RU2515442C1 - Method of recovery of solid household wastes combustion heat at incinerator plant and device to this end - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to decontamination of solid household wastes. Proposed method consists in feeding the afterburnt offgas heated to 1150°C-1250°C in turns to parallel flow channel two-way gas-air heat exchangers. Said heat exchangers, compressed air system, air turbine and generator make the electric power generation system. Note here that offgas flow feed is changed over to every next heat exchanger after heating of previous heat exchanger to 800-1000°C. Note here that offgas flow cooled in every said heat exchanger is fed after gas cleaning system into atmosphere. Note here that after heating compressed air is fed to every heat exchanger for it to be heated to 600-800°C and, further, to inlet of air turbine connected with electric power generator. Said compressed air gets cooled and fed to incinerator kiln.

EFFECT: lower costs and pollution, higher efficiency of power production.

5 cl, 1 dwg

Description

The invention relates to techniques and technologies for thermal neutralization of solid household waste and is intended to reduce their negative impact on the environment and increase the efficiency of energy production in waste incineration plants (MSU).

A known method and device for utilization of the calorific value of solid household waste (DE 4235464 A1, publ. 04/28/1994), according to which in the process of burning waste, feed water and high pressure steam are formed in the MSU boiler evaporator, generated as saturated steam or wet steam , which is removed from the boiler and overheated in an external heating boiler and then fed to high pressure turbines to produce electricity. Thus, the enthalpy of waste combustion can be used with a high degree of efficiency, by converting all the steam of the local self-government into electricity.

The traditional heat recovery scheme for ISUs according to this invention also has a traditional drawback: steam obtained from specially prepared chemically purified water is used as a heat carrier. The water treatment system, as a rule, is closed and requires large capital and operating costs.

A known method and device for using garbage or other waste as fuel for environmentally friendly electricity production (EP 0399104 A1, publ. 08.12.89), in which the steam generated in the heat recovery system of the local self-government is supplied to the turbines of the power plant and used to generate electric current.

This makes it possible to use the generated electricity when generating energy for the MSU for the operation of the apparatus of the system for cleaning flue gases from solid waste products at the outlet of the MSU, pumps of the water treatment system, conveyors for feeding the MSW into the furnace and auxiliary devices of the MSU.

A disadvantage of the known invention is the need for cooling the exhaust gases in the gas-water heat exchangers before the gas purification system, which leads to steam for operation of the steam turbine and thermal energy for heating and industrial purposes, while the water treatment and conditioning system for the steam in front of the turbine is usually closed and requires large capital and operating costs.

The prototype of the proposed invention is a method and device for using solid household waste, in thermal power plants (TPP) as fuel, for environmentally friendly production of electricity (EP 1428987 A1, publ. 24.04.2003), in which the waste is burned in a combustion reactor with a variable speed air flow, flue gases are cooled in gas-air heat exchangers and cleaned in a gas purification system, and purified flue gases, mixed with air, are used in these power plants to operate gas turbines ny generating installations.

The disadvantages of the known invention are: the need for additional heating of the mixture of exhaust gases with air in front of the gas turbine generating units due to the additional supply and combustion of fuel, which leads to a rise in the cost of the generated energy, as well as the need for additional gas purification of the exhaust gases after the gas turbine from the combustion products of the additionally supplied fuel.

In the first and second objects of the invention, a technical result is achieved, which consists in reducing the cost of obtaining thermal energy by eliminating a closed system of water cooling of the exhaust gases, as well as eliminating additional heating of the mixture of exhaust gases with air in front of the gas turbine generating units due to the additional supply and combustion of fuel, and additional gas purification of the exhaust gases after the gas turbine from the combustion products of the additionally supplied fuel.

The specified technical result in the first object of the invention is achieved as follows.

A method of utilizing the heat of combustion of solid household waste in an incinerator is that the flow of exhaust gases generated in an incinerator equipped with an oven, afterburning and cooling systems, exhaust gas treatment and ash removal comes at a temperature of 1150 ° С-1250 ° С from the system afterburning alternately in parallel-connected flowing two-channel gas-air heat exchangers.

