JP7107673B2 - Flood prevention devices and nuclear plants - Google Patents

Description

The present invention relates to anti-flooding measures for liquid storage facilities.

During the Niigata-ken Chuetsu-oki Earthquake, liquid in the spent fuel storage pool installed in the reactor building overflowed onto the operation floor. As a result, flooding due to sloshing of the liquid surface during an earthquake has been emphasized, and flooding evaluation of the liquid stored in the spent fuel storage pool has been conducted both in Japan and overseas. Flood prevention measures based on the results of this flood assessment have become an important issue.

As a measure to prevent flooding, for example, as in Patent Document 1, a method has been proposed in which a collapsible weir is used to prevent the liquid in the spent fuel storage pool from escaping.

Further, as in Patent Document 2, a method for suppressing the fluctuation of the liquid surface is also disclosed by causing only the liquid that has reached a predetermined height or higher due to the fluctuation of the liquid level to flow out of the container.

In addition, as in Patent Document 3, by installing an auxiliary tank for liquid level height adjustment, adjusting the liquid level height of the stored liquid, and adjusting the tank rigidity, the liquid storage tank A method of avoiding peak seismic forces by changing the natural period is also disclosed.

JP 2010-190605 A JP 2007-197057 A Japanese Patent Application Laid-Open No. 2003-300590

By the way, facilities important to safety at nuclear power plants need to be designed with appropriate margins, maintained appropriately, and given sufficient consideration to prevent damage, as well as ensuring redundancy and diversity. be. Reliable measures are required so that the safety protection function will not be lost even in the event of flooding during an earthquake as described above.

However, it is difficult to prevent the liquid from escaping beyond the height of the weir or to prevent the upper part of the liquid storage tank from overflowing due to breakage in the upper part of the liquid storage tank.

In addition, in the method for suppressing the fluctuation of the liquid surface of Patent Document 2 and the method of changing the natural period of Patent Document 3, not only the dynamic load of water due to the shaking of the earthquake, that is, the static load and the hydraulic head pressure, but also the vibration due to the fluctuation of the liquid surface. It is necessary to design the strength of pipes and storage tanks into which water flows, taking into consideration the actual load.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a flood prevention device capable of reliably preventing overflow of liquid stored in liquid storage equipment such as a liquid storage pool and a liquid storage tank during an earthquake, and a nuclear power plant and nuclear power plant equipped with the same. To provide a plant flood prevention method.

In order to solve the above problems, the present invention provides a drainage pipe connected to a liquid storage facility, a water injection pipe connected to the liquid storage facility, and a drainage for controlling the drainage of liquid from the liquid storage facility. a control valve, a water injection control valve for controlling water injection of the liquid into the liquid storage facility, and a layer below the liquid storage facility and above the lowest layer, wherein an auxiliary tank for storing liquid discharged from the liquid storage facility through a drainage pipe; and a pumping device for pumping up the liquid stored in the auxiliary tank, wherein the drainage pipe It is connected at a position lower than the liquid surface of the liquid stored in the storage facility, and the drainage control valve is automatically opened based on the information of the observed seismic motion or the earthquake information to drain the liquid in the liquid storage facility by gravity. The liquid is drained to the auxiliary tank by the action to prevent the liquid from overflowing from the liquid storage facility, automatically closed based on the information on the amount of liquid drained from the liquid storage facility, and stored in the liquid storage facility. Based on the information regarding the state of the liquid surface of the liquid, the water pumping device automatically operates, the water injection control valve automatically opens, and the water pumping device is operated based on the information regarding the amount of liquid water injected into the liquid storage facility. is automatically stopped, and the water injection control valve is automatically closed.

Further, the present invention is a nuclear power plant equipped with the flood prevention device described above, wherein the liquid storage facility is a spent fuel storage pool in a reactor building.

Further, the present invention is a nuclear power plant comprising the flood prevention device described above, wherein the liquid storage facility is a condensate storage tank of the nuclear power plant.

ADVANTAGE OF THE INVENTION According to this invention, the water level of the liquid stored in the liquid storage facility can be lowered at the time of an earthquake, and the overflow of the liquid from the liquid storage facility can be reliably prevented.

Problems, configurations, and effects other than those described above will be clarified by the following description of the embodiments.

It is a figure which shows the overflow prevention apparatus which concerns on Example 1 of this invention. (Normal state) It is a figure which shows the overflow prevention apparatus which concerns on Example 1 of this invention. (state after draining) It is a flowchart which shows the flood prevention method (operation|movement) which concerns on Example 1 of this invention. It is a figure which shows the spent fuel storage pool which concerns on Example 1 of this invention. FIG. 2 is a diagram showing a flood prevention device according to Embodiment 2 of the present invention; (Normal state) FIG. 2 is a diagram showing a flood prevention device according to Embodiment 2 of the present invention; (state after draining) FIG. 3 is a diagram showing a flood prevention device according to Embodiment 3 of the present invention; (Normal state) FIG. 3 is a diagram showing a flood prevention device according to Embodiment 3 of the present invention; (state after draining) It is a figure which shows the modification of Example 3 of this invention. (Normal state) It is a figure which shows another modification of Example 3 of this invention. (Normal state) It is a flowchart which shows the flood prevention method (operation|movement) which concerns on Example 3 of this invention. FIG. 4 is a diagram showing a flood prevention device according to Embodiment 4 of the present invention; (Normal state) FIG. 4 is a diagram showing a flood prevention device according to Embodiment 4 of the present invention; (state after draining) It is a figure which shows the modification of Example 4 of this invention. (Normal state) It is a figure which shows another modification of Example 4 of this invention. (Normal state) FIG. 5 is a view showing a flood prevention device according to Embodiment 5 of the present invention; (Normal state) FIG. 5 is a view showing a flood prevention device according to Embodiment 5 of the present invention; (state after draining) It is a figure which shows the modification of Example 5 of this invention. (Normal state) It is a figure which shows another modification of Example 5 of this invention. (Normal state) It is a flowchart which shows the overflow prevention method (operation|movement) which concerns on Example 5 of this invention. FIG. 6 is a view showing a flood prevention device according to Embodiment 6 of the present invention; (Normal state) FIG. 6 is a view showing a flood prevention device according to Embodiment 6 of the present invention; (state after draining) It is a figure which shows the modification of Example 6 of this invention. (Normal state) It is a figure which shows another modification of Example 6 of this invention. (Normal state) FIG. 7 is a view showing a flood prevention device according to Embodiment 7 of the present invention; (Normal state) FIG. 7 is a view showing a flood prevention device according to Embodiment 7 of the present invention; (state after draining) It is a figure which shows the modification of Example 7 of this invention. (Normal state) FIG. 12 is a diagram showing another modification of the seventh embodiment of the present invention; (Normal state) FIG. 10 is a view showing an overflow prevention device according to Embodiment 8 of the present invention; (Normal state) FIG. 10 is a view showing an overflow prevention device according to Embodiment 8 of the present invention; (state after draining) It is a figure which shows the modification of Example 8 of this invention. (Normal state) FIG. 12 is a diagram showing another modification of the eighth embodiment of the present invention; (Normal state) FIG. 10 is a view showing a flood prevention device according to Embodiment 9 of the present invention; (Normal state) FIG. 10 is a view showing a flood prevention device according to Embodiment 9 of the present invention; (state after draining) FIG. 12 is a flow chart showing an overflow prevention method (operation) according to Example 9 of the present invention. FIG. Fig. 10 is a diagram showing a condensate storage tank according to Embodiment 9 of the present invention; FIG. 10 is a diagram showing a flood prevention device according to a tenth embodiment of the present invention; (Normal state) FIG. 10 is a diagram showing a flood prevention device according to a tenth embodiment of the present invention; (state after draining) FIG. 11 is a view showing a flood prevention device according to Embodiment 11 of the present invention; (Normal state) FIG. 11 is a view showing a flood prevention device according to Embodiment 11 of the present invention; (state after draining) It is a figure which shows the modification of Example 11 of this invention. (Normal state) It is a figure which shows another modification of Example 11 of this invention. (Normal state) FIG. 13 is a flow chart showing an overflow prevention method (operation) according to Embodiment 11 of the present invention; FIG. FIG. 12 is a diagram showing a flood prevention device according to a twelfth embodiment of the present invention; (Normal state) FIG. 12 is a diagram showing a flood prevention device according to a twelfth embodiment of the present invention; (state after draining) FIG. 22 is a diagram showing a modification of the twelfth embodiment of the present invention; (Normal state) FIG. 22 is a diagram showing another modification of the twelfth embodiment of the present invention; (Normal state)

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, in each drawing, the same reference numerals are assigned to the same configurations, and detailed descriptions of overlapping portions are omitted.

