SU649861A1 - Method of localization of gas-dynamic effects in mines - Google Patents

Description

one

The invention relates to the mining industry and can be used to retard the development at an early stage, reduce the intensity and reduce the danger of ejection of coal and gas and other gas-dynamic phenomena in mines.

There is a known method of reducing the intensity of gas-dynamic phenomena and delaying their development in the "initial stage" through the use of safety bars, which close the faces and apply to it. The xDites consist of movable horizontal or vertical shafts, which, when moved apart, create shells 0.3 m wide, allowing us to not dig coal 1.

However, when using this method, it is impossible to ensure a tight fit of the shields to the array, to create a uniform pressure on the face and the required resistance due to the unevenness of the slaughter. In addition, due to the presence of leaks in the shield, gas emission from the massif into the mine workout is not excluded.

The closest technical solution to the invention is a method for localizing gas and dust explosions in a mine, based on the use of guards 2.

However, the use of such a method does not exclude, due to the inconsistency of the overlapping of the cross sections by these jumpers, gas emission from the destructive massif, and consequently, gas sinking of the mine workings, and tilting of the air flow. In addition, jumpers, having experienced significant dynamic loads, are in many cases destroyed.

The aim of the invention is to exclude

gas desorption, scatter destroyed

rock mass and gas generation.

This goal is achieved by the fact that

isolating non-clamps} set

at a distance of Q, 0i-0.10 m from the chest, and in the gap between the bridge and the chest, before the explosive works, a non-explosive gas is supplied to create a borehole BI

a pressure equal to the pressure of gas in the mountain massif maintains this pressure until the completion of blasting, and then reduces it at a rate of 0.1-25.0 kg / cm-s by venting the gas from the bottom hole.

An example of the method. In studies on the model, the sample of coal in the form of a cylinder with a diameter and height of 0.06 m with methane is saturated until a sorption equilibrium is established at a pressure of 4 atm to supply gas to one of its end surfaces. In some cases, 0.01 m in some cases, and 0.1 m from the other end surface of the sample in the cross section — a model with a diameter of 0.055 m — is installed as a jumper a pneumballall 0.03 m wide, which is filled with air - under pressure of 3 atm. Under the action of internal pressure, the balloon is tightly pressed against the walls of the model and held in the desired position. at the expense of friction.

In a p-growth between the pneumatic balloon and the end face of the sample, an air pressure of 4 atm is created. Then the microzar placed in the coal sample is blasting. Due to the presence of free gas pressure in the space between the coal sample and the pneumatic balloon, methane desorption from the destroyed coal is excluded, and its discharge range does not exceed 1 cm. This pressure is maintained (Lives for 30 min.

Then the gas pressure is reduced to 1 atm at a rate in some cases x 0.1 kg / cm-s, in others - 25 kg / cm-s.

No additional destruction of the coal by tearing is observed. In the first minute, about 50% of the adsorbed methane is released from coal. The gassing process ends 5 minutes after the pressure is released.

Claims (2)

1. Reference mining engineer. M., Gostekhizdat, 1960, p. 328. 2. USSR Author's Certificate No. 250081, cl. E 21F 5/00, 1967.