RU2013138267A - METHOD FOR WORKING STEAM-GAS POWER INSTALLATION AND DEVICE FOR ITS IMPLEMENTATION - Google Patents

Abstract

1. The method of operation of a combined cycle gas turbine power plant, including compressing air, heating it with burning fuel in a combustion chamber, expanding a heated working fluid in a gas generator turbine using obtained mechanical energy to compress air, heating a working fluid in a afterburner, expanding a working fluid in a power turbine to below atmospheric pressure, cooling the working fluid with the utilization of its thermal energy to generate steam and for heating, expansion of the generated steam in a steam turbine, with a supply its smaller part into the combustion chamber. overheating of most of this steam with its supply to the afterburner, extraction of water condensate from the steam component of the expanded working fluid with its use in the generation of steam. the compression of the dried working fluid and its release into the atmosphere, the use of the obtained mechanical energy of a power turbine to generate electricity and for the compression of the dried working fluid, characterized in that the cooling of the expanded working fluid, after generating steam, is carried out in a heating heat exchanger, and the steam component is condensed in a contact cooler-condenser due to the injection of cooling water; a smaller part of the generated steam is expanded in a steam turbine to a pressure exceeding the pressure of the compressed air in the combustion chamber by at least 20%, and most of it to a pressure exceeding the pressure in the afterburner by at least 20%; the heat energy of the compressed, dried working fluid is utilized to heat part of the aqueous condensate used to generate steam. 2. Combined cycle energy

Claims (2)

1. The method of operation of a combined cycle gas turbine power plant, including compressing air, heating it with burning fuel in a combustion chamber, expanding a heated working fluid in a gas generator turbine using obtained mechanical energy to compress air, heating a working fluid in a afterburner, expanding a working fluid in a power turbine to below atmospheric pressure, cooling the working fluid with the utilization of its thermal energy to generate steam and for heating, expansion of the generated steam in a steam turbine, with a supply its smaller part into the combustion chamber. overheating of most of this steam with its supply to the afterburner, extraction of water condensate from the steam component of the expanded working fluid with its use in the generation of steam. the compression of the dried working fluid and its release into the atmosphere, the use of the obtained mechanical energy of a power turbine to generate electricity and for the compression of the dried working fluid, characterized in that the cooling of the expanded working fluid, after generating steam, is carried out in a heating heat exchanger, and the steam component is condensed in a contact cooler-condenser due to the injection of cooling water; a smaller part of the generated steam is expanded in a steam turbine to a pressure exceeding the pressure of the compressed air in the combustion chamber by at least 20%, and most of it to a pressure exceeding the pressure in the afterburner by at least 20%; the heat energy of the compressed, dried working fluid is utilized to heat part of the aqueous condensate used to generate steam. 2. Combined-cycle power plant implementing the method of operation of combined-cycle power plant according to claim 1, comprising a compressor, a combustion chamber, a gas generator turbine, a afterburner, a free power turbine, and a steam turbine. an electric generator, an exhaust gas compressor, a recovery boiler, including a superheater, a recovery steam generator, a heat recovery heat exchanger, a cooler-condenser; the compressor is connected by a shaft to the gas generator turbine, the free power turbine is connected by a common shaft to the power generator, steam turbine and exhaust gas compressor, the compressor output through the combustion chamber is communicated with the gas generator turbine inlet, the output of which is communicated with the recovery boiler through the afterburner and the free power turbine, the cooler output -condenser is connected through the working fluid through the exhaust gas compressor to the atmosphere, the output of the cooler-condenser is connected via condensate through a waste steam generator with the input of the steam turbine, which is in pairs with the combustion chamber and the afterburner, characterized in that it additionally uses a heat exchanger, contact cooler-condenser, condensate collection tank, condensate cooler, steam turbine made with an intermediate selection of steam; the heat-exchanging heat exchanger is placed along the working fluid behind the recovery steam generator, the condensate collecting tank is connected at the condensate inlet to the contact cooler-condenser, and at the output it is connected by one condensate conduit through an additional heat exchanger to the input of the recovery steam generator, and the second condensate conduit through the condensate cooler with the contact cooler inlet a condenser, a heat exchanger is installed in the pipeline of a compressed, dried working fluid, its inlet is connected via condensate to a collection tank ensata, and the output - to the input of heat recovery steam generator.