RU2565700C2 - System of dust and gas suppression, ventilation and fire extinguishing during large surface and underground explosions, autogenic and open fires at objects difficult to access and large areas - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mine industry, and can be used to control dust and gas content in case of coyote blasts in mines and at borrow pits in rocks of any strength category and watercut degree, and during fire extinguishing of large areas of difficult to access fixed objects. The dust and gas suppression, ventilation and fire fighting system is suggested for mines, it contains: first block comprising mine field with spent chambers and mine tunnels, borrow pit, aquifer, drain system connected in single system, having outputs to open space; at least one second block to form three-phase flow, installed at output to the open space and comprising the ejector device, they contain turbocharger, cryogenic plant, pressure accumulator, cryogenic chamber with build-in at output Laval nozzle; third block to control sequence of switching on of the system assemblies. At that the spent chambers are connected with the aquifer and are tanks to store water supplied to the ejector plant to form the three-phase screen above blasts of the dust-gas discharges and/or for three-phase mixture delivery to the fire spot. Also method of dust-gas suppression is described with use of the said system.

EFFECT: increased degree of dust and gas suppression during large coyote blasts and ventilation of the deep borrow pits and mine tunnels.

14 cl, 6 dwg

Description

The invention relates to the mining industry and can be used to combat dust and gases during mass explosions in mines, quarries, in rocks of any strength category and degree of water cut, as well as when extinguishing large areas of large stationary and hard-to-reach objects.

A known method of dust and gas suppression during massive explosions during mining in underground conditions, including drilling holes in the face, followed by placement of BB charges in them, pumping water and sealing the mouth of the hole. After the explosion of explosive charges, water irrigates the dust cloud and explosion products formed during the destruction of the rock mass [1].

The disadvantage of this method is the low efficiency of dust and gas suppression due to the limited amount of water contained in the hole, and a low degree of dispersion of water.

A known method of dust and gas suppression during mass explosions during mining operations, including the liquid curtain covering a dust and gas cloud formed during explosions of explosive charges in a rock mass, by displacing liquids from tanks using pressure generators [2].

The disadvantages of this method are local effects on the surface of the quarry (small area and range of the water curtain), the presence of bulky equipment on the ledges of the quarry and low efficiency in the production of large-scale mass explosions in mines and quarries.

The objective of the invention is to increase the degree of dust and gas suppression during large-scale explosions, ventilating deep quarries and mine workings by increasing the dynamics of three-phase flows, volumes of finely dispersed water curtains and the overlap area of the dust and gas cloud in open and underground operations, as well as increasing the efficiency of fire extinguishing in large and hard-to-reach objects.

The task is achieved in that the proposed dust and gas suppression, ventilation and fire extinguishing system during mining, large-scale explosions, open, underground, both endogenous and exogenous fires in hard-to-reach facilities and large areas, characterized in that it contains:

- the first block, consisting of a mine field (a) with spent chambers (1) and mine workings (2) quarry (b), an aquifer (7), a drainage complex (5), connected to a single system with access to open space ;

- at least one second unit for forming a three-phase flow, mounted at the outlet into the open space and consisting of an ejector device (18), which includes a turbocompressor (22), a cryogenic installation (24), a pressure accumulator (26), cryogenic a chamber with an integrated Laval nozzle (28);

- the third control unit for the sequence of inclusion in the operation of the system nodes;

- the spent chambers (1) communicate with the aquifer (7) and serve as containers for storing water supplied to the ejector unit (18) for forming a three-phase curtain (31) over explosions with dust and gas emissions and (or) delivering a three-phase mixture to the ignition site.

In another embodiment, a dust and gas suppression, ventilation and fire extinguishing system during mining, large-scale explosions, open, underground both endogenous and exogenous fires at inaccessible facilities and large areas, characterized in that it contains:

- the first block, consisting of a mine field (a) with spent chambers (1) and

mine workings, quarry (b), aquifer (7), drainage complex (5), connected into a single system with access to open space (17);

- at least one second block for forming a three-phase flow, mounted at the outlet into the open space and consisting of an ejector device (s) (18), which include a turbocompressor (22), a cryogenic installation (24), a pressure accumulator (26 ) connected to the chamber (25), at the output of which a Laval nozzle is mounted, - a pressure accumulator (29), having a rotary nozzle (49) at the output with a Laval nozzle (28);

- the third control unit and the sequence of inclusion in the operation of the system nodes;

- spent chambers (1) communicate with the aquifer (7) and serve as containers for storing water supplied to the ejector unit (18) to form a three-phase curtain (31) over the explosion, dust and gas emissions and (or) delivery of the three-phase mixture to the fire

System options have versions that improve their performance.