A flood prevention device and a flood prevention method of Embodiment 1 will be described with reference to FIGS. 1A to 3 .

In this embodiment, the drainage pipe 21 connected to the spent fuel storage pool 11, the water injection pipe 22 connected to the spent fuel storage pool 11, and the liquid drainage from the spent fuel storage pool 11 are controlled. An example of a flood prevention device composed of a valve 31 that controls the injection of liquid into the spent fuel storage pool 11 and a valve 32 that controls the injection of liquid into the spent fuel storage pool 11 will be described.

The valves 31 and 32 are normally closed. The valve 31 is opened based on information on observed seismic motion or earthquake information such as an earthquake early warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valve 32 opens based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closes based on information regarding the amount of water injected into the spent fuel storage pool 11 .

In addition, the drainage pipe 21 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained. It is connected at a position lower than the liquid level.

1A and 1B are examples of the flood prevention device in this embodiment. FIG. 1A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, by opening the valve 31, the liquid stored in the spent fuel storage pool 11 is drained from the spent fuel storage pool 11 through the drainage pipe 21, and by closing the valve 31, the Drainage of liquid from the spent fuel storage pool 11 stops. Then, by opening the valve 32, the liquid to be injected into the spent fuel storage pool 11 is injected into the spent fuel storage pool 11 through the water injection pipe 22, and by closing the valve 32, the spent fuel storage pool Liquid water injection to 11 is stopped.

1A and 1B show an example in which the reactor containment vessel 10 is installed near the center of the reactor building 0. As shown in FIG. The reactor building 0 has a layered structure of layer 1 (1F) 1, layer 2 (2F) 2, layer 3 (3F) 3 in order from the lower layer to the upper layer. In order to efficiently store the spent fuel 4 taken from the side into the spent fuel storage pool 11, the spent fuel storage pool 11 is installed on the upper story 3 (3F) 3.

However, depending on the construction location and scale of reactor building 0, floor 1 (1F) 1 and floor 2 (2F) 2 may be constructed underground, so floor 1 (1F) 1 is necessarily the first floor above ground. are not limited to those placed in

1A and 1B show an example in which the valves 31 and 32 are installed inside the reactor building 0, they may be installed outside the reactor building 0. FIG.

FIG. 2 is an example flow for explaining the opening and closing of the valve 31 and the opening and closing of the valve 32 in the flood prevention method (operation) of this embodiment.

In the present embodiment, the closed valve 31 opens upon detection of seismic motion or acquisition of earthquake information such as an earthquake early warning. Then, when the amount of liquid drained from the spent fuel storage pool 11 reaches the drain set value, the valve 31 is closed. Here, the drainage setting value is the amount of liquid drainage required for the water level of the liquid stored in the spent fuel storage pool 11 to drop to the target water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, when the liquid level is lowered by 2 m, the drainage set value is 200 m ³ .

When time has passed since the occurrence of the earthquake and the sloshing of the liquid stored in the spent fuel storage pool 11 subsides, the closed valve 32 opens. Then, when the amount of liquid water injected into the spent fuel storage pool 11 reaches the water injection set value, the valve 32 is closed.

Here, the water injection set value is the amount of liquid water required to return the water level of the liquid stored in the spent fuel storage pool 11 to the normal water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, the difference between the water level of the liquid stored in the spent fuel storage pool 11 before water injection and the normal water level If the difference was 2 m, the water injection set point would be 200 ^m3 .

In the above description, the valve 31 and the valve 32 are automatically opened and closed. is also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 or to pour liquid into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator).

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 is stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . The effect of shielding the radiation emitted from can also be maintained.

In addition, in this embodiment, since the drain pipe 21 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. There is a high probability that the action will start early and prevent flooding of the liquid stored in the spent fuel storage pool 11 .

A flood prevention device and a flood prevention method of Embodiment 2 will be described with reference to FIGS. 4A and 4B.

In this embodiment, the drainage pipe 21 connected to the spent fuel storage pool 11, the water injection pipe 22 connected to the spent fuel storage pool 11, and the liquid drainage from the spent fuel storage pool 11 are controlled. and a valve 32 for controlling the injection of liquid into the spent fuel storage pool 11 to prevent the water level of the liquid stored in the spent fuel storage pool 11 from lowering more than necessary. In order to prevent this, an example of a flood prevention device will be described in which the connection position between the spent fuel storage pool 11 and the drainage pipe 21 is set at a position higher than the minimum water level that should be ensured. (In this embodiment, the "minimum water level to be ensured" means a water level that can sufficiently shield the radiation emitted from the spent fuel 4 stored in the spent fuel storage pool 11.)
The valves 31 and 32 are normally closed. The valve 31 is opened based on information on observed seismic motion or earthquake information such as an earthquake early warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valve 32 opens based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closes based on information regarding the amount of water injected into the spent fuel storage pool 11 .

In addition, the drainage pipe 21 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained. It is connected at a position lower than the liquid level.

4A and 4B are examples of the flood prevention device in this embodiment. FIG. 4A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In the present embodiment, unlike the first embodiment, in order to prevent the water level of the liquid stored in the spent fuel storage pool 11 from falling below the minimum water level that should be secured, The drain pipe 21 and the spent fuel storage pool 11 are connected at a high position. For example, if the minimum water level to be secured is 15 m, the connection position between the drain pipe 21 and the spent fuel storage pool 11 is set at 15 m. As a result, when the water level of the liquid stored in the spent fuel storage pool 11 is 15 m or less, the liquid is not drained and the water level of the liquid can be prevented from dropping below 15 m.

In this embodiment, the drainage of the liquid stored in the spent fuel storage pool 11 and the injection of liquid into the spent fuel storage pool 11 due to the opening and closing of the valves 31 and 32 are the same as in the first embodiment. Therefore, the description is omitted.

Further, in this embodiment, the flow for explaining the opening and closing of the valve 31 and the opening and closing of the valve 32 is also the same as in FIG. 2 explained in the first embodiment, so the explanation is omitted.

In the above description, the valve 31 and the valve 32 are automatically opened and closed. is also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 or to pour liquid into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator).

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 is stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . The effect of shielding the radiation emitted from can also be maintained.

In addition, in this embodiment, since the drain pipe 21 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. There is a high probability that the action will start early and prevent flooding of the liquid stored in the spent fuel storage pool 11 .

Furthermore, in this embodiment, in addition to the effects of Embodiment 1, since the drain pipe 21 and the spent fuel storage pool 11 are connected at a position higher than the minimum water level that should be ensured, the spent fuel storage pool 11 It is possible to prevent the water level of the liquid stored in the device from falling below the minimum water level that should be ensured.

