RU2003102313A - METHOD FOR OPERATING ATOMIC STEAM TURBINE INSTALLATION AND INSTALLATION FOR ITS IMPLEMENTATION - Google Patents

Claims (7)

1. A method of operating a steam turbine power plant, in which water vapor is produced, for example, in a single-circuit water-water nuclear reactor of a reactor installation (RU) or, at least, in a double-circuit nuclear reactor installation, in which feed water compressed by a pump is passed through heated primary or, for example, the intermediate heat carrier side of the steam generators of a power plant, producing water vapor due to the heat of a nuclear reactor, which is subsequently heated in the heated side of the steam superheater The boiler, to the heating side of which is supplied for combustion, mainly gaseous or liquid fossil fuels, as well as an oxidizing agent in the form of, for example, atmospheric air, and then superheated steam, is sent to perform operation in a rotating electric generator of a steam turbine of a plant equipped with, inter alia, for example, by surface regenerative heaters of feed water, which is obtained in the condenser of the steam turbine part (PTC) of the installation, characterized in that it leaves the reactor installation, for example, from a single-circuit About a water-cooled nuclear reactor or of steam generators of a two- or three-circuit switchgear, steam is compressed in at least one, for example, multi-stage compressor, predominantly with intermediate cooling of its stages with feed water to such high up to supercritical pressure, which in combination with a higher temperature for heating the compressed steam in at least one superheater provides higher economical conjugate initial parameters s (pressure and temperature) steam diverted for doing work in the steam turbine plant. 2. The method according to claim 1, characterized in that the steam that is spent in the high-pressure cylinder (CVP) of the steam turbine is heated in the heated side of at least one additional superheater, to the heating side of which is fed mainly combustion gas or liquid fossil fuels, as well as an oxidizing agent in the form of atmospheric air, after which secondarily superheated water vapor is sent further along the standard cylinder path of the steam turbine of the power plant. 3. The method according to claim 1, characterized in that the water vapor compression compressor is rotated by a steam turbine of a power plant or by rotating a second electric generator of an additional gas turbine power plant, the combustion chamber of which runs on organic fuel, and the exhaust gases of a gas turbine are directed to the heating side of a heat exchanger-recuperator, providing the consumer in the heating season with hot water or steam from the heated side of the heat exchanger-recuperator. 4. The method according to claim 1, characterized in that the feed water is compressed by the pump to the maximum pressure at the entrance to the plant’s steam generators, which, at nominal thermodynamic parameters of the heating coolant, provides water to steam in the heated sides of the plant’s steam generators, as a result of which, together with subsequent compression by the compressor of the obtained steam and its additional heating in one or two intermediate steam superheaters of the steam turbine obtain higher conjugate initial parameters steam, which provide more efficient operation of the steam turbine part of the plant and a power plant in general. 5. The operation method according to claim 1, characterized in that during periods of shutdown (for example, during scheduled fuel overload) of a nuclear reactor and / or shutdown of a steam turbine part of the installation, including, for example, for operation of emergency-disconnected circulation pumps of the 1st the switchgear circuit, electric and thermal energy is produced due to the operation of a gas turbine power plant operating on organic fuel, while the shaft of the gas turbine plant is mainly disconnected from the shaft of the water vapor compression compressor. 6. Nuclear steam-turbine power plant, including a single-circuit or double-circuit nuclear reactor combined by tank cavities or pipelines, heating sides of steam generators and circulation pumps of the first, for example, water circuit, as well as a steam-turbine part (PTC) of a plant, including heated sides of electric power generators connected by pipelines, heated the side of at least one superheater of water vapor, the heating side of which is connected through locking and control devices with a source of gaseous or liquid fossil fuels, as well as, for example, through a gas blower with atmospheric air for burning fuel, a steam turbine driving an electric generator, a condenser, a condensate pump, a deaerator, a feed pump, and also mainly surface regenerative feed water heaters, characterized in that the output of water vapor from a single-circuit water-cooled nuclear reactor or from the heated sides of the steam generators of the reactor is connected via shut-off devices simultaneously with the input a steam house in the first or only multi-stage polytropic compressor driven either by a steam turbine or an additional gas turbine power plant, as well as with the steam inlet into the medium pressure cylinder (CSD) of the steam turbine or with the steam inlet into the organic superheater installed in front of the steam turbine DPS, wherein the output of the compressed water vapor from the polytropic compressor is connected to the steam inlet to the CVP of the steam turbine through the heated side of the organic superheater, and the heating sides s each superheater arranged to supply them in gaseous or liquid organic fuel and oxidizer - the atmospheric air. 7. Nuclear steam turbine power plant according to claim 10, characterized in that during operation of the plant in the mode with the maximum heat energy output to the consumer during the heating season or during, for example, disconnection of the shaft of a gas turbine installation (GTU) from the shaft of a steam polytropic compressor during shutdown reactor (for example, when overloading its core), the compressed gas turbine working fluid is sent to bypass the heat exchanger-recuperator in the gas turbine combustion chamber, the power of which is increased corresponding to an expanded range of the temperature of the heated working fluid, while the heat exchanger-recuperator is connected on the heated side to the selection of heat from the exhaust gases of the gas turbine to the consumer, and during operation of the installation in the mode with minimal heat to the consumer or during, for example, disconnection of the gas turbine shaft from the shaft of the steam polytropic compressor the compressed gas turbine working fluid is passed as a heated medium through the heating side of the heat exchanger-recuperator, and the power of the gas turbine combustion chamber installed behind it is reduced in accordance with the current range of the GTU heated working fluid.