Multi-information coupling prediction method of coal and gas outburst danger

摘要

Disclosed in the invention is a multi-information coupling prediction method of coal and gas outburst danger, which is achieved by establishing a multi-index coupling prediction model to detect indexes including original gas pressure of a coal layer, the original rock stress, the critical burst gas pressure of a coal sample, the mechanical performance of coal body, the exploit influence, the drilling cutting gas desorption index, the drilling cutting quantity index and the like, therefore to coupling predict the coal and gas outburst danger. By the multi-information coupling prediction method, the information of the coal and gas outburst danger can be fully complemented; the gas and crustal stress outburst danger prediction is carried out; the defects of insufficient complementation information of a single-index and inaccurate prediction are overcome; and the accuracy of the coal and gas outburst danger prediction is improved.

主权项

1. A multi-information coupling prediction method for coal and gas outburst danger, comprising:
a. testing an original gas pressure repeatedly in the coal seams in a mining zone and the maximum value is determined as P and the maximum concentrated ground stress σmax in a coal body in front of the mining face is tested via a hydraulic pressure rupture method, stress relaxation method or other methods that can detect ground stress, and testing the critical gas pressure rupture and critical compression strength of coal samples obtained on site; b. drilling a hole in length not less than 10 m into the coal body in front of the mining face in the mining direction, measuring a gas desorption index of drill cutting once every 1 m drilling length, and recording a desorption index K1 at 1 m, a desorption index K2 at 2 m, a desorption index K3 at 3 m, . . . , respectively, until the desorption index has stabilized, and taking the stabilized desorption index as a maximum desorption index Kmax; measuring a total amount of drill cutting within every 1 m drilling segment, recording a total amount of drill cutting S1 within the 1 m segment, total amount of drill cutting S2 within the 2 m segment, total amount of drill cutting S3 within the 3 m segment, . . . , respectively, and taking a highest value among the total amounts of drill cutting as the maximum amount of drill cutting Smax; c. owing to the fact that the gas desorption index of drill cutting increases as the gas pressure increases and decreases as the gas pressure decreases, there is a mapping relation between the gas desorption index of drill cutting and gas pressure, the maximum gas desorption index Kmax of drill cutting corresponds to the maximum original gas pressure P of the coal seams; then, calculating a gas pressure P1 at 1 m, a gas pressure P2 at 2 m, a gas pressure P3 at 3 m, . . . , with formulaP1K1=P2K2=P3K3=P4K4=…=PKmax;owing to the fact that the amount of drill cutting reflects the magnitude of ground stress, the amount of drill cutting increases as the ground stress increases, and decreases as the ground stress decreases, and the maximum amount of drill cutting Smax corresponds to the maximum ground stress σmax; calculating a ground stress σ1 within the 1 m segment, a ground stress σ2 within the 2 m segment, ground stress σ3 within the 3 m segment, . . . , respectively, with formulaσ1S1=σ2S2=σ3S3=σ4S4=…=σmaxSmax; d. plotting a curve of gas pressure distribution in the coal body in front of the drilling face in the tunnel and a straight line of critical gas pressure of coal body rupture by a multi-information coupling predictor for coal and gas outburst danger or plotting them manually, with the obtained gas pressure values and ground stress values at different positions, wherein, the distance from the mining face to the intersection point between the curve of gas pressure distribution and the straight line of critical gas pressure rupture is the gas-based critical drilling depth; in addition, plotting a curve of ground stress distribution in the coal body in front of the mining face and a straight line of critical compression strength of the coal body, wherein, the distance from the mining face to the first intersection point between the curve of ground stress distribution and the straight line of critical compression strength near the mining face is the ground stress-based critical drilling depth; taking the smaller one in the gas-based critical drilling depth and ground stress-based critical drilling depth as the critical drilling depth; if the drilling depth in one operation in the tunnel is smaller than the critical drilling depth, predicting that the result is “safe”; if the drilling depth is greater than or equal to the critical drilling depth, predicting that the result is “dangerous”; thereby accomplishing the ground stress-based multi-information coupling prediction of coal and gas outburst danger.