RU2630465C1 - Deep pit ventilation device - Google Patents

Abstract

FIELD: mining engineering.

SUBSTANCE: device includes an elastic exhaust pipe with toroidal stiffness chambers located along its length and filled with light inert gas, electric heating elements with supporting frame, a heat exchanger made of shielding film. The device is equipped with vertical telescopic hollow shaft located in the elastic exhaust pipe, on which a wind wheel with curvilinear cavities and an impeller is fixed. In this case, the profile of the wing impeller lower surface and the profile of the curvilinear cavity upper surface of the wind wheel form, in the joint motion, a cavity in the form of a tapering rotation cone, which axis coincides with the telescopic hollow shaft axis. Between the impeller and the wind wheel in hollow shafts there are inlet windows and outlet windows provided at the turbine level, in addition, the device is provided further with thermal generator that consists of a ring-shaped body mounted above the upper toroidal stiffness chamber with internal surface constantly blown by ventilation air and a set of differential thermocouples. At that, the lower surface of the impeller wing and the upper surface of the wind wheel are covered with nano and glass-like tantalum oxide film obtained by the ion-plasma method.

EFFECT: reducing the intensity of corrosion destruction wing surfaces of the impeller and wind wheel.

5 dwg

Description

The invention relates to the mining industry, in particular to the tasks of ventilating deep quarries.

A device for ventilating deep pits is known (see RF patent No. 2143076 IPC E21F 1/00, published on December 20, 1999 Bull. No. 35), including an elastic exhaust pipe with toroidal stiffeners located along its length and filled with a light inert gas , a device for moving the device, electric heating elements with a support frame, an electric power plant in the form of a turbine and an engine generator, a heat exchanger made of a shielding film, in addition, is equipped with a vertical telescopic hollow shaft placed in an static chimney on which a wind wheel with curved cavities and an impeller is mounted, while the profile of the lower surface of the wing of the impeller and the profile of the upper surface of the curved cavity of the wind wheel form a cavity in the form of a tapering rotation cone, the axis of which coincides with the axis of the telescopic hollow shaft, the impeller and the wind wheel in the hollow shaft are made exhaust, and at the level of the turbine inlet windows are provided.

The disadvantage is the unproductive energy costs associated with the use of energy from electrical networks for emergency lighting at night and during fogs, while the presence of electrical wires stretched along the length of the elastic exhaust pipe, especially in the presence of atmospheric precipitation in the form of snow, rain or fog, can lead to to dampening of electric wires with the subsequent occurrence of emergency situations when performing mining operations.

A device is known for ventilating deep quarries (see RF patent for utility model No. 153647, IPC E21F 1/00, publ. 07.27.2015), including an elastic exhaust pipe with toroidal stiffeners located along its length and filled with a light inert gas, a device for moving the device, electric heating elements with a supporting frame, an electric power plant in the form of a turbine and an engine generator, a heat exchanger made of a shielding film, in addition, is equipped with a vertical telescopic hollow shaft, in an elastic exhaust pipe, on which a wind wheel with curved cavities and an impeller is mounted, while the profile of the lower surface of the wing of the impeller and the profile of the upper surface of the curved cavity of the wind wheel form a joint in the form of a tapering cone of rotation, the axis of which coincides with the axis of the telescopic hollow shaft, moreover, exhaust pipes are made between the impeller and the wind wheel in the hollow shaft, and inlet windows are provided at the turbine level, in addition, the device is additionally equipped with generator, which consists of a housing in the form of a ring mounted above the upper toroidal stiffness chamber with a constantly washed internal surface with ventilated air and a set of differential thermocouples, with the "hot" ends of the differential thermocouples mounted on the inner surface of the housing in the form of a ring, and the "cold" ends are located on its outer surface.

The disadvantage is the energy intensity during long-term operation, due to the need for unscheduled dismantling to replace the wind wheel and impeller due to the intensity of corrosion damage, as a result of cavitation effects of vaporizing bubbles of atmospheric and technological moisture, which adhere to the outer surfaces of the blades and wings, respectively.

The technical task of the invention is the maintenance of normalized energy consumption for ventilating deep pits during long-term operation with the presence of atmospheric and technological vapor and droplet moisture affecting the wind wheel and impeller located on the exhaust pipe by eliminating the buildup of steam bubbles formed on the outer surfaces, respectively, of the wind wheel blades and impeller wings.

The technical result is achieved by the fact that the device for ventilating deep pits includes an elastic exhaust pipe with toroidal stiffeners located along its length and filled with a light inert gas, a device for moving the device, electric heating elements with a support frame, an electric power plant in the form of a turbine and an engine generator , the heat exchanger made of a shielding film, in addition, is equipped with a vertical telescopic hollow shaft placed in an elastic exhaust pipe on which a wind wheel with curved cavities and an impeller is mounted, while the profile of the lower surface of the wing of the impeller and the profile of the upper surface of the curved cavity of the wind wheel form a joint in the form of a tapering cone of rotation, the axis of which coincides with the axis of the telescopic hollow shaft, between the impeller and exhaust wheels are made in the hollow shaft, and inlet windows are provided at the turbine level, in addition, the device is additionally equipped with a thermal generator, which consists of from the case in the form of a ring mounted above the upper toroidal stiffening chamber with a constantly washed inner surface with ventilated air and a set of differential thermocouples, the "hot" ends of the differential thermocouples mounted on the inner surface of the case in the form of a ring, and the "cold" ends are located on its outer surface while the lower surface of the wing of the impeller and the upper surface of the wind wheel are covered with a nano-shaped glass-like film of tantalum oxide obtained by ion-plasma method th.