A system in which a mine field (a) has horizontal and vertical openings through which lines are laid for transporting water from an aquifer (7) to exhaust chambers, as well as lines for air supply, which serve as components of a multiphase working environment for dust and gas suppression and (or) fire extinguishing, moreover, reagents are added to form a three-phase flow, the solid phase is formed by ice crystals, and the gaseous phase is formed by high-speed and low-temperature water-crystalline flows.

A system in which a mine field is connected to a quarry through mine workings, which are connected to a drainage complex and generators for forming three-phase flows, including a turbocompressor, a cryogenic installation, gas-dynamic pressure accumulators and ejector devices for forming a supersonic three-phase flow, fine curtains, the control unit contains sensors air conditions, mine atmosphere, quarry, fire, explosion.

A system in which the outlet of the working cavity of the turbocharger (22) is connected to the initial zone of the cryogenic installation (24) equipped with a cryogenic chamber (25) is made of at least a cylindrical, spiral shape made of durable heat-resistant material and having a longitudinal extension to exit a cryogenic installation, wherein the chamber exit is equipped with a Laval nozzle to create a supersonic low-temperature gas stream, and the inlet of the cryogenic chamber (25) is connected to the first pressure accumulator (26) installed by the coaxial but cryogenic unit (24).

A system in which the output of the second pressure accumulator (29) for forming a supersonic high-temperature gas stream is located above the exit of the cryogenic chamber (25), ensuring the position of the zone of the high-temperature gas stream above the zone of the low-temperature three-phase flow.

A system in which pressure accumulators are made sectional like a revolving magazine and mounted with the possibility of stepwise rotation with stops, at least for the duration of the generation of the powder charge in one section of these accumulators.

A system in which a cryogenic chamber (25) is mounted with the possibility of step-by-step rotation with a stop, at least for the time the powder charge is generated in one of the sections of the pressure accumulator (26).

A system in which it has means (21, 23, 30) for supplying to the turbocharger (22) water from the exhaust chambers (1), polluted air from the exhausted space (23) and reagents that stimulate the formation of at least solid carbon dioxide, silver iodide.

In another embodiment, the method of dust and gas suppression, ventilation and fire extinguishing during mining, large-scale explosions, open, underground, both endogenous and exogenous fires at inaccessible facilities and large areas, which consists in the following operations:

- form one low-temperature three-phase flow or

- form two streams, one low-temperature three-phase, the other gas high-temperature;

- a low-temperature flow or low-temperature and high-temperature flows are fed over the explosion with a dust-gas cloud or a fire focus at the same time or with a time delay relative to the time of the explosion initiation;

- the supply of the high-temperature gas stream is carried out over the low-temperature three-phase stream.

The method in which the air-water crystalline stream at the outlet of the turbocharger (22) is subjected to ultrasonic vibrations in the range of 10-1500 kHz, and N ₂ CO ₃ reagents are added to the water _. N _a2 SiO _2.

A method in which a water-air-crystalline stream at the outlet of a turbocompressor (22) is subjected to electric discharges or electromagnetic pulse processing from energy storage devices such as capacitive or inductive storage, and when magnetic-pulse processing, the magnetic field induction is of the order of 0.5-1, 5 T, pulse duration from 10 ^-2 -10 ^-8 s.

A method in which the water supply is brought closer to possible foci of ignition, explosion, dust and gas emission by supplying it from the aquifer to the spent chambers.

A method in which water supplies are brought closer to a possible source of ignition, explosion, dust and gas emission by supplying it from an aquifer to artificial or natural containers.

The invention is illustrated by the diagrams in which in FIG. 1 shows a combined plan of mine (a) and quarry fields (b). The mine field is represented by spent chambers 1 and mine workings 2, drifts and crosshairs. The plan for the open pit field shows the non-working sides 3, the boundary of the open pit 4, the drainage complex 5 and the multiphase (solid, liquid, gaseous) flow generators 6. The mine field is connected to the pit by means of mine workings 2, which are connected to

drainage complex 5 and generators for the formation of three-phase flows 6.

