RU2407583C2 - Complex to recover gas-smoke emissions in constrained conditions - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to recovery of gas-smoke and dust emissions in constrained conditions of operating enterprise. Proposed complex comprises water sprinkler 35. Said water sprinkler is located either aside from gas duct lengthwise axis within the limits of production building or outside it and nearby waste-gas flue. Gas duct incorporates gas branch pipe 4 of lower level and shutter. Lower level gas branch pipe is fitted into gas duct at acute angle to lengthwise axis. Said shutter is arranged nearby said gas branch pipe on the side of waste-gas flue. Waste-gas flue 3 is arranged in pre-fabricated vertical slot in gas duct 2 parallel with fitted-in lower level gas duct. Water sprinkler gas collector 55 communicates via upper level gas duct 14 with existing gas duct at the height exceeding that of gas collector top pint, and is arranged at acute angle to its lengthwise axis, directly with waste gas flue 3 at acute angle to its vertical axis.

EFFECT: improved environmental protection, simplified design.

5 dwg

Description

The invention relates to ecology and can be used in metallurgical, energy and other industries for the disposal of gas and smoke emissions and dust in the cramped conditions of an existing enterprise.

A known method of purification of process gas from sulfur dioxide (patent No. 2214857, publ. 10.27.2003), which includes continuous counter-current stepwise contacting of gases with an aqueous lime pulp in absorbing apparatus-absorbers, and contacting is carried out in vortex scrubbers in a layer of finely dispersed pulp limestone with a gas residence time in the reactionary absorption zone of 0.001-0.005 s, limestone content in the pulp of not more than 60 g / dm ³ and a molecular ratio of SO ₂ and CaCO ₃ fed to the treatment for currents of gas and pulp, equal to 1-2. The disadvantages of this method include the complexity of the design, as well as the difficulty of construction in the cramped conditions of existing enterprises.

A device for cleaning hot gases is known, comprising a nozzle scrubber and a scrubber with an annular gap installed downstream of the gas flow, a long vertical saturation tube extending from top to bottom is installed in front of the nozzle scrubber, the scrubber with an annular gap is located in its lower part, the apparatus is equipped with two separators, installed sequentially after the scrubber with an annular gap (see RF patent No. 2091135, IPC 6 B01D 47/05, 47/06). The disadvantages of the known technical solutions are the complexity of the design and the difficulties of implementing the invention in the cramped conditions of an existing enterprise.

The invention is known "complex utilization of gas and smoke emissions" patent No. 2336934 publ. October 27, 2008. The gas-exhaust emissions disposal complex includes a gas-smoke pipe with a two-level gas duct, a gas collector, a reverse water supply pumping station with a pressure water conduit, and a slurry preparation unit. The lower duct in the end part is equipped with a nozzle with a C-shaped supercharging. The complex also contains a grid-type sprinkler on a welded metal case with three-sided casing and a pool for neutralization and wastewater treatment, divided into sections by internal transverse filter prisms. The proposed invention will allow for more complete utilization of sulfur dioxide and other water-soluble flue gas emissions and solid particles contained in them, using recycled water supply (prototype).

The disadvantages of the prototype include the complexity of its implementation in cramped conditions, when it is not possible to place a sprinkler installation along the longitudinal axis of the existing gas duct, as well as provide free access to the sprinkler installation of technological vehicles and self-propelled lifting mechanisms.

The technical result of the invention is to reduce the environmental load on the environment and simplify the design of the complex for the disposal of gas and smoke emissions and dust in the cramped conditions of an existing enterprise.

