RU2359011C1 - Method of solid fuel conversion and installation to this end (versions) - Google Patents

Abstract

FIELD: production processes.

SUBSTANCE: proposed method comprises feeding the crushed solid fuel and oxidiser into converter, firing and converting fuel mix, followed by removing the conversion gas products, combustion products and solid remnant from the converter. Fuel mix combustion and conversion are carried out in different intercommunicating converter chambers. Note here that fuel is fed into combustion chamber, for firing and combustion, mixed with oxidiser. Note also that the fuel mix is combusted in vortex flow formed in the combustion chamber. Note further that the conversion is realised in the combustion chamber due to interaction of solid fuel particles directed flow coming from the combustion chamber into that of conversion along with a counter flow of oxidiser fed into the converter gasification chamber. The proposed installation comprises converter, device to feed fuel mix into converter, fuel firing device, device to withdraw the conversion gas products, combustion products and solid remnant. The converter accommodates intercommunicating fuel mix combustion chamber housing fuel mix flow swirler and accommodating fuel mix firing and feeding devices mounted on the said chamber. It also comprises solid fuel conversion chamber furnished with additional device designed to feed oxidiser therein. Note that the device designed to withdraw combustion products from the converter incorporates adjustable gate element, while that designed to withdraw the conversion gas products and solid remnant includes adjustable gate elements.

EFFECT: method perfection.

9 cl, 4 ex, 3 dwg

Description

The group of inventions relates to methods and means of processing solid fuel into combustible gas and can be used for the conversion (gasification) of solid combustible substances such as coal, coke, shale, rubber, combustible materials of plant and animal origin, solid municipal waste. The target products obtained from the conversion of solid combustible substances can be used as fuel for internal combustion engines, to generate heat and electricity, liquid motor fuels and useful chemical products.

There is a method of gasification of solid fuel, for example coal, according to which solid lump fuel and gasification reagents are fed into the gasifier cavity with the formation of volatile gases discharged from the upper part of the gasifier and solid fractions removed from its lower part, and the process of gasification of solid fuel in the gasifier is carried out by its interaction with gaseous fuel, moreover, after gasification of solid fuel, solid fractions are precipitated from the gas component and removed from the gasifier (see RF patent 2084493, cl. C10J 3/14, 1997).

As a result of the analysis of the known method, it should be noted that it is characterized by low productivity, a high percentage of underburning of carbon, low calorific value of the resulting combustible gas and its high contamination with resins.

A known method of processing municipal solid waste by pyrolysis and gasification of the organic component of the waste, which is mixed with pieces of solid non-combustible and non-consumable materials and loaded into the reactor, which also serves an oxygen-containing gasifying agent, and gasification is carried out by the sequential stay of raw materials in the heating, drying, pyrolysis, combustion (oxidation) and the cooling zone, and the maximum temperature in the reactor is maintained within 800-1300 degrees by adjusting at least one a parameter selected, for example, from the mass fraction of oxygen in the gasifying agent or the mass fraction of combustible or non-combustible material in the charge, moreover, as a gasifying agent, a mixture of flue gas, air and water vapor released during the drying of raw materials is used (see RF patent No. 2150045, C. F23G 5/027, 2000).

As a result of the analysis of this method of processing municipal solid waste, it should be noted that it provides the processing of municipal solid waste with the production of combustible gas, which can be burned directly in the boiler or sent to consumers, or processed using known technologies. Flue gases generated during the processing of raw materials can be supplied to the zone of processing of raw materials as a gasifying agent. Thus, the known method provides a process for processing raw materials without supplying heat from outside, since the energy necessary to maintain the combustion process is generated by burning the combustible portion of the utilized waste, and the introduction of water vapor into the gasification agent avoids additional energy costs. However, this method is characterized by low productivity, low calorific value and high clogging of the resulting combustible gas, as well as high costs due to the need to ensure a constant flow through the gasifier of inert bulk materials.

There is a method of oxygen-free gasification of coal, according to which crushed coal is fed to the gas generator from above for combustion, and water vapor is fed from below. A pipe for discharging gasification products is inserted along the axis of the retort with a fluidized bed. The air necessary to ensure the autothermal process is supplied to the upper part of the fluidized bed and the products of coal combustion are taken from here. Ash residue is removed from the bottom of the gas generator. Thus, the known method provides a separate outlet of the target product and combustion products (see article AMDubinina and OM Panova “Oxygen-free steam coal gasification as a means of fuel economy.” Journal of Heat, No. 4, 1997, p. 51 -53) is the closest analogue (for the method).