In FIG. 2 shows a sectional view of the overburden, the spatial location of the aquifer, the position of the horizons of the mine and quarry, underground mine workings, for example, with a chamber-pillar mining system, as well as spent chambers and individual elements of the drainage complex.

The underlying aquifer 7 with respect to the overburden 8 is located above the spent 1 and working chambers 9 in the ore mass 10, between which there are interchamber pillars 11. On the earth's surface drainage equipment 12 is installed, connected, for example, with underlying horizons of -25 m, - 75 m, -125 m, -175 m, -225 m (position 13) through well 14, which, in turn, is connected to chambers 1. To prevent water from breaking into working chambers 9 from well 14 at the interface between workers and non-workers zones installed waterproofing lintel bridges 15. In the working space of horizontal workings 13 there is an extended dust and gas suppression and ventilation system 16, which communicates with the open space of the open pit zone 17 by means of ejector devices 18, and a system for generating three-phase flows of fine curtains 19.

In FIG. Figure 3 shows a three-phase flow formation system with the aim of creating a fine curtain for dust and gas suppression in large-scale mass explosions. This system is installed on a bed 20, which is located on the soil of the mine 13. Well 21 is connected to the working cavity of the turbocompressor 22 (with the ability to control the volume of water supplied), which is fed into the worked out space 23. The output of the working cavity of the turbocompressor 22 is connected with the initial zone of the cryogenic installation 24 by means of a flange connection (not shown in FIG. 3). The cryogenic unit 24 is provided with a chamber 25 of a cylindrical, spiral or other shape. Coaxially cryogenic installation 24 is a gas-dynamic pressure accumulator 26. As a gas-dynamic generator, it is possible to use powder pressure accumulators (PAD). Gases leaving the gas-dynamic generator expire at a speed of at least 2000 m / s [3]. The output of the pressure accumulator 26 is coaxially connected to the enclosed space 27 by means of a cryogenic chamber 25 (cylindrical or other shape made of durable heat-resistant material), having a longitudinal length until it leaves the cryogenic installation 24. Moreover, the exit section of the chamber 25 for creating a supersonic low-temperature gas stream can be provided with the possibility of equipping it with a Laval nozzle 28. At the exit of the cryogenic installation 24, for example, a powder pressure accumulator (PAD) 29, for the formation of a supersonic high-temperature gas stream. Moreover, the output section of the three-phase flow former 28 to create a temperature gradient from (PAD) 29 is equipped with a diffuser 32, which is located above the output part of the three-phase flow former.

In FIG. 4 shows a control system for dust and gas suppression and ventilation of deep pits and mines in large-scale mass explosions. It consists of the following basic elements:

- An industrial computer with a real-time operating system Vx Work RTLinux 33;

- A / D converters for local sensors 34, 35, 36 and actuators 37i, 38i, 39i, 40i;

- actuators of power units: for a turbocompressor 40, cryogenic installation 24, gas-dynamic pressure accumulators 26, servomotors for controlling the position of the Laval nozzles 41;

- local sensors of speed and temperature of gas flows 34;

- local dust meters 36 type CIP-10;

- multi-gas sensors of the TX652 or TX6523 type with “intelligent” gas-sensitive modules: infrared gas sensors 35, electrochemical sensors 36, thermocatalytic sensors 49;

- microprocessors (12-bit A / D signal converter) 42;

- acousto-optical spectrometers (for on-line measurement in real

concentration time of harmful gases 43 and fine particles 44 in large volumes and over large areas);

- laser analyzers of the composition of the atmosphere (real-time measurement of large volumes and speeds of dust and gas emissions) controlled by fiber optic communication lines and / or radio signal 45;

- a central control point for monitoring spaced elements of the system with telemetric sensors 46.47.

The system is additionally equipped with a software package, for example, "Monitoring" or another software package. Moreover, the above sensors and actuators are connected via an analog-to-digital converter unit 42 and a bus 48 (RS 485 brand) to an industrial computer 33, for example, to a computer with a Vx Work RTLinux real-time operating system, the output of which is via a CANBUS, MODBUS control bus connected to actuators. As an actuating unit 40i, a control pulse generator is also used, the output of which through a movement mechanism is connected to a control actuator of the Laval nozzles.

