WO2006104471A1 - Method for thermally processing domestic wastes and device for carrying out said method - Google Patents

Abstract

The invention relates to processing domestic and industrial organic substance-containing wastes consisting in loading wastes into a shaft furnace, in compacting and simultaneously heating said wastes by plasma jets, in lowering the initial level of a waste column at a rate proportional to a gasification speed, in discharging the thus obtained pyrolysis gas from the top part of the furnace, in cleaning said gas and in directing it for producing thermal and chemical energy, wherein a working medium for plasmotrons is embodied in the form of water and a cleaned, dried and compressed by a compressor waste gas, in compacting and fusing by a plasma jet the wastes remaining after pyrolysis and in tapping a metal and slag. The inventive device for thermally processing domestic wastes comprises a shaft furnace (1) provided with a loading device (25), a press-filter (26), a drying device (29) and a lock device (30). A forehearth (11) provided with a plasmotron (12) and tap holes (13, 14) for tapping a metal and slag is placed in the lower section of the shaft furnace. A gas main (15) connected to a plasma-chemical gas generator (16), which is provided with plasmotrons (17) arranged therein, is mounted above said forehearth. The top section of the furnace is provided with a rod (2), which has a perforated water-cooled piston (3) and is arranged in the furnace cavity in such a way that it is fixedly longitudinally movable. The controllable reciprocating stroke of the piston (3) is carried out by means of an automation system. A pipeline (18) for removing the pyrolysis gas is connected to a cyclone-type gas cleaner (22), a sulphur-removing device (23) and to a receiver (24).

Description

 Method for thermal processing of household waste and device for its implementation

An interrelated group of inventions relates to techniques for processing household and industrial wastes containing organic substances, as well as plant wastes in agricultural production.

A known method for the pyrolysis of municipal solid waste, including loading the waste, followed by its grinding and feeding it into the pyrolysis reactor, heated by burning pyrolytic gaseous fuel in the surrounding jacket, unloading the waste with separation of ferrous metal fractions, introducing salts into the pyrolysis gas behind the reactor to bind toxic gaseous substances , subsequent purification of gases from salts and the supply of purified pyrolysis gas to the combustion chamber, the separation of the exhaust gases from the combustion chamber into two streams and the supply of one of them into a waste heat boiler for generating steam, and the other into a jacket of the reactor, in which gas flows are circulated by taking part of the purified pyrolysis gases behind the gas scrubber, followed by heating it in the combustion chamber and feeding it into the reactor, in which the waste is sprayed and agitated together with jets purified pyrolysis gases, and the combustible exhaust gases from the reactor jacket are sucked off, mixed with fresh air, and the gas mixture is fed into the combustion chamber (A.S. USSR JN ° 1548601, class F 23 G 5/027, priority 20.01.88, publication date Bull. N ° 9, 1990). The disadvantage of this method is the complexity of the technological scheme, and the resulting products need further neutralization and processing, which partially leads to significant environmental pressures.

The closest in technical essence and the achieved result (prototype) method is adopted for the thermal processing of household waste in a shaft furnace, which includes preparation, loading into the shaft, heating in plasma jets in an oxidizing environment, followed by the release of the resulting melts of slag, metal and gases with cleaning and disposal of the latter , according to the invention, the processing is carried out in a sealed reaction space, and the gases are passed first through the formed melt, and then act on them with an electric spark discharge, and part of the exhaust gases after purification is returned to the reaction space, while the gases are circulated in the reaction zone, and the slag is heated before the discharge (Russian Patent No. 1836603, CL F 23 G 5/00, priority 24.06.91, date publication Bul. JCHsZl, 1993).

However, the known method is not suitable for the treatment of such waste, such as paste-like, as well as liquid substances, both from the point of view of technology and profitability, as well as from an environmental point of view, while obtaining raw materials suitable for reuse, in addition, disadvantages should be attributed to the low efficiency of using the physical heat of pyrolysis gases.

