RU193042U1 - DEVICE FOR LOCALIZING EXPLOSIONS OF DUST AND GAS AIR-MIXTURES IN UNDERGROUND MINING PRODUCTION - Google Patents

Abstract

The proposed utility model relates to the mining industry, in particular to the technology and technical means of protecting production and other personnel located in underground mines, the equipment located in them, and the underground mines themselves from explosions of mixtures of mine gas or (and) coal dust ( dust and gas mixtures) contained in the atmosphere of coal mines. The technical task, the solution of which is provided by this useful model, is to increase the speed of the device and thereby increase the reliability of the localization of explosions of dust and gas mixtures in underground mine workings. The specified technical problem is solved in that in a device for localizing explosions of dusty-gas mixtures in underground mine workings, including a container filled with fire extinguishing powder, a high-pressure chamber placed inside the tank with exhaust holes extending into the tank and blocked by a movable piston placed inside the high-pressure chamber, and a mechanism for initiating piston movement, including a sliding sleeve connected to a receiving shield, while on the side surface of the high-pressure chamber p a fitting is placed for refueling it with compressed gas, and a pressure measuring device is placed on the front end of the high-pressure chamber, the movable piston in its rear part is made with a stepped stop made by reducing the diameter, and the piston movement initiating mechanism consists of balls supported by on the stepped emphasis in the rear of the movable piston and fixed in the radial holes made in the rear of the high-pressure chamber, by pressing them against the inner surface of the sliding sleeve, while the sliding clutch is mounted on the high-pressure chamber with the possibility of releasing the balls from the stop in the movable piston when it moves to the front end of the high-pressure chamber. The implementation of the mechanism for initiating the movement of the piston in the above manner provides a significant reduction in the response time of the entire device as a whole, since initially, even in standby mode, there is a maximum pressure difference between the supra-piston and sub-piston cavities of the high-pressure chamber, which immediately after release of the balls causes the piston to move from the maximum speed. The end result of the proposed implementation of the device for the localization of explosions is to increase the reliability of the localization of explosions of dust and gas mixtures and, as a result, to increase the safety of work when it is used in coal mines. 1 ill.

Description

The proposed utility model relates to the mining industry, in particular to the technology and technical means of protecting production and other personnel located in underground mines, equipment located in them, and underground mines themselves from explosions of mixtures of mine gas or (and) coal dust ( dust and gas mixtures) contained in the atmosphere of coal mines.

As you know, the goal of localizing explosions of dusty gas and air mixtures is to limit the distribution area along underground underground mine workings of the flame front, which is formed as a result of these explosions and, in turn, initiates new, often more powerful explosions of these substances.

To this end, since 1930, in shale mines, which are dangerous for gas or dust, they began to use shale shields and, later, water barriers.

Many years of experience in operating shale and water barriers in mines in Russia and abroad have shown their lack of reliability and efficiency in the localization of explosions in gassed workings, because their operation is passive in nature, they fulfill their function only due to the energy of the shock air wave, coming from the explosion of dusty-gas mixtures.

In order to increase the reliability of localization of explosions of dusty-gas mixtures in coal mines, a significant number of automatic systems and devices have been developed to date that are different in terms of operation and technical implementation.

So, it is known a device that performs automatic localization and suppression of explosions of methane-air mixtures (patent for the invention of the Russian Federation No. 2278270, IPC-2006.01 E21F 5/00, published 2006). The device includes shock wave and open flame sensors. The sensors are associated with means of degassing, obstacles and suppressing the spread of flame and shock wave in a specific area. This device is based on the detection and suppression of flame and explosion products that have already appeared in the atmosphere and does not have sufficient reliability for people and equipment in mining.