The dust and gas suppression system for ventilation and fire extinguishing in case of large-scale ground and underground explosions, endogenous and open fires in hard-to-reach objects and large areas works as follows.

As a result of the pressure drop (Fig. 2), water between the overlying and underlying horizons enters the waste chambers through pipelines 16 located in the workings 13. At the same time, protective waterproofing jumpers 15 are installed to prevent water from breaking into the working zone at the interface between the working and non-working zones. chambers 1 are used as storage tanks for water, which are connected to systems for the formation of three-phase flows having access to the open space of the open pit zone 17 by means of an ejector devices 18.

From the exhausted space 23 (Fig. 3), contaminated air enters the inlet of the working turbocompressor 22. Water is supplied from the well 21 to the working area of the turbocompressor 22, where it is dispersed to a finely divided state. To form a three-phase flow through the well 30, reagents are supplied. The solid phase is formed by ice crystals, and the gaseous phase is formed by a high-speed low-temperature air-gas flow. Currently, two reagents are most widely used: solid carbon dioxide and silver iodide, which are used to affect naturally supercooled fine fractions of water droplets in order to initiate their crystallization and cause precipitation. In addition, reagents such as Na ₂ CO 3, Na ₂ SiO ₃ and others can be used.

In order to create a solid phase of the flow, the contaminated air (Fig. 3) is sucked in by the turbine 22 and mixed with water and reagent particles. The result is a fine dust-air-water mixture 31, which is fed into the zone of the cryogenic installation 24 and under the influence of the pressure of the turbine 22

this stream continues to move through the interior of the cryogenic chamber 24. As a result of cooling, the particles coarsen to a crystalline state and continue to move to the mouth of the outlet of the three-phase flow former. Coaxial to the refrigerator are chambers 25 of the powder pressure accumulator (PAD) 26, which allow the supersonic gas flow rate to be created at the mouth of the refrigerator.

PAD cameras, for example, of a “revolver type”, can be rotated along the longitudinal axis to ensure recharging of the gas generator. The cooling of the chambers of gas generators is carried out by a low-temperature three-phase stream 31, which is directed to the mouth of the cryogenic chamber, which communicates with the open atmosphere of the quarry.

As a result, a discharge zone is formed at a section of the mouth of the cryogenic chamber 24, into which conglomerates of ice crystals are ejected and released into the open space. At the same time, on the slice (outlet) of the refrigerator above its upper part there is a shaper of warm air-gas flow, which passes through the Laval nozzle 28 and is thrown into the open space at supersonic speed.

The formation of a three-phase flow mainly depends on the ambient temperature and the presence of supercooled moisture. Initially, in a dusty-air-water mass, a region oversaturated with moisture appears, where intense condensation of water vapor occurs on finely dispersed dust particles.

If the temperature in this formation is below 0 ° C (the initial zone of the cryogenic unit 24, Fig. 3), conditions are created for the subsequent nucleation of polycrystals of ice. This occurs at a temperature of about -5 ° C, which causes an intensive process of formation and coarsening of the smallest particles of ice polycrystals. For example, the initial crystal diameter is less than 75 microns. When moving along the longitudinal axis of the cryogenic installation 24 under the influence of the initial dust-air-gas flow from the turbocompressor 22, the size of the crystals can exceed 200-300 microns. The speed of the air-gas stream from the turbocharger 22 to create the required size of the solid phase fraction is regulated from 0 to the nominal speed and is determined by calculation using the appropriate program. The intensive process of crystal enlargement usually occurs at temperatures from -5 ° to -20 ° C. Depending on the time the particles are in the zone of the cryogenic chamber 25, crystals of about 250 μm in size can reach 1-2 mm or more. It was established that the greater the distance they travel in the internal cavity of the cryogenic installation, the larger they can reach (up to several centimeters).

During supersonic outflow (Fig. 3) of the gas flow through the Laval nozzle 28, ejection of ice polycrystals occurs in the outlet pipe of each generator of the water curtain. Moreover, the larger the mass of ice crystals, the greater the distance possible delivery of a three-phase flow into the working area of the quarry due to the kinetic energy of the particles.

