RU2528190C2 - Steam gas plant - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to power engineering. A steam gas plant comprises a gas turbine plant, a boiler-utiliser, a steam turbine plant, a discharge gas flue, a stack, connecting pipelines, an external gas flue, a burner device and a steam reheater connected to the external gas flue. The boiler-utiliser and the steam reheater comprise modules of heating surfaces of a steam and water circuit of the steam gas plant. The external gas flue is made in the form of a recirculation circuit equipped with a fan. The outlet of the external gas flue is connected to a boiler-utiliser in the zone of placement of heating surface modules, and the outlet is taken out upstream the zone of placement of modules of boiler-utiliser heating surfaces.

EFFECT: invention makes it possible to increase efficiency of using heat of gaseous combustion products and efficiency of a plant.

11 cl, 1 dwg

Description

The invention relates to the production of thermal and electric energy, namely to the production of thermal and electric energy based on installations operating on a binary cycle in the combined use of gas turbine and steam turbine installations.

A known combined-cycle gas recovery unit, which includes a gas turbine installation consisting of a compressor, a gas turbine and a generator located on one shaft, a combustion chamber located between the compressor and the gas turbine, and a steam turbine installation consisting of a steam turbine and a generator located on one shaft, a regeneration system, a condenser, condensate and feed pumps, a deaerator and connecting pipelines, a waste heat boiler located on a gas duct behind a gas turbine , Which water and steam conduits communicates with a steam turbine installation (US Patent №4466241 IPC R02S 6/18, publication date 21.08.1984).

The main disadvantage of this installation is that the temperature of the combustion products behind the gas turbine does not allow to obtain steam in the recovery boiler with the temperature necessary for traditional steam turbine plants at 535-565 ° С. Steam in a known installation has a temperature of 500-520 ° C. The operation of the turbine with a low steam temperature reduces the efficiency of the steam turbine unit and the efficiency of the whole combined cycle plant.

The closest analogue of the claimed invention is a well-known combined-cycle plant containing a gas turbine installation connected to it through a gas path by a transitional gas duct of a recovery boiler, a steam turbine installation connected by steam and water pipelines to a recovery boiler and having a common steam-water circuit, an exhaust gas duct, a chimney with it , connecting pipelines, as well as an external gas duct, a superheater and a burner connected to an external gas duct, and a recovery boiler and a superheater neigh modules steam circuit of heating surfaces of a steam turbine installation (Russian patent for invention №2078229, IPC F02C 6/18, publication date 04.27.1997). The inlet of the external gas duct is connected through a gate to a transitional gas duct of a combined-cycle plant, and the outlet is connected to a waste gas duct.

The main disadvantage of the known combined-cycle plant is the lack of efficient use of the heat of the gaseous products of combustion passing through an external gas duct in the absence of heat load from the mains water. In this installation, due to the connection of the output of the external gas duct with the exhaust gas duct, the combustion products from the external gas duct enter the exhaust gas duct, mix with the combustion products that passed the recovery boiler, raising the temperature of the latter, and then are discharged into the chimney. In turn, an increase in temperature of the combustion products removed from the installation leads to a decrease in the efficiency of the combined cycle plant as a whole. In addition, the well-known combined-cycle plant has a number of design flaws, in particular, the difficulty of regulating the exhaust gas flow rate, the complexity of manufacturing and operating the regulating gate, at high gas temperatures reducing the reliability of the installation, the increased aerodynamic resistance of the gas path, reducing the power and efficiency of the gas turbine and combined-cycle plant generally.

The objective of the invention is to increase the efficiency of a combined cycle plant due to a more rational and full use of the heat of the gaseous products of combustion resulting from the combustion of fuel.

The task is achieved by the fact that in the well-known combined-cycle plant containing a gas turbine unit connected to it through a gas path by a transitional gas duct, a recovery boiler, a steam turbine installation connected by steam and water pipelines to a recovery boiler and having a common steam-water circuit with it, a waste gas duct, a chimney, connecting pipes, an external gas duct, a superheater and a burner connected to an external gas duct, the recovery boiler and the superheater comprising modules According to the proposed technical solution, the external gas duct is made in the form of a recirculation circuit equipped with a fan, and the input of the external gas duct is connected to the recovery boiler in the zone of placement of the modules of the heating surfaces, and the output is output in front of the zone of placement of the modules of the boiler heating surfaces -utilizer.

It is possible to carry out an installation in which the output of an external gas duct is connected to a waste heat boiler.

It is possible to carry out an installation in which the output of an external duct is connected to a transition duct.

It is possible to carry out an installation equipped with a low-pressure steam turbine installation with its own steam-water circuit of one or more pressures.

It is possible to carry out an installation in which the steam-water circuits of both steam-turbine plants are configured to communicate with each other.

It is possible to carry out an installation equipped with an intermediate steam overheating circuit, and the waste heat boiler and superheater contain additional modules of the heating surfaces that are part of the mentioned circuit.

