SU962655A2 - Apparatus for dust suppression and localizing dust and gas blasts in mines - Google Patents

Description

one

The invention relates to mining and can be used to clean mine air streams from dust and to protect mine workings from the propagation of a shock wave during explosions of the dust-gas-air mixture in gas and dust mines. According to the main author. St. No. 670730, a device for dust suppression and localization of dust explosions and gas Q in mines is known, which includes a housing, a container for a liquid, made in the lower part of the housing. A protrusion is formed in the upper part of the body, forming an atomizer with the liquid mirror, and a recess behind it forming the air flow rate quenching chamber.

The air stream with dust particles enters through the inlet 20 and is directed by a protrusion into the atomizer, where at high speed (10-12 m / s) an o-mirror of the liquid hits and carries away the drops that are wetted

dust particles. Then the air flow enters the quench chamber, where its velocity decreases by -3 times, which contributes to the intensive precipitation of the moistened dust into the container with the liquid. Purified air through the outlet enters the outgoing jet or to the consumer. As slaked, the container is cleaned. The device is made stationary and can be installed, for example, on the haul horizon til

However, it is not effective enough with weak explosions.

The purpose of the invention is to increase the efficiency of dust suppression of the localization of weak explosions of the dust-gas-air mixture.

This goal is achieved by the fact that the device is equipped with a triangular-section reflector with a concave side panel and channels for water passage located in front of the quenching chamber.

In addition, it is provided with an additional quench chamber located symmetrically with respect to said quench chamber in front of the protrusion, wherein the reflector is made with two concave side surfaces.

, FIG. 1 shows a device for dusting and locating explosives and gas in mines, a longitudinal section; in fig. 2 - principle of operation in localizing an explosion; in FIG. 3, an i device with two blanking chambers; in fig. k is a section A-A in FIG. 3

The device includes a section of primary mine workings with a length of 30 mA, which is body 1 of the device, with an inlet 2 and an outlet 3 apertures with a cross section equal to the output cross section. Capacity i, representing the dimple in the working soil, is filled with fluid 5. Protrusion 6 forming a dispenser with a liquid mirror, for example, in the form of an aperture with a cross section providing speed; air flow 10-12 m / s, and the chamber 7 damping the speed of the air flow is made inside the housing 1 in its upper part and placed behind the inlet 2, respectively. The minimum height from the lower edge of the protrusion 6 to the liquid mirror 5 in the spray area is within permissible safety rules. A reflector is installed in the tank, in the spray gun, in front of the blanking chamber 7. 8 triangular sections with a concave side surface 9 and channels 10 for the flow of fluid from one side of the container k S to the other. The device is made stationary and be supplied with

 The additional chamber 11 is quenched, and the reflector 8 is made with two concave surfaces 9 and 12.

The device works as follows.

During daily operation of the device, the air flow containing dust particles enters through the inlet 2 and the protrusion 6 is deflected and pressed against the water mirror 5, causing disturbance of the fluid. The resulting waves, reaching the side walls of the chamber, are reflected. In a collision of forward and backward waves, spattering occurs. In addition to the toro, the waves that form are incident on the reflector 8 and are sprayed on its non-smooth edge with the formation of a large number of drops. Water droplets caught up by air due to the high turbulence that occurs at the interface of two media are effectively in contact with dust particles. Then a stream of air containing droplets of water and particles of dust absorbed by them enters the quench chamber 7, where, as a result, the speed decreases. Intense droplets and dust particles fall out of the stream. Thus purified air through the outlet 3 enters the outgoing jet or to the consumer. As the slurry proceeds, the liquid container i is cleaned. ,

In an explosion, the shock wave reaches the protrusion 6, changes the direction of movement and acts on the liquid5 in the atomizer chamber, creating a large number of drops at this. In addition, the shock wave displaces the liquid from the chamber, the atomizer, reaches the concave surface of the reflector 8 and throws the liquid to the top of the quench chamber 7, where it is further dispersed by the air flow following the shock wave. As a result, the flame front following the shock wave goes out. During gas explosions in coal dust, the temperature of the hot dust-gas appearance is reduced due to a water curtain formed when a moving stream hits a liquid mirror 5 s of the sprayer - and the flow rate decreases in the quench chamber 7 by k-S times.

In order to allow the localization of explosions propagating from either side of the mine, as well as to extinguish possible repeated explosions propagating in. In the same direction, the quenching chambers 7 and 11 are made on both sides with a slope of the bases of the liquid container toward the reflector 8. In this case, both side surfaces 9 and 1 of the reflector are concave, and to allow the flow of liquid from one chamber to the other has channels 10.

The proposed device will allow cleaning air streams from dust and reliably protect areas, excavation floors, blocks and horizons from explosions of dust-gas-air mixtures during exploitation, and the use of a reflector in the device is significant

Claims (2)

Claim 1. A device for dust suppression and localization of explosions of dust and gas 10 in mines by ed. St. No. 670730, of a different section with a concave lateral surface and channels for water passage. 2. The device according to π. 1, characterized in that it is provided with an additional blanking chamber located in front of the protrusion symmetrically with respect to said blanking chamber, wherein the reflector is made with two concave side surfaces. · Available in order to increase the efficiency of dust suppression and localization of weak explosions, it is equipped with a triangular reflector located in front of the quenching chamber15