SU1550173A1 - Method of degassing a mined seam - Google Patents

Abstract

This invention relates to the coal industry. The goal is to increase the efficiency of degassing. The orientation of the crack system with the highest gas permeability value is determined. After the formations, the degassing cavities (DP) are created along the entire length of the reservoir drainage wells. In this case, the DP plane is oriented perpendicularly to the direction of the detected system of cracks. The width of the DP is taken not less than the distance between two adjacent cracks of the gas transmission system. Improving the efficiency of degassing is provided by the additional removal of methane from gas-conducting cracks. 2 Il.

Description

The invention relates to the coal industry and can be used in the development of gas-bearing sheets.

The purpose of the invention is to increase the efficiency of degassing.

FIG. 1 shows the reservoir under development, an incision along the strike; in fig. 2 - position of mining operations in the plan.

The essence of the method is as follows. It is known that a coal-bearing gas reservoir is a fractured porous body, which is divided into separate structural blocks by fracture systems. Cracks are collectors of free gas. If a well drilled in a coal seam does not intersect any systems

fractures, gas evolution occurs only from the zone of inelastic deformations that form in the formation around the contour of the well. When a well or a zone of inelastic deformation crosses any fracture system, the gas release increases dramatically. The gas release per unit time is characterized by fracture permeability, which is higher for a system with a large crack opening. Therefore, in order to more intensively the coal seam degassing process, it is necessary to create an effective degassing cavity. In this case, the cavity should cross the cracks with the maximum value of gas permeability and, at least, two lines of adjacent cracks. Inelastic deformation zone, forming

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around a well with a cavity, it will be much wider than around a well without a cavity. Due to this, the area of the degassing effect of the well expands and a large volume of the reservoir is degassed around one well.

The method includes the following operations. During the development of gas-bearing layer 1 (Fig. 1 and 2), outflow wells 3 are drilled from advanced development workings 2. In the course of drilling wells 3 and in the walls of development workings, the number of systems and the geometric (linear and angular) characteristics of each fracture system of the coal seam are determined 1: orientation of cracks, opening and thickness of cracks. By the maximum values of crack thickness, a system of cracks 4 is identified with the highest gas permeability values. In each well, a degassing cavity 5 is cut through, oriented perpendicular to the direction of the fracture system 4 "The size of cavity 5 is taken to be not less than the distance between two adjacent fractures of the gas-conducting system. The wellhead 3 is sealed, connected to a vacuum line, and methane is being sucked from reservoir 1 under development.

The proposed method was implemented during degassing outburst formation. From the advanced workings produced the fracturing of the coal seam. The angle of incidence of cracks was measured by a mountain compass. The length of the cracks and the distance between adjacent cracks were measured with a tape measure. According to the results of the survey, 2 systems of cracks were identified: system 1 with cross-cutting cracks and system II - normal cracks. In each system, the fracture intensity was determined (the number of cracks in the system was 1 m depth) and the crack opening. The system of cross-cutting cracks with a dip angle of 40 ° has the highest values of these indicators. Therefore danna

the crack system is characterized by the highest permeability values. The distance between adjacent cracks of the selected system is 120 mm. Then from prep you Q 5 0 5

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the works were drilled by reservoir drainage wells with a diameter of 70 mm. In each well using a hydraulic perforator. with directed holes, the degassing cavities were cut. The cavity plane was oriented at an angle of 50 ° to the bedding, i.e. perpendicular to the direction of the cracks of system 1 with the highest gas permeability. The cavity was cut to a width of 140 mm, which is larger than the distance between. cracked system I, which is equal to 120 mm. After that, the wellhead was sealed, connected to a vacuum line, and gas was sucked from the reservoir under development.

As a result of the operations presented in the proposed technical solution, it was possible to raise the outgassing efficiency of the outburst-hazardous formation to 75% and increase the average daily loads on the lava to 1600 tons. At the same time, the safety of mining operations on the outburst-hazardous formation was ensured.

The use of the proposed degassing method of the reservoir being developed provides the following advantages as compared with the existing methods: the efficiency of the degassing of the reservoir being developed increases; ensures stable, high-performance work in outburst-hazardous mines.

Claims (1)

Invention Formula The method of degassing the developed reservoir, including drilling from the workings of reservoir degassing wells and creating a degassing cavity along the entire length of each well, characterized in that, in order to increase the efficiency of degassing, before creating the degassing cavity, determine the orientation of the fracture system with the highest gas permeability, while the plane the degassing cavity is oriented perpendicular to the direction of the detected system of cracks, and the width of the cavity is no less than the distance between two neighbors them cracks gas pipeline system.  4 5 3  l I / S 3 LL 5 j M //// / //// / /// / v / / 4f / /% / AV / / / / /14 / / / / 5 j / /// / P1 U /, V // Phie.1 /; / / a