JPH03170899A - Cooling apparatus for wall of reactor vessel - Google Patents

Abstract

PURPOSE:To obtain high cooling effect and to make a heat insulating material thin by providing a heat radiation accelerating mechanism for accelerating the heat radiation from a safety vessel to the inner surface of a heat insulating material cover. CONSTITUTION:Since a large number of fins 19 are integrally provided to the inner surface of a heat insulating material cover 18, the heat insulating material cover 18 is rapidly and well cooled by the air streams due to air conditioning ducts 16, 17 and the temp. thereof falls. Since the heat radiation from a safe vessel 10 to the heat insulating material cover 18 increases in direct proportion to the fourth power of the temp. difference between the safety vessel 10 and the heat insulating material cover 18, the heat transfer due to radiation increases to a large extent when the temp. of the heat insulating material cover 18 falls and the removal of heat from the safety vessel 10 is accelerated. Therefore, high cooling effect is obtained in the same air flow rate. Further, since the temp. of the heat insulating material cover 18 is lowered, a heat insulating material can be made thin without being accompanied by the temp. rise of the cavity wall 11 of a nuclear reactor.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a reactor vessel wall cooling device for a fast breeder reactor.

(Prior Art) FIG. 4 shows a conventional nuclear reactor vessel wall cooling system of this kind, in which a reactor core 1 and a primary coolant are housed in a reactor vessel 9 of a fast breeder reactor. The upper surface of the reactor vessel 9 is sealed by a roof slab 7 to which the upper core mechanism 6 is attached. The reactor vessel 9 further includes an intermediate heat exchanger 3.
, a circulation pump 5 is equipped. Inside the reactor vessel 9,
From top to bottom, it is divided into a hot plenum 2, an intermediate plenum 12, and a cold plenum 4. A space between the liquid level of the primary coolant in the hot blemish 2 and the lower surface of the roof slab 7 is filled with cover gas. The primary coolant first enters the cold plenum 4, is then sucked in by the circulation pump 5, is fed into the core 1 and heated, enters the hot plenum 2, and is further led into the intermediate heat exchanger 3. After exchanging heat with the secondary coolant circulating in the intermediate heat exchanger 3, it is returned to the cold blenum 4. The intermediate blemish 12 isolates the hot blemish 2 and the under-coal blemish 4 and insulates them, and also thermally protects the reactor vessel 9 and its internal structures.

As shown in FIG. 4, the wall of the reactor vessel 9 is filled with an inert gas so that temperature changes in the sodium contained in the hot plenum 2 are not directly applied to the reactor vessel 9. A gas dam 8 is installed.

As shown in FIG. 4, a safety vessel 10 is installed outside the reactor vessel 9 as a boundary in the event of a primary coolant leakage accident due to damage to the reactor vessel 9. The space between them is filled with inert gas.

As shown in FIG. 4, the reactor cavity wall 11 is a concrete structure that supports the reactor vessel 9, the roof slab 7, and the safety vessel 10, and on its inner surface, in order to form a containment vessel boundary, A steel liner 13 is attached, and a heat insulating material 14 is attached to the inner surface of the liner 13 to prevent the liner 13 and the reactor cavity wall 11 from becoming excessively heated due to the heat of the reactor.

In addition, air conditioning ducts 16 and 17 are installed in the annulus space 15 between the safety vessel 10 and the reactor cavity wall 11, as shown in FIG. Further, the reactor vessel 9 is indirectly cooled to reduce the thermal load applied to the reactor vessel 9.

[Problems to be Solved by the Invention] In the conventional reactor vessel wall cooling system, the safety vessel 10 is cooled by air flow from the air conditioning ducts 16 and 17, but the structural integrity of the safety vessel 10 is From the viewpoint of security, it is not possible to attach structures such as fins to increase the surface area of the safety container 10, so if it is necessary to increase the cooling capacity, the air flow rate must be increased, which is not economical. There is a problem.

The present invention has been made with these points in mind, and it is possible to efficiently cool the safety vessel without increasing the flow rate of the gas flow flowing through the annulus space between the safety vessel and the reactor cavity wall. It is an object of the present invention to provide a reactor vessel wall cooling device that can reduce the thickness of the heat insulating material provided on the inner surface of the reactor cavity wall.