To increase the kinetic velocity of ice fractions or finely divided fractions of water and to generate a low-temperature supersonic gas flow, for example, a pressure powder accumulator 29 (PAD) is used. It is provided with the ability to control the resulting velocity vector with respect to the horizon line due to the presence of Laval rotary nozzles (with three degrees of freedom).

To create a positive temperature gradient between the underlying and overlying gas streams of the system, overlying groups of inclined Laval nozzles 28 are used with respect to the axis of the chamber 25 with the possibility of controlling their angle of inclination relative to the horizon. These groups are activated synchronously with the initiation of PAD 29 low-temperature supersonic gas flow. Due to the positive temperature gradient, it is possible to control the resulting velocity vector of the particles of the three-phase flow, which, in turn, allows the creation of curtains at any point in the quarry field over the blasting blocks at any time specified by the program. Since the temperature of this gas stream is much higher than the previous one, a high gradient of the gas stream is created, which allows according to the laws of ballistics to deliver the solid crystalline phase of the stream to any point in the quarry, and during fire extinguishing, the curtains over large fires. Under the influence of the so-called "thermals" from explosions of borehole charges BB, ice conglomerate particles containing adsorbents, toxic elements, fine dust particles finally decay into steam, water with adsorbents and solid particles, which, in turn, (fine dust fractions) are coagulated , coarsen and fall out in the form of precipitation within the quarry field [3].

Let us further consider the operation of the dust and gas suppression system and ventilation of deep mine workings, for example, in relation to the Lebedinsky career.

The number of mass explosions per year with an explosive mass exceeding 100 tons can reach more than 30. For one mass explosion, the explosive mass can be 800-900 tons. Wind at the surface of the earth reaches 5 m / s. After detonation of all explosive charges, studies show that a single gas-dust cloud is formed with a diameter of 3-4 km and a height of 300-400 m, containing up to 800 tons of dust particles ranging in size from 1 μm to 1 cm. The volume of a dust-gas cloud, for example, when 200- 300 tons of BB reaches 15-19.5 million m ³ , the initial concentration of dust exceeds 4000 mg / m ³ , and the visually observed length of its propagation in the wind reaches 15 km. In large-scale mass explosions (about 1000 tons of explosives), up to 4 billion m ^{3 of} atmospheric air is polluted to dangerous concentrations.

Without a dust suppression and ventilation system during large-scale mass explosions, a dust and gas cloud about 15 km in size reaches the city of Stary Oskol. The mass of precipitated dust is from 10 to 100 kg / km ² or 1.4 -14 g per inhabitant, and at a distance of 7 km from the city of Gubkin with the corresponding wind direction, the mass of precipitated dust is 150-200 kg / km ² and, accordingly up to 3-30 g of fine dust (in most cases containing radionuclides and other elements - toxicants) per inhabitant.

It should be noted that according to the development plan for open cast mining, more than 50 million tons of ore are subjected to explosive ore preparation per year. This constantly requires ensuring the production of a significant amount of blasting and explosives. Due to the large volume of blasting operations and, accordingly, the release of large dust and gas emissions, in order to block this area with a finely dispersed water curtain created using three-phase flows from the dust and gas suppression system, the number of underground chambers should be about 5-10 pcs. The chamber volume can reach from 50 to 80 thousand / m ³ . The cameras are located along the perimeter of the quarry in the zone of the limiting contour of the quarry and the drainage system at distances providing mutual overlap of the water curtains. The cameras are connected to a three-phase flow formation system, which, in turn, includes a gas turbocharger 22 (Fig. 3), a cryogenic installation 24, gas-dynamic generators 26, for example, based on ballistic solid fuel. These generators are able to ensure the formation of a three-phase flow up to a height of 300-500 m and a distance of up to 2000-3000 m, followed by the formation of a finely divided water curtain over blasting blocks above any point in the quarry. As a pressure generator, for example, gas-dynamic solid rocket fuel generators can be used. The composition of ballistic fuel can be RSI, NRSI, but other compositions and gas-dynamic generators can be used. Currently, separate gas-dynamic generators from solid-fuel ballistic missiles may be available for use in industry, in connection with their decommissioning, as they have expired and should be disposed of and processed. At a rate of 0.2 liters of water per 1 m ^{3 of} polluted air, a significant amount of water will be required to cover a dust and gas cloud with a radius of 2-2.5 km and a height of 500-600 m, which can be placed in 5-10 spent underground chambers of a neighboring mine.