A complex of gas-and-gas emissions disposal in cramped conditions, including a pollution source, a gas-and-gas pipe with a gas duct constructed in two vertical levels, a grate-type sprinkler on a metal casing with three-sided casing with a catchment basin and a gas collector, a reverse water supply pool with a reverse water supply pumping station, and a system pressure and non-pressure water and air ducts with locking devices, while the lower duct in the end part is equipped with a nozzle with a C-shaped overhead alas, with an air duct and a nipple, it is distinguished by the fact that the sprinkler is located away from the longitudinal axis of the existing gas duct within the production building or outside it in the immediate vicinity of the smoke pipe, while the existing gas duct has a lower level gas outlet cut into it under a sharp angle to its longitudinal axis, as well as a shutter located close to the specified gas outlet from the side of the gas-flue pipe, installed in a pre-constructed vertical slot in the existing gas ode and parallel to the longitudinal axis of the incised lower level gas duct, and the sprinkler gas collector is connected to the upper level gas duct with the existing gas duct outside the damper at a height exceeding the height of the upper point of the sprinkler gas collector and at an acute angle to its longitudinal axis or directly with the exhaust pipe at an acute angle to its vertical axis.

The location of the sprinkler system away from the longitudinal axis of the existing gas duct or in the immediate vicinity of the gas and smoke pipe will allow reconstruction of any enterprise for the implementation of the complex, where there is at least a small section of the gas duct that allows you to embed the lower level duct and make a vertical gap under the damper. This arrangement of the sprinkler will allow unhindered access to it of technological transport and self-propelled lifting mechanisms. The implementation of the invention will allow to solve the problem of introducing the proposed complex in the cramped conditions of an existing enterprise, which will maximize the utilization of gas and smoke emissions and dust, while ensuring the possibility of free access of technological vehicles and self-propelled lifting devices. Inserting gas outlets and a vertical damper (hereinafter, the damper) at an acute angle will minimize the resistance of the gas stream when it comes into contact with the walls of the ducts and the damper, which will reduce dust loss in the ducts on the way to the sprinkler, which will improve conditions for maximum dust utilization, and this will to help reduce the environmental burden on the environment and simplify the design of the gas ducts of the proposed complex in the cramped conditions of an existing enterprise.

In general, the above significant distinguishing features will lead to the claimed technical result by increasing the amount of utilized gas and smoke emissions, dust and simplifying the design of the complex in the cramped conditions of reconstructed enterprises and, ultimately, reducing the environmental load on the environment.

The inventive step is proved as follows.

The location of the sprinkler installation away from the existing gas duct or near the gas-flue pipe will allow to carry out all the preparatory work for the construction of the proposed complex without stopping the main production. At present, as a rule, gas and dust collection is carried out in devices made at the base or at the upper end of the smoke pipe, in the proposed complex gas and smoke emissions are not disposed of in the chimney, which is new for existing enterprises - sources of environmental pollution natural environment.

Inserting newly constructed gas outlets and gates at an acute angle to the longitudinal axis of the existing gas duct is rarely encountered in practice, however, various types of gas outlets and pipe outlets cut into main pipelines, as a rule, at right angles or elbows, less often at an acute angle, are proposed According to the invention, the gas outlets and the damper are constructed at an acute angle to the longitudinal axis of the previously existing gas duct or the vertical axis of the gas flue pipe, which will significantly reduce energy consumption for the speed of movement flue gas stream with suspended particles towards sprinkler and the purified gas towards the flue gas pipe, which will also reduce clogging of the gas ducts and improve the operating conditions of the complex, i.e., performs a different function - the function of maximum utilization of not only gas and smoke emissions, but also dust, which means it will reduce the environmental load on the environment, and also helps to solve an important environmental problem when using TPPs and TPPs that run on solid or gaseous fuels, which allow the latter to compete with sources of atomic and other types of energy, corresponding, therefore, to the novelty and inventive step. In general, the above mentioned significant distinguishing features are distinguished by novelty and inventive step, which allow solving environmental problems of existing enterprises - sources of gas and smoke emissions, as well as solving an important national economic problem of involving enormous reserves of coal and gaseous hydrocarbons in the heat power industry. Of particular relevance, as mentioned above, is the introduction of such complexes at existing CHP plants operating on coal fuel, metallurgical and other enterprises. In general, the implementation of the invention will contribute to the improvement of the natural environment of many regions, with a slight reconstruction of existing enterprises. In this case, all preliminary preparation and basic construction work on the implementation of the invention is carried out without stopping production. A short stop is required only for the insertion of gas ducts, making gaps in the existing gas duct and sealing them.

