JPH06230166A - Protective system for reactor vessel - Google Patents

Abstract

PURPOSE:To suppress emission of fission product to the outside of a reactor vessel by protecting the reaction vessel against fracture under severe conditions. CONSTITUTION:A unit common bent tank 13 is coupled with reactor vessels 1 of a plurality of nuclear power plants A, B through a common bent line 14 and reactor vessel bent lines 15. The common bent tank 13 comprises a vapor-phase section 16, a particle removing filter 17, and a discharge gas condensation pool 18. The vapor-phase section 16 is coupled with a nitrogen gas tank 21 whereas the discharge gas condensation pool 18 is coupled with a supply tank 34. Discharge side line 8 of the reactor vessel 1 is coupled with an emergency gas treating system 10 which discharges gas to the atmosphere through a discharge line 11 and a stack 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention prevents damage to a containment vessel in a nuclear power plant when the pressure of the containment vessel (hereinafter referred to as the containment vessel) exceeds its design pressure. The present invention relates to a reactor containment vessel protection device that suppresses the amount of fission products released to the outside of the containment vessel.

[0002]

2. Description of the Related Art In a nuclear power plant, various safety devices are multiply installed and designed so that the soundness of a nuclear reactor can be secured no matter what kind of event occurs.
It is very unlikely that the safety device will cause multiple obstacles,
If various safety devices cause multiple obstacles, the fission products (hereinafter referred to as FP) retained in the fuel of the reactor due to loss of the integrity of the reactor are transferred from the reactor to the containment vessel. May be released.

Even if such a phenomenon occurs, the containment container is
It is installed to confine the FP inside so that P is not directly released to the outside of the nuclear power plant.

Therefore, by ending the event while the FP is confined in the containment vessel, it is possible to prevent the FP from being released to the outside of the nuclear power plant even if an event occurs in which the fuel of the nuclear reactor is melted. You can

However, the possibility that the event cannot be terminated cannot be completely denied, and in this case, the pressure and temperature inside the PCV gradually rise due to the decay heat of the FP trapped inside the PCV. The design pressure or temperature of the containment vessel or higher. Eventually the containment vessel was damaged,
A large amount of FP trapped up to that time may be released to the outside at one time, which may have a great impact on the periphery of the power plant.

According to a physical behavior analysis and a FP behavior analysis under severe conditions such as melting of fuel of a nuclear reactor, the containment vessel is vented under such severe condition and the containment vessel is prevented from being damaged, and is released to the outside. It is known that the FP amount can be reduced.

[0007]

Therefore, in order to prevent damage to the containment vessel from the past, research has been conducted on means for reducing the amount of FP released by the containment vessel venting utilizing the existing inert N ₂ purge line. Has been done. The typical one is
As shown in FIG. 6, it is released from the wet well of the suppression chamber to the environment through the emergency gas treatment system (SGTS).

That is, in FIG. 6, reference numeral 1 is a containment vessel, a reactor pressure vessel 2 is installed in the containment vessel 1, and the interior of the containment vessel 1 is roughly divided into a gas phase part 3 called a dry well. It is partitioned into a suppression chamber 4 that serves as a wet well, and a suppression pool 5 is provided in the suppression chamber 4.

Gas phase section 3 and suppression chamber 4
Is connected to a discharge side lead-out line 8 via valves 6 and 7, respectively, and the discharge side lead-out line 8 is connected to an emergency gas treatment system 10 via a valve 9. The emergency gas treatment system 10 is exhausted. It connects to stack 12 through line 11.

Here, the exhaust gas in the suppression pool 5 is opened through valves 7 and 9 and passes through the discharge side outlet line 8 to be processed by the emergency gas processing system 10 for impurities and the like, and passes through the exhaust line 11 through the stack 12. Released into the atmosphere.

However, the exhaust gas discharged from the containment vessel 1 under severe conditions has a high pressure and a high temperature, and contains a large amount of water vapor, iodine, particles, and a rare gas, so that a sufficient scrubbing effect in the suppression pool 5 is expected. Can not.
Further, since high-temperature and high-pressure exhaust gas exceeding the design conditions is vented, the processing effect of removing iodine and particles in the emergency gas processing system 10 cannot be expected.

Therefore, when venting the containment vessel, the amount of FP released to the outside cannot be reduced sufficiently. In particular, all of the rare gas, which cannot be expected to have both the scrubbing effect of the suppression pool 5 and the removal effect of the emergency gas treatment system 10, is released to the environment.

The present invention has been made in order to solve the above-mentioned problems, and in a severe time that affects the environment around the nuclear power plant such that the soundness of the reactor is impaired and the soundness of the containment vessel is threatened. Another object of the present invention is to provide a protection device for a containment vessel that prevents damage to the containment vessel and reduces the amount of FP released outside the containment vessel.

