RU2602649C2 - Steam turbine npp - Google Patents

Abstract

FIELD: energy.

SUBSTANCE: invention relates to power engineering. Steam turbine nuclear power plant includes reactor plant steam generator connected to turbine consisting of high and low pressure cylinders installed on same shaft with electric generator, cylinders are connected to each other via steam pipeline, at which separator and two-staged steam-to-steam superheater are installed in steam flow direction, low-pressure cylinder is connected via steam pipeline with main condenser, which in its turn is connected by condensate line to deaerator, where condensate pumps are arranged in condensate flow direction, modular demineralizing plant, ejectors cooler and group of low pressure heaters. Deaerator is connected with reactor plant steam generator by makeup water pipeline, where makeup pump and group of high pressure heaters are installed in direction of water flow. Group of high pressure heaters is connected with high-pressure cylinder by steam extraction pipelines, and with two-staged steam-to-steam superheater is by steam superheater stages condensate lines. Deaerator is connected with high-pressure cylinder via steam extraction pipeline, to separator is by separator drain pipeline, with group of high pressure heaters is by high-pressure heater drain pipeline. Group of low pressure heaters is connected with low-pressure cylinder by steam extraction pipelines. Plant also includes satellite turbine connected with satellite turbine condenser and satellite turbine electric generator and start-up and redundant boiler room with pumps and control valves, which at inlet is connected with main condenser and with satellite turbine condenser, and at outlet is with low-pressure cylinder, with group of high pressure heaters and satellite turbine located on same shaft with satellite turbine electric generator.

EFFECT: invention enables to obtain additional power and maneuverability due to generation of additional steam and its supply to main turbine, due to creation of additional circuit containing satellite turbine with condenser and electric generator, also generating additional electric energy in peak period.

1 cl, 1 dwg

Description

The invention relates to the field of power engineering, mainly to nuclear energy, and is intended for use in steam turbine units of nuclear power plants (NPPs) of a double-circuit type with water-cooled power reactors (WWER), in particular, the invention can be applied to serial and designed domestic nuclear power plants for the purpose obtaining additional power on them, increasing the installed capacity utilization factor (KIUM), as well as the participation of nuclear power plants in the regulation of load schedules above the nominal noy with partial substitution of new construction.

The invention appears to be relevant in the light of the energy strategy of the Russian Federation, as it is aimed, firstly, at further improving efficiency and safety at nuclear power plants with VVER-1000 reactors and, secondly, at solving the problem of sufficient maneuverability to ensure the adjustment range in power systems with a high share of nuclear power plants.

Known combined-cycle plant (AS No. 1060798 Combined-cycle plant - Publ. 12/15/1983), containing a steam turbine with high and low pressure cylinders, interconnected by a steam line with a separator having a water discharge line, and an intermediate steam a superheater, and a gas-vapor intermediate superheater connected to the exhaust path of the gas turbine, is equipped with an additional heat exchanger connected along the heated side between the water drain line and the steam line and in front of the cylinder low pressure, heating - to the exhaust gas path of the gas turbine, and the gas-vapor intermediate superheater is connected to the steam line between the high and low pressure cylinders parallel to the steam-steam superheater.

The disadvantages of this installation include the relatively low provided unloading range. Due to the deep discharge of the gas turbine unit (GTU) during the hours of the failure of the electrical load schedule, switching on the combined-cycle gas superheater is inefficient.

Closest to the claimed technical solution is a steam turbine nuclear power plant - a basic thermal diagram of a turbine unit (Truhniy A.D., Bulkin A.E. Steam turbine installation of power units of the Balakovo NPP: a training manual in two parts. - M: MEI Publishing House, 2004, p. 68 -69), containing a steam generator of the reactor installation, connected to a turbine consisting of high and low pressure cylinders mounted on the same shaft as the electric generator. The cylinders are interconnected by a steam line, on which a separator and a two-stage steam-steam superheater are installed along the steam. The low-pressure cylinder is connected by a steam line to the main condenser, which in turn is connected to a deaerator by a condensate line, where condensate pumps, a block desalination plant, an ejector cooler and a group of low-pressure heaters are located along the condensate. The deaerator is connected to the steam generator of the reactor installation by a feed water pipe, where a feed pump and a group of high-pressure heaters are located along the water. The group of high-pressure heaters is connected to the high-pressure cylinder by steam lines for steam extraction, and to a two-stage steam-steam superheater by steam lines of the steam superheater stages. The deaerator is connected to the high-pressure cylinder by a steam withdrawal line, to the separator - to the separator drain pipe, to a group of high-pressure heaters - to the drain pipe of the high-pressure heater. A group of low pressure heaters is connected to the low pressure cylinder by steam lines.

The disadvantage of the prototype is that the presented installation is not sufficiently high maneuverability, which reduces its effectiveness.

The present invention is to increase efficiency by improving the maneuverability of the installation and increasing the power of the turbine.

The technical result of the invention is to obtain additional power and maneuverability by generating additional steam and supplying it to the main turbine by creating an additional circuit containing a satellite turbine with its condenser and electric generator, which also generates additional electric energy during the peak period.

