RU120764U1 - EXPLOSIVES CHARGE FOR EXPLOSION OF HIGH-TEMPERATURE ARRAY (OPTIONS) - Google Patents

Abstract

1. An explosive charge for blasting a high-temperature array, containing a thermal insulating sleeve installed with a gap relative to the explosive mine, an explosive, an initiation means, a dam, a cooling agent, a cooling agent supply, movement and removal path, cooling agent flow reflectors, characterized in that the explosive charge is made in a sealed polymer waterproofing shell with a detonating cord laid and tightly fixed on its surface along the axis of the charge, exiting the sleeve through a sealing gasket and connected to an electric detonator protected from extraneous currents; as a cooling agent of an explosive and a detonating cord, water is taken, which simultaneously serves as a damming charge and an additional dense shell of it; the charge is placed in the inner tube of the liner with a gap, which is fixed by centering elements installed along the axis of the charge, the coolant entering through the nozzle connected to the upper part of the inner tube washes the charge, the inner tube of the liner, the inner surface of the outer tube and exits through the nozzle connected to the top of the outer tube; the bottom reflector of the coolant flow is made removable in the form of a cover of a thermal insulating sleeve, which serves to introduce an explosive charge with a detonating cord. ! 2. The charge according to claim 1, characterized in that the outer surfaces of the liner tubes can be additionally treated with a non-combustible liquid ceramic heat-insulating coating. ! 3. The charge according to claim 1, characterized in that, as

Description

The utility model relates to the field of blasting when crushing hot masses in open-hearth and blast furnaces, while removing plaques in gas ducts of oxygen-flare furnaces and other metallurgical units.

Explosive charges are known in a heat-insulating asbestos sleeve coated with refractory clay (1), in a sleeve consisting of two shells, while the outer shell is made of tin (2), for loading and blasting a high-temperature array, the drawback of which is to limit the temperature regime to 200 ° C and the duration of charging operations up to 5 minutes due to the rapid heating of the charge and the high risk of blasting.

The explosive charge for blasting a high-temperature massif having a temperature of up to 1000 or more degrees should have a special shell cooling system in which the charge is placed, the presence of a cooling agent and its path of movement, allowing for a long time to maintain the temperature of the explosive charge, excluding its explosion from overheating .

Known devices containing a thermally insulating sleeve, consisting of two coaxially located shells, an explosive charge placed in the inner shell, a main pipe for supplying a cooling agent (air), located between the inner and outer shells of the sleeve and a reflector of the flow of the cooling agent mounted on the outer shell sleeves (3).

A device for blasting hot arrays is known, comprising a thermally insulating sleeve made of coaxially arranged tubes with a gap for passing a cooling agent, an explosive charge with initiating means, a main tube and a coolant flow reflector, the explosive charge in the shell and a coolant supply main pipe placed inside a thermally insulating sleeve with direct contact of their surfaces along the entire length of the charge along an arc of 100-160 ° (4). Known heat-insulating sleeve for blasting a high-temperature array, containing a glass with locking elements mounted on its side surface and rigidly fastened to it with a main pipe, a bottom reflector of a cooling agent in the form of a plate rigidly fixed to the bottom of the main pipe, installed with a gap relative to the glass within which a side hole is made in the main tube, the upper reflector of the cooling agent (5). The disadvantage of these devices is the complexity of their design, high metal consumption when using explosive charges of large diameter, high risk of blasting.

Known explosive charge, consisting of explosives and means of initiation for blasting a high-temperature array. The charge is placed in a thermally insulating sleeve, consisting of inner and outer shells, a separation tube, which are installed with the help of the protrusions with a gap in relation to each other. The separation tube is fastened with screws to the outer shell and from the side of the open end of the sleeve by means of a ring is hermetically attached to the inner shell. The gap between the separation tube and the inner shell is connected to the main pipe supplying the cooling agent (air). The outer shell is equipped with a reflector of the flow of the cooling agent (6), the disadvantage of which is the design complexity due to the tight connection of the upper ends of the inner and outer shell liners, low efficiency of thermal insulation of the charge.

