JPS645663B2 - - Google Patents

Description

Detailed Description of the Invention The present invention provides a control rod drive mechanism for a nuclear reactor.
This invention relates to a control rod drive water supply device that supplies water for scram and cooling.

A plurality of control rods with a neutron absorption function are arranged in the core of the reactor pressure vessel, and each control rod is driven by a control rod drive mechanism to insert or withdraw from the reactor core to control the reactor output. It is configured. In addition, in the event of an emergency, all control rods are inserted in an emergency manner to shut down the reactor.

The control rod drive mechanism has a drive piston connected to the control rod in a cylinder, and is configured to drive the piston with water pressure to insert or withdraw the control rod.

Pressure water is supplied to the control rod drive mechanism by a control rod drive water supply device. In addition, in order to prevent the control rod drive mechanism from overheating, cooling water is constantly supplied from the control rod drive water supply device.

By the way, foreign matter may get mixed into the flow path of the piping system of the control rod drive water supply device. If such foreign matter gets mixed into the cooling water, the cooling water, which is constantly flowing into the control rod drive mechanism, will cause damage to the cooling water.
The effects of this are significant, such as the possibility that the orifice in the drive mechanism may become clogged and cause the drive mechanism to malfunction, or seals within the drive mechanism may be damaged, leading to the shutdown of the reactor and reducing operating efficiency. .

The present invention was made based on the above circumstances, and its purpose is to provide a control rod drive water supply system that supplies water for driving, scram, and cooling to the control rod drive mechanism of a nuclear reactor. A filter is inserted into the cooling piping system that constantly supplies cooling to the rod drive mechanism, thereby preventing clogging of orifices in the drive mechanism and damage to seal parts, and improving the integrity of the reactor. The aim is to maintain this and improve the operating rate of the reactor.

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

1 in the figure is a water supply source, and this water supply source 1 has a pump 2.
A master control unit 3 is connected via. This master control unit 3 adjusts the pressure of water sent out from the water supply source 1 in four ways. Headers 5, 6, 7, and 8 are connected so that each header delivers water at a different pressure. Each header 5, 6, 7, 8 has a scram piping system 9, a drive piping system 10, a cooling piping system 11 corresponding to each control rod drive mechanism 4, respectively.
and a return piping system 12 are connected.

First, the scram piping system 9 is constructed by connecting an accumulator 14 that stores high-pressure water to the first header 5 via a check valve 13.

Further, the drive piping system 10 is connected to the second header 6
A check valve 16 is connected to the check valve 16 via a filter 15, and an insertion pipe 19 is connected to the insertion side water supply nozzle 18 of the control rod drive mechanism 4 via an electromagnetic switching valve 17 on the outlet side of the check valve 16. It is connected to a withdrawal pipe 22 connected to a withdrawal side water supply nozzle 21 of the control rod drive mechanism 4 via a solenoid valve 20.

Further, the cooling piping system 11 connects a check valve 24 to the third header 7 via a filter 23,
The outlet side of the check valve 24 is connected to the middle of the insertion pipe 19.

Note that a scram inlet valve 25 is connected between each outlet side of the check valves 13 and 24.

The return piping system 12 connects a branch pipe 27 that connects to the fourth header 8 via a filter 26 to the middle of the insertion pipe 19 and a branch pipe 28 that connects to the middle of the withdrawal pipe 22. One branch pipe 27 is provided with an electromagnetic switching valve 29 and a filter 30, and the other branch pipe 28 is provided with an electromagnetic switching valve 31 and a filter 32, respectively.

A scram discharge pipe 36 is connected to a scram discharge header 35 through a scram outlet valve 33 and a check valve 34 in the middle of the drawn pipe 22 .

Next, the operation of this embodiment will be explained.

Water delivered from a water supply source 1 by a pump 2 is adjusted to four different pressures by a master control unit 3 and sent to headers 5, 6, 7, and 8.

First, the water in the first header 5 is stored as high-pressure water in the accumulator 14 through the check valve 13 of the scram piping system 9.

In addition, the water in the third header 7 is supplied to the cooling piping system 1.
It passes through the filter 23 and check valve 24 of No. 1, further passes through a part of the drive piping system 10, is guided into the inside of the control rod drive mechanism 4 from the insertion side water supply nozzle 18, and passes through the orifice 37 to the outer circumferential surface of the cylinder 38. It is cooled and flows into the reactor pressure vessel 39.

Further, in order to insert the control rod 40 during normal operation, the electromagnetic switching valves 17 and 31 are respectively opened. Therefore, the pressure water in the second header 6 passes through the filter 15, the check valve 16, and the switching valve 17 of the drive piping system 10, and is guided into the inside of the control rod drive mechanism 4 from the insertion side water supply nozzle 18 through the insertion piping 19. This flows into the space below the drive piston 41 in the cylinder 38, pushes the drive piston 41 upward, and inserts the control rod 40 connected thereto. Further, the water on the upper surface side of the drive piston 41 in the cylinder 38 flows out from the extraction side water supply nozzle 21 and returns to the fourth header 8 through the extraction piping 22, the filter 32 of the return piping system 12, the electromagnetic switching valve 31, and the filter 26. , flows into the third header 7 via the master control unit 3.

