RU98625U1 - NUCLEAR GAS STATION - Google Patents

Abstract

1. Nuclear steam-gas installation containing a reactor located on the central axis of the dome of a dry cooling tower, under which all elements of a nuclear steam-gas installation are located, having at least two independent circulation loops, each of which consists of two closed circuits, the first of which includes includes an evaporator with a separator, located in a safety housing, and the second circuit includes a high-pressure superheater, a low-pressure superheater and an economizer in series in the gas path, a high-pressure steam turbine and a low-pressure steam turbine, a gas turbine with a combustion chamber and a compressor, electric generators, air coolers connected by means of an intermediate circuit with a condenser, characterized in that the compressor is made of two parts in the form of a low pressure compressor and a high pressure compressor, between which an intermediate air cooler is installed, having two inputs and two outputs: one inlet is connected to the condenser, the outlet is connected to the first inlet of the introduced deaerator, the second inlet is connected to a low pressure compressor, and its outlet is connected to a high pressure compressor; the unit is equipped with a gas heater with two inlets and two outlets, the first inlet which is connected to the fuel gas pipeline, and its outlet to the combustion chamber of the gas turbine, the second inlet is connected to the low-pressure steam turbine, and its outlet to the condenser, the deaerator, in addition, has a second inlet and one outlet, the second inlet of which is connected to a low-pressure turbine, and its output with an economizer. ! 2. Nuclear steam

Description

The utility model relates to nuclear energy, heat and power engineering, and can be applied at a nuclear power plant to create a single nuclear complex with a steam turbine and gas turbine.

Currently, nuclear power plants are a promising source of energy. A significant number of technical solutions are known related to nuclear power plants having double-circuit nuclear power plants with a pressurized water-water power reactor and a nuclear steam generating unit, divided into several independent circulation circuits (loops), for example, RF patent 2228488, RF patent 2205969 A known patent of the Russian Federation 1428078 with publication of 09/10/1999, which describes a nuclear power combined cycle plant, which contains a reactor connected through a steam generator to the steam an urban circuit with primary and intermediate superheaters and heaters for high and low pressure feed water, a gas turbine. The disadvantage of these installations is the relatively low efficiency and relatively low reliability.

A technical solution is known for a nuclear combined-cycle plant described in the catalog of gas-turbine equipment 2003-2004 p. 172 of the specialized information-analytical journal "Gas-turbine technologies", which includes a reactor and at least two independent circulation loops, each of which consists of two closed circuits, the first of which includes an evaporator with a separator located in the safety housing, and the second circuit includes: steam in series in the gas path high pressure superheater, low pressure superheater, economizer, high pressure steam turbine with high pressure heater and low pressure steam turbine with low pressure heater, gas turbine, condenser, electric generators.

The closest technical solution is the technical solution of a nuclear combined-cycle plant, described by the patent for utility model of the Russian Federation No. 86783

This patent describes a nuclear combined cycle plant containing a reactor 1 located on the central axis of the dome 14, a dry cooling tower, under which all elements of a nuclear combined cycle plant are located, having at least two independent circulation loops, each of which consists of two closed loops the first of which includes an evaporator 2 with a separator 3 located in the safety housing 4, and the second circuit includes: high pressure superheater sequentially located in the gas path 5 I 6, a low pressure superheater 7, and an economizer 8, a high pressure steam turbine 9 and a low pressure steam turbine 10, a gas turbine 11, with a combustion chamber 12, and a compressor, electric generators 13, air coolers 14 connected via an intermediate circuit 15 s capacitor 16.

The disadvantage of this solution is the relatively low efficiency of the installation and the relatively low reliability.

The objective of the utility model is to increase the efficiency of the installation and the reliability of its operation.

The technical result of the claimed utility model is to increase the efficiency and reliability of a nuclear combined cycle plant.

To achieve the technical result, the compressor is made of two parts in the form of a low-pressure compressor 20 and a high-pressure compressor 21, between which an intermediate air cooler 18 is installed, having two inputs and two outputs: one input is connected to a condenser 16, the output to the first input of the input deaerator 17, the second input with a low pressure compressor 21, and its output with a high pressure compressor 22, the installation is equipped with a gas heater 19, which has two inputs and two outputs, the first input of which is connected to the fuel gas pipeline, and its output - with the combustion chamber 12 of the gas turbine 11, the second input is connected to the low pressure steam turbine 10, and its output - to the condenser 16, the deaerator 17, in addition, has a second input and one output, the second input of which is connected with a low pressure turbine, and its output with an economizer 8.