A flood prevention device and a flood prevention method of Example 3 will be described with reference to FIGS. 5A to 6 .

In this embodiment, the auxiliary tank 12, the pumping device 13, the pipe 23 connecting the spent fuel storage pool 11 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed outside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 33 that controls the drainage of liquid from the spent fuel storage pool 11 to the auxiliary tank 12, and an auxiliary tank 12 to the pumping device 13 and a valve 35 controlling the injection of liquid from the pumping device 13 into the spent fuel storage pool 11. do.

Normally, the valves 33, 34, and 35 are closed. The valve 33 is opened based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

In addition, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the drainage pipe 23 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level.

5A and 5B are examples of the flood prevention device in this embodiment. FIG. 5A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, by opening the valve 33, the liquid stored in the spent fuel storage pool 11 is drained to the auxiliary tank 12 through the drain pipe 23, and by closing the valve 33, the spent fuel Drainage of liquid from the storage pool 11 stops. By opening the valves 34 and 35 and operating the pumping device 13, the liquid stored in the auxiliary tank 12 passes through the pipe 24 and is pumped by the pumping device 13. Liquid is injected into spent fuel storage pool 11 through line 25 . In addition, by closing the valves 34 and 35 to stop the water pumping device 13, the injection of liquid from the auxiliary tank 12 to the spent fuel storage pool 11 is stopped.

FIG. 6 is an example of a flow for explaining the operation and stoppage of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 in the flood prevention method (operation) of this embodiment. is.

In this embodiment, the closed valve 33 opens upon detection of seismic motion or acquisition of earthquake information such as an earthquake early warning. When the amount of liquid drained from the spent fuel storage pool 11 reaches the drain set value (that is, when the amount of liquid injected into the auxiliary tank 12 reaches the set water injection value), the valve 33 is closed.

Here, the drainage setting value is the amount of liquid drainage required for the water level of the liquid stored in the spent fuel storage pool 11 to drop to the target water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, when the liquid level is lowered by 2 m, the drainage set value is 200 m ³ .

When the sloshing of the liquid stored in the spent fuel storage pool 11 subsides after some time has passed since the earthquake, the closed valves 34 and 35 are opened and the water pumping device 13 is activated. Then, when the amount of liquid water injected into the spent fuel storage pool 11 reaches the water injection set value, the valves 34 and 35 are closed and the water pumping device 13 is stopped.

Here, the water injection set value is the amount of liquid water required to return the water level of the liquid stored in the spent fuel storage pool 11 to the normal water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, the difference between the water level of the liquid stored in the spent fuel storage pool 11 before water injection and the normal water level If the difference was 2 m, the water injection set point would be 200 ^m3 .

In the above description, the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. , the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In addition, in this embodiment, since the drain pipe 23 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. is started early due to the action of , and there is a high probability that the liquid stored in the spent fuel storage pool 11 can be prevented from overflowing.

In the description of this embodiment, as shown in FIGS. 5A and 5B, the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1). An example in which the auxiliary tank 12 is installed at a high position (floor 2 (2F) 2) is also included in this embodiment.

Further, in the description of this embodiment, as shown in FIGS. 5A to 5C, the liquid pumped by the pumping device 13 is directly injected into the spent fuel storage pool 11 through the pipe 25. As shown in FIG. 5D, the liquid pumped by the water pumping device 13 flows into the pipe 26 (the pipe connecting the water pumping device 13 and the pipe 27) and the valve 36 (the amount of the liquid pumped by the water pumping device 13 injected into the pipe 27). ) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. are included in this embodiment because they are the same in that they are filled with water. In other words, the water injection pipe in FIG. 5D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

With reference to FIGS. 7A and 7B, a flood prevention device and a flood prevention method of Example 4 will be described.

In this embodiment, the auxiliary tank 12, the pumping device 13, the pipe 23 connecting the spent fuel storage pool 11 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed outside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 33 that controls the drainage of liquid from the spent fuel storage pool 11 to the auxiliary tank 12, and an auxiliary tank 12 to the pumping device 13, and a valve 35 for controlling the injection of liquid from the pumping device 13 to the spent fuel storage pool 11. In order to prevent the water level of the stored liquid from lowering more than necessary, a flood prevention device in which the connection position between the spent fuel storage pool 11 and the drainage pipe 23 is positioned higher than the minimum water level that should be secured. An example of (In this embodiment, the "minimum water level to be ensured" means a water level that can sufficiently shield the radiation emitted from the spent fuel 4 stored in the spent fuel storage pool 11.)
Normally, the valves 33, 34, and 35 are closed. The valve 33 is opened based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

In addition, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the drainage pipe 23 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level.

7A and 7B are examples of the flood prevention device in this embodiment. FIG. 7A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, unlike the third embodiment, in order to prevent the water level of the liquid stored in the spent fuel storage pool 11 from falling below the minimum water level that should be secured, The drain pipe 23 and the spent fuel storage pool 11 are connected at a high position. For example, if the minimum water level to be ensured is 15 m, the connection position between the drain pipe 23 and the spent fuel storage pool 11 is set at 15 m. As a result, when the water level of the liquid stored in the spent fuel storage pool 11 is 15 m or less, the liquid is not drained and the water level of the liquid can be prevented from dropping below 15 m.

In this embodiment, the liquid stored in the spent fuel storage pool 11 is drained due to the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35. And the injection of the liquid into the spent fuel storage pool 11 is the same as in the third embodiment, so the explanation is omitted.

Further, in this embodiment, the flow for explaining the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 is also the same as the diagram described in the third embodiment. 6, the description is omitted.

In the above description, the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. , the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In addition, in this embodiment, since the drain pipe 23 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. is started early due to the action of , and there is a high probability that the liquid stored in the spent fuel storage pool 11 can be prevented from overflowing.

Furthermore, in this embodiment, in addition to the effects of the third embodiment, since the drain pipe 23 and the spent fuel storage pool 11 are connected at a position higher than the minimum water level that should be ensured, the spent fuel storage pool It is possible to prevent the water level of the liquid stored in 11 from falling below the minimum water level that should be ensured.

In the description of this embodiment, as shown in FIGS. 7A and 7B, the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1). An example in which the auxiliary tank 12 is installed at a high position (floor 2 (2F) 2) is also included in this embodiment.

Further, in the description of this embodiment, as shown in FIGS. 7A to 7C, the liquid pumped by the pumping device 13 is directly injected into the spent fuel storage pool 11 through the pipe 25. As shown in FIG. 7D, the liquid pumped by the water pumping device 13 flows into the pipe 26 (the pipe connecting the water pumping device 13 and the pipe 27) and the valve 36 (the amount of the liquid pumped by the water pumping device 13 injected into the pipe 27). ) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. are included in this embodiment because they are the same in that they are filled with water. In other words, the water injection pipe in FIG. 7D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

A flood prevention device and a flood prevention method of Example 5 will be described with reference to FIGS. 8A to 9 .

In this embodiment, the auxiliary tank 12, the pumping device 13, the pump 14, the pipe 28 connecting the pump 14 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed outside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 34 that controls the flow of liquid from the auxiliary tank 12 to the pumping device 13, and the pumping device 13 A valve 35 for controlling the injection of liquid into the spent fuel storage pool 11 will be described as an example of a flood prevention device.