Heat exchangers form, together with a compressed air supply system, an air turbine and a generator, an electric energy generation system.

In the process of disposal, the flow of exhaust gases is switched to each subsequent heat exchanger after heating the previous heat exchanger to a temperature of 800 ° C-1000 ° C.

The exhaust gas stream, cooled during passage in each heat exchanger, is supplied after the gas cleaning system to the atmosphere.

After heating, compressed air is alternately supplied to each heat exchanger, which is heated in each apparatus to a temperature of 600 ° C-800 ° C and enters the inlet device of an air turbine connected to an electric energy generator.

When passing through an air turbine, the compressed air is cooled and fed into the furnace of the incinerator.

In addition, the exhaust gas stream is cooled when passing in each heat exchanger to a temperature of 250 ° C-350 ° C.

Also, compressed air, when passing through an air turbine, is cooled to a temperature of 250 ° C-350 ° C.

The specified technical result in the second object of the invention is achieved as follows.

A device for utilizing the heat of combustion of solid household waste from an incineration plant equipped with an oven, exhaust gas afterburning systems, gas treatment, ash and slag removal and connected to an electric energy generation system includes a system of parallel-connected flow-through single-case two-channel gas-air heat exchangers with a high intrinsic heat capacity that are thermally insulated from the environment and made of high temperature non-metallic refractory materials.

The inlet of one channel of each heat exchanger through a gas flow switch is connected to a channel for supplying an exhaust gas stream from the afterburning system. The output of this channel is connected to the channel for the discharge of the exhaust gas stream into the gas treatment system.

The input of the second channel of each heat exchanger through the air flow switch is connected to the channel for supplying compressed air from the compressor, and the output of the second channel is connected to the channel for supplying heated compressed air to the inlet of the air turbine.

The latter is connected to an electric energy generator, the output device of which is connected to a channel for supplying cooled compressed air to the furnace of the incinerator.

In addition, the number of heat exchangers, the area and cross-sectional shape of the inlet and outlet channels, as well as their length are selected from the condition of heating the compressed air in the apparatus with an exhaust gas stream to a temperature of 800 ° C-1000 ° C, and the pressure and flow rate of compressed air at the outlet from the second channel of each device are selected based on the characteristics of the air turbine.

The invention is illustrated in the drawing, which shows a device for utilization of the calorific value of solid household waste incinerator.

The drawing shows an incinerator 1 equipped with either a fluidized bed furnace or an oven with grates, as well as exhaust gas afterburning systems, gas treatment, ash and slag removal systems connected to heat recovery and electric energy generation systems, a bunker 2 for feeding waste to the incinerator 1, a series of parallel-mounted flow-through single-case two-channel heat-exchange capacitive regenerative devices 3 of a shaft type, thermally insulated from the environment and made of of low-temperature non-metallic refractory materials, each apparatus 3 has a channel 4 for supplying an exhaust gas stream from the afterburning system of installation 1, channel 5 for extracting an exhaust gas stream into a gas cleaning system 6, a channel 7 for supplying compressed air to the apparatus 3 from a compressor 8, a channel 9 for discharging heated compressed air in an air turbine 10, an electric energy generator 11, a channel 12 for discharging exhausted cooled air from the air turbine into the furnace of the installation 1.

The invention is as follows.

Utilization of the heat of the exhaust gases generated during the combustion of solid household waste from the incinerator 1 takes place by alternating regenerative convective heating with a stream of exhaust gases from the compressed air flow in parallel-connected flow-through single-case two-channel heat-exchange capacitive regenerative devices 3 of the shaft type, heat-insulated from the environment and made from high-temperature refractory materials. Each device 3 is a massive case 13, which has a large intrinsic heat capacity. The cycle of alternately heating the compressed air with a stream of exhaust gases is repeated continuously.

Each apparatus 3 contains in its massive case 13 an exhaust gas supply channel 4 from the afterburning system of installation 1, an exhaust gas discharge channel 5 to the gas treatment system 6, a compressed air supply channel 7 to the device 3 from the compressor 8, a heated compressed exhaust channel 9, isolated from each other air to the air turbine 10.