The refrigerator 18 can be made of a vertical shell-and-tube type, the coils of which have a small bending radius and are combined into hexagonal heat exchange modules.

Air cooling units can be located at two levels, with the same distance between the units and with the same offset pitch at each level, and are connected in pairs, and units from the first level and units from the second level are connected in series.

The gas heater can be equipped with a tank located in the lower part of the heat exchanger, which collects moisture and liquid impurities, separated during the movement of fuel gas inside the coils of small bending radius.

Figure 1 shows a schematic diagram of one loop of a nuclear combined cycle plant

Figure 2 shows a cross section of a nuclear combined cycle plant;

Figure 3 shows the module of a gas heater or an intermediate air cooler, vertical design, the coils of which have a small bending radius.

A nuclear combined-cycle plant contains a reactor 1 located on the central axis of the dry-cooling tower dome 14, under which all elements of a nuclear combined-cycle plant are located, which have at least two independent circulation loops, each of which consists of two closed loops, the first of which includes includes an evaporator 2 with a separator 3 located in the safety housing 4, and the second circuit includes: a superheater of high pressure 6 sequentially located in the gas path 5, a superheater of low pressure pressure 7, and an economizer 8, a high pressure steam turbine 9 and a low pressure steam turbine 10, a gas turbine 11, with a combustion chamber 12, and a compressor, electric generators 13, air coolers 14 connected via an intermediate circuit 15 to a condenser 16. The compressor made of two parts in the form of a low-pressure compressor 20 and a high-pressure compressor 21, between which an intermediate air cooler 18 is installed, having two inputs and two outputs: one input is connected to a capacitor 16, the output to the first input ohm of the deaerator 17, the second input is with a low-pressure compressor 21, and its output is with a high-pressure compressor 22. The installation is equipped with a gas heater 19, which has two inputs and two outputs, the first input of which is connected to the fuel gas pipeline, and its output - the combustion chamber 12 of the gas turbine 11, the second input is connected to the low pressure steam turbine 10, and its output is connected to the condenser 16. The deaerator 17, in addition, has a second input and one output, the second input of which is connected to the low pressure turbine, and its output with economizer 8.

At the nuclear combined-cycle plant, the refrigerator 18 is of a vertical shell-and-tube type, the coils of which have a small bending radius and are combined into hexagonal heat-exchange modules.

At a nuclear combined-cycle plant, the gas heater is made of a vertical shell-and-tube type, the coils of which have a small bending radius and are combined into hexagonal heat-exchange modules.

In a nuclear combined-cycle plant, air-cooling units are located at two levels, with the same distance between the units and with the same displacement step at each level, and are connected in pairs, with the unit from the first level and the unit from the second level connected in series.

In a nuclear combined-cycle plant, the gas heater is equipped with a capacity 22 located in the lower part of the heat exchanger, which collects moisture and liquid impurities, separated during the movement of fuel gas inside the coils of small bending radius.

A nuclear combined-cycle plant operates as follows.

The heat charged in the nuclear reactor is transferred to the water circulating with the pump in a closed primary circuit, transferring heat to the evaporator. The feed water of the second circuit enters the evaporator and turns into saturated steam, which is dried in a separator located in the upper part of the evaporator body.

Saturated steam from the evaporator enters the high pressure superheater located in the gas path. In a high-pressure superheater, saturated steam, moving inside the coils from top to bottom, counter-flowing to the combustion products, turns into superheated steam and enters the high-pressure turbine. In the turbine, energy is converted. The steam exiting the high-pressure turbine is supplied to the low-pressure superheater and, moving inside the coils from top to bottom, countercurrent to the combustion products, overheats and enters the low-pressure turbine. At least two steam take-offs take place from the low-pressure turbine, one of which enters the deaerator, and the other into the gas heater. Waste steam from the last stages of the low-pressure turbine enters the condenser and is cooled using an intermediate circuit in which air-cooling units are installed. Cooled water from the condenser, heated in an intermediate air cooler, with gas compressed in a low-pressure compressor, enters the deaerator, where it is mixed with the extraction of steam from a low-pressure turbine. After that, water is fed to the economizer using a feed pump. In the economizer, water, moving from top to bottom inside the coils countercurrent to the combustion products, is heated and enters the evaporator. Thus, the second circuit is closed. The coaxial high and low pressure turbines operate on an electric generator.

Through the gas path, atmospheric air is compressed in a low-pressure compressor, after which it enters an intermediate air cooler, where it transfers part of the heat to the feed water from the condenser, and then is additionally compressed in the high-pressure compressor. Heated water of the second circuit enters the deaerator.