Known explosive charge for crushing a high-temperature array, including a sleeve made of two shells installed with the formation of an annular gap between them and their bottoms, the outer shell on the side of its bottom is made with an opening for the outlet of the cooling agent into the space between the sleeve and the blasting, charge explosive in the inner shell, the main pipe for supplying a cooling agent (air) and a flow reflector mounted on the outer shell, the outer shell is provided iksiruyuschimi protrusions defined on its outer surface, and the annular gap of the sleeve at the opposite end from the bottom sealing ring (7) received by the authors as the prototype. The disadvantage of the prototype charge is the design complexity, increased metal consumption, insufficient cooling of the explosive charge, and therefore, the increased risk of explosions. The main disadvantage of such a charge is the extremely low explosive efficiency due to the low charge density of the explosive charge by the explosive, the presence of a multilayer air gap around the explosive charge, screening the effect of the shock wave and the explosion gases on the destructible durable high-temperature array.

The technical task of the utility model was to simplify the design of the charge, increase its thermal insulation, increase explosive efficiency and safety of blasting

The technical problem was solved by developing an explosive charge for blasting a high-temperature massif and its variant containing a thermally insulating sleeve installed with a gap relative to the blasting, explosive, initiating means, jamming, cooling agent, coolant supply and movement path, coolant flow reflectors, in which the explosive charge is made in a sealed polymer waterproofing shell with a padded and tightly fixed on its surface in ol axis charge detonating cord exiting the liner through a gasket and connected to the protected electric detonators; as a cooling agent for an explosive and a detonating cord, water is taken, which simultaneously plays the role of jamming the charge and its additional dense shell;

- option 1 - explosive charge with an internal liquid cooling system of a thermally insulating sleeve -

the charge is placed in the inner tube of the sleeve with a gap, which is fixed by the centering elements installed along the axis of the charge, the coolant flowing through the pipe connected to the upper part of the inner tube washes the charge of the explosive and the detonating cord, the inner tube of the sleeve, the inner surface of the outer tube and exits through a pipe connected to the upper part of the outer tube;

- option 2 - explosive charge with internal and external cooling systems of a thermally insulating sleeve -

the charge is placed in the sleeve in the form of a tube with a gap, which is fixed by centering elements installed along the axis of the charge, the coolant entering through the nozzle connected to the upper part of the tube washes the explosive charge and detonating cord, the inner and outer surfaces of the sleeve, the surface of the hot massif and deviates when the reflector exits to the side of the charge axis.

The need for two options for the explosive charge for blasting a high-temperature array (hereinafter referred to as charge) is determined by the variety of metallurgical units to be processed by the explosion, and their temperature regime.

Schematic diagrams of explosive charges are shown in figures 1, 2.

- figure 1 is a diagram of the explosive charge according to option 1;

- figure 2 is a diagram of the explosive charge according to option 2.

The charge of the explosive 1 is made in the form of a cartridge, the explosive 2 is placed in a sealed polymer waterproofing shell 3, on the outer surface of which a detonating cord 4 is laid and firmly fastened with it. The charge of the explosive of option 1 is placed in the inner tube 5 of the sleeve. The coaxiality of the inner 5, outer 6 tubes of the liner and charge 1 between themselves and with respect to the explosive opening 10 is provided by the centering elements 6, 7, 8. Elements 7 are simultaneously fasteners holding the sleeve in the charging generation of the hot mass. The explosive charge of option 2 is placed in a sleeve consisting of one tube 11. The coaxiality of the sleeve and the explosive charge between themselves and with respect to the explosive generation 10 is provided by the centering elements. The detonating cord 4 is removed from the sleeve through the gasket 12 and connected to the initiator of the explosion 13 - protected from the action of extraneous currents by an electric detonator, for example, an induction high-frequency detonator ED-24. The charge in the sleeve is fixed by the centering elements 6 mounted along the charge. The sleeve on the outside is provided with mounting tabs 7 for securing and fixing it in the charging hole (well or hole). The supply of liquid cooling agent (water) 14 is carried out through the main pipe 9 connected to the upper part of the sleeve. The sleeve is equipped with an upper 15 and lower (bottom) 16 reflectors of the coolant flow, the lower reflector being removable in the form of a cover of a thermally insulating sleeve, which serves to introduce an explosive charge with initiation means. In the proposed charge, water simultaneously performs the role of stemming and an additional dense shell of the explosive charge, which enhances the efficiency of the explosion. The path of supply, movement and discharge of the liquid cooling agent is shown by arrows. For the charge of option 1, the coolant is pumped under pressure, washes the inner tube, the explosive charge and the inner surface of the outer liner tube, the high-temperature array is not directly affected by the cooling agent. For the charge of option 2, the inner and outer walls of the sleeve, the charge and the wall of the high-temperature array are cooled.