It is possible to carry out an installation equipped with a system of regenerative heating of condensate and feed water with steam from turbine offsets.

It is possible to perform an installation in which the inlet of the external gas duct is equipped with an air heater configured to use the heat of the combustion products of the burner device of the superheater.

It is possible to carry out an installation in which the external gas duct is equipped with an oxygen input device.

It is possible to carry out an installation in which the external duct is equipped with a device for introducing oxygen-enriched air into it.

It is possible to carry out an installation in which the external gas duct is equipped with an atmospheric air input device.

The technical result is to increase the efficiency of using the heat of gaseous products of combustion, which becomes possible due to the direction of part of the products of combustion from the recovery boiler to an external gas duct and their subsequent use for heating steam in a superheater.

Equipping a combined cycle gas turbine unit with a low pressure steam turbine unit with its own steam-water circuit allows an additional increase in the amount of generated electricity, and equipping the superheater with additional heating surface modules makes it possible to more efficiently use the heat of gaseous products of combustion.

The implementation of the steam-water circuits of both steam-turbine units with the possibility of communication with each other allows you to more flexibly change the operating mode of a combined-cycle plant depending on external conditions.

Installing an air heater in the external gas duct allows reducing fuel consumption in the burner device of the superheater and lowering the temperature of the combustion products leaving the external gas duct to the temperature of the combustion products after the gas turbine in front of the recovery boiler to ensure uniform temperature field.

It becomes possible to reduce the aerodynamic drag of the gas path of the combined cycle plant by eliminating the regulating gate from the circuit and thereby increasing the electric power of the gas turbine, i.e. electric power and efficiency of a combined cycle plant as a whole.

The equipment of the installation with a system of regenerative heating of condensate and feed water with steam from turbine offsets allows more efficient use of the heat of steam in the turbine.

The equipment of the external gas duct with a device for introducing oxygen enriched in air or atmospheric oxygen into it allows the burner device to operate at a low oxygen content in the combustion products taken from the waste heat boiler.

The drawing shows the proposed combined cycle plant.

The combined-cycle plant has an air intake device 1 connected by an air duct to a gas turbine installation 2, which is connected through a gas duct to a transitional gas duct 3 with a recovery boiler 10 and an exhaust gas duct 9 with a chimney 11. The combined-gas plant is equipped with a burner 6 and a superheater 7 mounted on an external gas duct made in the form of a recirculation circuit, including a fan 5, an air heater 43, flues 44, 45, 17, 18, 19. The inlet duct 18 of the recirculation circuit is connected to the boiler tilizatoru 10 in the zone where the modules of heating surfaces disposed inside the recovery boiler flue 10. The input 18 may be equipped with input of oxygen therein, oxygen-enriched air or atmospheric air (not shown). The outlet gas duct 45 of the recirculation loop is connected to the waste heat boiler 10 in front of the area where the surface heating modules are located in it. It is possible to connect the duct 45 to the transition duct 3 in the area between the gas turbine unit 2 and the waste heat boiler 10.

The combined-cycle plant contains a high-pressure steam turbine unit 13 having a steam-water circuit joint with a recovery boiler 10, consisting of a condensate line 14, a regenerative condensate heater 41, a regenerative feed water heater 42, a feed pump 28, a feed water pipe 26, heating surface modules 35, 38 , 39 in the waste heat boiler 10, pipe 15, heating surface modules 32 in the superheater 7, pipe 16. The high-pressure steam turbine 13 also has an intermediate circuit full-time steam overheating, consisting of pipeline 21, heating surface modules 36 in a waste heat boiler 10, pipe 22, heating surface modules 33 in a superheater 7, pipe 23. Feed water pipelines are equipped with shut-off valves 31 and 29. In turn, heaters 41 and 42 together with the pipelines connecting them to the turbine of the steam turbine unit 13, form a system of regenerative heating of condensate and feed water with steam from the turbine offsets.

The combined-cycle plant contains a low-pressure steam turbine installation 20 with a low-pressure steam-water circuit consisting of a pipeline 27, modules of heating surfaces 37, 25, 12 in a waste heat boiler 10, a pipe 30. Steam and water circuits of high and low pressure are interconnected by a pipe 24 with installed on shutoff valves 40. The pipeline 14, in turn, is equipped with shutoff valves 34. Steam and water circuits of high and low pressure have a common deaerator installation 8, combined with a low pressure drum 4 waste heat boilers 10. It is possible to install a separate deaerator that is not combined with a low pressure drum 4.

The proposed combined cycle plant operates as follows.