Further, in order to withdraw the control rod 40 during normal operation, the electromagnetic switching valves 20 and 29 are respectively opened. Therefore, the pressurized water in the second header 6 is guided into the inside of the control rod drive mechanism 4 from the extraction side water supply nozzle 21 through the extraction piping 22 through the filter 15, check valve 16 and switching valve 20 of the drive piping system 10, It flows into the space above the drive piston 41 in the cylinder 38, pushes down the drive piston 41, and pulls out the control rod 40 connected thereto. Further, the water on the lower surface side of the drive piston 41 in the cylinder 38 flows out from the insertion side water supply nozzle 18, passes through the insertion piping 19, the filter 30 of the return piping system 12, the electromagnetic switching valve 29, and the filter 26, and reaches the fourth header 8. and flows into the third header 7 via the master control unit 3.

Next, in order to perform an emergency insertion operation of the control rod 40 in an emergency, the scram inlet valve 25 and the scram outlet valve 33 are opened. Therefore, Accumulator 1
The high-pressure water stored in the control rod drive mechanism 4 flows into the control rod drive mechanism 4 from the insertion side water supply nozzle 18 through the scram inlet valve 25 and the insertion pipe 19, and flows into the space below the drive piston 41 in the cylinder 38. , push the drive piston 41 upward,
The control rod 40 is operated for emergency insertion. Further, the water on the upper surface side of the drive piston 41 in the cylinder 38 flows out from the withdrawal side water supply nozzle 21, passes through the withdrawal pipe 22, and further passes through the scram outlet valve 33 and check valve 34 in the scram discharge pipe 36 to the discharge header. It is discharged from 35.

According to the control rod drive water supply system configured as above, the drive piping system 10 and the return piping system 12 are provided with filters 15, 26, 30, 32 for protecting the electromagnetic switching valves 17, 20, 29, 31. Therefore, even if foreign matter gets mixed into the water in these piping systems 10 and 12, the foreign matter will be captured by either of the filters and will not enter the control rod drive mechanism 4. do not have. In addition, since the cooling piping system 11 is provided with a filter 23, when foreign matter gets mixed into the water in the piping system 11, the foreign matter is captured by the filter 23, and the control rod drive mechanism 4 Intrusion of foreign matter into the interior is prevented. Therefore, there is no fear that the orifice 37 in the control rod drive mechanism 4 will be clogged or that seal parts will be damaged, and the reactor can maintain its integrity and improve its operating rate.

In the above embodiment, the filter 23 of the cooling piping system 11 is inserted upstream of the check valve 24, but it is inserted downstream of the check valve 24 as shown by the imaginary line 23' in the figure. You can also insert it. Furthermore, filters 23 and 23' may be used together.

As described in detail above, according to the control rod drive water supply device of the present invention, by inserting a filter into the cooling piping system that constantly supplies cooling water into the control rod drive mechanism, the control rod drive It is possible to prevent clogging of orifices in the mechanism, damage to seal parts, etc., and it is possible to maintain the integrity of the reactor and improve the operating rate of the reactor.

In particular, in the case of the present invention, since a filter is inserted into the cooling piping branched from the cooling piping system header to each control rod drive mechanism, foreign matter is removed in the vicinity of each control rod drive mechanism. This makes it possible to reliably prevent foreign matter from entering the control rod drive mechanism.

[Brief explanation of the drawing]

The drawing is a system diagram of a control rod-driven water supply device in one embodiment of the present invention. DESCRIPTION OF SYMBOLS 1... Water supply source, 2... Pump, 3... Master control unit, 4... Control rod drive mechanism, 5, 6,
7, 8...header, 9...scrum piping system, 10...
Drive piping system, 11... Cooling piping system, 12... Return piping system, 17, 20, 29, 31... Solenoid switching valve, 1
8... Insertion side water supply nozzle, 21... Removal side water supply nozzle, 23... Filter.

Claims (1)

[Claims] 1. A master control unit that adjusts the pressure of water sent out from the water supply source in multiple ways, a header for the drive piping system connected to this master control unit, and a header for the scram piping system connected to the master control unit. ,
A header for the return piping system connected to the master control unit, a header for the cooling piping system connected to the master control unit, and a header for the drive piping system are branched and connected for each control rod drive mechanism and have multiple switching points. A drive piping system that selectively supplies pressurized water to the insertion side or withdrawal side water supply nozzle of the control rod drive mechanism through a valve, and a drive piping system that is branched and connected to each control rod drive mechanism from the header for the scram piping system and sent out from the master control. A scram piping system that supplies high-pressure water stored in the accumulator to the insertion side water supply nozzle of the control rod drive mechanism through a part of the drive piping system in an emergency, and a branch connection for each control rod drive mechanism from the header for the return piping system. a return piping system that returns water discharged from the insertion side or withdrawal side water supply nozzle of the control rod drive mechanism to the return piping system header and further to the master control unit through a part of the drive piping system and a plurality of switching valves; a cooling piping system that is branch-connected from the cooling piping system header to each control rod driving mechanism and constantly supplies cooling water into the control rod driving mechanism through a part of the driving piping system; and this cooling piping system. A control rod-driven water supply device comprising: a filter inserted into the control rod-driven water supply device;