The invention is illustrated by drawings:

figure 1 shows a diagram of existing facilities in the plan;

figure 2 shows a diagram of the objects in the implementation of the invention in plan;

figure 3 shows the block of the sprinkler in the context of the flues, gas collector, sprinkler lattice type, a catchment basin with a drain, ducts and air duct;

figure 4 shows a cross section of a sprinkler unit in the plane of the gas collector;

figure 5 shows a cross section of the nozzle of the duct of the lower level.

The invention is as follows.

First, a site is selected for the construction of the sprinkler unit 35, the insert points of the lower and upper levels of vents. Next, the construction of pile or metal supports for mounting the lower level gas outlet 4 with nozzle 5 in its wellhead, including a figured plate 6 (hereinafter referred to as the plate), bent in factory or workshop conditions from heat-resistant and chemically resistant material and rigidly fixed by welding ( not shown) in the mouth part of the nozzle 5 so that a C-shaped charge 7 is formed in the mouth part of the nozzle 5, and its side surfaces are welded to the inner side surfaces of the nozzle 5, and its back part is welded they are pressed to the top of the inner surface of the nozzle 5. Then, in the rear of the nozzle 5, at a distance of at least 100 mm from the weld of the rear of the plate 6 and the nozzle 5, the air nipple 8 is fixed to the pre-made hole by welding or carving, connected to duct (signed on the drawing) made of metal, polyvinyl chloride or other pipe materials with a diameter of at least 40 mm. Between the mouth surface of the plate 6 and the inner surface of the nozzle 5, heat-resistant and chemically resistant stiffening rods 9 are installed by welding (not shown) with a distance between them of up to 300 mm along the perimeter of the C-shaped pressurization 7. Then it is rigidly, by welding and metal rods ( not shown), nozzles 5 are attached to the housing 10, to its horizontal beam 11, with a slope of at least 0.001 towards the sprinkler 35. In this case, the end part of the nozzle 5 must be recessed under the working body 45 of the sprinkler 35 not less than twice Noe distance between adjacent nozzles 12 along the longitudinal axis of the sprinkler 35. Thus the nozzle 12 is rigidly on welding (not shown) mounted in a staggered lattice on the frame body 45 of the working sprinkler installation 35 consisting of a water-supply pipeline 13 high pressure. The working body 45 of the trellised type of the sprinkler 35 is manufactured in workshop conditions from water supply tubes 13 with a diameter of 1.5 inches, in the nodes of which nozzles (water outlets) 12 are placed (patent No. 1769401, publication date 02/20/1995 g) or a crevice nozzle (patent No. 2201807 publ. 04/10/2003) sprinklers, etc. devices well known in sprinkler machines used in agriculture to irrigate cultivated plants, or in spray plants used to cool hot water before dumping it into water bodies. In this case, the nozzles 12 equally spaced from each other on the water supply pipes 13 are installed so that the cone-shaped fan jets from the nozzles 12 overlap the similar jets of the nozzles 12 adjacent to them by at least 1/3. The width of the sprinkler 35 should be equal to twice the diameter of the end of the console part of the nozzle 5, and the length of the sides located along the longitudinal axis, triple the diameter of the end of the console part of the nozzle 5. The design of the working body 45 of the sprinkler 35 is made of chemical eski of resistant material, and the distance of the maximum overlap of the fan jets (shown in thin 3.4 in dashed lines) is selected in the workshop, pre-installing the design of the working body 45 of the sprinkler 35 on used metal or plastic barrels and connecting the water supply tubes 13 through hoses (not shown) to the factory pressure water supply network. The horizontal plane with a continuous water curtain will correspond to the excess of the working body 45 of the sprinkler 35 above the upper surface of the nozzle 5. This plane of the working body of the sprinkler 35 will also determine the height of the working body 45 over the metal housing 10 with its