In FIG. 1 shows a schematic diagram of a device for ventilating deep pits; FIG. 2 shows a tapering rotation cone as an element of a device for ventilating a medium; FIG. 3 - thermogenerator, in FIG. 4 - the lower surface of the wing of the impeller, covered with a nano-shaped glass-like film of tantalum oxide. In FIG. 5 - the upper surface of the curved blade of the wind wheel, covered with a nano-shaped glass-like film of tantalum oxide.

A device for ventilating deep pits contains a chimney 1 with toroidal chambers 2 located along its length and filled with a light inert gas, a power plant 3 made in the form of an engine generator 4 and turbine 5, distribution unit 6, as well as electric heating elements 7, mounted on prefabricated support frame 8, a vertical telescopic hollow shaft 9, on which a wind wheel 10 with curved cavities 11 and an impeller 12 is mounted. In the device for moving the device in the form of a self-propelled chassis 13 pos COROLLARY tie 14 is fastened shaped segment 15 associated with the cable system shading film 16 heat exchanger is rigidly fastened to the toroidal chamber 2 the exhaust pipe 1. In this case, the toroidal chamber 17, located at the base of the exhaust pipe 1 is mounted coaxially to the turbine 5 and is provided with a pressure valve 18. And the last stiffening chamber 19 has an emergency valve 20 and tension cables 21 with fixing rings 22. A support frame 8 with heating elements 7 is placed inside the chamber 12. A vertical telescopic hollow shaft 9 is placed in an elastic exhaust pipe 1 and fixed to its base (not shown) to self-propelled chassis 9 and has inlet windows 23 at the level of the turbine 5, and the outlet windows 24 are located between the impeller 12 and the wind wheel 10, while the profile of the lower surface 25 of the wing of the impeller 12 and the profile of the upper surface 26 of the curved blade 11 of the wind okoles 10 are made arcuate, i.e. so that they create a joint circular motion of the cavity 27 in the form of a tapering cone of rotation, the axis of which coincides with the axis of the telescopic hollow shaft 9.

The device for ventilating deep pits is additionally equipped with a thermogenerator 28, which consists of a ring-shaped housing 29 mounted over a toroidal stiffness chamber 19 with constantly ventilated internal surface 30 and a set of differential thermocouples 31 mounted on the inner 30 of the surface of the housing 29 in the form of a ring, and the cold 33 ends are located on its outer surface 34, i.e. in contact with ambient air. The lower surface 25 of the wing of the impeller 12 and the upper surface 26 of the wind wheel 10 are covered with a nano-shaped glass-like film, 35 and 36, respectively.

The device operates as follows. The specifics of the mining industry, especially in deep quarries, is due to the presence of a high concentration of polluting solid particles in the environment, which, along with droplet-like particles of atmospheric and technological moisture, are the nuclei of condensation of water vapor, which sticks in the form of steam bubbles on the outer surface of the wing of the impeller 12, and the wind wheel 10, which leads to their corrosion failure.

Moreover, the adhesion of vapor bubbles on the lower surface 25 of the wing of the impeller 12 and on the upper surface 26 of the curved strip 11 of the wind wheel 10 leads to an intensification of their corrosion damage.

This is due to the fact that a rarefaction zone is formed around the wind wheel 10 in the process of joint rotation with the impeller 12, and here the pressure sharply decreases in the place of “collapse” of steam bubbles. As a result, cavitation destruction is observed (see, for example, p. 38. Popov VM, Drainage plants. / Reference manual - M .: Nedra. 1990-254s., Silt) of the material of the wind wheel 10 and the impeller 12, which requires subsequent unscheduled repairs and, as a consequence, an increase in the energy intensity of the operation of the device for ventilating deep quarries.

When covering the lower surface 25 of the wing of the impeller 12 and the upper surface 26 of the wind wheel 10 with a nano-shaped glass-like film, 35 and 36, respectively, the formed vapor bubbles glide without enlargement and “collapse” (see, for example, Litvinova V.A., Savruk E.N. Nanoscale films of tantalum oxide obtained by the ion-plasma method // Proceedings of the regional scientific-practical conference "Modern problems and achievements of agricultural science in animal husbandry, crop production and the economy." -Tomsk: TSCH NGAU-Issue 12-2010, p. 299- 301) and discharges anija the environment. Therefore, the elimination of the conditions for the formation of cavitation destruction of the material of the wind wheel 10 and the impeller 12 leads to the appearance of the reliability of the device.