The task is achieved in that a steam turbine nuclear power plant containing a steam generator of a reactor installation, connected by a stop-control valve to a turbine consisting of high and low pressure cylinders mounted on the same shaft with an electric generator, the cylinders are interconnected by a steam line, with a separator installed along the steam a two-stage steam-superheater, the output of the low-pressure cylinder is connected by a steam line to the main condenser, which in turn is connected to the deaerator by a pipe, moreover, along the condensate there are condensate pumps, a block desalting plant, an ejector cooler and a group of low pressure heaters, the deaerator is connected to the steam generator of the reactor installation by a feed water pipe on which the feed pump and a group of high pressure heaters are located, a group of high pressure heaters is connected to the high pressure cylinder steam pipelines of steam withdrawals, and with condensate collectors of steps of an intermediate superheater - condensate pipelines, drainage g UPPA of high pressure heaters is discharged through the drainage pipes of high pressure heaters, the deaerator is connected to the high pressure cylinder by a steam withdrawal line, to the separator - to the separator drain pipe, to the group of high pressure heaters - to the drain pipe of the high pressure heater, the low pressure heaters group is connected to the low pressure cylinder steam pipelines for steam extraction, the drainage of a group of low-pressure heaters is discharged through the pipelines of the drainage heaters of low pressure, the turbine drive is fed with superheated steam taken from the steam line after the separator and the two-stage steam-steam superheater, and has its own condenser, after which the condensate enters the condenser through the condensate pump through the condensate pump, characterized in that the satellite turbine and the satellite turbine condenser are additionally introduced , satellite generator turbine generator and start-up boiler room with auxiliary equipment - pumps for start-up boiler room, by a regulating valve, the start-up boiler room is connected at the inlet to the condenser by condensate pipelines, into which the start-up boiler room pumps and the control valve are connected, along with the condenser of the satellite turbine and the gas pipeline, and at the outlet, from the low-pressure cylinder through the throttle shut-off valve, with a group of high-pressure heaters, with a satellite turbine, which has its own condenser and is located on the same shaft with its electric generator.

The scheme of the proposed steam turbine nuclear power plant is presented in FIG. one.

A steam turbine nuclear power plant contains: a steam generator of a reactor installation 1 connected by a steam line 32 to a turbine consisting of high-pressure cylinders (CVP) 2 and low pressure (TsND) 7 mounted on one shaft with an electric generator 8. The CVP and TsND are interconnected by a steam line 33, on which , along the steam, a separator 3 and a two-stage steam-superheater 4 and 5 are installed. The output of the low-pressure cylinder is connected by a steam line 34 to the main condenser 9, which in turn is connected to a deaerator 26 by a pipe 35, where the condensate pumps 10 and 17, a block desalination plant (BOW) 15, an ejector cooler 16 and a group of low pressure heaters (PND) 24. The deaerator 9 is connected to the steam generator of the reactor installation 1 by a feed water pipe 36, on which the feed pump 30 and a group of high pressure heaters are located (LDPE) 31. The LDPE group 31 is connected to the high-pressure cylinder by 2 steam lines of the steam withdrawals 37, 38, and to the condensate collectors of the intermediate superheater stages by the condensate lines 41, 42. The LDPE group 31 is connected to the pipe deaerator 26 PVD drainage odes 53. Deaerator 26 is connected to CVP 2 by a steam withdrawal pipe 39, to separator 3 to a drainage pipe of separator 40. The PND group 24 is connected to a low pressure cylinder 7 by steam withdrawal pipes 43, 44, 45 and 46. The PND 24 group is connected to pipeline 35, PND drainage pipelines 53. The turbo drive 27 is connected to the steam line 33 after the separator and the two-stage steam-superheater by the steam line 27 and has its own turbo-drive condenser 28, which in turn is connected to the main condenser 9 by a pipe 47. To pipes a condensate pump of a turbo drive 29 is located on the wire 47. The main condenser 9 is connected by an additional condensate line 49, which is divided into two lines 18 and 19, with a start-up boiler (PRK) 13 through a control valve 20. A pump PRK 11 is located on the condensate line 49, and on the pipeline line PRK 18 the pump PRK 12 is located. PRK 13 is connected at the inlet to the main condenser 9, at the outlet - a steam line 47 with a low pressure valve 7 through a throttle shut-off valve (DOK) 6, a steam line 49 with a PVD group 31, and a steam line 51 with a satellite turbine 21 which in howl turn connected to the capacitor 23 and the satellite turbine is a generator on one shaft 22. Gas turbine satellite to PPH is supplied through gas conduit 14.

The device operates as follows.

