JPS60187892A - Air piping system of control rod driving driving hydraulic device - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a pneumatic piping system for a control rod drive hydraulic system used for controlling a control rod drive hydraulic system of a nuclear reactor.

[Technical Background of the Invention] Generally, in a boiling water reactor, a control rod drive hydraulic device is installed to drive the control rods. Water pressure control unit 1 for emergency insertion operation (hereinafter referred to as scram)
~ is arranged and C. In addition, a scram discharge container is provided to temporarily store scram discharge water discharged by the operation of the control rod drive mechanism during scram. These hydraulically controlled cornits and scram 1/1 outlet vessels are controlled by a pneumatic piping system of an air controlled control rod driven hydraulic system.

FIG. 1 shows the air piping system of such a control rod-driven water LF device, and in the figure, reference numeral C 1 indicates a water pressure control unit, and reference numeral 2 indicates a scram discharge container.

The water pressure control unit 1 is provided with a scram inlet valve 3715 and a scram outlet valve 4, and the scram inlet valve 3 and scram outlet valve 4 are provided with a scram solenoid valve 5.6.
A scram air pipe 7 inserted therein is connected. A vent valve 8.9 and a drain valve 10.11 are provided on the inlet and outlet sides of the scram discharge container 2.
These pens 1 to 8.9 and drain valve 10.1
1 is connected to a discharge container piping 14 into which a discharge container solenoid valve 12.13 is inserted. The scram air line 7 and the discharge vessel line 14 are each connected to an air supply line 15 which is connected to an air source 16. This air supply piping 15
A filter 17, a pressure regulating valve 18, and a backup scram solenoid valve 19, 20 are inserted in this order from the air source side, and a check valve 21 is arranged in parallel with the backup scram solenoid valve 20.

In the air piping system of the control rod-driven hydraulic system configured as described above, compressed air is normally supplied from the air source 16 to the scram inlet valve 3 and the scram outlet valve 4 via the air supply piping 15 and the scram air piping 7. Further, compressed air is sent to the vent valve 8.9 and the drain valves 10, 11 via the air supply pipe 15 and the discharge container pipe 14.

In the air piping system of such a control rod drive hydraulic system, during a scram for emergency shutdown of the reactor, a scram signal is sent from the reactor protection system to the scram solenoid valve 5.6 disposed in the hydraulic control unit l-1. is input, and the scram solenoid valve 5
．． 6 is opened, and at the same time compressed air in the piping connected to the scram population valve 3 and the scram outlet valve 4 is exhausted by the scram solenoid valve 5.6. As a result, the scram inlet valve 3 and the scram outlet valve 4, which are normally closed by compressed air and operated by the pneumatic c, are opened, and the control rod drive mechanism 22 causes the control rods to be inserted into the reactor 23 in an emergency manner.

On the other hand, the scram signal is also input to the discharge container solenoid valve 12.13, and this discharge container solenoid valve 12.13 is closed.
The compressed air in 9.11 is exhausted, and the vent valve 8.9 and drain valve 10.1 are normally opened by the compressed air.
1 is considered closed. As a result, scram discharge water flowing out from the control rod drive mechanism 22 during scram is temporarily stored in the scram discharge container 2.

Also, the scram solenoid valve 5.6 and the discharge container solenoid valve 12
．． What is 13? If there is a failure, the two children do not respond to the scram signal from the system, the backup scram solenoid valve 19.20 is closed, and the scram population valve 3, scram outlet valve 4, vent valve 8.9, and drain valve are closed. Valve 10.1
1 is discharged, thereby opening the scram population valve 3 and the scram outlet valve 4, opening the vent valve 8.9 and the drain valve 10.11, and performing a scram operation.

[Problems in the background art] However, in the air piping system of the control rod drive hydraulic system configured in this way, if the scram signal is not output from the reactor protection system during scram due to a disconnection, etc., the matc will not be able to scram due to a failure etc. Solenoid valve 5.6, discharge container solenoid valve 12.
13 and backup scram solenoid valve 19.20 do not operate, the scram population valve 3, scram outlet valve 4, vent valve 8.9, and drain valve 10.11 cannot exhaust air. 3 and the scram outlet valve 4 are closed, and the vent valve 8.9
There is also a possibility that the drain valves 10.11 will be in an open state, making it impossible to perform a scram operation.

[Object of the invention] The present invention has been made in response to such conventional circumstances,
If the scram signal from the reactor protection system is not output,
Another object of the present invention is to provide a pneumatic piping system for a control rod drive hydraulic device that can reliably perform a scram operation even when the scram solenoid valve, discharge container solenoid valve, and backup scram solenoid valve do not operate due to failure or the like.

[Summary of the Invention 1 That is, the present invention provides an air supply pipe in which a backup scram solenoid valve connected to an air source and closed during scram is inserted, and a scram population valve and scram valve of a water pressure control unit that are branched from this air supply pipe. A scram air pipe in which a scram solenoid valve is connected to an outlet valve and is opened during a scram, and a scram air pipe is connected to a scram solenoid valve that is branched from the air supply pipe and connected to a vent valve and a drain valve of the scram discharge container and is closed during a scram. At 85, in the air piping system of the control rod-driven hydraulic device, which is equipped with a discharge container piping into which a solenoid valve is inserted, an exhaust electromagnetic valve is installed in each of the scram air piping and the discharge container piping, or the air supply piping, which is kept quiet during the scram. This is a pneumatic piping system for a control rod-driven hydraulic device characterized by the insertion of a valve.

[Embodiment of the Invention] The details of the present invention will be described below with reference to an embodiment shown in the drawings.