A device is known that performs automatic localization and suppression of explosions of dusty-gas mixtures in underground mine workings, including a container made in the form of a truncated cone, filled with fire extinguishing powder and closed at the front end with an easily destructible diaphragm located inside the tank with a coaxial high-pressure chamber with exhaust openings extending into the container and overlapped by a movable piston located inside the high-pressure chamber, and a triggering mechanism leading action of the movable piston, wherein the pressure chamber is provided with a nipple for feeding pressurized gas and an instrument for measuring pressure therein (patent RU №2342535, IPC E21F 5/00, priority 14.05.2007). The device operates autonomously, does not require power supply, due to its high speed and long time in suspension, the extinguishing powder dynamically expelled by compressed air energy (or special gas) when it is activated, localizes explosions of dust and gas mixtures from the weakest explosions in the initial stage to advanced explosions. However, the known device has a significant drawback associated with the aerodynamics of the exhaust of compressed gas through the container, which leads to the predominant flow of gas from the upper part of the container, partially free from the extinguishing powder due to its compaction, which entails an incomplete discharge of the volume of the extinguishing powder from the lower part of the container and incomplete its ejection range, i.e. incomplete implementation of the capabilities of an explosion localization device when it is turned on.

The indicated drawback is devoid of a device for localizing explosions of dusty-gas mixtures in underground mine workings (adopted as a prototype of this utility model), including a tank made in the form of a truncated cone, the front end of which is slanted by a secant plane inclined from top to bottom, filled with fire extinguishing powder and at its exit in the front the end face is closed by an easily destructible diaphragm located inside the tank coaxially to it a high-pressure chamber with exhaust openings that exit into the tank and are overlapped with a movable piston located inside the high-pressure chamber, and a triggering mechanism that drives the movable piston, while the high-pressure chamber is equipped with a fitting for supplying compressed gas and a device for measuring pressure in it (patent for invention RU No. 2651821, IPC E21F 5 / 14, priority 04/21/2017).

However, the execution of the front end of the tank with a slanting secant plane sloping from top to bottom, aimed at optimizing the aerodynamic characteristics of the device, makes it difficult to place a nozzle for supplying compressed gas to a high-pressure chamber and a device for measuring pressure in it, as well as performing technological operations with them (installation of this equipment, refueling the high-pressure chamber with compressed gas and taking readings from the pressure measuring device) due to the significant space constraint, limited to sec conductive plane and the outer surface of the pressure chamber in the front end of the latter. On the other hand, the possible placement of a nozzle for supplying compressed gas to the high-pressure chamber and a device for measuring pressure in it directly on the high-pressure chamber requires an increase in the axial dimensions of the device by lengthening the said chamber with the removal of its front end outside the space bounded by the secant plane and the outer surface of the pressure chamber. These circumstances make it difficult to assemble the known device and its preparation for use in underground mining, characterized by the already cramped working space. In addition, the placement of a nozzle for supplying compressed gas to the high-pressure chamber and a device for measuring the pressure in it radially of the high-pressure chamber on its front part leads to their damage when the device is triggered, since they are located directly on the path of the extinguishing powder when the device is triggered.

The indicated drawbacks are devoid of a device for localizing explosions of dusty-gas mixtures in underground mine workings, including a container filled with fire extinguishing powder, a high-pressure chamber placed inside the tank with exhaust holes extending into the tank and blocked by a movable piston placed inside the high-pressure chamber, and a piston movement initiating mechanism including a sliding clutch connected to the receiving shield, while on the side surface of the high pressure chamber there is a fitting for apravki its compressed gas, and on the front end of the high pressure chamber is arranged a device for measuring the pressure therein (patent RU №2440496, IPC E21F 5/14, priority 05.10.2010).

A significant drawback of the described device is the difficulty of performing numerous gas channels in the system of the piston movement initiation mechanism and the associated high value of aerodynamic drag, which leads to unacceptably slow response of the device due to the difficult outflow of compressed gas from the supra-piston cavity into the atmosphere and, as a result, the slow differential pressure between supra-piston and sub-piston cavities. At the same time, the device’s response time from the moment the receiver receives the shock wave overpressure until the end of the discharge of the extinguishing powder is vital for reliable localization of explosions of dust and gas mixtures

The technical problem, the solution of which is provided by this useful model, is to increase the speed of the device and thereby increase the reliability of localization of explosions of dust and gas mixtures in underground mine workings.