Consider the operation of the system for the conditions of underground mining, for example, OJSC KMARuda. During mining and blasting a set of holes with a usual charge of 20-30 kg, more than 800-1000 g of dust enters the air for an explosion. During mass explosions in the chambers, a significantly larger amount of dust enters the air, which in pollutants with a cross-section of 10-12 m ² over 1 km can pollute the air so that its dust content exceeds the maximum permissible norms by tens or more times. The speed of the air stream in underground workings is about 0.2 m / s. At the same time, the dust cloud after the explosion, for example, of holes in 1.4 hours, can move 1 km from the face and up to 80% of suspended dust remains in the air. The absolute value of air pollution in this place with standard stemming will be 77.8 mg / m ³ , and when using a finely divided water curtain 5 mg / m ³ with a MAC of ≈4 mg / m ³ .

The dust-gas cloud suppression efficiency can be increased due to Na ₂ CO ₃ , Na ₂ SiO ₃ with harmful gases (NO ₃ and СО) containing polar adsorbents Fe ₂ O ₃ , CaO and others.

It is possible to suppress dust and gas clouds using aqueous solutions

silicic acid salts to form silica gel from a hydrogel, H ₂ S _I O _3, which is a good polar adsorbent. Fine dispersion of water (liquid) to a state of fog is created additionally by special installations with fogging machines. Dust deposition occurs as a result of condensation of water vapor on the surface of dust particles and the collision of the finest droplets with dust particles, and coagulation, and weighting. To ensure fine dispersion of large volumes of water and working fluid, their dispersion can be carried out under the influence of supersonic outflow of a gas stream. At low gas-water flow rates at the outlet of the turbocharger 22 (Fig. 3), the dispersion of water and the working fluid can also be carried out additionally by the action of ultrasonic vibrations on the fluid flow in the range of 18-1500 kHz. At speeds of air-water flow close to supersonic, it is exposed to electric discharges from a current generator or electromagnetic impulse processing from energy storage devices (capacitive, inductive, etc.).

The efficiency of dust suppression by fogging agents reaches 90-95% at a water pressure of 0.5 MPa and compressed air of 0.6 MPa. With high-pressure irrigation, dispersion of the liquid occurs, due to which the number of drops per unit volume of air increases, the flow becomes more saturated with drops of liquid, and the flight speed of the drops increases.

The fluid flow rate for high-pressure irrigation is 0.07-0.25 l / m ³ dusty air. The efficiency of dust cleaning during high-pressure irrigation is up to 97%, while the degree of capture of fine-dynamic dust particles 5 microns in size increases.

It is known that dust particles carry charges of various signs. In this case, the electric field strength of the dust aerosol reaches 3 S / m. Knowing the charge sign on the dust particles, the liquid droplets are charged with the opposite sign at the beginning of the cryogenic unit 24 (Fig. 3).

During sonar irrigation, dust vibrations are simultaneously affected by acoustic vibrations created by a liquid stream at the outlet of the turbocompressor 22 or Laval nozzle 28 (Fig. 3). For effective dust suppression, it is necessary to withstand the following parameters: water pressure from 1 MPa, liquid flow rate from 0.2 l / m ³ , vibration frequency from 10 kHz. Specific acoustic power from 25 W / m ² .

During electromagnetic processing of a liquid (magnetic pulse), the field parameters are B≈1.5-2 T. The pulse duration is from 10 ^-2 to 10 ^-8 s. Inductive, capacitive storage devices and other pulse generators can be used to create pulses.

In the mine. Gubkin KMA ore plant as chambers for liquid placement (Fig. 3), already used chambers 50 × 50 × 30 m in size can be used, which are connected to a dust and gas suppression system, including turbochargers 22, a cryogenic installation 24, pressure generators 26. For small volumes dust and gas emissions to disperse the liquid and the formation of fog at the output of the turbocharger 22 can be additionally applied ultrasonic disperser with a frequency of 10-150 kHz. Reagents Na ₂ CO ₃ , Na ₂ SiO ₃ and others are added to the water.

