JPH0692724B2 - Reactor isolation cooling system - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reactor isolation cooling system, and more particularly to a reactor isolation cooling system suitable for activating a gland seal device before starting a turbine.

[Background of the Invention]

 FIG. 2 shows a conventional cooling system for reactor isolation.

At the time of reactor isolation, the steam generated by the decay heat of the reactor core is guided from the reactor pressure vessel 1 to the steam pipe 2 and the main steam stop valve
It is supplied to the turbine 3 through the control valve 10 and the regulator valve 11 to drive the turbine 3. The turbine exhaust passes through the exhaust pipe 4,
It is discharged to the pressure control chamber 5. The water for cooling the reactor is put into the cooling water pump 8 from the condensate storage tank 6 through the pipes 7 and 9, and is sent to the reactor pressure vessel 1 by this cooling water pump 8 and sprayed into the reactor from the top spray nozzle. ,
Mix with internal steam or hot water.

On the other hand, the leaked steam from the gland portion of the turbine 3 and the leaked steam from the valve rods of the main steam stop valve 10 and the regulator valve 11 are guided to the barometric capacitor 13 by the gland steam pipe 12. This ground steam is cooled by the cooling water that has passed through the cooling water pipe 19 and the lubricating oil cooler 18 that are branched from the outlet of the cooling water pump 8, and becomes condensed water in the vacuum tank 14
to go into. Condensed water in the vacuum tank 14 is discharged by the condensate pump 17 to the suction side of the cooling water pump 8 through the pipe, while the non-condensable gas is extracted by the vacuum pump 15.
It is collected in the pressure control chamber 5 through the separator 16. Sealing water required for the casing and shaft seal of the vacuum pump 15 is supplied by a sealing water pipe 20 branched from the cooling water pipe 19, and the discharged sealing water is separated from the non-condensed gas by the separator 16. Collected in the vacuum tank 14.

The gland seal device having pipes such as the barometric capacitor 13, the vacuum tank 14, the vacuum pump 15, the separator 16, the condensate pump 17, and the cooling water pipe 19 is a steam leak from the gland portion of the turbine 3 and a main steam stop valve. Although it is for treating the leaked steam from the control valve 10 and the control valve 11, the cooling water and the sealing water are branched from the discharge side of the reactor cooling water pump 8, so that the cooling water pump 8 and the turbine 3
The cooling water and the sealing water cannot be supplied to the gland sealing device of the turbine unless the engine is in the operating state. Therefore, when the turbine 3 is started before starting the rated operation, radioactive steam may leak from the gland portion of the turbine, the main steam stop valve and the steam control valve.

[Object of the Invention]

An object of the present invention is to provide a reactor isolation cooling system that can put a gland seal device into an operating state before starting a turbine.

[Outline of Invention]

In order to achieve the above-mentioned object, the present invention installs a cooling water pump for a gland sealing device in a gland sealing device of a turbine, and uses this gland sealing device cooling water pump by a drive source unrelated to the driving of the turbine. In addition to being able to drive, the gland seal device cooling water pump is piped so that the cooling water can be branched from the upstream side of the reactor cooling water pump, and the gland seal device cooling water pump can be connected before starting the turbine. The feature is that it was made to drive.

As described above, according to the present invention, the gland sealing device cooling water pump is driven before the turbine is started to supply the cooling water branched from the upstream side of the reactor cooling water pump to the gland sealing device. Since the sealing device is first operated independently and the turbine is started in this state,
It is possible to reliably prevent leakage of radioactive steam from the gland portion, the main steam stop valve and the steam control valve when the turbine is started.

Example of Invention

 Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the present invention. A gland seal device for a reactor isolation cooling system includes a barometric capacitor 13, a vacuum tank 14, a vacuum pump 15, a separator 16, and a condensate. A pump 17, a lubricating oil cooler 18, a cooling water pipe 19, a seal water pipe 20, a gland seal device cooling water pump 21 and the like are provided.

The gland seal device cooling water pump 21 is connected to a battery 22 as a drive source (power source) and can be independently driven before the turbine 3 is started. Further, the gland seal device cooling water pump 21 is connected to a pipe 24 on the upstream side of the cooling water pump 8 via a pipe 23 so that the cooling water can be branched from the upstream side of the cooling water pump 8.

A valve 25 is provided on the upstream side of the lubricating oil cooler 18.

Incidentally, regarding the other configuration of the embodiment shown in FIG. 1,
It is similar to that shown in FIG.

The reactor isolation cooling system of this embodiment operates and operates as follows.

That is, the gland seal device cooling water pump 21 is activated in response to the activation signal of "reactor water level low". At the same time, the valve 25 on the upstream side of the lubricating oil cooler 18 is opened, the cooling water passes through the lubricating oil cooler 18, and the barometric condenser 13 is guided by the cooling water pipe 19 to the barometric condenser 13
Sprayed in.

