RU2137981C1 - Technological power plant for thermal processing of solid waste - Google Patents

Abstract

FIELD: processing of solid waste containing organic matter to generate heat and electricity. SUBSTANCE: technological power plant for thermal processing of solid waste includes drier, pyrolysis chamber and gas generator. It is combined with steam and gas plant incorporating gas-turbine unit with combustion chamber and gas turbine, steam-turbine set with waste-heat boiler and steam turbine and lines to supply natural gas to pyrolysis chamber, gas generator and combustion chamber. Air heater is installed in gas conduit of waste-heat boiler and combustion chamber of gas-turbine unit and gas generator are fitted with devices that supply them with hot air. In addition technological power plant can include line to supply pyrolysis gas to drier, pyrolysis furnace, gas generator and combustion chamber. Hot air can be supplied to gas generator from air heater of waste-heat boiler or from autonomous steam or fire air heaters. EFFECT: increased efficiency of conversion of energy during processing of solid household garbage. 4 cl, 3 dwg

Description

 The invention relates to the processing of solid waste containing an organic component, for example, municipal solid waste (MSW).

 The most promising is the energy technological processing of solid waste with the generation of heat and electricity.

 Known energy-technology installation for thermal processing of solid waste containing a pyrolytic furnace, a gas generator, a gas treatment device, a gas turbine installation and a steam recovery boiler [1]. A disadvantage of the known installation is the relatively low efficiency of the thermodynamic cycle of electricity generation due to the lack of a steam turbine installation.

 The achieved result of the invention is to increase the efficiency of energy conversion during energy technological processing of solid waste.

 This is ensured by the fact that the energy-technological installation for thermal processing of solid waste, containing a pyrolytic furnace, a gas generator, a gas treatment device, a gas turbine installation and a steam recovery boiler, according to the invention further comprises a steam turbine installation working in conjunction with a gas turbine installation in a single thermodynamic combined-cycle gas-to-heat conversion to heat mechanical energy on the shafts of the corresponding steam and gas turbines, and the line for supplying natural gas to pyrolytic Coy furnace gasifier and the combustion chamber, in the gas path recovery boiler installed air heater and the combustion chamber of a gas turbine plant and the gas generator are provided with feeding devices are hot air.

 Additionally, according to the invention, the installation may include a supply line of pyrolysis gas to the drying device, pyrolytic furnace, gas generator and combustion chamber.

 The hot air supply to the gas generator according to the invention can be made in the form of an air duct connected to the air heater of the recovery boiler, as a separate steam air heater, connected on the heating side to a selection of a steam turbine steam turbine, or as a separate fire air heater.

 In FIG. 1 shows a schematic diagram of the described energy-technology installation with the supply of hot air to the gas generator from the air heater of the recovery boiler; in FIG. 2 - the same scheme with the supply of hot air to the gas generator from the steam air heater; in FIG. 3 - the same scheme with the supply of hot air to the gas generator from a separate fired air heater.

 The installation comprises a pyrolytic furnace 1, a gas generator 2, a gas treatment device 3, a gas turbine unit (GTU) with a combustion chamber 4 and a gas turbine 5, a steam recovery boiler (KU) 6, a steam turbine unit (PTU) with a steam turbine 7, and lines 8.9 , 10 supply of natural gas, respectively, to the pyrolytic furnace 1, the gas generator 2 and the combustion chamber 4. GTU KU and PTU together form a combined cycle gas turbine unit (CCGT) 11 operating in a single thermodynamic combined-cycle gas-to-heat conversion on the shafts of gas 5 and steam 7 turbines. In this case, the exhaust of the gas turbine 5 is connected by a gas line 12 to KU 6, connected to the steam turbine 7 on the steam side by the steam line 13 and by water through the line 14. In the gas path 15, 16 KU 6, an air heater 17 is installed, which is connected via hot air to the combustion chamber 4 gas turbine installation and gas generator 2 (Fig. 1) air ducts, respectively 18 and 19.

 The apparatus may include a drying device 20 and a device 21 for cleaning the spent drying agent. Hopper 22 with estrus 23 is used to load solid waste into the power plant, pipeline 24 is used to discharge slag from the gas generator 2. To the drying device 20, the pyrolytic furnace 1, the gas generator 2 and the gas turbine combustion chamber 4 are connected supply lines 25, 26, 27, 28, respectively pyrolysis gas. The gas pipeline 29 serves to divert the generator gas from the gas generator 2, the gas pipeline 30 to return the ash collected in the gas treatment device 3 to the gas generator 2, the gas pipeline 31 to discharge the pyrolysis gas from the pyrolytic furnace 1, the gas pipe 32 to supply from the pyrolytic furnace 1 to the gas generator 2 solid carbonized pyrolysis products, a gas duct 33 for discharging flue gases from KU 6 into the chimney 34 and a gas duct 35 for discharging the spent drying agent through the device 21 for purifying the latter into the same chimney 34. Air duct 36 is used to supply cold air to the air heater 17.

