RU2707826C1 - Pneumatic charger for granular explosives - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining industry. Charger includes horizontally oriented cylindrical chamber 1 with hatch 2, hopper 3, connected through loading opening with cylindrical chamber 1, compressed air pipeline, aerator 5, unloading pipeline 6, charging hose, membrane mechanism 8 with rocker arm 9, four-way distributor 10a and crane installed in front of charging hose. Aerator 5 is made in the form of cylindrical pipe with two longitudinal slotted holes – main 12, directed upward along wall of cylindrical chamber 1, and auxiliary 13 directed in opposite direction. Aerator 5 is installed inside lower part of cylindrical chamber 1 along its generatrix with displacement relative to vertical longitudinal axis and is connected through four-way distributor 10 with membrane mechanism 8 and compressed air pipeline. Unloading pipeline 6 is cylindrical with longitudinal slotted hole 14 directed upward along housing of cylindrical chamber 1 and is installed symmetrically to aerator 5 relative to vertical longitudinal axis of cylindrical chamber 1.

EFFECT: simplified design, increased reliability and safety of loading, as well as performance and density of loading.

1 cl, 3 dwg

Description

The invention relates to the mining industry, and can be used for mechanized loading of holes and boreholes with granular explosives, mainly in underground mining.

Known pneumatic charger for plastic explosives, including a chamber with an aerator introduced into its internal cavity, pipes and piping (see AS USSR No. 4667645, IPC E21C 37/00, F42D 1/16, publ. 09/27/2004, Bulletin No. 27). In this charger, the camera has a cylindrical shape mounted vertically. Aerator tubes are placed along the walls of the conical bottom, connected with a torus ring, into which compressed air is supplied from the mine shaft. The torus ring is placed outside the chamber in order to evenly supply compressed air to each tube. In this case, the tubes are equipped with holes directed to the surface of the conical bottom, aerating the explosive inside the chamber of the charger.

The disadvantage of the analogue is the design complexity, low aeration efficiency and limited chamber volume due to its vertical orientation and, therefore, low charge density.

The closest in technical essence to the claimed air charger is a device for the delivery of alluvial explosives and loading wells, including a horizontally oriented cylindrical chamber with a hatch, a hopper connected through a loading window to a cylindrical chamber, a compressed air pipe, an aerator, a discharge pipe and a charge hose (see RF patent for invention No. 2204797, IPC F42D 1/10, B65G 53/08, publ. 05.20.2003, bull. No. 14). This device for transporting explosives (BB) to the mixing chamber is equipped with a screw, which is located along the lower generatrix of the cylindrical chamber. In this case, the screw is hollow on one side. To supply compressed air to the aerator, the cavity of the screw is connected to the mine shaft. The auger blades are counter-wound to the middle of the auger, so that when the auger rotates, the explosive material is picked up into the mixing chamber, in the region of which the hollow auger is perforated.

The disadvantage of the prototype is the complexity of the design and manufacture associated with the presence of rotating parts and assemblies. In addition, the elements rotating inside the chamber with explosives make the design unsafe and less reliable in operation.

The technical result is to simplify the design, increase the reliability and safety of loading holes and boreholes with granular explosives, as well as productivity and loading density.

The technical result is achieved by the fact that the pneumatic charger for granular explosives, including a horizontally oriented cylindrical chamber with a hatch, a hopper connected through a loading window to a cylindrical chamber, a compressed air pipe, an aerator, a discharge pipe and a charging hose, according to the invention, is additionally equipped with a membrane mechanism with a rocker arm, a four-way distributor and a crane installed in front of the charging hose, while the aerator is made in the form of a cylindrical pipe with sensing with longitudinal slotted holes the main one directed upward along the wall of the cylindrical chamber and the auxiliary one directed in the opposite direction, the aerator mounted inside the lower part of the cylindrical chamber along its generatrix with an offset relative to the vertical longitudinal axis and connected through a four-way distributor with a membrane mechanism and a compressed air pipeline and the discharge pipe is cylindrical with a longitudinal slotted hole directed upward along the cylinder body nical chamber and aerator set symmetrically about a vertical longitudinal axis of the cylindrical chamber.

