JPH0247586A - Suppression pool water cooling system - Google Patents

Abstract

PURPOSE:To heighten the cooling efficiency of pool water and simplify a suppression pool water cooling system by providing a pool water cooling coil for flowing cooling water such as sea water and fresh water in a suppression pool. CONSTITUTION:A suppression pool 23 for storing a large quantity of pool water is formed on the bottom part of a reactor containment vessel 21 in a reactor building 20. A cooling system 30 for directly cooling pool water is provided in the suppression pool 23. The cooling system 30 consists of a cooling coil 31 housed in the suppression pool 23, inlet tubing 32 and outlet tubing 33 for guiding cooling water in the cooling coil 31 and a cooling water pump 35 for gathering cooling water from a cooling water source 34 such as sea water or fresh water. Since the suppression pool water cooling system directly cools the pool water, cooling efficiency is high and system formation can be simplified because an intermediate cooling system and the like are not needed.

Description

DETAILED DESCRIPTION OF THE INVENTION (Object of the Invention) (Industrial Application Field) The present invention relates to a suppression pool water cooling system for cooling pool water stored in a suppression pool at the bottom of a nuclear reactor containment vessel.

(Prior art) In general, a boiling water reactor, which is a light water reactor, has a reactor containment vessel 2 provided in a reactor building 1, as shown in FIG. A reactor pressure vessel 3 formed inside is accommodated. The above reactor containment capacity! ! A suppression pool 4 is provided at the bottom of 2, and a large amount of pool water is stored in this suppression pool 4.

Suppression pool water is used to cool the reactor water when shutting down the reactor, to cool the reactor core via the emergency core cold system 5 in the event of an abnormality such as a loss of cooling I accident, and to cool the reactor core in the event of an accident. The system condenses the vapor released into the reactor and safely cools the reactor and reactor containment vessel.

On the other hand, the emergency core cooling system (ECC8) 5 is partially equipped with a residual heat removal system (hereinafter referred to as Rl-IR) 6. The RHR 6 has an RHR heat exchanger 7 arranged in the nuclear detached house N1, and this RHR heat exchanger 7 is connected to the suppression pool 4 via an RHR pipe 8 and an RHR pump 9. The RHR heat exchanger 7 is installed to be able to exchange heat with fresh water circulating within the intercooling system 10 of the leap loop.

The pool water cooled by this fresh water is returned to the suppression pool 4 through piping to cool the suppression pool water.

The intermediate cooling system 10 includes an RHR heat exchanger 7 and an intermediate heat exchanger 311.
and intercooling pump 12 are connected by circulation piping 13 to form a closed loop. The intermediate heat exchanger 11 and the intermediate cooling pump 12 are installed in a heat exchanger building 1 constructed outside the reactor building.
It is accommodated in 4.

Cooling of the intermediate heat exchanger 11 of the intermediate cooling system 10 is performed by seawater sent by a seawater pump 15. The seawater pump 15 is installed in a seawater pump room 16 constructed on the coast.

A conventional subledge compound pool water cooling system is configured as shown in FIG. ing.

(Problems to be Solved by the Invention) In the conventional subledge pool water cooling system, a system is adopted in which fresh water is cooled by seawater, and the suppression pool water is cooled by an intermediate cooling system 10 that uses this fresh water. Therefore, the cooling system for tatami nabreshion boulevard water is complicated, and a large number of various devices such as heat exchangers, piping, and electrical control system equipment are installed in the cooling system. For this reason, not only is the operation control of the cold N1 system complicated and troublesome, but the cooling efficiency of the suppression pool water is poor, and a large installation space is required to install the cooling system components, making it difficult to store the components in the building. It had to be constructed separately from the reactor building, which increased costs.

Furthermore, even if the storage building at Tachibana Sekitake is completed, it will take a long time to install the various equipment and piping, which will lengthen the first construction phase of the entire nuclear power generation system, leading to problems such as increased construction costs. there were.

The present invention has been made in consideration of the above-mentioned circumstances, and thus improves the cooling efficiency of suppression pool water, and
The present invention provides a suppression pool water cooling system that can simplify operation control of the cooling system, shorten the construction period, and reduce construction costs.

(Structure of the Invention) (Means for Solving the Problems) A suppression pool water cooling system according to the present invention includes:
In order to solve the above-mentioned problems, a suppression pool water cooling system is provided in which a suppression pool is provided at the lower part of the reactor containment vessel and the pool water stored in this suppression pool is cooled. It houses a pool water cooling coil, and a cooling pipe for guiding cooling water such as seawater or fresh water is connected to this cooling coil.

(Function) This suppression pool water cooling system houses a cold section coil in the suppression pool, and allows cooling water such as seawater or fresh water guided through the cooling pipe to flow through the cooling coil. The flowing cooling water can directly cool the pool water in the suppression pool, improving cooling efficiency, and greatly simplifying the system configuration of the suppression pool water cooling system, making it easier to operate the cooling system. Control procedures are simplified.

In addition, this cooling system eliminates the need for intermediate heat exchangers, intercooling pumps, piping, etc., and also eliminates the need for buildings to house them.
This can significantly reduce construction costs.