rigid attachment to the housing 10 using clamps or staples (not shown). Next, on the surface of the metal housing 10 of the sprinkler 35, a gas collector 55 is constructed, for which a top level gas outlet 14 is first cut over the sprinkler 35 into two parts in a horizontal plane. The length of the cut corresponds to the length of the sprinkler 35. The lower part of the cut of the gas outlet 14 of the upper level is cut and sent to scrap metal or used for the manufacture of small embedded plates. Cutting is carried out by welding or electrophoresis (grinder) (not shown). Then, on both sides, the side plates 15 and the end plate 16 of a chemically resistant metal (material) are welded by welding (not shown) to the longitudinal dome remaining above the sprinkler and the case 10 of the sprinkler 35. To seal the gas collector 55, the existing gaps by welding are sealed with small metal shaped plates by welding (not shown). After that, the three sides of the housing 10 from the inside or outside are sheathed with 0.2 mm thick sheet of acid-resistant material (for example, titanium) (not shown). At the same time, in the casing of one of the sides most convenient for the entrance and operation of a self-propelled load-lifting mechanism (not shown), shutters (not shown) that are tightly hinged are constructed to extract and maintain the working body 45 of the sprinkler 35. The entire installation of the gas collector 55 and the entire sprinkler unit 35 is carried out by welding using a crane (not shown). The top of the duct 14 of the upper level by 1 diameter of the duct 14 exceeds the height of the housing 10 of the sprinkler 35. Next, in the lower part of the housing 10 of the sprinkler 35, a drainage basin (signed) is constructed of acid-resistant concrete. To do this, first formwork (not shown) is made of used wood plank materials, for the construction of the outer layer 17 of concrete or reinforced concrete, a metal chemically resistant reinforcement (not shown) is installed and poured with concrete mortar. Then, after gaining strength, the stabilization acid-resistant polyethylene film 18 is laid in two layers along the inner area and its perimeter. Then, from the inside of the pool (signed), a formwork (not shown) is constructed for the construction of an acid-resistant inner layer 19 of reinforced concrete with acid-resistant reinforcement (not shown). At the same time, the volume of the catchment basin (signed on the drawing) should exceed the unit flow rate of the sprinkler not less than 100 times. The water flow rate of the sprinkler 35 is calculated taking into account the solubility and flow rate of gas and smoke emissions and the volumes of utilized dust. For example, the solubility of sulfur dioxide is 40 l / 1 l of water. Considering the fact that the width of the working element 45 of the trellised type of the sprinkler 35 is increased 2 times, and the length is three times compared with the diameter of the end part of the nozzle 5, the flow rate for sprinkling can be increased 2 times. The consumption of gas and smoke emissions is calculated for each specific gas and smoke pipe 3 separately and taking into account the solubility in water of the utilized gas and smoke emissions and the amount of dust particles. For example, the consumption of flue gas emissions from sulfur dioxide is 4000 l / s. Then the water flow rate of the sprinkler will accordingly be equal to: 4000 l / s / 40 * 2 = 200 l / s, i.e. 0.2 m ³ / s. As a result, the catchment basin (signed on the drawing), with a hundred-fold reserve, should have a volume of at least 20 m ³ . During the construction of the catchment basin (signed in the drawing), a drainage pipe 20 is arranged in one of its walls. In this case, the bottom of the catchment basin (signed in the drawing) should have a slope towards the open side of the housing 10 in order to accumulate sludge. After the construction of the catchment basin (signed) and the gas collector 55, a top-level gas outlet (s) 14 are constructed by welding on supports (not shown) at an acute angle (preferably 20 °) to the axis of the previously existing gas duct 2 or to the vertical axis of the gas-exhaust pipe 3 (shown in dashed lines in FIG. 2).