This method is inefficient, has a high percentage of underburning coal, low specific yield of combustible gas.

A device for the gasification of solid fuels, such as coal, is known to produce a mixture of various gases, including a pressure vessel with which a solid fuel supply source, gaseous fuel pipelines, gasifying reagents and volatile gases are connected, and an opening for ejecting solid fractions by means of an installed in a vessel of a rotating lattice (RF patent No. 2084493, class C10J 13/14 1997). A tubular pyrolyzer is installed inside the pressure vessel, in which gaseous and solid fuels interact. This installation is very complex structurally, costly to manufacture and operate and does not provide a high coefficient of useful conversion of solid fuel energy into combustible gas energy.

A known installation for gasification of solid fuel, in which the gasification chamber inside additionally contains an annular transport channel, inside which is located the fuel supply screw. Fuel moves through the transport channel, where it is pre-dried, heated, and then gets into the gasification chamber (RF patent, No. 2307864, class C10J 3/20, C10J 3/30, 2007). This installation is inefficient, its operation is associated with a large underburning of fuel, high clogging and low heat of combustion of combustible gas.

A known installation for the processing of combustible solid household waste (fuel) into combustible gas based on super-adiabatic heating, including a chamber for gasification of raw materials by moving it sequentially in the working gasification zones, containing a grate, located at the bottom of the chamber, tuyeres for supplying a gasifying agent containing oxygen, an outlet for discharging product gas; an ash pan for collecting the residue with an outlet for discharging it. The installation also contains transport chains located outside the gasification chamber for loading the raw materials into the chamber from above and unloading the remainder from the ash pan (RF patent, No. 2150045, class F23G 5/027. 1998). This installation is very complex, inefficient, costly to manufacture and operate.

A known installation of oxygen-free steam gasification of coal in a fluidized bed gas generator ("Heat" No. 4, 1997, S. 51-53). In the gas generator, on top there is a means for supplying crushed coal with fractions up to 5 mm in size to the combustion chamber, on the bottom there is a water vapor supply device and air supply means for ensuring the process autothermality. A pipe is vertically inserted along the axis of the casing in the gasifier to discharge gasification products, the lower end of which is included in the steam gasification zone, and coal combustion products are discharged from the gasifier through a tap in the upper part of the gasifier casing. Ash is discharged at the bottom of the gas generator. The installation also includes a pressure control device in the combustion zones and steam gasification. The heat released during the combustion of fuel is transferred to the volume of the fluidized bed by circulation of particles. In this process, the circulation of burning particles and gases in the gas generator body occurs randomly and this leads to a large entrainment of unburned coal particles and gasification products with combustion products removed from the gas generator, significant clogging of the generator gas with combustion products and solid particles. These factors lead to a low yield of gasification products and a low coefficient of useful conversion of fuel energy into energy of the generator gas, as well as significant clogging of gasification products with ballast gases and ash particles from combustible fuel. This installation is accepted as the closest analogue for installation options.

The objective of this group of inventions is to develop a method and installation for the conversion of solid fuel into combustible gas, which would increase the relative yield of combustible gas, reduce the clogging of combustible gas by combustion products, reduce the loss of combustible gas with combustion products, and reduce losses in the form of unburned fuel with combustion products and as a result, increase the coefficient of useful conversion of fuel energy into energy of combustible gas.

The task is ensured by the fact that the installation converter is divided into a combustion chamber located in its upper part, where fuel and oxidizer are supplied, and a gasification (conversion) chamber, which is located in the lower part of the converter. The chamber data is communicated with each other by a channel for passing solid combustion products from the combustion chamber to the conversion chamber.

During the operation of the installation (implementation of the method), a separate output from the converter of gaseous products of combustion and gasification, each in its own channel through the shutter devices, can be carried out.

Conversion ash products are discharged through a sealing device, which is adjacent to the outlet channel at the bottom of the converter.

The implementation of the combustion chamber provides for the supply of a mixture of fuel and an oxidizing agent (fuel mixture) under pressure and giving this mixture a swirling motion in the combustion chamber. In this case, the gaseous products of combustion are concentrated in the central part of the vortex, rise up and out of the converter housing through the channel and the damper in the upper part of the combustion chamber, and the solid combustion products are concentrated in the peripheral part of the vortex, are lowered and taken down into the conversion chamber into which the oxidizing agent is fed . Steam, oxygen, air, etc. can be used as an oxidizing agent. Solidification of gas is carried out in the conversion chamber to produce combustible generator gas as a product.