A device for processing waste and household waste, comprising a housing lined with refractory material, a loading hopper, tapering downward with a window in the lower part adjacent to the housing, and a lid in the upper part, gas and air supply pipes and gas vents, the housing being the height is divided into zones of drying, pyrolysis and combustion with the help of paired leaves located at an angle to each other, moreover, the pairs of leaves located at the entrance and exit to the body are solid, and the pairs of leaves separating the zones are made with holes holes, the gas and air supply pipe is located above the pair of valves located at the outlet, and the exhaust gas pipe is located above the pair of valves located at the inlet, and the hopper is equipped with an air discharge pipe (Russian Patent ЖУ23211, CL F 23 G 5/00, Priority 06/18/92, publication date Bull. N ° 21, 1994).

The technology for processing garbage and household waste, implemented in the described reactor, is unproductive and inefficient due to the low degree of control and maintaining the temperature level of processes occurring in parallel in neighboring zones, taking into account certain requirements for the composition and size of the feedstock.

The closest in technical essence and the achieved result (prototype) adopted device for the thermal processing of household waste, including a shaft with a loading device in the upper part, plasma torches installed in the nadgorny zone of the mine along its perimeter, a notch for the production of slag and a flue for exhaust gases, according to the invention, it it is equipped with a sub-water bath adjacent to the mine horn with a notch for the release of metal melt, and the sealed mine and bath working spaces are separated by a vertical partition with a window in the bottom part to form a water seal, and the slag outlet is made siphon and is located at the end of the bath with a level far from the mine the drain threshold is higher than the partition window, and the gas duct is installed in front of the tap hole in which the electric-discharge device is installed, while in the bath with the drain threshold of the siphon tap hole there is one electric ktropechnoy electrode or a plasma torch, and the perimeter of the shaft above plasma torches are arranged fuel burner (Russian Patent JfeShbbOZ, cl. F 23 G 5/00, priority 24.06.91, publication date Bul. ZH31, 1993).

The disadvantage of this device is the low productivity of the furnace, due to a two-stage process - burning and pyrolysis, in addition, the device is not intended for the processing of such waste materials as liquid substances, pasty waste and other materials with high viscoelastic properties.

The first of the group of inventions is based on the task of improving the method of thermal processing of household waste, in which by creating a closed technological system for converting waste into metal, slag and gas components and utilizing the heat and chemical energy of the exhaust gases for energy converting devices, and neutralizing the separated liquid phase from waste, ensure the efficiency of waste processing, reduce harmful emissions into the atmosphere and increase the productivity of the process.

The second of the group of inventions is based on the task of improving the device for the thermal processing of household waste, in which by changing the design of the reactor, as well as the technological layout of the units and the connections between them, provide a cost-effective mode of operation of the device, increase its specific productivity and reduce environmental pollution . The first task is solved in that in a method for the thermal processing of household waste, including preparation, loading into a mine, heating in plasma jets in an oxidizing environment with gas circulation in a sealed reaction space with subsequent release the resulting melts of slag, metal and gases with the purification and utilization of the latter, the return of part of the exhaust gases to the reaction space, according to the invention, the prepared waste is subjected to volume compression, neutralize the separated liquid phase, and the resulting solid product is sent to drying, which is produced by the thermal effect of the waste after utilization gas, periodically load the dried product into the shaft furnace without the thermal effects of plasma jets, and after the furnace is fully loaded, the product is compacted at one belt heating of products with plasma jets, while the compaction process lowers the initial level of the product column in the reaction space of the furnace at a rate proportional to the gasification rate, and the resulting pyrolysis gas, due to the pressure in the shaft furnace, which is created by the plasma torches, is removed from the top of the shaft furnace, through the gas treatment system, accumulate in the receiver and sent to the utilization of thermal and chemical energy, while the cleaned, compressed gas in the compressor serves as the working fluid of the plasma torches, the effluent after drying, and water, and the waste remaining in the shaft furnace are compacted and melted with a plasma jet, after which the metal and slag are drained from the shaft furnace.

The method includes four stages: - waste preparation, environmental disposal of the liquid phase in them and drying; - loading, compaction of drained waste in a shaft furnace with simultaneous heating of them in an oxidizing environment by plasma jets, pyrolysis and production of pyrolysis gas; - transportation of pyrolysis gas through a closed path, including the purification and utilization of heat, the use of exhaust gases to produce electricity and steam, the generation and accumulation of water condensate, the use of it and pyrolysis gas for the operation of plasma torches, the return of a portion of the water to the heat exchanger and the selection of heated gas from it drying waste; - obtaining metal and slag as a result of exposure to a plasma jet on the compacted layer of waste in the furnace obtained after pyrolysis.