Next, close to the incised and fixed gas outlet 4 of the lower level in the gas duct 2, from the side of the gas pipe 3, a slit 21 is made up to 5 mm wide, for example, using a laser beam or other method, under the shutter 22. In this case, the gap is constructed at an acute angle to the longitudinal axis of the duct 2, coinciding with the insertion angle of the exhaust 4 into the duct 2, preferably equal to 20 °. All components, parts and fragments of gas outlets 4, 14, gas collector 55, working body 45 of the sprinkler 35, except for the drainage basin (signed on the drawing) and the reverse water supply basin (not shown), are made in the factory or workshop conditions from heat-resistant and chemically resistant materials. To the installation site, the assembly units, parts and fragments of the gas outlets 4, 14 and the sprinkler 35 are delivered by any available overall ground transport. At the same time, a reverse water supply pool (not shown) is being constructed by construction methods and methods well known in hydraulic engineering. If there is a reverse water supply pool at the enterprise, the latter type of work is not performed. Then, on town or other types of supports (not shown), gravity flows from the catchment basin (signed in the drawing) and high-pressure water conduits (signed in the drawing of Fig. 3) from the reverse water supply pumping station (NOV) (not shown). A pressure duct is connected (FIG. 3 is signed in the drawing) with shutoff valves (not shown) to the factory main duct or oxygen duct. During the reconstruction of existing enterprises, the height of the sprinkler unit is determined locally at the reconstructed object, but it should be lower than the insert of the upper level gas outlet 14 into the gas duct 2 or gas pipe 3 (shown in Fig. 2 by a dashed line).

A circulating water supply pump (NOV) (not shown) is usually selected depending on the required circulating water flow and, at low costs, it can be mobile pumping units of the type HGN 20 * 20 or 30 * 50 (not shown) suitable for working with aggressive liquid media. For significant circulating water costs, it is preferable to build a stationary NOV (not shown) that can work with aggressive liquid media. In each specific case, depending on the circulating water costs, the energy services of enterprises or design organizations independently select for the enterprise from a large number of existing and reliably proven NOVs in operation (not shown). In the presence of NOV in the existing pool of reverse water supply (not shown), this type of construction is not performed. Next to the NOV (not shown) connect the suction conduit (not shown) coming from the pool of reverse water supply (not shown). A reagent preparation unit with a clay mixer, a dispenser and a flow meter (optional solution) is built in an extension (not shown) to the NOV (not shown). If there is a clay mixer on a NOV (not shown), a metering mixer with a flow meter (not shown), this type of work is not performed. The air duct (signed), the nozzle 5 is connected to the nipple 8 and the pressure main duct (oxygen duct) (not shown) of the enterprise.

Connecting the nipple 8 to the duct (oxygen pipe) (signed in the drawing, Fig. 3), and the pressure pipe (signed in the drawing (Fig. 3)) to the high-pressure pipe from the NOV (not shown), conduct trial tests of the operation of the sprinkler system installation 35, for which they include in the work of the NOV (not shown), sprinkler and pressure duct (signed in the drawing, figure 3). These tests are carried out before inserting the gas outlets 4, 14 into the gas duct 2 or into the gas pipe 3 (shown in dashed lines in Fig. 2), as well as before constructing a slot 21 in the gas duct 2. After these tests of the operation of the sprinkler unit 35, the gas outlets 4 are inserted, 14 into the gas duct 2 or the latter into the gas-flue pipe 39 (shown in dashed lines in Fig. 2) and a gap 21 is constructed under the shutter 22 in the gas duct 2.

It should be noted that the insertion of the vents of the lower 4 and upper 14 levels, as well as the construction of the slit 21 and the installation of the damper 22 in the duct 2 is carried out when the source of pollution is stopped. According to the results of the above-mentioned tests of the systems of the sprinkler unit 35 when water is supplied to the working body 45 of the sprinkler 35 and air to the nozzles 5 through the air nipple 8 and the C-shaped pressurization 7, the commission of the enterprise draws up the act of readiness of the invention for work and gives the green light to the insertion of gas outlets 4, 14 and the construction of a gap 21 under the valve 22 in the duct 2 or insert the top level gas outlet 14 into the gas pipe 3.