This pneumatic charger will simplify the design and increase the reliability and safety of loading boreholes and boreholes with granular explosive, as well as increase productivity and loading density.

The invention is illustrated by drawings, where in FIG. 1 shows a cross section of a pneumatic charger during a purge of a cylindrical chamber with compressed air, FIG. 2 - the same in the process of filling the cylindrical chamber BB, in FIG. 3 is a longitudinal section of a pneumatic charger according to AA.

A pneumatic charger for granular explosives includes a horizontally oriented cylindrical chamber 1 with a hatch 2, a hopper 3 connected through a loading window to a cylindrical chamber 1, a compressed air pipe 4, an aerator 5, a discharge pipe 6, a charging hose 7, a membrane mechanism 8 with a rocker 9, a four-way distributor 10 and a valve 11 installed in front of the charging hose 7. The aerator 5 is made in the form of a cylindrical pipe with two longitudinal slotted holes of the main 12, directed upward, along the wall of the cylinder 1-symmetric chambers 13 and auxiliary directed in the opposite direction. Moreover, the aerator 5 is installed inside the lower part of the cylindrical chamber 1 along its generatrix with an offset relative to the vertical longitudinal axis and is connected through a four-way distributor 10 with a membrane mechanism 8 and a compressed air pipe 4. The discharge pipe 6 is made cylindrical with a longitudinal slotted hole 14 directed upward the housing of the cylindrical chamber 1 and is mounted symmetrically to the aerator 5 relative to the vertical longitudinal axis of the cylindrical chamber 1. The membrane mechanism 8 consists of a body and a cover, between which is secured diaphragm 15, springs 16 and the rod 17 connected to the rocker arm 9 associated, in turn, with a hatch 2.

The air charger works as follows.

According to the requirements of the unified safety rules for the development of ore, non-metallic and placer mineral deposits by underground method, the metering chamber, charging hose and rechargeable cavity (borehole or well) are initially purged. In this case, the hatch 2, being in the closed position, overlaps the loading hole of the cylindrical chamber 1, preventing the ingress of foreign objects into it. After connecting the compressed air pipe 4 to the mine shaft, the four-way distributor 10 is set to position 10a (Fig. 1), and the valve 11 to position 11a. In this case, the loading hole of the cylindrical chamber 1 remains closed, and the cylindrical chamber 1 is filled with compressed air. The pressure of the compressed air in the cylindrical chamber 1 and in the mine shaft is compared. The charging hose 7 is inserted into the blown well (not shown in FIG.), The tap 11 is moved to position 11b (FIG. 3), and the cylindrical chamber 1, charging hose 7 and the well are purged with compressed air. Then shut off the valve 11, stopping the supply of compressed air to the charging hose 7 and the well. At the same time, the pressure of compressed air in the cylindrical chamber 1 begins to increase. Rearranging the charging hose 7 to the next well, the cycle is repeated until all wells are blown. Next, fill the cylindrical chamber 1 with explosive. For this purpose, the four-way valve 10 is moved to position 10b (FIG. 2). In this case, compressed air leaves the cylindrical chamber 1 into the atmosphere. At the same time, compressed air enters the diaphragm 15 through the compressed air pipeline 4 from the common shaft line. The diaphragm 15 bends, compresses the spring 16 and extends the rod 17, which tilts the hatch through the rocker 9 and opens the loading hole of the cylindrical chamber 1. From the hopper 3, the explosives are filled inside the cylindrical chamber 1. After filling the explosives of the cylindrical chamber 1, the loading of wells begins.