The specified technical problem is solved in that in a device for localizing explosions of dusty-gas mixtures in underground mine workings, including a container filled with fire extinguishing powder, a high-pressure chamber placed inside the tank with exhaust openings extending into the tank and blocked by a movable piston placed inside the high-pressure chamber, and a mechanism for initiating piston movement, including a sliding sleeve connected to a receiving shield, while on the side surface of the high-pressure chamber p a fitting is placed for refueling it with compressed gas, and a pressure measuring device is placed on the front end of the high-pressure chamber, the movable piston in its rear part is made with a stepped stop made by reducing the diameter, and the mechanism for initiating the movement of the piston consists of balls supported by on the stepped emphasis in the rear of the movable piston and fixed in the radial holes made in the rear of the high-pressure chamber, by pressing them against the inner surface of the sliding sleeve, while the slip clutch is mounted on the high-pressure chamber with the possibility of releasing the balls from the stop in the movable piston when it moves to the front end of the high-pressure chamber.

The implementation of the mechanism for initiating the movement of the piston in the above manner provides a significant reduction in the response time of the entire device as a whole, since initially, even in standby mode, there is a maximum pressure difference between the supra-piston and sub-piston cavities of the high-pressure chamber, which immediately after release of the balls causes the piston to move from the maximum speed. The end result of the proposed implementation of the device for the localization of explosions is to increase the reliability of the localization of explosions of dust and gas mixtures and, as a result, to increase the safety of work when used in coal mines.

The proposed utility model is illustrated by a drawing, which shows a longitudinal schematic section along the axis of the device for localizing explosions of dust and gas mixtures in underground mine workings.

A device for localizing explosions of dusty-gas mixtures in underground mine workings includes a container 1 made in the form of a truncated cone, the front end of which is beveled with a secant plane inclined from top to bottom. The container 1 is filled with a fire extinguishing powder 2, which, over time, under the action of gravity and surface tension forces is compacted in the lower part of the tank, freeing the upper part of its volume. To waterproof the powder and prevent it from spilling out of the container, the outlet of the latter from the front end is blocked by an easily destructible diaphragm 3 made, for example, of polyethylene. In the tank there is a high-pressure chamber 4 with exhaust holes 5 oriented at an angle, for example, 40 °, to the longitudinal axis of the high-pressure chamber and overlapped by a movable piston 6 located inside the high-pressure chamber. The movable piston 6 is held in standby mode in the initial position by the mechanism for initiating its movement. For this, the piston in the rear part is made with a stepped emphasis 7, made by reducing its diameter. In the front part of the piston is equipped with sealing elements 8. On the back of the movable piston 6, having a reduced diameter, the balls 9 of the actuating mechanism are fixed, fixed in radial holes 10 made in the rear of the high-pressure chamber. The balls 9 are fixed in the radial holes 10 by compressing them to the inner surface of the sliding sleeve 11 by transferring the pressure of the compressed gas located in the high pressure chamber 4 to the front end of the movable piston 6 and through the step stop 7 of the latter to the balls 9. The sliding sleeve 11, mounted with the possibility of longitudinal movement relative to the high-pressure chamber 4, has an annular groove 12 on its inner surface, into which the balls 9 can be sunk when moving the sliding mu ft 11 forward. The sliding clutch 11 is rigidly connected with the extension rod 13, at the rear end of which is mounted a receiving shield 14 for perceiving the impact of an air shock wave. To simplify the design and reduce its longitudinal dimensions, the receiving shield can be fixed directly to the rear end of the sliding sleeve 11. For refueling the high-pressure chamber 4 with compressed gas, the device is equipped with a filling nozzle 15 with a check valve to prevent leakage of compressed gas from the high-pressure chamber 4 to the atmosphere. The filling nozzle 15 is placed on the outer end 16 of the hollow pipe 17 mounted radially in the inner volume of the container 1, protruding beyond the lateral surface of the latter and exiting into the high-pressure chamber 4 by the inner end 18. On the outer end 19 of the high-pressure chamber 4, a device for measuring pressure 20 when filling the latter with compressed gas and to monitor the operability of the device as a whole during its operation in standby mode. The specified device may be a mechanical, electric or electronic pressure gauge for visual monitoring of the parameters of the compressed gas in the high-pressure chamber 4 or their modification, which simultaneously allows data to be sent to a centralized safety monitoring system in the mine. A device for measuring pressure in a high-pressure chamber can also be made in the form of a pressure sensor that provides continuous remote monitoring of the state of the device for localizing explosions of dusty-gas mixtures. To ensure safety when filling the high-pressure chamber 4 with compressed gas, a locking element 21 is used, made in the form of a bolt or screw, or a rotary handle, etc., screwed into the side surface of the high-pressure chamber 4 through a sliding sleeve 11 and preventing the latter from being accidentally moved forward and the unauthorized operation of the device caused in this way. The hollow pipe 17 can be offset along the longitudinal axis of the high-pressure chamber 4 and rotated relative to the vertical plane at the necessary angle, based on the conditions of convenient access to the fitting and the device for measuring pressure and safe handling of the device when it is equipped with fire extinguishing powder, filling with compressed gas and installation in mining.