For intensive ventilation of a mine using this system, both vertical and horizontal excavations can be used. For both open and underground mining, the initiation of BB charges in the array and the initiation of gas-dynamic generators occur simultaneously or with a pause in time necessary to create a fine curtain of a two- or three-phase flow (from ms to several minutes). Time depends on many factors, for example, on the distance to the blasting unit, wind speed and direction, ambient temperature, degree of dust and gas contamination, and many other factors, the parameters of which are recorded by appropriate sensors and transmitted to the CPU.

The inclusion of the generator of water curtains is carried out in accordance with the program of drilling and blasting operations (Fig. 4) by initiating PAD at a time specified by the program and taking into account the moment of initiation of BB charges for each block. In this case, it is preferable that the curtain is created a few seconds before the moment of explosion of specific groups of explosive charges.

In accordance with the program of work of the dust and gas suppression system, which takes into account all the factors and the order of production of a mass explosion, specifically for each block in a quarry or mine, the order of initiation of hydrodynamic generators and their operation time, depending on the distance to the blown blocks, the predicted volume of dust and gas and other factors. This allows you to create water curtains of various spatial parameters, specified volumes with fine dispersion of water with different linear dimensions of the curtain within the quarry field or mining.

The presence of a single hydraulic system connected to the drainage system allows us to provide the necessary amount of discharged water to block the dust and gas cloud in all areas of the quarry or mine for a given volume of mass explosions. When extinguishing, land-based hydraulic systems (open water bodies, canals, etc.) can also be used.

This system, in addition to intensive ventilation of deep quarries and mines, is capable of creating water curtains with a volume of 10 ⁴ to 10 ⁵ m ^{3 with} a dust and gas suppression ratio of about 97-98% with a reduction in capital costs of 40-50% compared to installations containing powerful fans and turbo engines.

The system can be used to solve geoecological problems in the extraction and processing of minerals, where large-scale mass explosions are carried out, as well as in fire fighting on large areas and in inaccessible places [4].

Information sources:

1. Water jamming of holes. P.A. Demchuk. Nedra Publishing House 1964, p. 32. 2. Copyright certificate No. 1457517 of the USSR. The method of dust and gas suppression, 04.16.87.

2. V.N. Anisimov, V.A. Belin, A.V. Dugartsyrenov. Dust formation and dust and gas suppression during large-scale mass explosions in quarries. Mountain Journal, No. 12, 2007.

3. V.N. Anisimov, E.A. Kotenko, V.K. Kushnerenko, V.N. Morozov. Ways to solve the geoecological problems of safe operation of the mining and metallurgical complex KMA. GIAB, No. 1, 2002, p. 105.

Claims (14)