After stopping the source of gas-flue emissions for several hours, insert and seal the flues 4, 14, and build a gap 21, and install the damper 22, followed by sealing with heat-resistant and chemically resistant sealants in the form of various pastes or mastics widely used in the practice of building high-temperature devices. The invention is ready to go.

The work of the invention is as follows.

A smoke exhaust (not shown), under pressure, a gas-smoke stream with suspended dust particles from a pollution source 1 is directed into a gas duct 2 and then along a valve 22 it enters a gas outlet 4 of a lower level and then to nozzles 5 (shown by horizontal and upward bent arrows in FIG. 3 ), at the same time, air or oxygen (azone) from the duct (signed), through the nipple 8, enters the mouth part of the nozzle 5 (shown by horizontal and upward curved arrows in figure 3) through a C-shaped charge 7, while along the contour gas-jet stream (on black the same arrows) will form a dense air shell of cold oxygen (air) (shown in the drawing with small arrows). Next, the gas-dust-air mixture under pressure falls under a continuous water curtain (Figs. 3, 4 are shown by fan-shaped downward arrows from nozzles 12) of the working body 45 of the sprinkler 35. When mixed with water, the gases dissolve and the resulting solutions together with suspended particles ( figure 3 shows the arrows down with an oval end) under the influence of gravitational forces fall into the catchment (signed on the drawing). In the presence of an appropriate catalyst in the form of ribbons, garlands, tows, threads, etc. forms (not shown) suspended on the tubes 13 of the working body 45 of the sprinkler 35 and located at the level of a continuous water curtain. An individual catalyst (not shown) is selected for each specific gas or a universal catalyst based on platinum materials is used. In this case, redox chemical reactions will take place in a water-gas-air medium with the dissolution of gases and the deposition of dust particles heavier due to moisture.

Thus, the gas-smoke mixture (shown in the drawing by arrows, Fig. 3), mixed with oxygen or air, falls under a continuous rain curtain of industrial water, usually containing lime or chalk, used to reduce the aggressive effects of these waters, on the walls of water pipelines, entering into a chemical reaction at a high temperature within the sprinkler, will turn sulfur dioxide into sulfur trioxide, sulfurous acid with the subsequent formation of sulfuric acid with an excess of water. Interacting with the carbonate component of the circulating water in the wastewater of the circulating water supply basin (not shown), a precipitate will form in the form of two-water gypsum (CaSO ₄ * 2H ₂ O). Gypsum in its composition contains: CaO - 32.5%; SO ₄ - 46.6%; H ₂ O - 20.9%.

Air, water vapor and part of the water-insoluble gases through the gas collector 55, the gas outlet 14 of the second level and the smoke pipe 3 will come under the action of the exhaust draft of the smoke pipe 3 into the atmosphere for dispersion. Acidic wastewater from the catchment basin (signed, Fig. 3.4) is fed by gravity or by means of an additional pump (not shown) for neutralization and treatment to a recycled water supply pool (not shown). In this case, acidic solutions will be partially diluted with purified water from a factory or city sewage treatment plant and atmospheric precipitation, and most products of the utilization of water-soluble gases will precipitate, because when acidic effluents enter the drainage basin, they will encounter geochemical, acid-base and temperature barriers. The remainder of the unreacted acids will enter into a chemical substitution or metasomatism reaction with the carbonate component of the wastewater in the reverse water supply basin.