[0014]

According to the present invention, a plurality of containment vessels are connected to a single shared vent tank by a containment vessel vent line and a shared vent line, respectively, and a gas phase part and particles are contained in the shared vent tank. A removal filter section and an exhaust gas condensing pool section are provided, and a gas derivation line on the common vent line side and a gas derivation line on the containment vessel vent line side are connected to the containment vessel, and the release line side derivation line is for emergency use. Connected to a gas treatment system, the inlet side of the containment vessel vent line is connected to the gas phase portion, the outlet side of the discharge line is connected to the emergency gas treatment system,
An inlet side of the common vent line is connected to the common side gas outlet line, an outlet side of the common vent line is connected to the pool section, the vapor phase section is connected to an inert gas tank, and the pool section is replenished. It is characterized in that it is connected to a water tank and each line is provided with a valve.

[0015]

According to the present invention, at a site where a plurality of nuclear power plants are located, a common vent tank is used as the release location of the containment vessel vent from each plant, and the FP once held in the vent tank during severe conditions It is released to the gas phase part (dry well) of the containment vessel of another healthy side plant, passes through the suppression pool in the containment vessel of the healthy side plant, and then stored via the emergency gas treatment system of the healthy side plant. Venting the container can significantly reduce the amount of FP released into the environment.

That is, the high-pressure and high-temperature exhaust gas vented from the containment vessel of the plant on the severe side is released to the common vent tank at the time of severeness, and the exhaust gas condensing pool and the particle removal filter installed in the common vent tank cause water vapor, Iodine and particles are removed.

Next, by performing a second vent from the common vent tank to the dry well of the healthy plant,
The scrubbing effect in the suppression pool of the healthy plant and the noble gas damping effect can be expected.

Further, by carrying out the third containment vessel vent from this healthy side plant through the emergency gas treatment system of the healthy side plant, it is possible to greatly reduce the amount of FP released into the environment. Become. These multiple venting operations are possible as many as there are healthy plants in the site.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a protection device for a reactor containment vessel will be described with reference to FIGS. In the figure, the same parts as those in FIG. 6 are designated by the same reference numerals. FIG. 1 is a basic conceptual diagram for explaining the present embodiment. In FIG.
A, B, C, D, and E indicate different nuclear power plants, respectively, and reference numeral 13 is a common vent tank connected to the containment vessel 1 of each nuclear power plant.

The shared vent tank 13 is connected to the containment vessels 1 of the respective nuclear power plants A, B, C, D and E by a shared vent line 14 and a containment vessel vent line 15.

Next, the relationship between the common vent tank 13 and each of the storage containers 1 will be described with reference to FIG. In FIG. 2, for convenience of explanation, only two nuclear power plants A and B will be described, but the number is not particularly limited.

That is, in the common vent tank 13, a gas phase part 16, a particle removal filter 17 and an exhaust gas condensing pool 18 are provided. An inert gas supply line 19 is provided in the vapor phase section 16.
This inert gas supply line 19 is connected to an inert gas, for example, a nitrogen gas tank 21 via a valve 20.

The outlet side of the shared vent line 14 is the containment vessel 1.
Is connected to the inside of the exhaust gas condensing pool 18, and the inlet side thereof has a common side gas derivation line 24 having valves 22 and 23 derived from the gas phase part 3 of the containment vessel 1 and the suppression chamber 4. Connected to. The common vent line 14 has a valve 25.

The inlet side of the containment vessel vent line 15 is a valve
It is connected to the gas phase section 16 of the common vent tank 13 via 26, and its outlet side is connected to the emergency gas treatment system 10 via a valve 27.

The containment vessel vent line 15 and the common-side gas outlet line 24 are connected by a bypass line 29 via a valve 28. Make-up water line 30 in exhaust gas condensing pool 18
Is connected via a valve 31, and a make-up water line 30 has a diesel drive pump 32, a valve 33 and a make-up tank 34.
Are connected.

Next, the operation of this embodiment will be described on the assumption that a severe event occurs in one plant within the site.
In FIG. 2, the nuclear power plant A is a severe side plant, and the nuclear power plant B is a healthy side plant.
In addition, all the valves of the healthy plant are in the closed state.

Under severe conditions, a part of the reactor pressure vessel 2 of the nuclear power plant A is damaged, and water vapor is contained in the containment vessel 1.
A large amount of FP, H _2, etc. was released, and the pressure in the containment vessel 1,
The temperature keeps rising.

If the containment vessel is vented through the common vent line 14 before the containment vessel 1 is damaged, the pressure inside the containment vessel 1 is reduced. The exhausted fluid such as water vapor is first condensed in the exhaust gas condensing pool 18 in the common vent tank 13, and iodine and particles are subjected to scrubbing.