In the second embodiment, during the passage of solid products from the combustion chamber to the conversion chamber, the combustion products are separated into solid and gaseous ones, while the gaseous products are removed from the converter housing through the channel through the shutter device.

An additional technical result is the organization of increasing the heat transfer of the combustion gas products to the conversion chamber by passing the separated combustion gas products through the space between the converter housing and the casing, which limits the conversion chamber along the side surface and transfers heat from the combustion gas products to the conversion chamber medium, as well as the possibility of production steam in a superheater located in the space between the converter housing and the housing of the thermal casing. In this case, water is supplied externally to the superheater and it can have steam exits to the gasification chamber, which allows steam gasification of the fuel heated in the combustion chamber in the conversion chamber.

It is easy to notice that in the claimed method and installations for the conversion of solid fuel, the processes of heat production are separated by combustion in a vortex fuel stream with an oxidizing agent in the combustion chamber and the conversion of unburned products, for example, with steam in the conversion chamber, and in this case, separate movement of the gas stream can be organized combustion products beyond the converter from the movement of the flow of solid combustion products, which is organized in the conversion chamber. In addition, a separate flow of combustible gas from the conversion chamber outside the converter housing can be arranged. In this case, the optimum ratio of the volumes and pressure of the release of gas combustion products from the combustion chamber and the gas conversion products from the conversion chamber is automatically maintained due to a change in the resistance of the gates at the outlets of gas products from the converter housing. Fuel is supplied to the combustion chamber in the form of a stream of a mixture of oxidizing agent and fuel under pressure in the range from 0.11 to 16 MPa, and vortex movement is given to this stream in the combustion chamber. In this case, solid particles of fuel in the stream can have sizes up to 10 mm. In the gasification chamber, unburned and hot fuel particles are either gasified by contact with the oxidizing agent or pyrolyzed without contact with the oxidizing agent. In this case, the oxidizing agent is fed into the conversion chamber under pressure in the range from 0.11 to 16 MPa and with a temperature in the range from 10 ° C to 560 ° C. The swirling flow in the combustion chamber allows the separation of solid and gas combustion products in the combustion chamber with their separate release: solid products into the conversion chamber, gas products through the shutter device outside the combustion chamber. The possibility of using small fuel and a more intense combustion process can reduce the weight and size of the converter and make fuller use of carbon fuel.

In the second version of the installation, during its operation, solid and gas combustion products are separated during the passage of solid products from the combustion chamber to the conversion chamber, while the gaseous combustion products are removed from the converter housing through a channel through a shutter device.

It is advisable that the oxidizing agent supplied to the combustion chamber be preheated due to the heat of the combustion gas products and / or the heat of the conversion combustible gas and / or the heat of the ash residues removed from the converter, and it is also advisable that the steam is generated from the heat of the resulting combustible gas and / or the heat of the combustion gas products and / or the heat of the ash residues removed from the converter.

It is advisable, when implementing the method, to supply the catalyst to the gasification and / or combustion chambers to intensify the processes.

It is advisable to introduce a mixture of fuel and an oxidizing agent into the combustion chamber at several points for better distribution and turbulence of the air-fuel mixture in the combustion chamber.

It is advisable to introduce the oxidizing agent into the conversion chamber from several points from the bottom up to better mix the oxidizing agent with solid particles or introduce plasma.

It is advisable to carry out the afterburning of gaseous products of combustion due to a separate supply of oxidizing agent.

When conducting patent research from the prior art, no solutions were identified that are identical to the claimed group of inventions, and therefore, the claimed group of inventions meets the eligibility condition “novelty”.

The essence of the claimed group of inventions does not follow explicitly from the solutions known from the prior art, and therefore, the claimed group of inventions meets the eligibility condition "inventive step".

The information set forth in the application materials is sufficient for the practical implementation of the group of inventions.

The essence of the claimed group of inventions is illustrated by graphic materials on which:

figure 1 - installation for the conversion of solid fuel, the first option;

figure 2 - installation for the conversion of solid fuel, the second option;

figure 3 - installation with a superheater.

The installation for the conversion of solid fuel (Fig. 1) contains a converter 1 with a lined inner surface, in the upper part of the converter a vortex combustion chamber 2 is formed, in which a swirler 3 is placed. A device 4 for supplying the fuel mixture (fuel mixture with oxidizer) is mounted on converter 1 into the chamber 2 and the device 5 of ignition supplied to the chamber 2 of the fuel mixture. The device 5 can be made in the form of a liquid fuel or gas fuel burner. A plasma device can also be used to ignite. These devices are known and there is no need for a detailed description thereof.