Thermal insulation sleeves are made of metal or polymer heat-resistant pipes, for example, polypropylene pipes, the outer walls of which can be additionally treated with a non-combustible liquid ceramic thermal insulation coating of the isolat-04 type (heat insulator used at a coolant temperature of up to + 600 ° C).

The main differences of the proposed charge:

- the use of water as a cooling agent for explosives and detonating cord, stemming and additional shell of the charge;

- the design of the charge, increasing the efficiency of energy transfer of the explosion to destructible high-temperature array.

The explosive charge works as follows.

Before blasting, a sleeve without an explosive charge (not shown in FIG.), But with the coolant flow turned on, is placed in an explosive hole (hole or well) drilled in a high-temperature array. A thermometer or thermocouple is placed inside the sleeve, with which the temperature of the inner surface of the sleeve is measured. Coolant entering the sleeve begins to wash it, as shown by arrows, removing heat from the walls of the blasting hole and thereby prevents the sleeve from heating to a temperature that is dangerous with respect to premature explosion of the explosive charge. By varying the flow rate with the valve by controlling the flow rate and pressure of the coolant in the supply line, the required temperature is established and stabilized in the inner tube 5 of the sleeve (option 1) or tube 11 (option 2), which would ensure the safety of blasting operations, for example , temperatures below 80 ° C. According to the testimony of the flow meter and manometer, the parameters of the cooling fluid flow inside the sleeve with the charge of the explosive and detonating cord are recorded, which ensure a safe temperature regime. Then, an explosive charge with a detonating cord is introduced into the sleeve tube through a removable bottom reflector cap, and then coolant is supplied with the set flow rate and flow pressure when the coolant is continuously supplied, the heat-insulating sleeve with the charge of the explosive is introduced into the charging hole drilled in a high-temperature array, supply water does not stop until the blasting is completed. Upon completion of loading, the detonators are removed to a safe distance and produce an explosion using electric detonators protected from extraneous currents, for example, ED-24 induction high-frequency electric detonators.

In the proposed explosive charge and its variant, the liquid cooling agent simultaneously plays the role of an additional dense charge shell, while the critical diameter of the detonation of the explosive charge decreases, the mass of the explosive charge decreases, its efficiency increases, and a high crushing effect of the destroyed object is ensured. By reducing the mass of the explosive charge, you can increase the diameter of the charge by placing it in a sleeve in the form of a single tube. Since the liquid gap around the charge forms an additional shell, when the charge explodes, the liquid undergoes strong compression and passes into a gaseous state (gas), contributing to the additional destruction of the explosive object.