The wastewater treated and neutralized according to the above scheme using NOV (signed in the drawing) through the pressure pipe (signed in FIG. 3) is again supplied to the working body 55 of the sprinkler 35 for further disposal of the exhaust gas and smoke emissions. As solid sediment accumulates in the catchment basin (signed, Figs. 3, 4), it is removed by a mud pump (e.g., a mud pump) or excavation mechanisms, well known in construction and mining, and transported for storage at tailing dumps or sludge collectors (not shown). During the winter period, snow is accumulated (stored) during the winter within the recycling water pool (not shown) (optional performance) to dilute the treated water with melt water, while the anti-icing solid material will fall into the above pool, without falling onto the terrain and into watercourses 9 (not shown), which in turn will reduce the environmental burden on the environment.

The present invention can be used for the disposal of sulfur dioxide, carbon and other water-soluble flue gas emissions, including with the use of currently known catalysts of domestic and foreign industry, as well as for dust deposition using recycled water supply in all areas of industry, and especially at TPPs, TPPs operating on solid carbon fuel. Moreover, with the introduction of the invention, the relevance of the construction of thermal power plants and thermal power plants on coal and peat will sharply increase under the conditions of a sharp decrease in the environmental load on the environment and will make healthy competition with atomic and other energy sources. The recession will stop in the coal industry, and the industry will begin its new ascent. The above-described complex for the disposal of gas and smoke emissions in cramped conditions does not have experimental experience. Work on the implementation of the invention can be controlled remotely. The implementation of the invention will allow for more complete utilization of gas and smoke emissions, while the invention involves the use of mainly recycled and industrial water from factory or urban wastewater treatment plants, which is no less important. In this case, a substantial reconstruction of existing enterprises is not required, with the exception of the reconstruction of the existing gas duct between the gas release source 1 and the gas exhaust pipe 3. The invention also lacks rotating mechanisms in an aggressive gas-water-air environment, except for a NOV (not shown) and a pump or excavation mechanism ( not shown) catchment basin (signed in the drawing). The implementation of the invention does not require huge capital expenditures and preparatory work for its implementation, because main blocks and embedded parts can be manufactured in a machine shop or factory and delivered to the site for installation on any type of bulky ground transport. The proposed complex with a good organization of preparatory work can be carried out within a few weeks or months. Also, at one factory site, drainage basins (signed on the drawing) of sprinklers 35 of several gas pipes 3 can be closed to one pool of reverse water supply (not shown). The implementation of the invention in existing production will improve the environmental situation not only in the territories of individual enterprises, but also in entire regions, countries and the planet as a whole. The reduction of flue gas emissions and dust during the implementation of the proposed invention will contribute to the implementation of the Kyoto Agreement, and the reduction of the payment for harmful emissions and the income from the sale of quotas for harmful emissions to other states will make its implementation highly profitable. This is especially true during a period of global warming.

Claims (1)

A complex of gas-and-gas emissions disposal in cramped conditions, including a pollution source, with a gas duct and gas outlets constructed at two vertical levels, a gas-smoke pipe, a grate-type sprinkler installed on a metal casing with three-sided cladding, a gas collector, a catchment basin with a water outlet and a revolving pool water supply with a reverse water supply pumping station containing a slurry preparation unit, a metering unit with a flowmeter and a pressure and non-pressure water supply system arguments with locking devices, while the lower duct in the end part is equipped with a nozzle with a corresponding pressurization attached to the sprinkler installation body, with an air duct and a nipple, characterized in that the sprinkler installation is located away from the longitudinal axis of the existing duct within the production building, or behind limits in the immediate vicinity of the chimney, while the existing gas duct is equipped with a low level gas outlet cut into it at an acute angle to the longitudinal axis, as well as a shutter, p adjacent to the specified gas outlet from the side of the gas-flue pipe installed in a pre-constructed vertical slot in the existing gas duct and parallel to the longitudinal axis of the low-level incised gas duct, and the sprinkler gas collector is connected to the upper level gas duct with the active gas duct at a height exceeding the height of the upper point of the sprinkler installation gas collector, and at an acute angle to its longitudinal axis, or directly with a gas pipe at an acute angle to its vertical axis.

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