SU1694926A1 - Device for determining volume of gas emission from working face - Google Patents

Abstract

This invention relates to mining protrusion and is intended to measure gas evolution from the bottom of a useful mine finding. The goal is to increase the accuracy and efficiency of measurements, to simplify the design of gas emission from the bottom of the device. The device for determining the volume of gas emission contains a gas-collecting chamber (K) 1, installed with the open side to the bottom and communicated with a single-cavity vacuum K 2, the vacuum pump 3 and the measuring device 4 are connected to the latter. The device is K 5 of transparent material with an opening 6, partially filled with liquid 7. into which the measuring tube (T) 8 is placed at one end. The other end of T 6 is connected directly to the pump 3. At the same time, K 2 "and 1 and device 4 are opened in the form of a common body 9 having adjacent walls 10 and 11. Gas removal 1 and vacuum 2 K are connected by a channel 12 having a valve 13. To extend the measurement range, it is possible to use dimensional T 8 of various diameters. The emitted gas from the isolated section of the intake through channel 12 enters K 2 and in T 8. The liquid is lowered to a certain level, and the volume of gas released from the bottom is the x-gas emission. 1 il. Ј / v i

Description

The invention relates to the mining industry and can be used in the development of mineral deposits, in particular when measuring gas evolution from the bottom,

The aim of the invention is to improve the accuracy and efficiency of measurements by simplifying the design of the device.

The drawing schematically shows a device.

A device for determining the volume of gas evolution from the bottom of a mineral includes a gas chamber 1 installed with its open side to the face, a single cavity vacuum chamber 2, to which a vacuum pump 3 and a measuring device 4 are connected, made in the form of a housing 5 with an opening 6 filled with liquid 7, in which a measuring tube 8 is placed at one end, the second end is connected directly to the pump 3. The gas-extraction, single-cavity vacuum chambers and the measuring device are made in the form of a common housing 9 having -retarded adjacent walls 10 and 11. Gazosemnaya and sheeted vacuum chamber connected to a channel 12 having a valve 13.

The device operates as follows.

The common housing of the device with the open side of the gas chamber is set to the bottom of the mineral 14. When the valve 13 is closed by the vacuum pump 3, a vacuum is created in the vacuum single-chamber chamber 2 equal to ho - hi, where ho is the atmospheric pressure for the measurement period, mm water.st .; hi is the height of the liquid column in the measuring device, showing how much the air pressure in the vacuum chamber has decreased, mm. water column After that, the crane 13 is placed in the Open position. In this case, the gas released from the isolated bottom section through the channel 12 enters the vacuum chamber 2 and into a transparent tube with a diameter g of the measuring device, as a result of which the liquid is lowered to a certain level h ₂ . The volume of gas released from the bottom, equal to l r ^ fhj - h ₂ ), during t s, is a characteristic of gas evolution from this section of the bottom of the mineral. For the convenience of calculating the gas evolution, a scale of gas volumes and pressure is applied to a pipe made of a transparent material of the measuring device.

Examples of measuring gas evolution using a device.

When measuring gas evolution on coal seams in a mine, the following operations were performed.

The general case of the device with the open side of the gas chamber was applied to the coal face and the chamber base was sealed with an elastic gasket. When the position of the valve 13 was closed, the pump 3 was turned on. The air was sucked out of the vacuum chamber 2 until the water column in the measuring tube with a diameter of 40 mm rose to a height hi = 80 mm. After that, the crane 13 was placed in the Open position. At the same time, the gas evolved for 5 s from the isolated bottom hole of the coal face 1 through the channel 12 entered the gas reception (vacuum) chamber 2. Upon completion of the gas into chamber 2, which was done by shutting off the tap 13, the water column dropped to level h ₂ = 20 mm from the total water surface in the measuring device.

The volume of gas Q released during 5 s was equal to

Q = (hi - h ₂ ) π g ² = (80 - 20) 3.14x20 ² = 75.36 ml.

Accordingly, the gas evolution rate V ml / s is equal to t 5

It is practically possible to determine the movement of the water column in the tube over a segment of 1 mm. When lowering the water column by 1 mm in a tube with a radius of 20 mm, the gas volume will be lg ² ^ 3,14x20 ² = 1256 mm ³ = 1,256 ml. This amounted to the measurement accuracy of the instrument with a measuring tube having a radius of 20 mm

Measurement in another section showed that using a measuring tube with a diameter of 40 mm it was not possible to determine the rate of gas evolution: there was no lowering of the water column. For this, a measuring tube with a diameter of 10 mm was used with a measurement accuracy of log ² = 3.14x5 ² = 78 mm ³ = 0.078 ml. With a new measuring tube, the lowering of the water column in 5 s occurred by 12 mm, which meant the release of 12x78 = 936 mm ³ = 0.936 ml of gas. Such an amount of released gas was less, the measurement accuracy with a tube d = 40 mm.

Measurement of gas from sections of the formation, characterized by even lower rates of gas evolution, was carried out using a measuring tube with a diameter of 4 mm with an accuracy of 13 mm ³ = 0.013 ml. Lowering of the water column 1694926 occurred by 5 mm, in 5 s 13x5 = 65 mm ³ = 0.065 ml were released.

The maximum measurement accuracy was obtained using a measuring tube with a diameter of 2 mm (0.003 ml). 5

Claims (1)

Claim A device for determining the volume of gas evolution from the bottom of a mineral, including a gas chamber connected to a vacuum chamber connected to a pump and a measuring device, characterized in that, in order to improve the accuracy and efficiency of measurements, as well as simplify the design of the device, a measuring device made in the form of a chamber of transparent material, partially filled with liquid, into which one end of the graduated measuring tube is placed, while the other end of the measuring tube is in communication with the pump, and the vacuum chamber a wall adjacent to the measuring device and gazosemnoy camera.