The exhaust gas stream with a temperature of 1150 ° С-1250 ° С is directed from the exhaust gas afterburning system to the inlet of one of the channels 4 of one of the flow heat exchangers 3 and heats its body 13 to a temperature of 800 ° С-1000 ° С. When the specified temperature of the housing 13 is reached, the exhaust gas stream is switched into a similar channel of the next flow-through heat exchanger. After the heating of the last of the flowing single-case two-channel heat exchangers 3, the exhaust gas stream with a temperature of 1150 ° C-1250 ° C is sent from the afterburning system to the first of the heat exchangers 3. And the cycle of their alternating heating is repeated continuously.

After heating the casing of the first flow-through heat exchanger 3 to a temperature of 800 ° C-1000 ° C, compressed air is supplied to the input of its second channel 7, which is heated at the output to a temperature of 600 ° C-800 ° C and fed through channel 9 to the air inlet a turbine 10 connected to an electric energy generator 11. When the temperature of the exhaust air drops below 600 ° C, the air flow from the compressor switches to the same channel of the next flow-through heat exchanger. After the heating of the air in the last of the flow-through single-case two-channel heat exchangers, the air flow from the compressor is directed to the first of the heat exchangers and the cycle of their alternate heating is repeated continuously.

The air leaving the air turbine has a sufficiently high temperature for reuse and is directed through the channel 12 to combustion in the furnace of installation 1.

The application of the present invention can significantly reduce the cost of heat recovery of exhaust gases of the local self-government of any type due to the use of an open gas-air circuit instead of a closed traditional gas-water circuit with a water treatment system. The use of the invention allows to significantly increase the energy efficiency of generating electric energy through the use of an air turbine instead of a steam turbine.

Claims (5)

1. The method of utilization of the heat of combustion of solid household waste in an incinerator, which consists in the fact that the flow of exhaust gases generated in an incinerator equipped with an oven, afterburning and cooling systems, exhaust gas treatment and ash removal comes with a temperature of 1150 ° С-1250 ° C from the afterburning system alternately to the parallel-connected flowing two-channel gas-air heat exchangers forming together with a compressed air supply system, an air turbine and a generator a system of generating electric energy, while switching the flow of exhaust gases to each subsequent heat exchanger is carried out after heating the previous heat exchanger to a temperature of 800 ° C-1000 ° C, and the flow of exhaust gases cooled during passage in each heat exchanger is supplied after the gas purification system into the atmosphere, and after heating, compressed air is alternately supplied to each heat exchanger, which is heated in each device to a temperature of 600 ° C-800 ° C and enters the inlet GUSTs air turbine connected to an electric power generator, the passage through which compressed air is cooled and fed to the kiln incinerator. 2. The method according to claim 1, in which the exhaust gas stream is cooled when passing in each heat exchanger to a temperature of 250 ° C-350 ° C. 3. The method according to claim 1, in which compressed air, when passing through an air turbine, is cooled to a temperature of 250 ° C-350 ° C. 4. A device for utilization of the heat of combustion of solid household waste from an incineration plant equipped with an oven, exhaust gas afterburning systems, gas treatment, ash and slag removal system and connected to an electric energy generation system including a system of parallel-connected flow-through single-case two-channel gas-air heat exchangers with high intrinsic heat capacity that are heat-insulated from environment and made of high-temperature non-metallic refractory materials, while in One channel of each heat exchanger through a gas flow switch is connected to a channel for supplying an exhaust gas stream from the afterburning system, and the outlet of this channel is connected to a channel for exhausting a stream of exhaust gases into the gas purification system, the input of the second channel of each heat exchanger through an air flow switch is connected to a supply channel compressed air from the compressor, and the output of the second channel is connected to the channel for supplying heated compressed air to the input device of the air turbine connected to the generator m electric power output device which is connected to the feed duct the cooled compressed air into the kiln incinerator. 5. The device according to claim 4, in which the number of heat exchangers, the area and shape of the cross section of the input and output channels, as well as their length, are selected from the condition of heating the compressed air in the device with an exhaust gas stream to a temperature of 800 ° C-1000 ° C, and the pressure and flow rate of compressed air at the outlet of the second channel of each device are selected based on the characteristics of the air turbine.

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