The steam of the steam generator of the reactor unit 1 is supplied through the steam line 32 to the middle of the double-flow symmetric CVP 2. After expansion to the HPC, the steam is sent through the steam line 33 to the separator 3 and the group of superheaters 4.5 for drying and intermediate overheating. Drained steam is sent to two successively arranged superheaters, and the separator drain is piped (40) to the deaerator 26. The first stage of the superheater is supplied with wet steam taken from CVP 2 after the third stage. The main steam is overheated by the heat of condensation of the heating steam through the steam line 32, and the condensate formed is sent to the LDPE group 31 by the condensate lines of the steps of the steam superheater 41 and 42 to transfer its heat to the feed water. After leaving SPP, steam enters through DOK 6 into a double-flow low-pressure cylinder 7. From it, steam enters the main condenser 9 through the steam line 34. Drain the main condenser 9 through the condensate line 35, where the condensate pumps 10, 17, BOU 15, ejector cooler are located 16, and the PND group 24 enters the deaerator 26. The deaerator 26 is drained through the feed pipe 36, where the feed pump 30 is located along the drainage, the LDPE group 31 enters the steam generator of the reactor unit 1. Steam withdrawals to the LDPE group 31, the deaerator 26, and the PND group 24 implemented steam pipelines 37, 38, 39, 43, 44, 45, 46. Drainages of the LDPE group 31 and PND groups 24 are discharged through pipelines 53. The turbo drive 27 is fed with superheated steam, taken from the steam line 33 after the SPP, and has its own turbo drive condenser 28, after which condensate from the condensate drain 47, where the condensate pump of the turbo drive 29 is located along the condensate, enters the main condenser 9. Condensate from the main condenser 9 enters through the additional condensate line 49, which is divided into two lines 18 and 19 to the PRK 13 through the control valve 20. On the PRK 11 pump is located on the condensate line 49, and the PRK 12 pump is located on the pipeline line to the PRK 18. Steam from the PRK 13 enters through the steam line 48 to the low pressure pump 7 of the DOK 6, through the steam line 49 to the LDPE group 31, and through the steam line 51 to the satellite turbine 21, which in turn is connected to the condenser of the satellite turbine 23 and is located on the same shaft by the electric generator of the satellite turbine 22. The condensate after the condenser of the satellite turbine through the condensate line 51 enters the pipeline 19. Gas is supplied to the PRC through the gas pipeline 14.

The inventive device can generate additional power in several ways:

Method A. At peak load hours, a nuclear power unit is involved in partial participation in the load schedule coverage. The steam received in the start-up boiler (PRK) with a design pressure of 10 atm is supplied through steam line 48 through the throttle shut-off valve 6 (DOK) to the low-pressure cylinder of the turbine 7, due to which additional electricity is generated in the generator 8.

After condensation in the condenser 9, the previous flow rate of the condensate (for the basic operation mode) by the condensate pump 10 is fed into the regenerative path of the turbine installation of the NPP power unit, consisting of the PND 24 group, deaerator 26, feed pump 30, PVD group 31, and then to the CVP 2 of the NPP turbine unit. The additional condensate flow rate corresponding to the fraction of generated steam in the PRK is directed to the inlet of the PRK by pumps 11, 12 along lines 18, 19.

Method B. Additional power is also produced in a different way. At peak hours, the steam received in the PRK 13 is sent to the LDPE group 31 to partially or completely displace the heating steam of the corresponding regenerative selection. The displaced steam is sent to the flowing part for expansion from the selection chamber to the main condenser 9. The condensate is returned to the PRK 13 in the same way as in case A. In this case, the satellite turbine 21 is used occasionally to generate additional power from the steam pipe 33 for unloading the last stages of the low pressure turbine 7

Thus, method A makes it possible to involve a nuclear power unit in part in covering the load schedule while maintaining high power. Method B allows you to cover the load during peak hours due to the generation of additional power. Using this method of operation allows for high maneuverability while increasing the capacity of a steam turbine nuclear power plant due to the generation of additional power.

Claims (1)

A steam turbine nuclear power plant containing a reactor plant steam generator connected to a turbine consisting of high and low pressure cylinders mounted on the same shaft as an electric generator, the cylinders are interconnected by a steam line, on which a separator and a two-stage steam superheater are installed along the steam, and the low pressure cylinder is connected by a steam line with a main condenser, which in turn is connected to a deaerator by a condensate line, where condensate pumps are located along the condensate, block a water treatment unit, an ejector cooler and a group of low pressure heaters, a deaerator is connected to the steam generator of the reactor installation by a feed water pipe, where a feed pump and a group of high pressure heaters are located along the water, a group of high pressure heaters is connected to the high pressure cylinder by steam withdrawal pipelines, and with a two-stage steam steam superheater by condensate lines of the steam superheater stages, the deaerator is connected to the high pressure cylinder steam extraction, with a separator - a drainage pipe for the separator, with a group of high pressure heaters - a drainage pipe for a high pressure heater, a group of low pressure heaters is connected to the low pressure cylinder with steam extraction steam lines, characterized in that a satellite turbine connected to the satellite turbine condenser and satellite generator turbine generator, and a start-up boiler room with pumps and control valves, which is connected at the input to the main condens torus and satellite turbine condenser, and the output - the low-pressure cylinder, with a group of high-pressure preheaters and satellite turbine situated on the same shaft with a generator turbine satellite.

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