The sequence of actions of this process, the regulation of the thermal regime in the furnace by changing the power and flow rate of the plasma-forming gas in the plasma torches, provide sufficient flexibility technological process in relation to temperature conditions at individual stages, which leads to complete waste disposal in a given mode and completeness of the entire technological cycle while maintaining a clean environment. The second task is solved in that the device for the thermal processing of household waste, including a shaft furnace with a loading device, plasmatrons installed in the lower part of the shaft furnace, slots for the release of slag and molten metal, an additional plasma torch and flue for exhaust gases, according to the invention, shaft the furnace in the upper end part is equipped with a rod with a perforated piston with thermocouples placed in it and installed in the cavity of the furnace with the possibility of a fixed longitudinal movement in height the reaction space of the furnace, while the thermocouples are electrically connected to the memory unit, the piston drive mechanism and the furnace operating mode switch interacting with the emphasis on the rod during its movement, and in the lower part of the shaft furnace there is a piggy bank with an additional plasmatron, and above the piggy bank, on the external perimeter of the shaft furnace, there is a gas collector connected to a plasma-chemical gas generator with plasma torches installed in it, while the loading device is communicated with a press filter for dehydration I waste, with which the drying device is connected in series, a sluice device made in the form of a receiving container of drained waste with two drive gates, in the lower part of which there is a screw feeder connected to the internal cavity of the furnace through an opening made in its side wall, below the border the upper position of the piston, and in the upper part of the furnace there is a pyrolysis gas discharge pipe, which is connected through a non-return valve to a cyclone gas scrubber, sulfur removal device and receiver, output through a controlled valve and compressor, it is connected to a device for recovering the thermal and chemical energy of the pyrolysis gas, the exhaust gas pipeline of which is connected to the drying device through the heat exchanger of the steam generator, and the gas circuit leaving the drying device is connected to the plasma chemical gas generator and through an additional heat exchanger through the blower, filter and compressor - to the plasmatrons of the plasma chemical gas generator, while the plasmatrons of the plasma chemical the gas generator, at the time of heating the shaft furnace, is connected to an external source of electric energy and to an air compressor, and the internal cavity of the furnace through an auxiliary supply system is connected to the drying device through a control valve, an additional plasma torch installed in the piggy bank is connected to a cylinder with liquefied gas, for example, propane, and to the air compressor, and the drying device is equipped with a plate conveyor installed along the length of its internal cavity. The heat energy recovery device can be made in the form of a gas turbine or an internal combustion engine, and the press filter is equipped with a container for collecting the liquid phase associated with the neutralization tank, while the piston is water-cooled.

The piston in the shaft furnace is perforated to ensure the flow of gas during its movement, and thanks to the presence of thermocouples installed on the piston, electrically connected to the rod drive mechanism, a memory unit, an operating mode switch, a controlled reverse piston stroke is provided, the waste is compressed in the furnace while they are simultaneously heating, which leads to a decrease in the size of the voids in the loaded waste, an increase in the thermal conductivity of the waste and an acceleration of its heating.

The presence of a piston with an independent drive allows a wider range of variation of the compression mode of waste in the shaft furnace, which in combination provides a significant increase in the specific productivity of the furnace for recyclable waste, reduces the specific heat consumption for processing and increases the quality and energy content of pyrolysis gas.

The gas manifold is intended for the formation of directed heated gas jets in the sealed reaction space of the furnace.

The proposed design of the shaft furnace provides the specified thermal regime by the plasmatrons of the plasma chemical gas generator by changing their power and consumption of the plasma gas, and with a significant increase in the height of the shaft furnace and its diameter, the number of plasma chemical gas generators is set taking into account the scale factor.

The waste preparation system includes a press filter, in which the waste is pressed and the liquid is separated from the solid mass, while the liquid phase is discharged into the tank, where it is neutralized, and the solid mass enters into a drying device equipped, for example, with a plate conveyor, and through a lock device into the internal cavity of the furnace.

The energy of the pyrolysis gas leaving the furnace is realized using heat energy recovery devices, for example, an internal combustion engine or a gas turbine with an electric generator. The gas leaving the recovery device enters the heat exchanger of the steam generator, from which the gas enters the drying device. Part of the gas leaving the drying device, through a gas blower, filter, additional heat exchanger and compressor, enters the plasmatrons of the plasma chemical gas generator, and the second part directly into the plasma chemical gas generator.