Thereafter, the exhaust fluid further passes through the particle removal filter 17 and is accumulated in the gas phase portion 16 of the common vent tank 13. After that, the gas is further passed from the gas phase portion 16 through the containment vessel vent line 15 to be processed by the emergency gas processing system 10 and discharged from the stack 12. Therefore, the FP release amount is significantly reduced.

In order to replenish the common vent tank 13 with the water in the exhaust gas condensing pool 18, the replenishment tank 34 and the diesel drive pump 32 are driven, and the common vent tank 13 is prevented from reaching the flammability limit. It is necessary to fill the nitrogen gas from the nitrogen gas tank 21.

FIG. 3 shows a schematic system diagram in the case where the exhaust fluid discharged to the common vent tank 13 at the time of severeness is discharged to the gas phase portion 3 of the containment vessel 1 of the healthy side plant B in the same site.

In this case, after the exhaust fluid of the severe side plant A has been introduced into the common vent tank 13 to reduce the FP release amount, the containment vessel vent line 15 and the bypass line 29 at the healthy side plant B side. Scrubbing by Suppression Pool 5.

After that, the exhaust gas fluid passes through the emergency gas processing system 10 from the wet well of the suppression chamber 4 of the healthy side plant B, and then is released into the atmosphere via the stack 12.

Therefore, when operating in the mode shown in FIG. 3, a scrubbing effect, a filter effect, and an FP damping effect are expected multiple times, so that the FP released to the environment is further greatly reduced. .

Next, with reference to FIGS. 4 and 5, the effect of reducing the FP emission amount when the present invention is used for the rare gas and iodine that are typical FPs will be described. FIG. 4 shows the relationship between the amount of rare gas released and the holding time of the common vent tank. From FIG. 4, it is recognized that the amount of rare gas released gradually decreases with the passage of time.

FIG. 5 shows the relationship between the iodine release amount and the common vent tank holding time for the three types of filters a, b and c. As is clear from FIG. 5, it is recognized that the release amount of iodine decreases with the passage of holding time for all three types of filters a, b, and c.

[0037]

According to the present invention, the containment vessel is prevented from being damaged under severe conditions, and the amount of FP released to the outside of the containment vessel undergoes a plurality of scrubbing effects, filter effects, and FP attenuation effects. Will be reduced.

[Brief description of drawings]

FIG. 1 is a basic conceptual diagram of a protection device for a reactor containment vessel according to the present invention.

FIG. 2 is a system diagram showing an embodiment of a protection device for a reactor containment vessel according to the present invention.

FIG. 3 is a system diagram showing an example in which the operation mode is changed in FIG.

FIG. 4 is a characteristic diagram showing a relationship between a rare gas release amount and a common vent tank holding time when the device according to the present invention is used.

FIG. 5 is a characteristic diagram showing a relationship between an iodine release amount and a shared vent tank holding time in the same manner as in FIG.

FIG. 6 is a conceptual diagram showing a vent path of a conventional reactor containment vessel.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Reactor containment vessel, 2 ... Reactor pressure vessel, 3 ... Gas phase part, 4 ... Suppression chamber, 5 ... Suppression pool, 6, 7, 9 ... Valve, 8 ... Discharge side derivation line,
10 ... Emergency gas processing system, 11 ... Exhaust line, 12 ... Stack, 13 ... Common vent tank, 14 ... Common vent line, 15
... PCV vent line, 16 ... Gas phase part, 17 ... Particle removal filter, 18 ... Exhaust gas condensing pool, 19 ... Inert gas supply line, 20 ... Valve, 21 ... Nitrogen gas tank, 22, 23 ... Valve, 24 ... Common Side gas outlet line, 25, 26, 27, 28 ... Valve, 29 ... Bypass line, 30 ... Make-up water line, 31 ... Valve, 32 ... Diesel drive pump, 33 ... Valve, 34 ... Replenishment tank.

Claims (1)

[Claims] 1. A single common vent tank is connected to a plurality of containment vessels by a containment vessel vent line and a common vent line, respectively, and a gas phase section, a particle removal filter section and an exhaust gas condensing pool are provided in the common vent tank. And a gas discharge line on the shared vent line side and a gas discharge line on the storage container vent line side are connected to the containment vessel, and the discharge line side discharge line is connected to an emergency gas treatment system, The inlet side of the containment vessel vent line is connected to the gas phase part, the outlet side of the discharge line is connected to the emergency gas treatment system, and the inlet side of the shared vent line is connected to the shared side gas outlet line. The outlet side of the common vent line is connected to the pool section, the gas phase section is connected to an inert gas tank, and the pool section is connected to a makeup water tank. A protective device for a reactor containment vessel, wherein each of the lines is provided with a valve.