In the lower part of the converter 1 there is a conversion chamber 6 on which a device 7 for supplying an oxidizer (for example, steam or air) to the converter is installed.

Converter chambers are interconnected via channel 8 for bypassing solid combustion products.

On the converter, for example on camera 2, a device 9 for the removal of combustion products with an adjustable shutter element (flap) 10 is installed.

On the converter, for example in the upper part of the conversion chamber, there is installed a device 11 for withdrawing gas products of gasification with an adjustable shutter element (shutter) 12.

In the lower part of the conversion chamber there is a device for removing solid residue, which can be made in the form of a screw 13 with its rotation drive 14.

The shutter elements 10 and 12 are equipped with mechanisms for their movement (respectively 15 and 16), which are controlled by the control unit 17.

The installation for the conversion of solid fuel according to the second embodiment (FIG. 2) is characterized in that it is equipped with a separator 18 for separating solid and gas combustion products, located at the outlet of the chamber 2 in the channel 8. The device for the exit of combustion products can be placed in this embodiment in top of the converter. It can be connected by a channel (not shown) to the cavity of the conversion chamber.

Each of the installation options can be equipped with a casing 19, placed in the conversion chamber (figure 3). A superheater 20 can be placed between the casing and the chamber wall, the inlet of which through the pipe 21 is connected to the water supply line, and the outlet 22 to the cavity of the conversion chamber. The steam obtained in the superheater is used as an oxidizing agent supplied to the gasification chamber. Water is heated by heat transfer by combustion gas products passing between the casing and the wall of the conversion chamber. A plasmatron 23 can be mounted on the converter to supply plasma to the conversion chamber.

The implementation of the control unit, components and assemblies of the installation, the design of which is not disclosed in this application, is known and does not constitute the subject of patent protection.

The claimed method can be fully implemented by installations according to the first and second options.

The claimed method is implemented during operation of the installation as follows.

During operation of the installation, a mixture of ground fuel and an oxidizer (fuel mixture), which is ignited by the ignition device 5, is supplied to the swirler 3 in the combustion chamber 2 by the device 4. The ratio of oxidizing agent and solid fuel is selected so that a temperature of 800-1400 ° C is created and maintained in the vortex combustion chamber and at the same time the maximum possible amount of carbon remains in the solid combustion products. This optimal ratio of solid fuel and oxidizing agent depends on the properties and temperature of the fuel, properties and temperature of the oxidizing agent and is calculated on the basis of specific parameters of the fuel and oxidizing agent. For example, in the presence of Kuznetsk coal with a calorific value of 26 MJ / kg, a yield of volatiles of 38 wt.%, A moisture content of 12 wt.%, An ash content of 10 wt.%, A particle size distribution of coal up to 5 mm, an air temperature of 20 ° C, which is used as an oxidizing agent, the optimal ratio of fuel and air is in the range from 1: 1.4 to 1: 2. After creating in the combustion chamber a stable process of vortex combustion and the required temperature, the ignition device 5 is turned off and the supply of an oxidizing agent, for example steam, from the device 7 to the conversion chamber is turned on. The oxidizing agent is supplied either through the distribution grid (not shown) from the bottom up with the aim of creating an upward or upward and swirling steam flow in the chamber, which, with a downward flow of solid particles from chamber 2, increases the residence time of solid particles in the conversion chamber and the conversion (gasification) rate, or the oxidizing agent is fed tangentially to create a vortex flow that increases the conversion rate. The hot solid particles from the chamber 2 through the channel 8 under their own weight enter the gasification chamber, where when they meet with the vapor, gasification of the unburned carbon contained in the solid particles takes place. Upon receipt of the flow of combustion products in the form of solid particles from the chamber 2 into the channel 8, the gas part of the combustion products from the central part of the vortex is directed upward, then into the channel of the gas products of combustion 7 and then through the shutter device 9 and the open shutter 10, the gases are sent for cleaning, afterburning and further use, for example, for heating the air supplied as part of the air-fuel mixture. The ingress of gas combustion products into the conversion chamber is excluded not only due to the reduced pressure in the center of the vortex, but also due to the back pressure of the combustible gas conversion products from the conversion chamber. Solid combustion products overcome the specified back pressure due to its own weight and increased pressure at the periphery of the vortex and through channel 8 enter the conversion chamber 6. The combustible gases obtained in the chamber 6 due to the back pressure of the combustion products enter the gas channel 11 and then pass through the shutter device 12 for further use. When the shutter 10 is closed, partially or completely, the gas combustion products together with the solid products can partially or completely enter the conversion chamber, from where, together with the conversion gas products, they are discharged from the converter through the shutter device and the shutter for further use. The solid gasification residue (ash) flows under the influence of its own weight to the screw device 13 for the extraction of ash from the converter with the drive 14, in which the sealing is carried out by ash plugs. Given that the pressure in chambers 2 and 6 determines the necessary direction of movement of the gas flows of the products of combustion and conversion, the actuators 15 and 16 of the locking elements 10 and 12 are controlled by a custom control unit 17. To increase the intensity and quality of the processes in the combustion and conversion chambers, they can be supplied together with the fuel and / or oxidizing agent, the corresponding catalysts or plasma are the plasmatron 23. In addition, an oxidized gas-based plasma can be supplied to the combustion chamber to increase the intensity and completeness of combustion of the feed For example, steam (paroplasm).