With a large shaft furnace and, as a result of obtaining large volumes of pyrolysis gas, for additional heat recovery, a steam turbine with an electric generator is installed in the device after the heat exchanger of the steam generator, the exhaust steam from which is condensed in the condenser and fed into the feed water tank, from which it is pumped back into the heat exchanger of the steam generator and through a controlled regulator to the plasmatrons of the plasma chemical gas generator.

Thus, the device allows you to fully use the heat content of the exhaust gas, even if its energy content is not very high, without affecting the environment.

The device provides high performance waste recycling with increased environmental parameters, the processing of unsorted waste, creates the conditions for increasing the volume of waste processing as the needs increase and, at the same time, convert the electricity generated in the device itself to heat by plasmatrons and into mechanical energy by connecting the electrical equipment involved in the technological scheme.

The method is as follows.

The method of thermal processing of household waste involves preheating the shaft furnace with plasmatrons of a plasma chemical gas generator, which at the time of heating work from an external source of electricity and an air compressor without removing pyrolysis gases from the furnace. After heating the shaft furnace to a temperature of 150-200 ⁰ C solid and liquid household waste is sent to the press filter loading device, in which they are subjected to volume compression while squeezing the liquid phase, which is collected in a separate container and neutralized with a chemical solution. The resulting solid product is sent to drying, where gases heated in the reaction zone of the furnace, which enter through an auxiliary supply system, serve as a heating agent.

Upon reaching the temperature values of the internal walls of the furnace in the range of 300-400 ⁰ C in the pyrolysis zone, the dried solid product is loaded into the furnace through the lock chamber without thermal influence by plasma jets. The auxiliary system for supplying the drying agent is closed and the loop of pyrolysis gases leaving the furnace is turned on. After the furnace is fully loaded, the dried product is compacted while heating it with plasma jets with a controlled temperature of gases at the inlet of the furnace from 300 to 600 ⁰ C. In the process of heating, the organic component of the waste is pyrolyzed. As the pyrolysis during the compaction process, the initial level of the column of products in the reaction space of the furnace is reduced at a rate proportional to the rate of gasification.

The effect of pressure and shear deformations on a solid product occurs during its heating. The material is subjected to gradual compression, while the dimensions of voids present in the material are reduced. As a result, the calorific value of the material increases, intensive heat release begins in the entire volume of the processed material, leading to rapid heating.

The pyrolysis gas in the shaft furnace goes from bottom to top under the pressure necessary to overcome the hydraulic resistance of the entire column of the loaded material and provides the pressure that is set by the consumer of the pyrolysis gas at the outlet, while the pressure of the gas jets entering the shaft furnace from the plasma chemical gas generator is controlled within 0 , 05-0.1 MPa due to the relative low moisture content in dried solid products. Due to the pressure in the reaction space of the furnace, pyrolysis gas is removed from its upper part and accumulated in the receiver. The gas temperature at the outlet of the furnace is 200-500 C. When a sufficient amount of gas is accumulated in the receiver, the latter, after cleaning particles and sulfur are disposed of, for example, in an internal combustion engine or in a gas turbine, in order to obtain electricity. The exhaust gas after utilization is diverted to the heat exchanger of the steam generator, and the steam is fed to the steam turbine, which drives the generator. To form a closed thermodynamic cycle, the steam exhausted in the steam turbine is condensed, and the condensate is accumulated in the feed water tank, from which water is again supplied to the heat exchanger of the steam generator. Gas heated in a heat exchanger with a temperature of 150-200 ⁰ C is sent to the drying zone of the prepared waste. Part of the gas after drying, with a residual temperature of 50-120 ⁰ C, is sent to the plasma chemical gas generator by gas blowing, and the second part of the gas is filtered, its temperature is reduced to a value of less than 30 ⁰ C and fed to the plasmatrons of the plasma chemical gas generator. Water from a feedwater tank under pressure up to 4 atm is supplied to the plasmatrons of a plasma chemical gas generator and an additional plasmatron. With a plasma torch power of 0.5 MW, the water flow rate is up to 10 g / s. After each complete loading of the furnace and thermal decomposition of the prepared solid waste, the pyrolysis process ends with the formation and accumulation of solid waste in the piggy bank and at the bottom of the furnace.