(Embodiment) Hereinafter, an embodiment of the suppression pool water cooling system according to the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows an example in which the suppression pool water cooling system according to the present invention is applied to a boiling water reactor as a light water reactor. This nuclear reactor is provided with a reactor containment vessel 21 in a detached nuclear house pA20, and a reactor pressure vessel 22 is accommodated within this containment vessel 21. In addition, a suppression pool 23 is formed at the bottom of the reactor containment vessel 21,
A large amount of pool water is stored in this suppression pool 23.

The pool water in the suppression pool 23 is used to cool the reactor water when shutting down the reactor, to cool the reactor core via the emergency core cooling system 24 in the event of an abnormality such as a loss of coolant accident, and to cool the reactor core through the emergency core cooling system 24. The vapor released into the reactor 21 is condensed to safely cool the reactor and reactor containment vessel.

The emergency core cooling system 24 includes a residual heat removal system (hereinafter referred to as RHR).
That's what it means. ) 25 is provided, and this R) (R25 extends from the subledge combination 23.
An RHR heat exchanger 27 is provided in the piping 26 . R.H.
R25 removes the decay heat generated from the fuel and the heat generated by the heat chamber of the reactor-subsystem, even if the reactor is shut down and the reactor output decreases, keeping the reactor and system FM device at room temperature. It is designed to cool down to

On the other hand, the suppression pool 23 is provided with a suppression pool water cooling system 30. This cooling system 30 directly cools the suppression pool water, and includes a cooling coil 31 as a heat exchange coil housed within the suppression pool 23. An inlet pipe 32 and an outlet pipe 33 are connected to both ends of the cooling coil 31 as cooling pipes for guiding cooling water.

The inlet pipe 32 and the outlet pipe 33 are connected to the reactor containment vessel 21
The water exits from the reactor building 20 and is connected to a cooling water source 34 such as seawater or fresh water. Among these, the input pipe 32 is connected to a cooling water pump 35 such as a seawater bomber freshwater pump,
This pump 34 is installed in a pump room 36 constructed on the shore, river, or lake. The outlet pipe 33 opens near the pump chamber 36.

By configuring the suppression pool water cooling system 30 as shown in FIG.
Intermediate heat exchangers can be eliminated. In addition, the RHR heat exchanger 27 of the conventionally installed residual heat removal system (RHR) 25 is connected from the suppression pool 23 to the RHR piping 2.
It has a structure that can be cooled by the cooling water injection pump 38 provided in the RHR heat exchanger 27, and the reactor water cooling pipe 39
is connected.

Next, the operation of the suppression pool water cooling system will be explained.

By the operation of the cooling water pump 35 from this Navretion Boule water cooling system 301, cooling water such as seawater or fresh water is guided to the cooling coil 31 through the cooling pipe (inlet pipe) 32, and the cooling coil 31 converts the Navretion Bour water into water. The pool water is directly cooled by heat exchange.

The cooling water that cooled the suppression pool water is at the outlet pipe 3.
3 into a cooling water source 34, for example near the pump chamber 36. In this case, the cold N1 coil 31 provided in the suppression pool 23 is preferably made of a corrosion-resistant material that is resistant to seawater corrosion, such as a titanium alloy. The cold section coil 31 may be coiled or tubular, and a plurality of cold section coils 31 may be installed in the suppression pool 23. By appropriately arranging the cooling coils 31, the suppression pool water can be uniformly cooled over the entire torus.

〔Effect of the invention〕

As described above, the suppression pool water cooling system according to the present invention accommodates the pool water cooling IAI coil in the suppression pool and connects this cooling coil to the cooling piping that guides cooling water such as seawater. The cold water can be guided into the cooling coil through the cooling pipe to directly cool the pool water, and the cooling efficiency of the pool water can be improved, while this 1-Nabrection water cooling system Since an intercooling system or the like is not required, the system configuration can be greatly simplified, and its operation can be easily controlled.

In addition, this suppression pool water cooling system eliminates the need for an intercooling system and also eliminates the need for a building to house the intermediate heat exchanger and pump, making it possible to construct a nuclear power plant even if the installation space is small. and 1
1 Construction period can be shortened and construction costs can be significantly reduced.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing an embodiment of a suppression pool water cooling system according to the present invention, and FIG. 2 is a schematic diagram showing a conventional suppression pool water cooling system. 20... Reactor building, 21... Reactor containment vessel, 2
2... Reactor pressure vessel, 23... Suppression pool, 24... Emergency core cooling system, 25... Residual heat removal system, 30... Suppression pool water cooling system, 31... Cooling Coil, 32.33...Cooling pipe, 34...Cold part water source, 35...Cold W water pump.

Claims (1)

[Claims] A suppression pool is installed at the bottom of the reactor containment vessel.
In a suppression pool water cooling system that cools pool water stored in the suppression pool, a pool water cooling coil is housed in the suppression pool, and cooling water such as seawater or fresh water is guided to the cooling coil. A suppression pool water cooling system characterized by connecting cooling piping.