During operation of the installation according to the second embodiment, the combustion gas products from the chamber 2 through the separator 18 enter the channel 8 and then through the shutter device for further use, for example, cleaning, afterburning, steam production, etc., the combustion gas products are sent to the separator 18 under the action of backpressure of gas products of gasification, and solid combustion products overcome the back pressure of gas conversion products due to their own weight and enter through the channel 8 into the conversion chamber 6. In the chamber 6 through the feeding device 7 an oxidizing agent is given for the conversion of the heated solid fuel coming from chamber 2. With a closed shutter for the release of gas combustion products, the latter, together with the solid conversion products, pass through channel 8 to the conversion chamber, from where they are transferred from the converter for further use together with the combustion products. The ash from the conversion and combustion of solid fuel under the influence of its own weight is fed to the screw device 13 for issuing ash from the converter with the drive 14, in which it is sealed by ash plugs.

If there is a casing 19 and a superheater 20 installed in the chamber 6 in the installation structure (for two variants) (Fig. 3), the gases passing through the gap between the casing and the chamber wall heat the water to a state of steam, which is supplied to the chamber 6 as oxidizer, and additionally heat the chamber 6.

The essence of the claimed group of inventions will be more clear from the following examples of their implementation.

Example 1

In the converter chamber 2 according to the first embodiment, a fuel-air mixture of coal with a particle size distribution of up to 5 mm, a heat of combustion of 26 MJ / kg, a moisture content of 12 wt.%, An ash content of 10 wt.%, And a yield of volatiles of 35 wt.% Was supplied. The ratio in the mixture of coal and air was 1: 1.45. The air temperature in the mixture was 180 ° C. A mixture of coal and air was supplied under a pressure of 16 MPa. The temperature in the combustion chamber was maintained at 1400 ° C. Steam was supplied to chamber 6 at a pressure of 16 MPa and a temperature of 560 ° C. In this case, combustible gas with a calorific value of 11.4 MJ / m ³ with a very low content of ballast components in the gas was obtained from chamber 6. In gas products discharged from chambers 2 and 6, there were practically no unburned fuel particles. Calculations showed that 560 kg of this type of coal are consumed in order to produce 1000 m ^{3 of} combustible gas by this method, which is 12% less than by a known solution.

Example 2

In the second chamber of the converter according to the second embodiment, brown coal and air were supplied in a ratio of 1: 1.5. Brown coal had a particle size distribution of up to 10 mm and a heat of combustion of 16 MJ / kg, a moisture content of 32 wt.%, An ash content of 9 wt.%, And a yield of volatiles of 42 wt.%. The air temperature supplied to chamber 2 was 60 ° C; the pressure in the chamber was maintained at 0.11 MPa. Air enriched with oxygen was supplied to chamber 6 to an oxygen concentration of 70 vol.%, Under a pressure of 0.11 MPa, with a temperature of 10 ° C. The temperature in chamber 2 was maintained at 800 ° C. In this case, combustible gas with a heat of combustion of 6.7 MJ / m ³ in which particles of unburned coal were absent was obtained from chamber 6. Calculations showed that to obtain 1000 m ^{3 of} combustible gas, this method consumes 595 kg of this type of coal, which is 10.5% less than by a known solution.