Note that the valves 34 and 35 are normally closed. The pump 14 operates based on information on the observed seismic motion or earthquake information such as an earthquake early warning, and stops based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

8A and 8B are examples of the flood prevention device in this embodiment. FIG. 8A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, by operating the pump 14, the liquid stored in the spent fuel storage pool 11 is drained to the auxiliary tank 12 through the drain pipe 28, and by stopping the pump 14, Drainage of liquid from the spent fuel storage pool 11 stops. By opening the valves 34 and 35 and operating the water pumping device 13, the liquid stored in the auxiliary tank 12 passes through the pipe 24 and is pumped by the water pumping device 13, and the liquid pumped by the water pumping device 13 is injected into the spent fuel storage pool 11 through the pipe 25 . In addition, by closing the valves 34 and 35 to stop the water pumping device 13, the injection of liquid from the auxiliary tank 12 to the spent fuel storage pool 11 is stopped.

FIG. 9 is a flow for explaining the operation and stop of the pump 14, the operation and stop of the pumping device 13, the opening and closing of the valve 34, and the opening and closing of the valve 35 in the flood prevention method (operation) of this embodiment. is an example of

In this embodiment, the pump 14 is activated by detection of seismic motion or acquisition of earthquake information such as an earthquake early warning. Then, when the amount of liquid drained from the spent fuel storage pool 11 reaches the drain set value (that is, when the amount of liquid injected into the auxiliary tank 12 reaches the set water injection value), the pump 14 stops.

Here, the drainage setting value is the amount of liquid drainage required for the water level of the liquid stored in the spent fuel storage pool 11 to drop to the target water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, when the liquid level is lowered by 2 m, the drainage set value is 200 m ³ .

When the sloshing of the liquid stored in the spent fuel storage pool 11 subsides after some time has passed since the earthquake, the closed valves 34 and 35 are opened and the water pumping device 13 is activated. Then, when the amount of liquid water injected into the spent fuel storage pool 11 reaches the water injection set value, the valves 34 and 35 are closed and the water pumping device 13 is stopped.

Here, the water injection set value is the amount of liquid water required to return the water level of the liquid stored in the spent fuel storage pool 11 to the normal water level. For example, as shown in FIG. 3, in the spent fuel storage pool 11 of 10 m in the vertical direction and 10 m in the horizontal direction, the difference between the water level of the liquid stored in the spent fuel storage pool 11 before water injection and the normal water level If the difference was 2 m, the water injection set point would be 200 ^m3 .

In the above description, the operation and stop of the pump 14, the operation and stop of the pumping device 13, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. also has a function of manually operating and stopping the pump 14, operating and stopping the water pumping device 13, opening and closing the valve 34, and opening and closing the valve 35. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In the description of this embodiment, as shown in FIGS. 8A and 8B, an example in which the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1) is used, but as shown in FIG. 8C, An example in which the auxiliary tank 12 is installed at a high position (floor 2 (2F) 2) is also included in this embodiment.

Further, in the description of this embodiment, as shown in FIGS. 8A to 8C, the liquid pumped by the pumping device 13 is directly injected into the spent fuel storage pool 11 through the pipe 25. As shown in FIG. 8D, the liquid pumped by the water pumping device 13 flows into the pipe 26 (the pipe connecting the water pumping device 13 and the pipe 27), and the valve 36 (the amount of the liquid pumped by the water pumping device 13 injected into the pipe 27). ) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. are included in this embodiment because they are the same in that they are filled with water. In other words, the water injection pipe in FIG. 8D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

The overflow prevention device and the overflow prevention method of Example 6 will be described with reference to FIGS. 10A to 10D.

In this embodiment, the auxiliary tank 12, the pumping device 13, the pipe 23 connecting the spent fuel storage pool 11 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed inside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 33 that controls the drainage of liquid from the spent fuel storage pool 11 to the auxiliary tank 12, and an auxiliary tank 12 to the pumping device 13 and a valve 35 controlling the injection of liquid from the pumping device 13 into the spent fuel storage pool 11. do.

Normally, the valves 33, 34, and 35 are closed. The valve 33 is opened based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

In addition, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the drainage pipe 23 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level.

10A and 10B are examples of the flood prevention device in this embodiment. FIG. 10A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, the liquid stored in the spent fuel storage pool 11 is drained and used by operating and stopping the pumping device 13, opening and closing the valve 33, opening and closing the valve 34, and opening and closing the valve 35. Since the injection of liquid into the spent fuel storage pool 11 is the same as in the third embodiment, the explanation is omitted.

Further, in this embodiment, the flow for explaining the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 is also the same as the diagram described in the third embodiment. 6, the description is omitted.

In the above description, the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. , the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In addition, in this embodiment, since the drain pipe 23 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. is started early due to the action of , and there is a high probability that the liquid stored in the spent fuel storage pool 11 can be prevented from overflowing.

In the description of this embodiment, as shown in FIGS. 10A and 10B, an example in which the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1) is used, but as shown in FIG. 10C, An example in which the auxiliary tank 12 is installed at a high position (floor 2 (2F) 2) is also included in this embodiment.

Further, in the description of this embodiment, as shown in FIGS. 10A to 10C, the liquid pumped by the pumping device 13 is directly injected into the spent fuel storage pool 11 through the pipe 25. As shown in FIG. 10D, the liquid pumped by the water pumping device 13 flows into the pipe 26 (the pipe connecting the water pumping device 13 and the pipe 27) and the valve 36 (the amount of the liquid pumped by the water pumping device 13 injected into the pipe 27). ) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. are included in this embodiment because they are the same in that they are filled with water. In other words, the water injection pipe in FIG. 10D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

11A to 11D, the flood prevention device and flood prevention method of Embodiment 7 will be described.

In this embodiment, the auxiliary tank 12, the pumping device 13, the pipe 23 connecting the spent fuel storage pool 11 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed inside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 33 that controls the drainage of liquid from the spent fuel storage pool 11 to the auxiliary tank 12, and an auxiliary tank 12 to the pumping device 13, and a valve 35 for controlling the injection of liquid from the pumping device 13 to the spent fuel storage pool 11. In order to prevent the water level of the stored liquid from lowering more than necessary, a flood prevention device in which the connection position between the spent fuel storage pool 11 and the drainage pipe 23 is positioned higher than the minimum water level that should be secured. An example of (In this embodiment, the "minimum water level to be ensured" means a water level that can sufficiently shield the radiation emitted from the spent fuel 4 stored in the spent fuel storage pool 11.)
Normally, the valves 33, 34, and 35 are closed. The valve 33 is opened based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closed based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

In addition, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the drainage pipe 23 is stored in the spent fuel storage pool 11 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level.

11A and 11B are examples of the flood prevention device in this embodiment. FIG. 11A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In the present embodiment, unlike the sixth embodiment, in order to prevent the water level of the liquid stored in the spent fuel storage pool 11 from falling below the minimum water level that should be secured, The drain pipe 23 and the spent fuel storage pool 11 are connected at a high position. For example, if the minimum water level to be ensured is 15 m, the connection position between the drain pipe 23 and the spent fuel storage pool 11 is set at 15 m. As a result, when the water level of the liquid stored in the spent fuel storage pool 11 is 15 m or less, the liquid is not drained and the water level of the liquid can be prevented from dropping below 15 m.

In this embodiment, the liquid stored in the spent fuel storage pool 11 is drained and used by operating and stopping the pumping device 13, opening and closing the valve 33, opening and closing the valve 34, and opening and closing the valve 35. Since the injection of liquid into the spent fuel storage pool 11 is the same as in the third embodiment, the explanation is omitted.

Further, in this embodiment, the flow for explaining the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 is also shown in FIG. , so the description is omitted.

In the above description, the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. , the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 are also provided. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In addition, in this embodiment, since the drain pipe 23 is connected at a position lower than the liquid level of the liquid stored in the spent fuel storage pool 11, the drain of the liquid from the spent fuel storage pool 11 is caused by gravity. is started early due to the action of , and there is a high probability that the liquid stored in the spent fuel storage pool 11 can be prevented from overflowing.

