RU133566U1 - STEAM GAS INSTALLATION - Google Patents

Abstract

Combined-cycle plant, including a gas turbine, a waste heat boiler with steam superheater and evaporator-economizer parts, an additional fuel combustion chamber, a gas condensate heater and a steam turbine, characterized in that the waste heat boiler is additionally equipped with a gas network water heater, while in the boiler flue a gas condensate heater, gas-tight gates, an additional combustion chamber are sequentially installed behind the superheater and evaporator-economizer chambers fuel, equipped with air channels, and a gas heater for network water, and a steam turbine of condensation type.

Description

The utility model relates to the field of power engineering and can be used in combined cycle plants with recovery boilers and condensing type steam turbines.

A well-known combined-cycle plant (Tsanev S.V., Burov V.D., Remezov A.N. Gas-turbine and combined-cycle plants of thermal power plants: Textbook for universities / Edited by S.V. Tsanev - M .: MEI Publishing House, 2002, 579 p., P. 426), containing a gas turbine, a single-circuit waste heat boiler with two afterburners and a gas mains heater, a backpressure steam turbine with production and heating steam extraction. Steam extraction steam turbine provides the technological heat load and heating of the mains water in a two-stage network installation. The peak of heat energy consumption is provided by fresh steam in the peak boiler, as well as by switching on the afterburner in front of the gas network heater in the recovery boiler.

The disadvantage of this technical solution is the lack of the possibility of using steam-gas units with heat recovery boilers and steam turbines of the condensation type to increase the thermal power, as well as the use of the afterburner only in peak heat consumption modes.

Known combined-cycle plant (patent for the invention of the Russian Federation No. 2100619, IPC F01K 21/04, 1997), adopted as a prototype containing a gas turbine, a steam turbine with regenerative heaters, a boiler with a combustion chamber (furnace) and furnace burners, equipped with a drum and a gas duct communicated at the inlet with the exhaust of the gas turbine with the possibility of blocking the specified inlet with a gas tight damper, and at the outlet with a firebox equipped with an additional convective heating surface located along the exhaust gases of the turbine, while the said gas duct keeps the air inlet connected with the blower with the possibility of overlapping it with a gas tight damper and located along the exhaust gases in front of the indicated additional surface.

The disadvantage of this technical solution is the high aerodynamic resistance of the recovery boiler when using the afterburner, the lack of the possibility of using steam-gas units with recovery boilers and condensing type turbines to increase the thermal power, and the use of the afterburner only in peak heat consumption modes.

In the well-known waste heat boilers of the listed combined cycle plants that produce steam by utilizing the thermal energy of the flue gases of the gas turbine unit, the following are located along the gas: superheater, evaporative circuit, gas condensate heater. For waste-heat boilers that are part of combined-cycle plants with a condensing type steam turbine, heat energy can be released only from the heat exchanger, the heating medium of which is the main condensate after the gas condensate heater. The installed heat capacity in this case is insignificant, the heat energy is released only for the station’s own needs. To supply thermal energy to an external consumer at stations with the indicated power units, the installation of hot-water boiler units is required. This is the main disadvantage of combined cycle plants with a condensing type steam turbine.

The technical result of the claimed utility model is to increase the efficiency of a combined cycle plant with waste heat boilers and condensing type steam turbines, namely, to increase the heat output and increase the reliability of heat supply.

The technical result is achieved by the fact that in a combined cycle plant including a gas turbine, a waste heat boiler with steam superheater and evaporator-economizer parts, an additional fuel combustion chamber, a gas condensate heater, and a steam turbine, a waste heat boiler is additionally equipped with a gas network water heater, while in the flue of the recovery boiler behind the steam superheater and evaporator-economizer chambers, a gas condensate heater, gas-tight gates are installed in series , an additional fuel combustion chamber equipped with air channels, and a gas heater for network water, and a steam turbine of a condensing type.

Placing the combustion chamber for additional fuel behind the gas condensate heater reduces the aerodynamic drag of the gas path in comparison with the prototype, therefore, in the inventive combined cycle plant, the magnitude of the decrease in the electric power of the gas turbine is less important.