 In other embodiments (FIGS. 2 and 3), the hot air heater 17 is connected by air duct 18 only to the gas turbine combustion chamber 4. To supply hot air to the gas generator 2, in one of these options (Fig. 2) a steam air heater 37 is provided, connected on the heating side to the selection of the steam turbine 7 by a steam line 38, by condensate - a pipe 39 to the water line 14 of the vocational school. According to another embodiment (Fig. 3), a separate fire air heater 40 with a burner device (not shown) connected to the natural gas pipeline 41 is provided for supplying hot gas to the gas generator 2. It is advisable to use separate air heaters to supply the gas generator with hot air when placing the equipment of the technological part of the installation at some distance from the energy block (extension of the incinerator complex to the existing power plant with combined cycle gas ohm energy conversion).

 The installation according to the invention operates as follows. Sorted from large solid inclusions and crushed solid waste are loaded into the hopper 22, from where they flow through the heat pipe 23 into a drying device 20, for example, a drum dryer heated by the combustion products of pyrolysis gas supplied to the combustion chamber (not shown) of the dryer 20 through gas pipeline 25 from gas pipeline 31 The vapor-gas mixture formed in the dryer 20 (spent drying agent) is discharged through the gas duct 35 through the cleaning device 21 into the chimney 34. The solid waste dried to the required degree is fed to the pyrolytic furnace 1, where it is subjected by heat treatment by the combustion products of pyrolysis gas taken through gas line 26 from gas line 31 to the combustion chamber (not shown) of pyrolytic furnace 1. Additionally, natural gas can be supplied to the pyrolytic furnace 1 through gas pipe 8, which allows the unit to be started and the required temperature conditions of the pyrolysis process with fluctuations in the composition of solid waste and pyrolysis gas. Solid carbonized pyrolysis products (pyrocarbon) are fed via line 32 to gas generator 2, where they are gasified with hot air supplied through air line 19. A part of the pyrolysis gas discharged through the gas pipeline 31 from the pyrolytic furnace 1 is sent through the gas pipeline 27 to the gas generator 2 through the gas treatment device 3. The resulting slag is discharged from the gas generator 2 through the pipe 24. A natural gas supply is provided for igniting the installation in the gas generator 2 through the pipe 9. From the gas generator 2, the generator gas is supplied through the gas pipeline 29 to the gas purification device 3, the collected ash from which can be returned to the gas generator 2 through the pipeline 19. The purified generator gas is supplied to the gas turbine combustion chamber 4, where additional gas and gas can be supplied via gas pipeline 10 pyrolysis gas. The combustion products from the combustion chamber 4 are fed to the inlet of a gas turbine 5 that generates electricity, and the gases exhausted in the turbine 5 are discharged through the gas pipeline 12 to the KU 6. The heat of the combustion products in the KU 6 is spent mainly on the generation of water vapor supplied through the steam line 13 to the steam vocational school turbine 7, which also generates electricity, and partially to heat the air entering through the air duct 36 to the air heater 17, placed in the gas path 15, 16 KU 6. The condensate of the steam spent in the steam turbine 7 is supplied to recirculation to the water line 14 of the KU 7. The air heated in the gas air heater 17 passes through the air duct 18 to the gas turbine combustion chamber 4 and, in one embodiment (Fig. 1), to the gas generator 2. In other embodiments, hot air enters the gas generator 2 from autonomous steam air heaters 37 (Fig. 2) or firing 40 (Fig. 3).

 Linking the heat balance of the power plant with the generation of electricity in a combined steam and gas cycle can significantly increase its efficiency.

Sourse of information
1. RF patent N 2075694, 6 F 23 G 5/00, 1991.

Claims (5)

 1. Energy-technological installation for the thermal processing of solid waste, containing a pyrolytic furnace, gas generator, gas treatment device, gas turbine installation and steam recovery boiler, characterized in that it further comprises a steam turbine installation, working in conjunction with a recovery boiler and gas turbine in a single thermodynamic combined-cycle gas and steam the cycle of converting heat into mechanical energy on the shafts of the corresponding steam and gas turbines, and the line for supplying natural gas to pyrolytic Coy furnace gasifier and the combustion chamber, in the gas path recovery boiler installed air heater and the combustion chamber of a gas turbine plant and the gas generator are provided with feeding devices are hot air.  2. The energy technology installation according to claim 1, characterized in that it further comprises lines for supplying pyrolysis gas to the drying device, pyrolytic furnace, gas generator and combustion chamber.  3. The energy-technological installation according to claim 1 or 2, characterized in that the device for supplying hot air to the gas generator is made in the form of an air duct connected to the air heater of the recovery boiler.  4. The energy-technology installation according to claim 1 or 2, characterized in that the device for supplying hot air to the gas generator is made in the form of a separate steam air heater connected on the heating side to a selection of a steam turbine of a steam turbine installation.  5. The energy-technology installation according to claim 1 or 2, characterized in that the device for supplying hot air to the gas generator is made in the form of a separate fire air heater.

Images