The solid waste remaining as a result of pyrolysis remains in the lower part of the furnace, and the rest of the furnace is loaded with new portions of the dried solid product, which is compacted and heated as described above. As the waste remaining after pyrolysis accumulates, they are compacted and heated at a temperature of 1500-2000 ⁰ C with a plasma jet of a plasma torch installed in the piggy bank until a melt is formed, after which the resulting metal and slag are drained.

Thus, to ensure environmental cleanliness of the exhaust gases, household waste is decomposed twice at temperatures,. excluding the formation or preservation of complex chemical compounds.

The energy of the obtained pyrolysis gas can be used in various ways, as well as a combination of several methods of use. The proposed method allows in energy converting devices to use the electricity generated in the waste processing system itself and to activate the mechanisms involved in the implementation way.

The drawing shows a schematic diagram of a device for the thermal processing of household waste.

The device includes a shaft furnace 1 made of a metal vertically arranged body lined with refractory bricks. In the upper end part of the furnace on the rod 2 there is a piston 3 mounted in the internal cavity of the furnace with the possibility of a fixed longitudinal movement using the drive mechanism 4. The piston is made with through holes 5 for the flow of gas and internal channels for a cooling agent (not shown). Thermocouples 6 and 7 are installed on the piston 3. The device also includes a memory unit 8, electrically connected to thermocouples 6 and 7, a drive mechanism 4 and a furnace operating mode switch 9, interacting with a stop 10 on the rod 2 while the latter is moving. In the lower part of the shaft furnace 1 there is a piggy bank 11 with an additional plasma torch 12. In the piggy bank there are slots 13 and 14 for the release of metal and slag. On the outer perimeter of furnace 1, above the piggy bank, there is a gas collector 15 connected by a thermally insulated channel with a plasma-chemical gas generator 16 with plasmatrons 17 installed in it. In the upper part of the furnace there is a pyrolysis gas discharge pipe 18 with a flow meter 19, which is connected through a controller 20 to the drive mechanism 4. The pipe 18 through a check valve 21 is connected to a cyclone gas scrubber 22, a device 23 for removing sulfur and its compounds, and a receiver 24. The charging device 25 is in communication with a press filter 26, In order to dehydrate the waste and drain the liquid phase into the tank 27. Tank 28 is filled with a substance to neutralize the liquid phase. A drying device 29, a sluice device 30, made in the form of a receiving container of drained waste with two drive gates 31 and 32, in the lower part of which a screw feeder 33 is connected to the internal cavity of the furnace 1 through an opening 34, are connected in series with the press filter 26 made in its side wall below the boundary of the upper position of the piston 3. The drying device 29 is provided with a plate conveyor 35 installed along the length of its internal cavity. An additional plasma torch 12 installed in the piggy bank 11 is connected to a cylinder 36 with liquefied gas, for example, propane and to the air compressor 37.

In the proposed invention, the use of any thermal energy recovery devices is possible, which is dictated by the needs of the consumer.