Furthermore, in this embodiment, in addition to the effects of the sixth embodiment, since the drain pipe 23 and the spent fuel storage pool 11 are connected at a position higher than the minimum water level to be secured, the spent fuel storage pool It is possible to prevent the water level of the liquid stored in 11 from falling below the minimum water level that should be ensured.

11A and 11B, the example in which the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1) is used in the description of this embodiment, but as shown in FIG. 11C, An example in which the auxiliary tank 12 is installed at a high position (floor 2 (2F) 2) is also included in this embodiment.

Further, in the description of this embodiment, as shown in FIGS. 11A to 11C, the liquid pumped by the pumping device 13 is directly injected into the spent fuel storage pool 11 through the pipe 25. As shown in FIG. 11D, the liquid pumped by the water pumping device 13 flows into the pipe 26 (the pipe connecting the water pumping device 13 and the pipe 27) and the valve 36 (the amount of the liquid pumped by the water pumping device 13 injected into the pipe 27). ) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. are included in this embodiment because they are the same in that they are filled with water. In other words, the water injection pipe in FIG. 11D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

12A to 12D, the overflow prevention device and the overflow prevention method of Example 8 will be described.

In this embodiment, the auxiliary tank 12, the pumping device 13, the pump 14, the pipe 28 connecting the pump 14 and the auxiliary tank 12, the auxiliary tank 12 and the pumping device 13 are installed inside the reactor building 0. , a pipe 25 that connects the pumping device 13 and the spent fuel storage pool 11, a valve 34 that controls the flow of liquid from the auxiliary tank 12 to the pumping device 13, and from the pumping device 13 A valve 35 for controlling the injection of liquid into the spent fuel storage pool 11 will be described as an example of a flood prevention device.

Note that the valves 34 and 35 are normally closed. The pump 14 operates based on information on the observed seismic motion or earthquake information such as an earthquake early warning, and stops based on information on the amount of liquid discharged from the spent fuel storage pool 11 . The valves 34 and 35 are opened based on information regarding the state of the liquid surface of the liquid stored in the spent fuel storage pool 11 and closed based on information regarding the amount of liquid injected into the spent fuel storage pool 11. .

12A and 12B are examples of the flood prevention device in this embodiment. FIG. 12A shows a normal state (the state before the water level of the liquid stored in the spent fuel storage pool 11 is lowered by drainage), and FIG. This indicates that the water level of the liquid in the tank has been lowered due to drainage.

In this embodiment, the operation and stop of the pump 14, the operation and stop of the pumping device 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 cause water to be stored in the spent fuel storage pool 11. Since the drainage of the liquid and the injection of the liquid into the spent fuel storage pool 11 are the same as those of the fifth embodiment, the description thereof will be omitted.

Also, in this embodiment, the flow for explaining the operation and stop of the pump 14, the operation and stop of the water pump 13, the opening and closing of the valve 33, the opening and closing of the valve 34, and the opening and closing of the valve 35 Since it is the same as FIG. 9 described in the fifth embodiment, the description is omitted.

In the above description, the operation and stop of the pump 14, the operation and stop of the pumping device 13, the opening and closing of the valve 34, and the opening and closing of the valve 35 are automatically performed. also has a function of manually operating and stopping the pump 14, operating and stopping the water pump 13, opening and closing the valve 34, and opening and closing the valve 35. Therefore, it is also possible to drain liquid from the spent fuel storage pool 11 to the auxiliary tank 12 or to pour liquid from the auxiliary tank 12 into the spent fuel storage pool 11 by manual operation at the discretion of a human (operator). be.

The overflow prevention device of this embodiment can lower the water level of the liquid stored in the spent fuel storage pool 11 and prevent the liquid from overflowing from the spent fuel storage pool 11 during an earthquake. After the sloshing of the liquid stored in the spent fuel storage pool 11 has stopped, the spent fuel 4 stored in the spent fuel storage pool 11 is discharged by injecting the liquid into the spent fuel storage pool 11 . It can also maintain the effect of shielding the radiation emitted from.

In the description of this embodiment, as shown in FIGS. 12A and 12B, an example in which the auxiliary tank 12 is installed at a low position (floor 1 (1F) 1) is used. 12 is installed at a high position (level 2 (2F) 2) is also included in this embodiment.

In addition, in the description of this embodiment, as shown in FIGS. 12A to 12C, the liquid pumped by the pumping device 13 is injected into the spent fuel storage pool 11 through the pipe 25. As shown in 12D, the liquid pumped by the pumping device 13 is connected to the pipe 26 (pipe connecting the pumping device 13 and the pipe 27) and the valve 36 (the amount of the liquid pumped by the pumping device 13 injected into the pipe 27). control valve) and piping 27, which is a system for injecting liquid into the spent fuel storage pool 11. Since the point of water injection is the same, it is included in the present embodiment. In other words, the water injection pipe in FIG. 12D has a piping configuration including a pipe 27 for supplying liquid to the spent fuel storage pool 11 in addition to the pipe 26 connected to the water pumping device 13 .

A flood prevention device and a flood prevention method of Example 9 will be described with reference to FIGS. 13A to 15 .

In this embodiment, a drain pipe 71 connected to the condensate storage tank 61, a water injection pipe 72 connected to the condensate storage tank 61, and a valve 81 for controlling the draining of liquid from the condensate storage tank 61. and a valve 82 for controlling the injection of liquid into the condensate storage tank 61.

Note that the valves 81 and 82 are normally closed. The valve 81 opens based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closes based on information on the amount of liquid drained from the condensate storage tank 61 . The valve 82 is opened based on information regarding the level of the liquid stored in the condensate storage tank 61 and closed based on information regarding the amount of liquid injected into the condensate storage tank 61 .

Further, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the liquid stored in the condensate storage tank 61 is connected to the drain pipe 71 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level of the

13A and 13B are examples of the flood prevention device in this embodiment. FIG. 13A shows the normal state (the state before the water level of the liquid stored in the condensate storage tank 61 drops due to drainage), and FIG. It shows the state that the water level of has decreased due to drainage.

In this embodiment, by opening the valve 81, the liquid stored in the condensate storage tank 61 is drained from the condensate storage tank 61 through the drain pipe 71, and by closing the valve 81, the condensate is stored. Drainage of liquid from tank 61 stops. By opening the valve 82, the liquid to be injected into the condensate storage tank 61 is injected into the condensate storage tank 61 through the water injection pipe 72, and by closing the valve 82, the liquid is injected into the condensate storage tank 61. Liquid injection stops.

FIG. 14 is an example flow for explaining the opening and closing of the valve 81 and the opening and closing of the valve 82 in the flood prevention method (operation) of this embodiment.

In this embodiment, the closed valve 81 opens upon detection of seismic motion or acquisition of earthquake information such as an earthquake early warning. Then, when the amount of liquid drained from the condensate storage tank 61 reaches the drain set value, the valve 81 is closed. Here, the drainage set value is the amount of liquid to be drained required for the water level of the liquid stored in the condensate storage tank 61 to drop to the target water level. For example, as shown in FIG. 15, in a condensate storage tank 61 having a diameter of 10 m, if the liquid level is to be lowered by 2 m, the drain setpoint is 157 m ³ .

When time has passed since the occurrence of the earthquake and sloshing of the liquid stored in the condensate storage tank 61 subsides, the closed valve 82 opens. Then, when the amount of liquid injected into the condensate storage tank 61 reaches the injection set value, the valve 82 is closed. Here, the water injection set value is the amount of liquid water required to return the water level of the liquid stored in the condensate storage tank 61 to the normal water level. For example, as shown in FIG. 15, in a condensate storage tank 61 having a diameter of 10 m, if the difference between the water level of the liquid stored in the condensate storage tank 61 before water injection and the normal water level is 2 m, , the water injection set value is ^157m3 .