Atmospheric air is supplied through the air intake device 1 to the compressor inlet of the gas turbine unit 2, from which, after burning the fuel and generating useful work, the hot gaseous products of combustion are supplied by the gas duct 3 to the recovery boiler 10, from which, after the heat has been transferred to produce steam, the combustion products with a temperature of 80- 100 ° C is discharged through the gas duct 9 into the chimney 11. The superheated high-pressure steam produced in the recovery boiler 10 is fed to the high-pressure steam circuit through a pipe 15 from which it enters to a superheater 7, equipped with a burner 6. In it, due to the burning of additional fuel and using the modules of the heating surfaces 32, steam is overheated to a temperature of 540-570 ° C. Then, the superheated steam is supplied by a pipe 16 to a high-pressure steam turbine unit 13. After partial operation and development of useful work in a steam-turbine unit 13, the steam enters the intermediate superheat circuit through the pipe 21 to the heating surface modules 36 in the recovery boiler 10. Then, the steam passes through the pipe 22 for additional overheating using the modules of the heating surfaces 33 to the superheater 7. Next, the superheated steam by the pipe 23 is returned to the steam turbine unit 13, and after generating useful work through the deaerator 8, combined with a low-pressure drum 4, the pump 28 in the form of feed water is returned through pipelines 14 and 26 to the recovery boiler 10 for the next steam production using the modules of heating surfaces 35, 38, 39. Using shut-off valves 31 and 29, the system of regenerative heating of feed water 42 with steam from turbine offsets can be turned off or turned on, and with the help of valves 40 and 34, respectively, the system of regenerative heating of condensate 41 is turned off or on. Using heaters 41, 42 add It contributes to increasing the efficiency of the steam turbine unit.

In a low-pressure steam-water circuit, a steam turbine of a steam installation of 20, heated by means of the heating surface modules 37 of the recovery boiler 10, is fed by a pipe 30 to a low-pressure steam turbine 20. Then, after generating useful work in the form of feed water, the pipe 27 again enters the boiler for heating waste disposer 10.

The gaseous products of combustion generated in the burner 6, give part of their heat to the modules of the heating surfaces 32, 33 in the superheater 7. Then, the products of combustion through the duct 19 enter the air heater 43, where they also give part of the heat to heat the gases sucked in by the fan 5 , and then along the flue 45 are fed to the waste heat boiler 10 in front of the zone where the modules of the heating surfaces are located in it, or they can be fed into the transition flue 3, if the flue 45 is connected to it. Further, the combustion products in the waste heat boiler 10 give heat to the modules of the heating surfaces 35, 36 of the high-pressure steam-water circuit, i.e. are used most rationally. Hot combustion products having a sufficient oxygen content by the duct 18 from the waste heat boiler 10 by a recirculation fan 5 are fed through the duct 44 for heating to the air heater 43 and then by the duct 17 are fed to the burner device 6 of the superheater 7. The use of an air heater 43 in the recirculation loop allows to reduce fuel consumption in the burner device 6, and also reduce the temperature of the combustion products after the superheater 7 to the temperature of the combustion products after the gas turbine by During a recovery boiler 10. When there is insufficient oxygen in the combustion products before the burner device 6 to the duct 18 can be installed in the device for supplying oxygen gas duct 18, oxygen-enriched air or atmospheric air.

Claims (11)

1. Combined-cycle plant containing a gas turbine unit connected to it through a gas path by a transitional gas duct, a recovery boiler, a steam turbine installation connected by steam and water pipelines to a recovery boiler and having a common steam-water circuit, a waste gas duct, a chimney, connecting pipelines, as well as an external gas duct, a superheater and a burner connected to an external gas duct, wherein the recovery boiler and the superheater comprise modules of the heating surfaces of the steam-water circuit to the steam A plant installation, characterized in that the external gas duct is made in the form of a recirculation circuit equipped with a fan, and the input of the external gas duct is connected to the waste heat boiler in the area where the heating surface modules are located, and the output is output in front of the zone where the heat surfaces of the heat recovery boiler modules are located. 2. Installation according to claim 1, characterized in that the output of the external gas duct is connected to a waste heat boiler. 3. Installation according to claim 1, characterized in that the output of the external duct connected to the transition duct. 4. Installation according to claim 1, characterized in that it is additionally equipped with a low pressure steam turbine installation with its own steam-water circuit of one or more pressures. 5. Installation according to claim 4, characterized in that the steam-water circuits of both steam-turbine plants are configured to communicate with each other. 6. Installation according to claim 1, characterized in that it is equipped with an intermediate steam overheating circuit, and the recovery boiler and superheater contain additional modules of the heating surfaces that are part of the said circuit. 7. Installation according to claim 1, characterized in that the steam turbine installation is equipped with a system of regenerative heating of the condensate and feed water with steam from the turbine offsets. 8. Installation according to claim 1, characterized in that the inlet of the external gas duct is equipped with an air heater configured to use the heat of the combustion products from the burner device of the superheater. 9. Installation according to claim 1, characterized in that the external gas duct is equipped with a device for introducing oxygen into it. 10. Installation according to claim 1, characterized in that the external gas duct is equipped with a device for introducing oxygen-enriched air into it. 11. Installation according to claim 1, characterized in that the external gas duct is equipped with a device for introducing atmospheric air into it.

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