In the above diagram of the device for the thermal processing of household waste, the receiver 24 is connected through a valve 38 to a compressor 39 connected to the combustion chamber 40 of the gas turbine unit 41, to which the electric generator 42 is connected. The exhaust pipe from the turbine is connected to the heat exchanger of the steam generator 43. The heat exchanger 43 is connected by a steam line to a steam turbine 44, which serves to rotate the electric generator 45. The pipe for removing steam from the steam turbine 44 is connected to the condenser 46 and then through the condensate pump 47 to the reserve a source of feed water 48, from which water is fed back to the heat exchanger 43 via the feed pump 49 and through the controlled regulator 50 to the plasma torches 17 of the plasma chemical gas generator 16 and to the additional plasma torch 12. The heat exchanger 43 is also connected by a gas line to the drying device 29, from which the branch gas pipe branches through the gas blower 51 - one branch is connected to the plasma chemical gas generator 16, and the second through the filter 52, an additional heat exchanger 53, and the compressor 37 to the plasma torches 17 of the plasma chemical a gas generator 16 and an additional plasma torch 12. The plasma torches 17 of the plasma-chemical gas generator 16, at the time of heating the shaft furnace, are connected to an external source of electric energy and to an air compressor 37, and the internal cavity of the furnace 1 is connected through an auxiliary system 54 to the drying device 29 through a controlled valve 55. The device operates as follows. The shaft furnace 1 is heated by low-temperature plasma generated by a plasma-chemical gas generator 16, in which the plasma torches 17 are fed from an external source of electricity and an air compressor 37 while the furnace is warming up. The check valve 21 of the pyrolysis gas exhaust pipe 18 is closed. Through the loading device 25, household waste enters the press filter 26, in which the waste is pressed and the liquid is separated from the solid mass. The liquid phase is discharged into a container 27, where a neutralizing substance from the tank 28 is simultaneously supplied. Solid waste after the press filter enters the drying device 29, directly on plate conveyor 35. During the heating of the furnace, an auxiliary hot gas supply system 54 is connected, which connects the internal cavity of the furnace 1 to the drying device 29. Warming up the furnace 1 is carried out to obtain temperatures of 500-700 ⁰ C internal walls. After warming up the furnace, the auxiliary system 54 is turned off by a controlled valve 55, the gate 31 is opened, and the dried material is transferred via the conveyor 35 to the receiving tank 30. The plasma torches 17 of the plasma-chemical gas generator 16 are turned off, the gate 32 is opened, the screw feeder 33 is turned on and the material enters the shaft through the opening 34 oven until its volume is completely filled. Close the gate 32 and turn on the plasmatrons 17. Turn on the mechanism 4 of the actuator rod 2. The piston 3 lowers down and compacts the dried material in the cavity of the furnace while it is heated by plasma jets with a controlled temperature of gases at the inlet of the furnace from 300 to 600 ⁰ C. During heating there occurs a pyrolysis of the organic component of the waste, and when the gas pressure in the furnace increases, the check valve 21 is activated and the pyrolysis gas enters through the gas scrubber 22, the device 23 for removing sulfur to the receiver 24. The magnitude of the electrical signal, which gives a flow meter 19, determine the gasification rate. During pyrolysis, the material undergoes gradual compression by a piston, which moves at a speed proportional to the rate of gasification. Thermocouples 6 and 7 control the temperature of the heating of the piston as it moves towards the pyrolysis zone.

The piston reverse modes are determined by the heating temperature of its lower part, corresponding to the distance from the furnace operating mode switch 9 to the installation site on the stop piston 10, which is selected experimentally depending on the type of material being processed. The signals from thermocouples 6 and 7 and the switch 9 of the furnace operating mode are entered into the memory unit 8, the output of which is connected to the drive mechanism 4. If during the movement of the piston its temperature reached 400 ⁰ C after the signal from the switch 9 of the furnace operating mode is activated, the memory unit 8 generates a signal to return the piston to its original position using the drive mechanism 4 and issue a command for reloading. If during the movement of the piston its temperature reached 400 ⁰ C before the operation of the signal of switch 9, then the memory unit 8 gives a signal to start melting, and it turns off a plasma-chemical gas generator 16 and an additional plasma torch 12 is turned on, and the piston continues to move down to a heating temperature of 600 ⁰ C in its lower part, and when this temperature is reached, the piston returns to its original position, and melting continues until the pyrolysis waste melts.

After filling the receiver with pyrolysis gas, the entire system is alerted. At this moment, the controlled valve 38 is opened, and the gas after cleaning through the compressor 39 is fed for its disposal, for example, to an internal combustion engine or a gas turbine 41. The gas worked off after utilization is taken to the heat exchanger of the steam generator 43, the steam from which is supplied to the steam turbine 44, which rotates the electric generator 45. The steam selected in the turbine is sent to the condenser 46, and the condensate is accumulated in the feed water tank 48, from which water is supplied through the feed pump 49 via separate pipelines to the heat exchange to 43 and controlled through the controller 50 by the plasma torches 17 or additional plasma torch 12. The gas from the steam generator heat exchanger 43 fed into device 29 for drying. The exhaust gas after drying through the gas blower 51 is transported by the gas path to the plasma chemical gas generator 16, and the gas is passed through the exhaust duct from the gas path through the filter 52, an additional heat exchanger 53, in which the gas is cooled to a temperature of less than 30 ⁰ C, and sent through the compressor 37 depending from the operating mode of the furnace to the plasmatrons 17 of the plasma chemical gas generator or to the additional plasma torch 12. The gas prepared in the plasma chemical gas generator is supplied to the gas manifold 15 and then to the reaction zone of the furnace 1. An analysis of the ongoing physicochemical and electrothermal processes shows that when using the claimed method and device, the mechanism of waste disposal changes qualitatively, the efficiency of utilization increases, the coefficient of utilization of received heat increases due to the generation of electricity directly in the waste processing, and the process is ecologically clean when closed coolant circulation.