In the above description, the opening and closing of the valve 81 and the opening and closing of the valve 82 are described as being performed automatically. is also provided. Therefore, it is also possible to drain the liquid from the condensate storage tank 61 or to pour the liquid into the condensate storage tank 61 by manual operation at the discretion of a human (operator).

With the flood prevention device of this embodiment, it is possible to lower the water level of the liquid stored in the condensate storage tank 61 and prevent the liquid from overflowing due to damage to the roof of the condensate storage tank 61 during an earthquake. . After the sloshing of the liquid stored in the condensate storage tank 61 is stopped, the liquid is injected into the condensate storage tank 61 so that the water level of the liquid stored in the condensate storage tank 61 is returned to the normal state. It is possible to return to

In addition, in this embodiment, since the drain pipe 71 is connected at a position lower than the liquid level of the liquid stored in the condensate storage tank 61, the drain of the liquid from the condensate storage tank 61 is caused by the action of gravity. An early start is likely to prevent flooding of the liquid stored in the condensate storage tank 61 .

A flood prevention device and a flood prevention method of Example 10 will be described with reference to FIGS. 16A and 16B.

In this embodiment, a drain pipe 71 connected to the condensate storage tank 61, a water injection pipe 72 connected to the condensate storage tank 61, and a valve 81 for controlling the draining of liquid from the condensate storage tank 61. and a valve 82 for controlling the injection of liquid into the condensate storage tank 61. In order to prevent the water level of the liquid stored in the condensate storage tank 61 from dropping more than necessary, the condensate storage An example of a flood prevention device in which the connection position between the tank 61 and the drain pipe 71 is set to a position higher than the minimum water level to be ensured will be described.

Note that the valves 81 and 82 are normally closed. The valve 81 opens based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and closes based on information on the amount of liquid drained from the condensate storage tank 61 . The valve 82 is opened based on information regarding the level of the liquid stored in the condensate storage tank 61 and closed based on information regarding the amount of liquid injected into the condensate storage tank 61 .

Further, when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained, the liquid stored in the condensate storage tank 61 is connected to the drain pipe 71 so that the liquid can be drained quickly by the action of gravity. connected to a position lower than the liquid level of the

16A and 16B are examples of the flood prevention device in this embodiment. FIG. 16A shows the normal state (the state before the water level of the liquid stored in the condensate storage tank 61 is lowered by drainage), and FIG. It shows the state that the water level of has decreased due to drainage.

In this embodiment, unlike the ninth embodiment, the water level of the liquid stored in the condensate storage tank 61 is higher than the minimum required water level in order to prevent it from falling below the minimum required water level. A connection is made between the drain pipe 71 and the condensate storage tank 61 at the position. For example, if the minimum water level to be secured is 15 m, the connection position between the drain pipe 71 and the condensate storage tank 61 is set at 15 m. As a result, when the water level of the liquid stored in the condensate storage tank 61 is 15 m or less, the liquid is not drained, and the water level of the liquid can be prevented from dropping below 15 m.

In this embodiment, the drainage of the liquid stored in the condensate storage tank 61 and the injection of the liquid into the condensate storage tank 61 due to the opening and closing of the valves 81 and 82 are the same as in the ninth embodiment. Description is omitted.

Further, in this embodiment, the flow for explaining the opening and closing of the valve 81 and the opening and closing of the valve 82 is also the same as in FIG. 14 explained in the ninth embodiment, so the explanation is omitted.

In the above description, the opening and closing of the valve 81 and the opening and closing of the valve 82 are described as being performed automatically. is also provided. Therefore, it is also possible to drain the liquid from the condensate storage tank 61 or to pour the liquid into the condensate storage tank 61 by manual operation at the discretion of a human (operator).

With the flood prevention device of this embodiment, it is possible to lower the water level of the liquid stored in the condensate storage tank 61 and prevent the liquid from overflowing due to damage to the roof of the condensate storage tank 61 during an earthquake. . After the sloshing of the liquid stored in the condensate storage tank 61 is stopped, the liquid is injected into the condensate storage tank 61 so that the water level of the liquid stored in the condensate storage tank 61 is returned to the normal state. It is possible to return to

In addition, in this embodiment, since the drain pipe 71 is connected at a position lower than the liquid level of the liquid stored in the condensate storage tank 61, the drain of the liquid from the condensate storage tank 61 is caused by the action of gravity. An early start is likely to prevent flooding of the liquid stored in the condensate storage tank 61 .

Furthermore, in this embodiment, in addition to the effects of the ninth embodiment, since the connection between the drainage pipe 71 and the condensate storage tank 61 is performed at a position higher than the minimum water level that should be ensured, water is stored in the condensate storage tank 61. It is possible to prevent the water level of the liquid being held from dropping below the minimum water level that should be ensured.

17A to 18, the flood prevention device and flood prevention method of Example 11 will be described.

In this embodiment, the auxiliary tank 62, the pumping device 63, the pipe 73 connecting the condensate storage tank 61 and the auxiliary tank 62, the pipe 74 connecting the auxiliary tank 62 and the pumping device 63, the pumping device 63 and the condensate storage tank 61, a valve 83 controlling the draining of liquid from the condensate storage tank 61 to the auxiliary tank 62, and the flow of liquid from the auxiliary tank 62 to the pumping device 63. An example of an anti-flood system comprising a valve 84 and a valve 85 controlling the injection of liquid from the pumping device 63 into the condensate storage tank 61 will be described.

Normally, the valves 83, 84 and 85 are closed. The valve 83 opens based on information on observed seismic motion or earthquake information such as an earthquake early warning, and closes based on information on the amount of liquid drained from the condensate storage tank 61 . The valves 84 and 85 are opened based on information regarding the level of the liquid stored in the condensate storage tank 61 and closed based on information regarding the amount of liquid injected into the condensate storage tank 61 .

In addition, the drainage pipe 73 is stored in the condensate storage tank 61 so that the liquid can be drained quickly by the action of gravity when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained. It is connected at a position lower than the liquid level.

17A and 17B are examples of the flood prevention device in this embodiment. FIG. 17A shows the normal state (the state before the water level drops due to drainage) of the liquid stored in the condensate storage tank 61, and FIG. It shows the state that the water level of has decreased due to drainage.

In this embodiment, by opening the valve 83, the liquid stored in the condensate storage tank 61 is drained to the auxiliary tank 62 through the drain pipe 73, and by closing the valve 83, the condensate storage tank is drained. Drainage of liquid from 61 stops. By opening the valves 84 and 85 and operating the pumping device 63, the liquid stored in the auxiliary tank 62 passes through the pipe 74 and is pumped by the pumping device 63, and the liquid pumped by the pumping device 63 is injected into condensate storage tank 61 through line 75 . In addition, by closing the valves 84 and 85 to stop the water pumping device 63, the injection of liquid from the auxiliary tank 62 to the condensate storage tank 61 is stopped.

FIG. 18 is an example flow for explaining the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 in the flood prevention method (operation) of this embodiment.

In this embodiment, the closed valve 83 is opened by detection of seismic motion or acquisition of earthquake information such as an earthquake early warning. Then, when the amount of liquid drained from the condensate storage tank 61 reaches the drain set value, the valve 83 is closed. Here, the drainage set value is the amount of liquid to be drained required for the water level of the liquid stored in the condensate storage tank 61 to drop to the target water level. For example, as shown in FIG. 15, in a condensate storage tank 61 having a diameter of 10 m, if the liquid level is to be lowered by 2 m, the drain setpoint is 157 m ³ .