Example 3

Coal with a grain composition of up to 5 mm and air at a temperature of 110 ° C and a pressure of 5 MPa were fed into the combustion chamber of the converter. Coal and air were supplied in a ratio of 1: 2. Coal had a heat of combustion of 27.8 MJ / kg, humidity of 11 wt.%, Ash content of 15 wt.%, The yield of volatile substances 18 wt.%. Steam was supplied to chamber 6 at a pressure of 5 MPa and a temperature of 260 ° C. The temperature in the combustion chamber was maintained at 1300 ° C. In this case, combustible gas with a low content of unburned fuel particles and a heat of combustion of 10.9 MJ / m ³ was obtained from chamber 6. Calculations showed that to produce 1000 m ^{3 of} combustible gas, 557 kg of this coal is consumed, which is 13.5% less than by a known solution.

Example 4

The initial parameters as in example 1, only the valve for the release of gas products from the chamber 2 is closed. In this case, we get at the outlet of the converter a combustible mixture of gas products of combustion and conversion, in which there are practically no particles of unburned fuel. The mixture of gas conversion products had a heat of combustion of 6.3 MJ / m ³ . Calculations showed that 350 kg of this type of coal are consumed for producing 1000 m ^{3 of} such a combustible mixture of gases by this method.

The implementation of the resulting combustible mixture of gas products of combustion and conversion is necessary when the gas products of combustion can contain harmful substances, for example dioxins and dibenzofurans, and the purification of gases from them is very expensive. At the same time, the further process of burning a combustible mixture of gas products of combustion and conversion allows the destruction of dioxins and dibenzofurans.

Claims (9)

1. A method of converting solid fuel, comprising feeding chopped solid fuel and an oxidizing agent into the converter, igniting and converting the fuel mixture, followed by removing gas conversion products, combustion products and solid residue from the converter, characterized in that the combustion and conversion of the fuel mixture is carried out in different interconnected converter chambers with each other, and for ignition and combustion, fuel is fed into the combustion chamber in a mixture with an oxidizing agent, the fuel mixture is burned in a vortex stream formed in chamber g rhenium, and conversion is performed in the chamber converter conversion due to interaction directional flow of solid fuel particles coming from the combustion chamber into the conversion chamber with oppositely-directed oxidant flow fed to the gasification chamber converter. 2. The method of conversion of solid fuel according to claim 1, characterized in that the output from the converter of gas conversion products, combustion products and solid residue is carried out separately. 3. The method of converting solid fuel according to claim 1, characterized in that during the conversion, steam and / or plasma and / or combustion gas products are supplied to the conversion chamber. 4. Installation for the conversion of solid fuel, including a converter, a device for feeding a fuel mixture to a converter, a device for igniting a mixture, a device for dispensing from a converter gas conversion products, combustion products and a solid residue, characterized in that a fuel combustion chamber communicating with each other is formed mixture, in which the swirl of the fuel mixture flow is placed, and on which the ignition and supply of the fuel mixture are placed, and the solid fuel conversion chamber, equipped with an additional device m of oxidizing agent feed into it, the device for issuing combustion products from the converter is equipped with an adjustable shutter element, and the devices for issuing gas conversion products and solid residue are equipped with adjustable shutter elements. 5. Installation for the conversion of solid fuel according to claim 4, characterized in that a casing is placed in the conversion chamber, between which and a converter wall there is a superheater that can be connected to the water supply line and connected to the conversion chamber. 6. Installation for the conversion of solid fuel according to claim 4, characterized in that a plasma torch is installed on the converter housing, designed to supply plasma to the conversion chamber. 7. Installation for the conversion of solid fuel, including a converter, a device for feeding a fuel mixture to a converter, a device for igniting a mixture, a device for dispensing from a converter gas conversion products, combustion products and ash, characterized in that a fuel mixture combustion chamber communicating with each other is formed in which the swirl of the fuel mixture flow is located, and on which the ignition and supply of the fuel mixture are placed, and the conversion chamber, equipped with an additional oxidizer supply device, inverter, at the outlet of the combustion chamber a separator is installed for the separation of solid and gaseous products of combustion, devices for issuing combustion products from the converter, issuing gas products of conversion and solid residue are placed on the converter and equipped with adjustable shutter elements. 8. Installation for the conversion of solid fuel according to claim 7, characterized in that a casing is placed in the conversion chamber, between which and a converter wall there is a superheater that can be connected to the water supply line and connected to the conversion chamber. 9. Installation for the conversion of solid fuel according to claim 7, characterized in that a plasmatron is installed on the converter housing for supplying plasma to the gasification chamber.

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