The heated ventilated air moves through the elastic exhaust pipe 1 before being discharged into the environment, washes the inner surface 30 of the housing 29 in the form of a ring, and contacts the “hot” 32 ends of the differential thermocouples 31. At the same time, the “cold” 33 ends of the differential thermocouples 31 are converted with the cold air of the surrounding environment, as a result, when using chromel drops as thermocouples, for example, thermoelectric power up to 6.96 mV appears (see, for example, Ivanov G.M. Thermotechnical measurements and instruments. M .: Energoatomizdat, 1984 - 230 p. Il). This allows you to get the voltage at the output of the thermoelectric generator 28 within 12-36 V (see, for example, Technical fundamentals of heat engineering. Thermotechnical experiment. Handbook / under the general editorship of VM Zorin. M: Energoatomizdat, 1980 - 560 S., il), which is quite enough for emergency lighting devices for ventilating deep quarries at night or in the presence of fog. As a result, energy-saving operation of the device for ventilating deep pits is ensured by eliminating the need to use power supply for emergency lighting from electrical networks. In addition, under conditions of fog formation, the likelihood of moistening the electric wires stretched along the length of the elastic exhaust pipe increases, all this is eliminated with the help of a thermoenergy generator that uses the heat of ventilating air to produce electric energy.

The device is delivered to the quarry area in need of ventilation, and mounted in it. The start-up and operation of the installation in the “Airing” mode is as follows. Through the pressure valve 18, compressed air fills the toroidal chamber 17 located at the base of the pipe 1 to the dimensions selected for the operating mode. An inert gas is fed into the chimney 1, filling the stiffening chambers 2, thereby bringing the chimney 1 to a vertical working position. At the same time, the hollow shaft 9 telescopically extends, lifting the wind wheel 10 and the impeller 12 in synchronization with the exhaust pipe 1. From the external power supply network, distribution point 6 includes electric heating elements 7 and the electric power plant 3 engine 4, which drives the turbine 5, which moves the air flow through the exhaust pipe from bottom to top . Part of the ventilated air at the level of the turbine 5 enters the inlet windows 23 of the hollow telescopic shaft 9, and it moves inside the shaft 9, after which it is ejected through the outlet windows 24 into the cavity 27, which is made in the form of a tapering cone of rotation. As a result of the movement of part of the ventilated air flow along the tapering cone 27, its speed changes and a speed difference is observed between the bulk of the ventilated air exiting the exhaust pipe 1 and part of the vented air exiting the cavity 27. This leads to the formation of a rarefaction zone around the wind wheel 10 , which ultimately helps to increase the speed of the ventilated air stream moving through the exhaust pipe 1. Upon reaching a constant flow of ventilated air scab over the entire height of the exhaust pipe 1, i.e. when the stationary mode of motion sets in, the turbine 5 is turned off and the valve 18 of the toroidal chamber 17 is opened. The air pressure in the toroidal chamber 17 drops, its walls are closed by the lifting force, providing a maximum inlet width at the level of the turbine 5. As the air warms up naturally under the screen film 16 from solar energy on the distribution point 6 sequentially automatically turn off the heaters, after which the installation operates in standalone mode (using the energy generated by rotating with 10 wind wheels, solar energy and, depending on the climatic zones, geothermal heat) for ventilation. The connection of the wind wheel 10 with an electric power plant 3 (not shown) allows the energy generated by the wind wheel 10 to be accumulated and used, for example, for light contouring of a device for ventilation at night or in conditions of poor visibility, and also partially as a cover for energy consumption for the production of compressed air or pumping drainage water from a quarry, etc.

The originality of the invention consists in maintaining normalized energy consumption during long-term operation by eliminating unscheduled repairs of the wind wheel and the impeller caused by intensive corrosion damage, by coating the lower surface of the wing of the impeller and the upper surface of the wind wheel with a nano-shaped glass-like film made of tantalum oxide by the ion-plasma method.

Claims (1)

A device for ventilating deep pits containing an elastic exhaust pipe with toroidal stiffening chambers located along its length and filled with a light inert gas, a device for moving the device, electric heating elements with a support frame, an electric power plant in the form of a turbine and an engine generator, a heat exchanger made of the shielding film, in addition, is equipped with a vertical telescopic hollow shaft, placed in an elastic exhaust pipe, on which a wind wheel with cr with curved cavities and an impeller, while the profile of the lower surface of the wing of the impeller and the profile of the upper surface of the curved cavity of the wind wheel form a cavity in the form of a tapering cone of rotation, the axis of which coincides with the axis of the telescopic hollow shaft, and the exhaust shaft is made between the impeller and the wind wheel in the hollow shaft and at the turbine level inlet windows are provided, the device being further provided with a thermal generator, which consists of a housing in the form of a ring mounted above an upper toroidal stiffening chamber with constantly washed internal surface with ventilated air and a set of differential thermocouples, moreover, the "hot" ends of differential thermocouples are mounted on the inner surface of the body in the form of a ring, and the "cold" ends are located on its outer surface, while the lower surface of the impeller wing and the upper surface of the wind wheel is covered with a nano-shaped glass-like film of tantalum oxide obtained by the ion-plasma method.

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