When the sloshing of the liquid stored in the condensate storage tank 61 subsides after some time has passed since the earthquake, the closed valves 84 and 85 are opened and the pumping device 63 is activated. Then, when the amount of liquid water injected into the condensate storage tank 61 reaches the water injection set value, the valves 84 and 85 are closed and the water pumping device 63 is stopped. Here, the water injection set value is the amount of liquid water required to return the water level of the liquid stored in the condensate storage tank 61 to the normal water level. For example, as shown in FIG. 15, in a condensate storage tank 61 having a diameter of 10 m, if the difference between the water level of the liquid stored in the condensate storage tank 61 before water injection and the normal water level is 2 m, , the water injection set value is 157 m ³ .

In the above description, the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 are automatically performed. , the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 are also provided. Therefore, it is also possible to drain the liquid from the condensate storage tank 61 to the auxiliary tank 62 or to pour the liquid from the auxiliary tank 62 into the condensate storage tank 61 by manual operation at the discretion of a person (operator).

With the flood prevention device of this embodiment, it is possible to lower the water level of the liquid stored in the condensate storage tank 61 and prevent the liquid from overflowing due to damage to the roof of the condensate storage tank 61 during an earthquake. . After the sloshing of the liquid stored in the condensate storage tank 61 is stopped, the liquid is injected into the condensate storage tank 61 so that the water level of the liquid stored in the condensate storage tank 61 is returned to the normal state. It is possible to return to

Further, in this embodiment, since the drain pipe 73 is connected at a position lower than the liquid level of the liquid stored in the condensate storage tank 61, the drain of the liquid from the condensate storage tank 61 is caused by gravity. is started early and has a high probability of preventing flooding of the liquid stored in the condensate storage tank 61 .

In the description of the present embodiment, an example in which the auxiliary tank 62 is installed at a low position as shown in FIGS. 17A and 17B has been described, but as shown in FIG. ) installed example is also included in the present embodiment.

In addition, in the description of this embodiment, as shown in FIGS. As shown in 17D, the liquid pumped by the pumping device 63 is connected to the pipe 76 (pipe connecting the pumping device 63 and the pipe 77) and the valve 86 (the amount of the liquid pumped by the pumping device 63 to be injected into the pipe 77). Control valve) and piping 77, which is a system for injecting liquid into the condensate storage tank 61. are the same and are therefore included in this example. In other words, the water injection piping in FIG. 17D has a piping configuration including a piping 77 for supplying liquid to the condensate storage tank 61 in addition to the piping 76 connected to the pumping device 63 .

19A to 19D, the overflow prevention device and the overflow prevention method of Example 12 will be described.

In this embodiment, the auxiliary tank 62, the pumping device 63, the pipe 73 connecting the condensate storage tank 61 and the auxiliary tank 62, the pipe 74 connecting the auxiliary tank 62 and the pumping device 63, the pumping device 63 and the condensate storage tank 61, a valve 83 controlling the draining of liquid from the condensate storage tank 61 to the auxiliary tank 62, and the flow of liquid from the auxiliary tank 62 to the pumping device 63. It is composed of a valve 84 and a valve 85 for controlling the injection of liquid from the pumping device 63 into the condensate storage tank 61 to prevent the water level of the liquid stored in the condensate storage tank 61 from dropping more than necessary. In order to prevent this, an example of a flood prevention device will be described in which the connection position between the condensate storage tank 61 and the drainage pipe 73 is set at a position higher than the minimum water level that should be secured.

Normally, the valves 83, 84 and 85 are closed. The valve 83 opens based on information on observed seismic motion or earthquake information such as an earthquake early warning, and closes based on information on the amount of liquid drained from the condensate storage tank 61 . The valves 84 and 85 are opened based on information regarding the level of the liquid stored in the condensate storage tank 61 and closed based on information regarding the amount of liquid injected into the condensate storage tank 61 .

In addition, the drainage pipe 73 is stored in the condensate storage tank 61 so that the liquid can be drained quickly by the action of gravity when information on the observed seismic motion or earthquake information such as an emergency earthquake warning is obtained. It is connected at a position lower than the liquid level.

19A and 19B are examples of the flood prevention device in this embodiment. FIG. 19A shows the normal state (the state before the water level of the liquid stored in the condensate storage tank 61 is lowered by drainage), and FIG. It shows the state that the water level of has decreased due to drainage.

In this embodiment, unlike the eleventh embodiment, the water level of the liquid stored in the condensate storage tank 61 is higher than the minimum required water level in order to prevent it from falling below the minimum required water level. A connection is made between the drain pipe 73 and the condensate storage tank 61 at the position. For example, if the minimum water level to be secured is 15 m, the connection position between the drain pipe 73 and the condensate storage tank 61 is set at 15 m. As a result, when the water level of the liquid stored in the condensate storage tank 61 is 15 m or less, the liquid is not drained, and the water level of the liquid can be prevented from dropping below 15 m.

In this embodiment, the liquid stored in the condensate storage tank 61 is drained and condensed by the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85. Since the injection of the liquid into the storage tank 61 is the same as in the eleventh embodiment, the explanation is omitted.

Further, in this embodiment, the flow for explaining the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 is also shown in FIG. , so the description is omitted.

In the above description, the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 are automatically performed. , the operation and stop of the pumping device 63, the opening and closing of the valve 83, the opening and closing of the valve 84, and the opening and closing of the valve 85 are also provided. Therefore, it is also possible to drain the liquid from the condensate storage tank 61 to the auxiliary tank 62 or to pour the liquid from the auxiliary tank 62 into the condensate storage tank 61 by manual operation at the discretion of a person (operator).

With the flood prevention device of this embodiment, it is possible to lower the water level of the liquid stored in the condensate storage tank 61 and prevent the liquid from overflowing due to damage to the roof of the condensate storage tank 61 during an earthquake. . After the sloshing of the liquid stored in the condensate storage tank 61 is stopped, the liquid is injected into the condensate storage tank 61 so that the water level of the liquid stored in the condensate storage tank 61 is returned to the normal state. It is possible to return to

Further, in this embodiment, since the drain pipe 73 is connected at a position lower than the liquid level of the liquid stored in the condensate storage tank 61, the drain of the liquid from the condensate storage tank 61 is caused by gravity. is started early and has a high probability of preventing flooding of the liquid stored in the condensate storage tank 61 .

Furthermore, in the present embodiment, in addition to the effects of the eleventh embodiment, since the drain pipe 73 and the condensate storage tank 61 are connected at a position higher than the minimum water level to be secured, the condensate storage tank 61 It is possible to prevent the water level of the stored liquid from falling below the minimum water level that should be ensured.

In the description of the present embodiment, an example in which the auxiliary tank 62 is installed at a low position as shown in FIGS. 19A and 19B was explained, but as shown in FIG. ) installed example is also included in this embodiment.

In addition, in the description of this embodiment, as shown in FIGS. 19A to 19C, the liquid pumped by the pumping device 63 is directly injected into the condensate storage tank 61 through the pipe 75. As shown in 19D, the liquid pumped by the pumping device 63 is connected to the pipe 76 (pipe connecting the pumping device 63 and the pipe 77) and the valve 86 (the amount of the liquid pumped by the pumping device 63 injected into the pipe 77). Control valve) and piping 77, which is a system for injecting liquid into the condensate storage tank 61. are the same and are therefore included in this example. In other words, the water injection piping in FIG. 19D has a piping configuration including a piping 77 for supplying liquid to the condensate storage tank 61 in addition to the piping 76 connected to the pumping device 63 .