1. The system of dust and gas suppression, ventilation and fire fighting during mining, large-scale explosions, open, underground, both endogenous and exogenous fires in hard-to-reach objects and large areas, characterized in that it contains:
- the first block, consisting of a mine field (a) with spent chambers (1) and mine workings (2) quarry (b), an aquifer (7), a drainage complex (5), connected to a single system with access to open space ;
- at least one second unit for forming a three-phase flow, mounted at the outlet into the open space and consisting of an ejector device (18), which includes a turbocompressor (22), a cryogenic installation (24), a pressure accumulator (26), cryogenic a chamber with an integrated Laval nozzle (28);
- the third control unit for the sequence of inclusion in the operation of the system nodes;
- the spent chambers (1) communicate with the aquifer (7) and serve as containers for storing water supplied to the ejector unit (18) for forming a three-phase curtain (31) over explosions with dust and gas emissions and (or) delivering a three-phase mixture to the ignition site. 2. The system of dust and gas suppression, ventilation and fire fighting during mining, large-scale explosions, open, underground, both endogenous and exogenous fires in hard-to-reach objects and large areas, characterized in that it contains:
- the first block, consisting of a mine field (a) with spent chambers (1) and mine workings, a quarry (b), an aquifer (7), a drainage complex (5), connected to a single system with access to open space (17 );
- at least one second block for forming a three-phase flow, mounted at the outlet into the open space and consisting of an ejector device (s) (18), which include a turbocompressor (22), a cryogenic installation (24), a pressure accumulator (26 ) connected to the chamber (25), at the output of which a Laval nozzle is mounted, - a pressure accumulator (29), having a rotary nozzle (49) at the output with a Laval nozzle (28);
- the third control unit and the sequence of inclusion in the operation of the system nodes;
- spent chambers (1) communicate with the aquifer (7) and serve as containers for storing water supplied to the ejector unit (18) to form a three-phase curtain (31) over the explosion, dust and gas emissions and (or) delivery of the three-phase mixture to the fire 3. The system according to claim 2, characterized in that the output of the second pressure accumulator (29) for forming a supersonic high-temperature gas stream is located above the exit of the cryogenic chamber (25), ensuring the position of the zone of the high-temperature gas stream above the zone of the low-temperature three-phase flow. 4. The system according to claims 1 and 2, characterized in that the mine field (a) has horizontal and vertical openings, through which lines are laid for transporting water from the aquifer (7) to the waste chambers, as well as lines for air supply, serving components of a multiphase working medium for dust and gas suppression and (or) fire extinguishing, and reagents are added to form a three-phase flow, the solid phase is formed by ice crystals, and the gaseous phase is formed by high-speed and low-temperature water-air crystalline Skim flows. 5. The system of claims. 1 and 2, characterized in that the mine field is connected with the quarry through mining, which are connected to a drainage complex and generators for the formation of three-phase flows,
including a turbocompressor, a cryogenic installation, gas-dynamic pressure accumulators and ejector devices for forming a supersonic three-phase flow, fine curtains, and the control unit contains sensors for monitoring the state of the air, mine atmosphere, quarry, fire, explosion. 6. The system of claims. 1 and 2, characterized in that the output of the working cavity of the turbocompressor (22) is connected with the initial zone of the cryogenic installation (24), equipped with a cryogenic chamber (25) made of at least a cylindrical, spiral shape made of durable heat-resistant material, and having a longitudinal length up to the exit from the cryogenic installation, and the chamber exit is equipped with a Laval nozzle to create a supersonic low-temperature gas stream, and the inlet of the cryogenic chamber (25) is connected to the first pressure accumulator (26) installed to axially cryogenic unit (24). 7. The system of claims. 1 and 2, characterized in that the pressure accumulators are made sectional like a revolving magazine and mounted with the possibility of stepwise rotation with stops, at least for the duration of the generation of the powder charge in one section of these accumulators. 8. The system of claims. 1 and 2, characterized in that the cryogenic chamber (25) is mounted with the possibility of step-by-step rotation with a stop at least for the duration of the generation of the powder charge in one of the sections of the pressure accumulator (26). 9. The system of claims. 1 and 2, characterized in that it has means (21, 23, 30) for supplying to the turbocharger (22) water from the exhaust chambers (1), polluted air from the exhausted space (23) and reagents that stimulate the formation of at least solid carbon dioxide silver iodide. 10. The method of dust and gas suppression, ventilation and fire extinguishing during mining, large-scale explosions, open, underground,
both endogenous and exogenous fires at inaccessible facilities and large areas, which consists in the following operations being carried out:
- form one low-temperature three-phase flow or
- form two streams, one low-temperature three-phase, the other gas high-temperature;
- a low-temperature flow or low-temperature and high-temperature flows are fed over the explosion with a dust-gas cloud or a fire at the same time, or with a time delay relative to the time of initiation of the explosion;
- the supply of the high-temperature gas stream is carried out over the low-temperature three-phase stream. 11. The method according to p. 10, characterized in that the air-crystalline stream at the outlet of the turbocompressor (22) is exposed to ultrasonic vibrations in the range of 10-1500 kHz, and N ₂ CO ₃ reagents are added to the water. Na ₂ SiO _2. 12. The method according to p. 10, characterized in that the water-crystalline stream at the outlet of the turbocompressor (22) is subjected to electric discharges or electromagnetic pulse processing from energy storage devices, such as capacitive or inductive storage, and when magnetic-magnetic processing induction magnetic fields are of the order of 0.5-1.5 T, pulse durations from 10 ^-2 -10 ^-8 s. 13. The method according to p. 10, characterized in that the water supply is brought closer to possible foci of ignition, explosion, dust and gas emission by supplying it from the aquifer to the waste chambers. 14. The method according to p. 10, characterized in that the water supplies bring closer to a possible source of ignition, explosion, dust and gas emission by feeding it from an aquifer into artificial or natural containers.

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