Heat flow and its coalbed gas effects in the central-south area of the Huaibei coalfield, eastern China

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• 作者：JingQiang Tan (1)
  YiWen Ju (1)
  WenYong Zhang (2)
  QuanLin Hou (1)
  YongJie Tan (3)
  
• 关键词：present geo ; temperature ; thermal conductivity ; heat flow ; coalbed gas ; resource effect ; coal measure ; Huaibei coalfield
• 刊名：Science China Earth Sciences
• 出版年：2010
• 出版时间：May 2010
• 年：2010
• 卷：53
• 期：5
• 页码：672-682
• 全文大小：722KB
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• 作者单位：JingQiang Tan (1)
  YiWen Ju (1)
  WenYong Zhang (2)
  QuanLin Hou (1)
  YongJie Tan (3)
  
  1. College of Earth Science, Graduate University of Chinese Academy of Sciences, Beijing, 100049, China
  2. No.3 Exploration Party of Anhui Bureau of Coal Geology, Suzhou, 234000, China
  3. Development and Research Center, China Geological Survey, Beijing, 100083, China
  
• ISSN：1869-1897

文摘

Based on an analysis of the present geo-temperature field and the thermal conductivity (K) of 62 samples from the central-south area of the Huaibei coalfield in eastern China, we calculated the heat flow and plotted its distribution map. The results show that the average heat flow in the research area is about 60 mW/m2. It is different from other major energy basins in the North China Plate, but has close relationship with the regional geology and the deep geological setting. The heat flow is comparatively higher in the southeastern, central, and northwestern areas than in the northeastern and southwestern areas. The geo-temperature distribution map of the bottom interface of the Permian coal measure was drawn by calculating its embedding depth and geo-temperature gradients. Finally, the present gas generation condition of the Permian coal measure is discussed by associating with the temperature condition, the vitrinite reflectance (R o), the metamorphism of coal and tectonic-burial evolution. The study indicates all present characters of the Permian coal measure, such as lower present temperature, higher R o value, middle-high rank coals, and uplift and extension events after the coal measure sediment, are favorable for the generation of secondary biogenic gas, but not thermogenic gas or primary biogenic gas.