The methane drainage can not only make coal seams deformation, but also effect its stress distribution. Based on lab experiment on methane drainage with a cubic coal sample of 500 mm×500 mm×500 mm, mutative ...The methane drainage can not only make coal seams deformation, but also effect its stress distribution. Based on lab experiment on methane drainage with a cubic coal sample of 500 mm×500 mm×500 mm, mutative law of coal of pore pressure (p) and effective stress (σef)i were investigated during methane drainage with the coal sample of China Lu'an coal field No.3 coal seam. The experiment results indicate: during methane drainage pore pressure (p) follows exponential attenuation law: p=aexp(-bt); effective stress (σef)i of coal masses follows logarithm incremental law: (σef),=aln t+b, (i=x, y, z); effective stress coefficient(a) follows logarithm attenuation law: a=a-bln t; effective stress coefficient, volume stress (Θef) and pore pressure (p) follow bilinear law.展开更多
基金Supported by the National Natural Science Foundation of China(50404017) the Natural Science Foundation for Young Scientists of Shanxi Province, China (20051026)
文摘The methane drainage can not only make coal seams deformation, but also effect its stress distribution. Based on lab experiment on methane drainage with a cubic coal sample of 500 mm×500 mm×500 mm, mutative law of coal of pore pressure (p) and effective stress (σef)i were investigated during methane drainage with the coal sample of China Lu'an coal field No.3 coal seam. The experiment results indicate: during methane drainage pore pressure (p) follows exponential attenuation law: p=aexp(-bt); effective stress (σef)i of coal masses follows logarithm incremental law: (σef),=aln t+b, (i=x, y, z); effective stress coefficient(a) follows logarithm attenuation law: a=a-bln t; effective stress coefficient, volume stress (Θef) and pore pressure (p) follow bilinear law.