RU11830U1 - DEVICE FOR EXPLOSIVE LIQUIDATION OF DEPENDINGS IN VERTICAL AND TILTED HOUSES - Google Patents

Abstract

1. Device for explosive elimination of freezes in vertical and inclined rock formations, containing a body filled with explosive and a delivery system to the blasting point, characterized in that the body is made in the form of two chambers, one after another and separated by a blank partition, in the front chamber two holes are made, one hole is made in the front end of the housing for loading explosive, closed by a screw plug, and the other hole is made in the side wall, in which the detonator is mounted with an ignition cord replicated to it, in the rear end of the housing, in the bottom of the second chamber, an opening is made in the form of a rigid shank hose, around which nozzle holes are located, at the end of the shank hose, a pneumatic coupling is connected to the air hose from a source of compressed air or air water mixture. 2. A device for explosive elimination of hangs in vertical and inclined rock runs according to claim 1, characterized in that a clamp with a tightening latch and radially arranged flexible safety antennae are fastened on the body, at the ends of which holes are made for a tightening cord. 3. A device for explosive elimination of hangs in vertical and inclined rock runs according to claims 1 and 2, characterized in that the stabilizer shank is mounted on the pre-pull shank hose. 4. A device for explosive elimination of hangs in vertical and inclined rock discharges according to claims 1 to 3, characterized in that the detonator hole in the side wall of the first chamber chamber is plugged, and a shock type detonator is inserted into the hole for loading the explosive. 5. Device for

Description

DEVICE FOR EXPLOSIVE LIQUIDATION OF DEPENDENCES IN VERTICAL AND TILTED HOUSES

The proposal relates to the field of rock mining and, in particular, to devices for eliminating rock hangings in coal runoffs, gozenki, ore passages and rock passages.

A known method and device for explosive cleaning of containers from freezes, where the explosive charge is delivered to the place of hovering using a cable from above (I).

The disadvantage of this device is that when blasting rock hangs from above, pieces of rock can jam even more in the sides of the mine, and in addition it is difficult to choose the place of the most optimal blasting.

A device for eliminating freezing rock mass in ore passages, containing a console mounted in a walker on which a rocket is mounted. (2),

The disadvantage is the need to make a walker to install the console, the possibility of explosion in case of accidental fall of the rock on the shell, the need for direct visibility. freezing of the breed and the impossibility of eliminating freezing in inclined rock runs.

The closest in technical essence and the achieved result is a device for eliminating freezing of rock mass in ore passages containing a console mounted in a walker on which a spherical head with

Device Object

Cl. E 21 0.37 / 00 B 21 P, 5/04 42 D, 3/00

missile on it. The device allows you to eliminate the hang of the rock in inclined and vertical ore passages (W).

The disadvantages of this device are all listed in the previously given device, as well as the impossibility of replacing the method of detonating a projectile with an impact fuse to detonate hovering at a given time, i.e. explosive remote control.

The aim of the proposal and its technical task is to increase the safety of miners, the accuracy of pointing the projectile at the point of detonation and reducing the cost of manufacturing the projectile.

This goal is achieved by the fact that the device for the explosive elimination of freezing rock in vertical and inclined rock runs, made in the form of a housing of two chambers located one after another. Two holes are made in the front chamber, one at the end of the casing, closed by a screw plug for loading explosive (BB), and the other in the side wall in which the detonator is mounted with an ignition cord attached to it. The bottom of the second chamber is made in the form of a shank hose, around which holes are made in the form of nozzles, and at the end of the shank itself, a pneumatic coupling is mounted to connect the device with an air hose to the air duct of the mine or to the compressor. Depending on the task of undermining the hover and the rock profile, either

a clamp with a tension latch and radially arranged flexible antennae, at the ends of which holes are made for a tightening cord, while the collar is put on the body itself, or the stabilizer shank, which is put on an extension on the body hose. In order to avoid yawing while aiming the device at the point of detonation, the casing is made of flexible or flexible material that allows excess air to be drawn into the chamber and, in case of uneven pressure in the mine air line, the excess pressure in the chamber will maintain an even reactive power of a stream of air. If it is possible to use a shock type detonator, it is installed in place of the screw plug, and the detonator hole in the side wall of the first chamber is plugged.

To suppress dust after the explosion and increase the lifting reactive force, a water-air mixture can be supplied to the device. By supplying a water-air mixture, the task of increasing labor productivity is also solved, since the time spent on dust suppression after the explosion is reduced until the start of the next work cycle.

This embodiment of the device allows you to safely conduct treatment work to eliminate the hang of the rock in the mine workings at any height of hovering and with any profile of the sides of the mine.

The essence of the pre-presentation is illustrated by drawings, in which Fig. 1 shows an explosive liquidation device for freezing in vertical and inclined rock formations with a clamp and safety antennae; figure 2 shows a device with a stabilizer shank; Fig. 3 shows a removable clamp with

safety antennae; on | ig, 4 shows the stabilizer tail; on Fig, 5,6,7 shows a diagram of mine workings with vertical and inclined rock runs with devices for eliminating freezing rock at the points of undermining the rock mass.