To do this, the valve 11 is set to position 11a (Fig. 3), and the four-way valve 10 to position 10a (Fig. 1). In this case, compressed air from under the membrane 15 enters the atmosphere, due to the release of the spring 16. The rod 17 enters the membrane mechanism 8 and, connected with it, the beam 9 rotates and lifts the hatch 2, blocking the loading hole of the cylindrical chamber 1. At the same time, compressed air enters the aerator 5 and then through the slotted holes 12 and 13 into the cylindrical chamber 1, aerating the explosive and translating it into a suspended state. Moreover, the main stream of compressed air exits along the body of the cylindrical chamber 1 through the main slotted hole 12, providing intensive aeration of the explosive. The pressure of the compressed air in this case in the cylindrical chamber 1 increases to the pressure of the compressed air in the mine shaft.

The charging hose 7 is placed in a rechargeable well and open the valve 11, translating it into position 11b (Fig. 3). A mixture of explosives with air from a cylindrical chamber 1 rushes into the slot 14 of the discharge pipe 6, then into the charging hose 7 and into the charged well. After filling the charged well with explosive, the valve 11 is closed, that is, it is moved to position 11a (Fig. 3), stopping the flow of explosives from the cylindrical chamber 1 to the charging hose 7. At the same time, the pressure of compressed air in the cylindrical chamber 1 rises, increasing the potential energy supply . In the process of transporting the explosives through the charging hose 7 to the charged well, the pressure in the cylindrical chamber 1 decreases to the resistance value to movement in the cylindrical chamber 1, the charging hose 7 and the charged well.

After rearrangement of the charging hose 7 in the next well, the valve 11 is opened, moving it to position 11b (Fig. 3). A mixture of explosives with air, located in a cylindrical chamber 1, rushes into the slot 14 of the discharge pipe 6, then into the charging hose 7 and into the charged well with a sufficiently high initial speed, providing high productivity and charging density. Next, the cycle is repeated until the explosive in the cylindrical chamber 1.

The horizontal arrangement of the cylindrical chamber 1 allows practically unlimited to increase the capacity of the chamber, since the horizontal size in the underground workings is not as critical as the vertical. This contributes to an increase in charging performance. The main slit hole 12 is directed upward tangentially to the wall of the cylindrical chamber 1 along its entire generatrix, and the auxiliary slit hole 13 of a smaller size is directed downward, which prevents the material from hanging in the lower part of the cylindrical chamber 1 between the aerator 5 and the discharge pipe 6.

The longitudinal slot hole 14 in the discharge pipe 6 is deployed in the opposite direction from the slot hole 12 of the aerator 5, through which the main air stream exits, which prevents the direct flow of air from the aerator 5 into the discharge pipe 6, provides stable and continuous unloading of the cylindrical chamber 1 from the explosive, and prevents runoff of explosive from the wall of the cylindrical chamber 1 into the slit hole 14.

The supply of compressed air to the cylindrical chamber 1 through the slotted holes 12 and 13 prevents the formation of natural islands of freezing of explosives on the stacks of the cylindrical chamber 1.

Using the proposed air charger in comparison with the prototype will simplify the design, increase the reliability and safety of loading holes and boreholes with granular explosives, as well as productivity and density of loading.

Claims (1)

A pneumatic charger for granular explosives, comprising a horizontally oriented cylindrical chamber with a hatch, a hopper connected through a loading window to a cylindrical chamber, a compressed air pipe, an aerator, a discharge pipe and a charging hose, characterized in that it is additionally equipped with a membrane mechanism with a rocker arm, a four-way distributor and a crane installed in front of the charging hose, while the aerator is made in the form of a cylindrical pipe with two longitudinal slotted holes - the main one, directed upward along the wall of the cylindrical chamber, and the auxiliary one, directed in the opposite direction, the aerator installed inside the lower part of the cylindrical chamber along its generatrix with an offset relative to the vertical longitudinal axis and connected through a four-way distributor to the membrane mechanism and the compressed air pipeline, and the discharge pipe made cylindrical with a longitudinal slotted hole directed upward along the body of the cylindrical chamber, and installed symmetrically about aerator relative to the vertical longitudinal axis of the cylindrical chamber.

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