The main technical result of the utility model is to simplify the design of the explosive charge, increase its thermal insulation, increase the safety of blasting - is achieved due to the distinguishing features of the claimed explosive charge:

- the placement of the explosive and detonating cord in a sealed polymer waterproofing shell, in which the coolant is the bottom of the charge, the location and fastening of the detonating cord on the surface of the cartridge charge simplifies the design of the charge;

- the use of a liquid cooler (water) improves and accelerates the cooling of the liner, which contains the explosive charge and detonating cord, which reduces or completely eliminates the downtime of metallurgical units associated with the need to cool the blasting arrays;

- the use of a liquid cooler (water), which simultaneously plays the role of an additional dense shell of the explosive charge increases the crushing effect of the charge, reduces the mass of the explosive charge;

- the use of the design of the proposed charge, liquid cooler reduces the risk of blasting in high-temperature arrays;

- and for option 2 in addition - the possibility of increasing the diameter of the charge.

The proposed charge was tested during the explosion of hot arrays with a temperature of 1000 or more degrees with positive results, while increasing the efficiency of thermal insulation of the charge, which reduced or completely eliminated the downtime of metallurgical units associated with the need to cool the blasting arrays, increased the crushing effect of the charge, and reduced the risk of conducting blasting.

Information sources:

1. B.N. Kutuzov “Designing of blasting operations”, M., “Nedra”, 1974.

2. V.G. Afonin, L.M. Geyman, V.M.Komir "Reference manual for blasting in construction", Kiev, Budivelnik, 1974.

3. USSR AS No. 708737.

4. USSR AS No. 997730.

5. USSR AS No. 995584.

6. USSR AS No. 719199.

7. USSR AS No. 739918.

Claims (6)

1. An explosive charge for blasting a high-temperature array, containing a thermally insulating sleeve installed with a gap relative to the blasting, an explosive, initiating means, clogging, a cooling agent, a path for supplying, moving and removing a cooling agent, reflectors of a coolant flow, characterized in that the explosive charge is made in a sealed polymer waterproofing shell with a detonating cord laid and tightly fixed on its surface along the charge axis, one from the sleeve through a gasket and connected to an electric detonator protected from the effects of extraneous currents; as a cooling agent for an explosive and a detonating cord, water is taken, which simultaneously plays the role of jamming the charge and its additional dense shell; the charge is placed in the inner tube of the sleeve with a gap that is fixed by the centering elements installed along the axis of the charge, the coolant entering through the nozzle connected to the upper part of the inner tube washes the charge, the inner tube of the sleeve, the inner surface of the outer tube and exits through the nozzle connected to the top of the outer tube; the bottom reflector of the coolant flow is removable in the form of a cover of a thermally insulating sleeve, which serves to introduce an explosive charge with a detonating cord. 2. The charge according to claim 1, characterized in that the outer surface of the tube tubes can be further processed with a non-combustible liquid ceramic thermal insulation coating. 3. The charge according to claim 1, characterized in that the ED-24 induction high-frequency electric detonators can be used as protected from the action of extraneous currents. 4. An explosive charge for blasting a high-temperature massif, comprising a thermally insulating sleeve installed with a gap relative to the blasting, an explosive, initiating means, jamming, a cooling agent, a path for supplying, moving and removing a cooling agent, reflectors of a coolant flow, characterized in that the explosive charge is made in a sealed polymer waterproofing shell with a detonating cord laid and tightly fixed on its surface along the charge axis, one from the sleeve through a gasket and connected to an electric detonator protected from the effects of extraneous currents; as a cooling agent, water is taken, which at the same time performs the role of jamming the charge and its additional dense shell; the charge is placed in the sleeve in the form of a tube with a gap, which is fixed by centering elements installed along the axis of the charge, the coolant entering through the nozzle connected to the upper part of the tube washes the charge, the inner and outer surfaces of the sleeve, the surface of the hot massif and is deflected by the reflector in side of the axis of charge; the bottom reflector of the coolant flow is removable in the form of a cover of a thermally insulating sleeve, which serves to introduce an explosive charge with a detonating cord. 5. The charge according to claim 4, characterized in that the outer surface of the sleeve can be treated with a non-combustible liquid ceramic thermal insulation coating. 6. The charge according to claim 4, characterized in that the ED-24 induction high-frequency electric detonators can be used as protected from the action of extraneous currents.