The device comprises a two-chamber housing I made in the form of two chambers 2 and 3, in the second chamber 3 in the rear torp there are holes-nozzles 4 between which a hose-shank 5 is made with a pneumatic coupling at the end 6 for attaching the device with an air duct to the air duct of the mine. Case I is divided into two chambers 2 and 3 by a partition 7, and in the upper part of the chamber 2 (at the end) there is a hole 8 with a stopper 9 for loading explosive substance U and a hole in the side wall for installing the ignition detonator II with the ignition cord 12, On case I, in one embodiment, wears a clamp 13 with radial antennae 14 with holes 15 made therein for a tightening cord 16, Clamp 13 is made with a cut 17 and a tightening clasp 18, In the second embodiment, instead of a clamp 13 with antennae 14, on a rigid shank hose 5 put on a preload shank stabilizer flaxed in the form of a rigid tube 19 with stabilizers 20, in working condition, the device moves in direction 21 under the influence of reactive force of the air or air-water mixture escaping from the nozzle openings 4, The device through the air coupling 6 is connected with an air hose 22 to the air duct of the mine or compress or a device creating an air-water jets mixture (shown in one drawing) 23, and the ignition cord 12 is connected to an explosive machine 24, The device is directed along a mine working 25 to a frozen rock (plug) 26, Corp. with

I can be drawn out both from hard material (for example: aluminum, hard plastic), and from elastic, in this execution the device in its operation does not depend on fluctuations in the air supply and its compress, since excessive air pressure in the device itself (in chamber 3) allows maintaining uniformity of the jet of air.

The device operates as follows,

With the help of the device, a charge of explosive (BB) 10 placed in the chamber 2 of building I is sent to the mine working 25, where the rock 26 has formed, air or air “. The water mixture from the highway 23 through the air hose 22 enters the chamber 3 of the housing I and exits through the nozzle holes 4 creating a reactive lifting force that moves the housing I with a BB-IO charge to the rock hovering26. A miner with a bang 22 gives direction to a blasting point. In order to prevent case I from breaking against the side of the mine, they put on it a clamp 13 with a flexible antenna 14, which absorb shock of the device against the mine. In the case when the development has a cross section smaller than the span of the antennae 14, they are pulled together by a cord 16 into the arc of S in the form of a Chinese lantern). For the exact direction of the device with the charge 10 to the point of explosion (detonation), instead of the Homzgt 13 with the antennae 14, put on a tight shank 5 pull the stabilizer shank (Fig. 2,4 and 7) due to which the device withstands a more stable direction of movement 21 to the point of detonation (Fig.7).

Instead of the fuse-detonator II, in place of the plug 9 in the hole 8, a shock-type detonator can be installed, and the hole of the fuse of the detonator II is muffled. The device can be made of both solid (hard material,

and elastic. When the device is made of elastic material, it ceases to be dependent on fluctuations in air pressure in the air line, which makes it possible to more accurately direct the explosive projectile Yu into the detonation point, since the device is inflated like a balloon, with the walls of the chamber /

3 creates excessive pressure and air from the nozzle openings

4 exits with constant force, which allows the miner to more accurately direct the device to the point of detonation. This is especially true when the rock hangs in inclined rocks (Fig.6 and 7).

Claims (5)

1. Device for explosive elimination of freezes in vertical and inclined rock formations, containing a body filled with explosive and a delivery system to the blasting point, characterized in that the body is made in the form of two chambers, one after another and separated by a blank partition, in the front chamber two holes are made, one hole is made in the front end of the housing for loading explosive, closed by a screw plug, and the other hole is made in the side wall, in which the detonator is mounted with an ignition cord replicated to it, in the rear end of the housing, in the bottom of the second chamber, a hole is made in the form of a rigid shank hose, around which nozzle holes are located, at the end of the shank hose, a pneumatic coupling of the connection to the air hose from a source of compressed air or air water mixture.  2. The device for explosive elimination of freezes in vertical and inclined rock runs according to claim 1, characterized in that a clamp with a tightening latch and radially arranged flexible safety tendrils, at the ends of which holes are made for a tightening cord, are fastened to the housing.  3. Device for explosive elimination of freezes in vertical and inclined rock runs according to claims 1 and 2, characterized in that the stabilizer shank is mounted on the pull-in hose.  4. A device for the explosive elimination of hangs in vertical and inclined rock runs according to claims 1 to 3, characterized in that the detonator hole in the side wall of the first housing chamber is plugged, and a shock type detonator is inserted into the hole for loading the explosive. 5. A device for the explosive elimination of freezing in vertical and inclined rock runs according to claims 1 to 4, characterized in that the housing is made of elastic material.