang, Xinyi. “ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE”. Bilimsel Madencilik Dergisi, c. 60, sy. 2, 2021, ss. 115-23, doi:10.30797/madencilik.950069.
Vancouver Wang X. ANALYSIS OF THE KARST DEVELOPMENT LAW BASED ON MULTIPLE EXPLORATION TECHNOLOGIES OF CAMBRIAN LIMESTONE. Madencilik. 2021;60(2):115-23.

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