In addition, the present invention is not limited to the above-described embodiments, and includes various modifications. For example, the above-described embodiments have been described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations. In addition, it is possible to replace part of the configuration of one embodiment with the configuration of another embodiment, and it is also possible to add the configuration of another embodiment to the configuration of one embodiment. Moreover, it is possible to add, delete, or replace a part of the configuration of each embodiment with another configuration.

In addition, the present invention also has features described in appendices 1 to 12 below.

[Appendix 1]
Drain the liquid from the liquid storage facility by opening the drainage control valve based on the information on the observed seismic motion or earthquake information such as an emergency earthquake bulletin,
A flood prevention method for a nuclear power plant, comprising the step of: closing the drainage control valve based on information on the amount of liquid discharged from the liquid storage facility to stop the liquid from being discharged from the liquid storage facility.

[Appendix 2]
A nuclear plant flood prevention method according to Supplementary Note 1,
opening a water injection control valve based on information about the state of the liquid surface of the liquid stored in the liquid storage facility to inject the liquid into the liquid storage facility;
A flood prevention method for a nuclear power plant, wherein the water injection control valve is closed to stop the injection of liquid into the liquid storage facility based on information about the amount of liquid water injected into the liquid storage facility.

[Appendix 3]
A nuclear plant flood prevention method according to Supplementary Note 1,
operating a pumping device based on information about the state of the liquid surface of the liquid stored in the liquid storage facility, and opening a water injection control valve to inject the liquid into the liquid storage facility;
Flooding of a nuclear power plant, characterized in that the water pumping device is stopped based on information about the amount of liquid water injected into the liquid storage facility, and the water injection control valve is closed to stop the injection of liquid water into the liquid storage facility. Prevention method.

[Appendix 4]
A nuclear plant flood prevention method according to Appendix 3,
The pump is operated based on the information of the observed seismic motion or the earthquake information such as the earthquake early warning, and the drainage control valve is opened to drain the liquid from the liquid storage facility,
A flood prevention method for a nuclear power plant, comprising: stopping the pump based on information on the amount of liquid discharged from the liquid storage facility; and closing the drainage control valve to stop the liquid from being discharged from the liquid storage facility. .

[Appendix 5]
Operate the pump based on the information of the observed seismic motion or earthquake information such as an emergency earthquake warning to drain the liquid from the liquid storage facility,
A flood prevention method for a nuclear power plant, comprising the step of: stopping the pump based on information on the amount of liquid discharged from the liquid storage facility to stop the liquid from being discharged from the liquid storage facility.

[Appendix 6]
A nuclear plant flood prevention method according to appendix 5,
opening a water injection control valve based on information about the state of the liquid surface of the liquid stored in the liquid storage facility to inject the liquid into the liquid storage facility;
A flood prevention method for a nuclear power plant, wherein the water injection control valve is closed to stop the injection of liquid into the liquid storage facility based on information about the amount of liquid water injected into the liquid storage facility.

[Appendix 7]
A nuclear plant flood prevention method according to appendix 5,
operating a pumping device based on information about the state of the liquid surface of the liquid stored in the liquid storage facility, and opening a water injection control valve to inject the liquid into the liquid storage facility;
Flooding of a nuclear power plant, characterized in that the water pumping device is stopped based on information about the amount of liquid water injected into the liquid storage facility, and the water injection control valve is closed to stop the injection of liquid water into the liquid storage facility. Prevention method.

[Appendix 8]
a drain pipe connected to the liquid storage facility;
a water injection pipe connected to the liquid storage facility;
a pump for draining liquid from the liquid storage facility;
a water injection control valve that controls water injection of the liquid into the liquid storage facility;
The overflow prevention device, wherein the pump operates based on information on observed seismic motion or earthquake information such as an emergency earthquake warning, and stops based on information on the amount of liquid discharged from the liquid storage facility.

[Appendix 9]
The flood prevention device according to appendix 8,
A flooding characterized in that the water injection control valve is opened based on information regarding the state of the liquid surface of the liquid stored in the liquid storage facility and closed based on information regarding the amount of water injected into the liquid storage facility. prevention device.

[Appendix 10]
The flood prevention device according to appendix 8,
an auxiliary tank for storing the liquid discharged from the liquid storage facility through the drainage pipe;
a pumping device for pumping up the liquid stored in the auxiliary tank,
Based on information about the state of the liquid surface of the liquid stored in the liquid storage facility, the water pumping device is operated and the water injection control valve is opened,
A flood prevention device, wherein the water pumping device is stopped and the water injection control valve is closed based on information about the amount of liquid water to be injected into the liquid storage facility.

[Appendix 11]
11. The flood prevention device according to Appendix 10,
The flood prevention device, wherein the auxiliary tank is installed on a floor higher than the lowest floor.

[Appendix 12]
11. The flood prevention device according to Appendix 10,
The overflow prevention device, wherein the water injection pipe includes a pipe of a system for supplying liquid to the liquid storage facility.

0...Reactor building 1...Layer 1 (1F)
2... Hierarchy 2 (2F)
3... Hierarchy 3 (3F)
4 Spent fuel 10 Reactor containment vessel 11 Spent fuel storage pool 12 Auxiliary tank 13 Pumping device 14 Pump 21 Drainage pipe 22 Water injection pipe 23, 24, 25, 26, 27, 28 ... Piping 31, 33 ... Valve (drainage control valve)
32, 34, 35, 36...valves (water injection control valves)
61 Condensate storage tank 62 Auxiliary tank 63 Pumping device 71 Drainage pipe 72 Water injection pipe 73, 74, 75, 76, 77 Piping 81, 83 Valve (drainage control valve)
82, 84, 85, 86 ... valves (water injection control valves)

Claims (6)

a drain pipe connected to the liquid storage facility;
a water injection pipe connected to the liquid storage facility;
a drainage control valve for controlling drainage of liquid from the liquid storage facility;
a water injection control valve for controlling liquid water injection into the liquid storage facility;
an auxiliary tank installed on a floor below the liquid storage facility and on a floor above the lowest floor for storing the liquid discharged from the liquid storage facility through the drainage pipe; ,
a pumping device for pumping up the liquid stored in the auxiliary tank,
The drainage pipe is connected to a position lower than the liquid level of the liquid stored in the liquid storage facility,
The drainage control valve is automatically opened based on the information of the observed seismic motion or earthquake information, and drains the liquid in the liquid storage facility to the auxiliary tank by the action of gravity, thereby preventing the liquid from overflowing from the liquid storage facility. and automatically closes based on information about the amount of liquid drained from the liquid storage facility,
Based on information about the state of the liquid surface of the liquid stored in the liquid storage facility, the water pumping device automatically operates and the water injection control valve automatically opens,
A flood prevention device, wherein the water pumping device automatically stops and the water injection control valve automatically closes based on information about the amount of liquid water injected into the liquid storage facility. A flood prevention device according to claim 1 ,
The overflow prevention device, wherein the water injection pipe includes a pipe of a system for supplying liquid to the liquid storage facility. A flood prevention device according to claim 1 or 2 ,
The drainage pipe is connected to the liquid storage equipment at a position higher than the minimum water level to ensure that the water level of the liquid stored in the liquid storage equipment does not fall below the minimum water level to be maintained. A flood prevention device characterized by: A nuclear power plant comprising the flood prevention device according to any one of claims 1 to 3 ,
A nuclear power plant, wherein the liquid storage facility is a spent fuel storage pool in a reactor building. A nuclear plant according to claim 4 ,
A nuclear power plant, wherein the flood prevention device is installed in a reactor building of the nuclear power plant. A nuclear plant according to claim 4 ,
A nuclear power plant, wherein the flood prevention device is installed outside a reactor building of the nuclear power plant.

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