Fuel gas, heated in the gas heater by extraction from the low pressure turbine, enters the combustion chamber and mixes with compressed air from the high pressure compressor. After that, it enters a gas turbine, which is located under the steam turbine, and which, in turn, operates on its own electric generator. Due to the heat of the gas turbine, the temperature of steam overheating in superheaters of high and low pressure and the heating of water in the economizer increase. The exhaust gases from the gas turbine enter the gas path, pass through the annulus of the superheaters of high and low pressure and the economizer, after which they enter the ejector 23. The ejector serves to transfer the kinetic and thermal energy of the combustion products to the air-cooled air cooler, and increase the natural circulation inside the dome. This contributes to the development of natural circulation during cooling of air cooling units and helps to reduce the power of electric motors.

An intermediate air cooler with a heat exchange surface made of coils of small bending radius reduces the work performed by the high-pressure compressor and increases its efficiency. Heat removal after the low-pressure compressor is due to the heating of the feed water coming from the condenser of the steam turbine. This allows you to abandon regenerative feed water heaters and effectively use the heat received in the low-pressure compressor.

The installed fuel gas heating heat exchanger saves fuel gas entering the combustion chamber due to the heat from the steam from the low pressure turbine. This steam has already done work in a low-pressure turbine and has a low-grade heat that can only be used to heat, in particular, fuel gas.

The proposed embodiment of gas heating heat exchangers makes it possible to ensure reliable and efficient operation of gas heating heat exchangers. The gas moving from top to bottom inside the coils of small bending radius, due to centrifugal forces, is cleaned of impurities, which then accumulate in containers where moisture and liquid impurities flow, which are separated during the movement of fuel gas inside the coils of small bending radius of the gas heat exchanger and are removed periodically .

Air cooling units are located on two levels, which allows more fully and efficiently use the internal space of the dry cooling tower. The cooling air, heating moves from bottom to top in the annular space of the air-cooling units located at two levels, with the same distance between the units and with the same displacement step at each level and connected in pairs, and, receiving additional dynamic energy from the exhaust gases from the gas turbine, allows high level of natural circulation. The pairwise connection of devices from the lower and upper levels allows to increase the natural circulation of the cooled water and, accordingly, the efficiency of the devices.

The industrial applicability of the utility model is obvious. The design can be made at enterprises using specialized equipment, units and machines.

Claims (5)

1. Nuclear combined cycle plant containing a reactor located on the central axis of the dome of a dry cooling tower, under which are located all the elements of a nuclear combined cycle plant with at least two independent circulation loops, each of which consists of two closed loops, the first of which includes includes an evaporator with a separator located in the safety case, and the second circuit includes a high-pressure superheater and a low-pressure superheater sequentially located in the gas path phenomena and economizer, a high-pressure steam turbine and a low-pressure steam turbine, a gas turbine with a combustion chamber and a compressor, electric generators, air coolers connected via an intermediate circuit to a condenser, characterized in that the compressor is made of two parts in the form of a low-pressure compressor and high-pressure compressor, between which an intermediate air cooler is installed, having two inputs and two outputs: one input is connected to a condenser, the output is to the first input of the cc deaerator, the second inlet is with a low-pressure compressor, and its outlet is with a high-pressure compressor, the unit is equipped with a gas heater with two inlets and two outlets, the first inlet of which is connected to the fuel gas pipeline, and its outlet - to the combustion chamber of a gas turbine , the second input is connected to a low-pressure steam turbine, and its output is connected to a condenser, the deaerator also has a second input and one output, the second input of which is connected to a low-pressure turbine, and its output to an economizer. 2. Nuclear combined-cycle plant according to claim 1, characterized in that the refrigerator is made of a vertical shell-and-tube type, the coils of which have a small bending radius and are combined into hexagonal heat-exchange modules. 3. Nuclear combined-cycle plant according to claim 1, characterized in that the gas heater is made of a vertical shell-and-tube type, the coils of which have a small bending radius and are combined into hexagonal heat-exchange modules. 4. Nuclear combined-cycle plant according to claim 1, characterized in that the air cooling apparatuses are located at two levels, with the same distance between the apparatuses and with the same displacement step at each level and are connected in pairs, moreover, the apparatus from the first level and the apparatus from the second level are connected sequentially. 5. Nuclear combined-cycle plant according to claim 3, characterized in that the gas heater is equipped with a tank located in the lower part of the heat exchanger, which collects moisture and liquid impurities, separated during the movement of fuel gas inside the coils of small bending radius.