Claims

Claim

1. A method for the thermal processing of household waste, including preparation, loading into a mine, heating in plasma jets in an oxidizing medium with gas circulation in a sealed reaction space, followed by the release of the resulting melts of slag, metal and gases with cleaning and disposal of the latter, returning part of the exhaust gases to reaction space, characterized in that the prepared waste is subjected to volumetric compression, neutralize the separated liquid phase, and the resulting solid product is sent for drying, which They are produced by the thermal effect of the exhaust gas after utilization, the dried product is periodically loaded into the shaft furnace without the thermal effects of plasma jets, and after the furnace is fully loaded, the product is compacted while the products are heated by plasma jets, while during the compaction process the initial level of the product column in the reaction space of the furnace is reduced at a speed proportional to the rate of gasification, and the resulting pyrolysis gas due to the pressure in the shaft furnace, which is created by plasmatrons, is removed from the upper part of the shaft furnace, they are passed through a gas treatment system, accumulated in the receiver and sent to the utilization of thermal and chemical energy, while the cleaned, compressed gas from the compressor, exhausted after drying, and water serve as the plasma torch working medium, and the waste remaining in the shaft furnace compacts and melted with a plasma jet, after which the metal and slag are drained from the shaft furnace.

2. Device for the thermal processing of household waste, including a shaft furnace with a loading device, plasmatrons installed in the lower part of the furnace, slots for the release of slag and molten metal, an additional plasma torch and flue for exhaust gases, characterized in that the shaft furnace in the upper end part equipped with a rod with a perforated piston with thermocouples placed in it and installed in the cavity of the furnace with the possibility of a fixed longitudinal movement along the height of the reaction space of the furnace, while thermocouples electrically connected to the memory unit, the piston drive mechanism and the furnace operating mode switch, interacting with the emphasis on the rod during its movement, and in at the bottom of the shaft furnace there is a piggy bank with an additional plasmatron, and above the piggy bank, on the outer perimeter of the shaft furnace, there is a gas collector connected to a plasma-chemical gas generator with plasma torches installed in it, while the loading device is communicated with a press filter for dehydration of waste, with which connected to a drying device, a lock device made in the form of a receiving tank of dried waste with two drive gates, in the lower part of which there is a screw a heater connected to the internal cavity of the furnace through an opening made in its side wall, below the boundary of the upper position of the piston, and in the upper part of the furnace there is a pyrolysis gas exhaust pipe, which is connected through a non-return valve to a cyclone gas scrubber, a sulfur removal device, and a receiver, the output of which through a controllable valve and compressor is connected to a device for recovering the thermal and chemical energy of pyrolysis gas, a steam pipe leaving the gas recovery device through the heat exchanger ra is connected to a device for drying a gas path, the exhaust from the drying device through the blower connected to the gas generator and plasmachemical through an additional heat exchanger, the filter and the compressor - the gas generator to the Plasma Chemical plasma torches.

3. The device according to claim 2. characterized in that the plasmatrons of the plasma-chemical gas generator, at the time of heating the shaft furnace, are connected to an external source of electric energy and to an air compressor, and the internal cavity of the furnace through the auxiliary supply system is connected to the drying device through a control valve.

4. The device according to claim 2. characterized in that the additional plasma torch installed in the piggy bank is connected to a cylinder with liquefied gas, such as propane, and to an air compressor.

5. The device according to claim 2. characterized in that the drying device is equipped with a plate conveyor installed along the length of its internal cavity.

6. The device according to claim 2. characterized in that the thermal energy recovery device is made in the form of a gas turbine.

7. The device according to claim 2. characterized in that the disposal device thermal energy is made in the form of an internal combustion engine.

8. The device according to p. 2. characterized in that the press filter is equipped with a container for collecting the liquid phase associated with the neutralization tank.

9. The device according to p. 2. characterized in that the piston is water-cooled.