Strata behavior in extra-thick coal seam mining with upward slicing backfilling technology

Based on the character of upward slicing backfilling mining and the condition of Gonggeyingzi coal mine in Inner Mongolia, this paper describes the studies of the strata behavior and the stress distribution in the process of backfilling mining in extra-thick coal seams. This was achieved by setting up and analyzing the elastic foundation beam model using the ABAQUS software. The results show that: (1) With the gradual mining of different slices, the roof appears to bend continuously but does not break. The vertical stress in the roof decreases and the decreasing amplitude reduces, while the tensile stress in the roof grows with the mining slices and the maximum tensile stress will not exceed the allowable tensile stress. (2) The front vertical stress at the working face exceeds the rear vertical stress and both show a trend of decrease with decreasing amplitude of decrease. (3) The slices mined early have more influence on the surrounding rock than the later ones. Similarly, the strata behavior experiences the same trend. The field measured data show that the roof does not break during the mining process, which is consistent with the conclusion.

[1]  Zhang Ji-xiong Analysis of Strata Behavior in the Process of Coal Mining by Gangue Backfilling , 2007 .

[2]  Qiang Zhang,et al.  BACKFILLING TECHNOLOGY OF SUBSTITUTING WASTE AND FLY ASH FOR COAL UNDERGROUND IN CHINA COAL MINING AREA , 2011 .

[3]  Nan Zhou,et al.  Strata movement controlling effect of waste and fly ash backfillings in fully mechanized coal mining with backfilling face , 2011 .

[4]  H. Yanli,et al.  Overlying strata movement law in fully mechanized coal mining and backfilling longwall face by similar physical simulation , 2011 .

[5]  Lu Ming The balance structure of main roof and its action to top coal in longwall top coal caving workface , 2002 .

[6]  Miao Xie-xing,et al.  Principle of Underground Pressure Control in Fully-Mechanized Coal Mining with Solid Filling and Force Analysis of Mining Support , 2010 .

[7]  Nan Zhou,et al.  Impact law of the bulk ratio of backfilling body to overlying strata movement in fully mechanized backfilling mining , 2011 .

[8]  Zhou Yue-jin,et al.  Strata pressure behavior by raw waste backfilling with fully-mechanized coal minning technology , 2010 .

[9]  Li Wen-zhou Fracture mechanical model of main roof along inclined for fully-mechanized top-coal caving in steep and extra-thick coal seam , 2008 .

[10]  Liu Ruirong,et al.  STUDY ON PHYSICAL SIMULATION OF FULL-SEAM MINING FOR A 20 m VERY THICK AND MEDIUM HARD SEAM BY SUB-LEVEL CAVING MINING WITH HIGH BOTTOM CUTTING HEIGHT , 2007 .

[11]  Liu Quan-ming,et al.  Determination of support working resistance of top coal caving in extra thick coal seam , 2012 .

[12]  Li Qian,et al.  Pressure character in caving steep-inclined and extremely thick coal seam with horizontally grouped top-coal drawing mining method , 2006 .

[13]  Dynamic destabilization analysis based on AE experiment of deep-seated, steep-inclined and extra-thick coal seam , 2008 .

[14]  Wang Cun-wen,et al.  STUDY OF REASONABLE WORKING RESISTANCE OF SUPPORT IN FULLY-MECHANIZED SUBLEVEL CAVING FACE IN EXTRA-THICK COAL SEAM , 2010 .

[15]  Yin Xi-wen,et al.  Discussing about the main theoretical problems of long wall with top coal caving , 2008 .