On the other hand, the cooling water branched from the cooling water pipe 19 is supplied as sealing water to the casing of the vacuum pump 15 and the shaft seal portion through the sealing water pipe 20. As a result, the vacuum pump 15 can be activated and receives a signal to activate.

When the vacuum pump 15 is started, the vacuum tank 14 and the valometric capacitor 13 are brought into a vacuum state, and the valometric capacitor 13, that is, the gland seal device serves as the gland leakage steam of the turbine 3, the main steam stop valve 10 and the regulator valve 11. The leaked steam can be processed.

Next, the steam valve receiving the start signal is opened, the main steam stop valve 10 and the regulator valve 11 are sequentially opened, and the turbine 3 and the cooling water pump 8 are started, whereby cooling water is supplied to the reactor pressure vessel. , Cool the inside of the furnace and secure the reactor water level (see Fig. 2).

On the other hand, the steam as the turbine exhaust becomes condensed water in the barometric condenser 13, the non-condensing gas such as air is cooled, and enters the vacuum tank 14. Condensate in the vacuum tank 14
Upon receiving the signal of "level high", the condensate pump 17 is started, the cooling water pump 8 enters the suction side, and is returned to the reactor pressure vessel. Further, the non-condensable gas in the vacuum tank 14 is sucked by the vacuum pump 15, passes through the separator 16, and is collected in the pressure control chamber.

Since this reactor isolation cooling system must operate in an emergency situation of the reactor, the gland seal device cooling water pump 21 along with the vacuum pump 15 and the condensate pump 17 has a battery 22.
As a driving source (power source), it operates even when the power source in the office is lost.

Further, in this reactor isolation cooling system, the cooling water pump 8
Cooling water is branched from the upstream side of the cooling oil, and the branched cooling water is cooled by the gland seal device cooling water pump 21.
18. Since the ballometric capacitor 13 is supplied with cooling water and the vacuum pump 15 is supplied with sealing water, the gland sealing device can be operated independently. Moreover, as described above, by using the battery 22 as the drive source (power source) of the gland seal device cooling water pump 21, it is possible to operate in an emergency.

When the turbine 3 and the cooling water pump 8 enter the rated operation, the gland seal device cooling water pump 21 is stopped.

〔The invention's effect〕

According to the present invention described above, the gland seal device cooling water pump is installed in the gland seal device of the turbine,
The gland seal device cooling water pump can be driven by a drive source independent of the drive of the turbine, and the gland seal device cooling water pump is cooled from an upstream side of the reactor cooling water pump. Since the piping is arranged so that water can be branched and the gland seal device can be operated independently even in an emergency, the gland seal device can be operated before starting the turbine, so that the turbine and main steam can be activated when the turbine is started. There is an effect that the leaked steam from the stop valve and the regulator valve can be completely treated, and there is an effect that the safety of the reactor isolation cooling system and eventually the entire nuclear power plant can be improved.

[Brief description of drawings]

FIG. 1 shows an embodiment of the present invention. FIG. 1 is a system diagram of a main part, and FIG. 2 is a system diagram showing a conventional technique. 3 ... Turbine, 8 ... Cooling water pump, 13 ... Barometric capacitor that constitutes the gland seal device,
14 …… same vacuum tank, 15 …… same vacuum pump, 16 …… same separator, 17 …… same condensate pump, 18 …… same lubricating oil cooler, 19 …… same cooling water pipe, 20 …… same seal water Plumbing, 21 ...
… Cooling water pump for the gland seal device, 22 …… Battery as a drive source for the gland seal device cooling water pump, 23
...... Pipes connecting the upstream side of the cooling water pump for the reactor and the gland seal device cooling water pump, 24 ...... Pipes connecting the cooling water pump for the reactor and the pressure control chamber as the water source.

Claims (2)

[Claims] Claims: 1. The steam generated by decay heat of the core during reactor isolation is supplied from a reactor pressure vessel to a turbine through a main steam stop valve and a control valve, and the turbine is used to drive a reactor cooling water pump. In the nuclear reactor isolation cooling system, a cooling water pump for the gland sealing device is installed in the gland sealing device of the turbine so that the gland sealing device cooling water pump can be driven by a drive source independent of the driving of the turbine. In addition, the gland seal device cooling water pump is piped so that the cooling water can be branched from the upstream side of the reactor cooling water pump, and the gland seal device cooling water pump is driven before the turbine is started. A cooling system for reactor isolation that is characterized by what it has done. 2. The reactor isolation cooling system according to claim 1, wherein a drive source of the gland seal device cooling water pump is a battery.