The device is prepared for operation as follows. Clockwise rotation of the locking element 21 until it stops, the sliding sleeve 11 is fixed in a fixed position. A fire extinguishing powder 2 is placed in the container 1, the front beveled end of the container is closed with a polyethylene easily destructible diaphragm 3. The sliding sleeve 11 is connected to the receiving shield via the extension rod 13. The device is suspended under the roof of the mine in its protected area using special fasteners. Through the fitting 15 with a non-return valve, the high-pressure chamber 4 is filled with compressed gas. In this case, the pressure value of the compressed gas is controlled using a pressure measuring device 20. After that, the locking element 21 is unscrewed. In this position, the device is prepared to perform its function in standby mode.

The device operates as follows. In an explosion of methane and / or coal dust, a shock air wave propagates through the underground mine, which acts on the receiving shield 14. Under the action of the shock wave, the receiving shield 14 through the extension rod 13 transfers force to the sliding sleeve 11, due to which it receives an impulse to move towards the front of the device. Due to the movement of the sliding sleeve 11, the spaces of the radial holes 10 in the high-pressure chamber 4 are combined with the annular groove 12 on the inner surface of the sliding sleeve 11. Then, under the action of excessive pressure of the compressed gas in the high-pressure chamber 4, the movable piston 5 moves toward the rear end of the high-pressure chamber 4 and step stops 7 pushes the balls 9 into the space of the annular groove 12. Freed from the balls fixing it 9, the movable piston 6 continues to move to the side at the rear end of the high-pressure chamber 4, eventually opening the exhaust openings 5. In this case, the compressed gas entering through the exhaust openings 5 into the container 1 is intensively mixed with the extinguishing powder 2 and, breaking the easily destructible diaphragm at the end of the front of the container, emits it into the mine working, forming an explosive-blocking barrier in it.

Claims (1)

A device for localizing explosions of dust and gas mixtures in underground mine workings, including a tank filled with fire extinguishing powder, a high-pressure chamber placed inside the tank with exhaust holes extending into the tank and blocked by a movable piston placed inside the high-pressure chamber, and a piston movement initiating mechanism including a sliding the clutch connected to the receiving shield, while on the side surface of the high pressure chamber there is a fitting for refueling it with compressed gas, and on The front end of the high-pressure chamber contains a device for measuring pressure in it, characterized in that the movable piston in the rear part is made with a stepped stop made by reducing its diameter, and the piston movement initiating mechanism consists of balls resting on a stepped stop in the back the movable piston and fixed in the radial holes made in the rear of the high-pressure chamber, by pressing them to the inner surface of the sliding sleeve, while the sliding sleeve is installed and on the high-pressure chamber with the possibility of releasing the balls from the stop in the movable piston when it moves to the front end of the high-pressure chamber.

Images