The claimed technical solution is illustrated by the illustration, which shows a combined-cycle plant including a compressor 1, a combustion chamber of a gas turbine 2, a gas turbine 3, a waste heat boiler 4 with steam overheating and evaporation-economizer parts and a gas condensate heater 5. In the gas path of the waste heat boiler 4 behind the gas condensate heater 5, an additional fuel combustion chamber is installed 6. In the gas path of the recovery boiler 4, between the gas condensate heater 5 and the combustion chamber, an additional of the fuel 6, gas-tight shutters 7 are installed, which ensure that the gas duct is shut off when the gas turbine 2 is stopped. Burners 8 are installed in the additional fuel combustion chamber 6 along the entire cross section, and air supply ducts are installed in the side walls of the gas duct 9. Last along the exhaust gas flow The gas path of the recovery boiler 4 is equipped with a gas heater for network water 10. A condensing type steam turbine (not shown in the illustration).

Combined-cycle plant operates as follows. Compressed to the required pressure, the atmospheric air from the compressor 1 enters the combustion chamber of the gas turbine 2, and the main fuel (natural gas) is supplied there, which, when burned, forms a large amount of high-pressure combustion products entering the gas turbine 3. The exhaust gases of the gas turbine 3 with a temperature of 480 ÷ 550 ° C enter the waste heat boiler 4, steam-overheating and evaporative-economizer parts pass sequentially where, due to heat recovery, the temperature of the exhaust gases decreases to 95 ÷ 120 ° C. After the gas condensate heater 5, the exhaust gases enter the combustion chamber for additional fuel 6, where in the exhaust gas stream additional fuel (natural gas) is supplied to the burner devices 8. As a result, the temperature of the exhaust gases increases to 200 ÷ 270 ° C and the coefficient decreases excess air. In the gas network water heater 10, the network water is heated to a temperature corresponding to the temperature schedule. Behind the gas heater for network water 10, exhaust gases with a temperature of 105 ÷ 110 ° C are discharged through the chimney into the atmosphere. In the event of a shutdown of the gas turbine 3, the gas tight shutters 7 close the gas duct, and air is supplied through the air supply channels 9 in an amount ensuring complete combustion of the fuel (natural gas).

An increase in the thermal power of a combined cycle plant is ensured by installing an additional fuel combustion chamber 6 and a gas network water heater 10 in the gas duct of the recovery boiler 4 behind the gas condensate heater 5. The oxygen contained in the exhaust gases of the gas turbine is used as an oxidizing agent for the fuel burned in the recovery boiler installation. In cases of a gas turbine 3 shutdown, for uninterrupted supply of thermal energy to the consumer, it is possible to autonomously operate the additional fuel combustion chamber 6 and the gas water heater 10. In autonomous operation, the air channels 9 provide the necessary amount of air for burning fuel to the burner devices 8, and the chamber burning additional fuel 6 and a gas network water heater 10 are separated from the chambers of the recovery boiler using gas-tight shutters 8. Also The inventive combined cycle plant provides a reduction in heat loss with flue gases, because the coefficient of excess air in the exhaust gases decreases.

A calculation based on a mathematical model of a combined cycle gas turbine plant shows that the proposed variant of the recovery boiler is capable of providing an increase in efficiency by 4.42% compared with the well-known combined cycle gas turbine unit with a steam turbine.

Thus, the application of the claimed utility model provides an increase in the efficiency of a combined cycle plant with waste heat boilers and condensing type steam turbines.

Claims (1)

Combined-cycle plant, including a gas turbine, a waste heat boiler with steam superheater and evaporator-economizer parts, an additional fuel combustion chamber, a gas condensate heater and a steam turbine, characterized in that the waste heat boiler is additionally equipped with a gas network water heater, while in the boiler flue a gas condensate heater, gas-tight gates, an additional combustion chamber are sequentially installed behind the superheater and evaporator-economizer chambers fuel, equipped with air channels, and a gas heater for network water, and a steam turbine of condensation type.

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