FIG. 2 shows an embodiment of the air piping system of the control rod drive hydraulic system of the present invention. Exhaust solenoid valve 2 downstream of valve 12 and 13
4.25.26 has been inserted. These exhaust solenoid valves 24, 25, and 26 are opened by receiving a reactor stop signal from the alternative control rod insertion system. It should be noted that, except for these parts, the construction is the same as the pneumatic piping system of the control rod drive hydraulic system shown in FIG. 1, so the same parts are given the same reference numerals and a detailed explanation will be omitted.

The air piping system of the control rod-driven hydraulic system configured as described above includes the scram solenoid valve 5.6, the discharge container solenoid valve 12.
13 or backup scram solenoid valves 19.20 from the reactor protection system, the scram population valve 3 and scram outlet valve 4 are opened, and the vent valve 8.9 and drain valve 10. 11 is opened and a scram operation is performed.

On the other hand, if the scram signal is not input from the reactor protection system due to a disconnection, etc., or if there is a failure, C scram solenoid valve 5.6
If the discharge vessel solenoid valve 12.13 and the backup scram solenoid valve 19.20 do not operate, a reactor stop signal is input from the alternative control rod insertion system to the exhaust solenoid valves 24, 25, and 26, respectively, and the exhaust Solenoid valve 24.25.2
6 is considered open. As a result, scram population valve 3, scram outlet valve 4, vent valve 8.9 iJ3 and drain valve 10
Compressed air at 11° is exhausted, the scram population valve 3 and scram outlet valve 4 are opened, and the vent valve 8.9 and drain valve 10.11 are closed.

Therefore, the scram operation can be performed reliably.

That is, in the air piping system of the control rod drive hydraulic system configured as described above, if the scram signal from the reactor protection system is not input, or due to a failure etc., the scram solenoid valve 5.
6. Even when the discharge vessel solenoid valve 12.13 and the backup scram solenoid valve 19.20 do not operate, the reactor stop signal from the alternative control rod insertion system makes it possible to reliably perform the predetermined scram operation. Since the scram discharge water discharged by the scram operation can also be reliably stored in the scram discharge container 2, the reactor water An exhaust solenoid valve 27, 28 that receives a signal from the scram delay prevention system is further provided downstream of the backup scram solenoid valve 19, 20 of the supply pipe 15, and this exhaust solenoid valve 27, 28 has a non-return function. Valves 29 and 30 are arranged in parallel and C
There is.

It should be noted that, except for this part, the structure is the same as the air piping system of the control rod drive hydraulic system shown in FIG. 1, so the same parts are given the same reference numerals and the explanation will be omitted.

In the air piping system of the control rod-driven hydraulic system configured in this way, the scram solenoid valve 5.6 and the discharge container solenoid valve 12
．． 13 or backup scram solenoid valve 19.20, the scram inlet valve 3 and scram outlet valve 4 are opened by inputting the scram signal from the reactor protection system, and the vent valve 8.
9 and drain valves 10 and 11 are opened and a scram operation is performed.

However, if the scram signal from the reactor protection system is not input due to a disconnection, etc., or due to a malfunction, the scram solenoid valve 5.6, discharge container solenoid valve 12.13, and backup scram solenoid valve 19.20 do not operate. In this case, a scram signal is input from the scram R spread prevention system to the exhaust solenoid valve 27.28, and the exhaust solenoid valve 27.28 is closed. As a result, the scram population valve 3, the scram outlet valve 4. Compressed air from the vent valve 8.9 and the drain valve 10.11 is discharged at JJI, the scram population valve 3 and the scram exit valve 4 are opened, and the vent valve 8.9 and the drain valve 10 are opened.
．． 11 is closed and a scram operation is performed.

Effects of the Invention] As described above, according to the air piping system of the control rod drive hydraulic system of the present invention, the scram solenoid valve, the extraction vessel solenoid valve J3, and the backup scram solenoid valve receive a scram signal from the reactor protection system. Even if no input is made or these electromagnetic valves do not operate, the scram operation can be reliably performed using the scram signal from the alternative control +1 insertion system or the scram delay cross-protection system.

[Brief explanation of drawings]

Fig. 1 is a piping system diagram showing the air piping system of a conventional control rod drive hydraulic system; FIG. 3 is a piping system diagram according to an embodiment of the pneumatic piping system of the control rod-driven hydraulic device of the present invention. 1...Water pressure control" - Knit 2...
...... Scrum 1) 1 container 3...
・・・・・・・・・Scrum people [1 valve 4・・・・・・・・・
...Scram outlet valve 5.6...Scram solenoid valve 7...Scram air piping 8.9.
...Pen mill valve 10.11...Drain valve 12.13...Discharge container solenoid valve 14...Discharge container piping 15...
......Air supply distribution room 19.20...Backup scram solenoid valve 24.25.26.27.28...Exhaust solenoid valve

Claims (1)

[Claims] (1) An air supply pipe connected to an air source and inserted with a backup scram solenoid valve that is closed during a scram, and an air supply pipe that branches from this air supply pipe and is connected to the scram population valve and scram outlet valve of the water pressure control unit and is closed during a scram. A scram air pipe in which a scram solenoid valve is inserted between the scram air piping and a discharge container solenoid valve which is branched from the air supply piping and connected to the vent valve and drain valve of the scram discharge container and is opened during scram. In the air piping system of a control rod-driven hydraulic device equipped with container piping, an exhaust solenoid valve that is closed during scram is inserted in each of the scram air piping and the discharge container piping, or the air supply piping. pneumatic piping system for control rod-driven hydraulic equipment.