[Structure of the invention]

(Means for Solving the Problems) As a means for achieving the above object, the present invention provides a safety vessel outside the reactor vessel and forms an annulus space between the safety vessel and the reactor cavity wall. In the reactor vessel wall cooling system, the safety vessel is cooled by the gas flow in this annulus space, and the reactor vessel wall is cooled by heat transfer between the reactor vessel and the safety vessel. A heat insulating material is provided on the inner surface, a heat insulating material cover is provided on the inner surface of the heat insulating material, and a heat radiation promotion mechanism is provided on the inner surface of the heat insulating material cover to promote heat radiation from the safety container. It is characterized by

(Function) In the reactor vessel wall cooling device according to the present invention, a heat insulating material is provided on the inner surface of the reactor cavity wall, and
A heat insulating material cover is provided on the inner surface of this heat insulating material, and a heat radiation promoting mechanism for promoting heat radiation from the safety container is provided on the inner surface side of this heat insulating material cover, such as a fin integrated with the heat insulating material cover or a heat insulating material. A heat collector or the like is provided with a required gas flow space between the heat collector and the material cover. This heat radiation promotion mechanism increases heat transfer by radiation from the safety container to the heat insulating material cover, and promotes heat removal from the safety container. Therefore, it is possible to obtain high cooling performance with the same gas flow rate.

(Example) Hereinafter, a first example of the present invention will be described with reference to FIG.

FIG. 1 shows an example of a reactor vessel wall cooling system according to the present invention. In the figure, reference numeral 1 indicates a reactor core, which is housed in a reactor vessel 9 together with a primary coolant. The upper surface of this reactor vessel 9 is sealed by a roof slab 7 on which a core upper mechanism is mounted.

The reactor vessel 9 is also equipped with an intermediate heat exchanger 3 and a circulation pump 5, as shown in FIG. 12 and cold plenum 4. A cover gas is filled between the liquid level of the primary coolant in the hot blemish 2 and the lower surface of the roof slab 7.

As shown in FIG. 1, the wall of the reactor vessel 9 contains an internal inert gas so that the temperature change of the sodium in the hot brenum 2 contained therein will not be directly applied to the reactor vessel 9. A gas dam 8 is installed on the outside of the reactor vessel 9, as shown in FIG.
A safety container 10 is provided as a boundary in the event of a primary coolant leak accident due to damage to the nuclear reactor vessel 9, and an inert gas is filled between the safety container and the reactor vessel 9.

As shown in FIG. 1, the outer circumference of the safety vessel 10 is provided with a reactor cavity wall 11, which is a concrete structure that supports the reactor vessel 9, the roof slab 7, and the safety vessel 10. A steel liner 13 is attached to form the containment vessel boundary.

A heat insulating material 14 is installed on the inner surface of the liner 13 to prevent the liner 13 and the reactor cavity wall 11 from becoming excessively heated due to the heat of the reactor.
Aninilas space 1 between 0 and the reactor cavity wall 11
5, air conditioning ducts 16 and 17 are installed respectively,
The safety vessel 10 is directly cooled and the reactor vessel 9 is indirectly cooled by air. As a result, the thermal load applied to the reactor vessel 9 can be reduced.

On the other hand, as shown in FIG. 1, a metal heat insulating cover 18 is installed on the inner surface of the heat insulating material 14, and a large number of fins 19 are integrally provided on the inner surface.

Next, the operation of this embodiment will be explained.

Since a large number of fins 19 are integrally provided on the inner surface of the insulation cover 18, the insulation cover 18 is quickly and well cooled by the air flow from the air conditioning duct 16, 17, and its temperature is lowered. .

By the way, the heat radiation from the safety container 10 to the heat insulator cover 18 is 4 times the temperature difference between the safety container 10 and the heat insulator cover 18.
Since the size increases in direct proportion to the power of the insulation material cover 18
If the temperature of the safety container 10 decreases, heat transfer by radiation increases significantly, and heat removal from the safety container 10 is promoted. Therefore, a high cooling effect can be obtained with the same air flow rate. Furthermore, since the temperature of the heat insulating cover 18 can be lowered, the heat insulating material 14 can be made thinner without increasing the temperature of the reactor cavity wall 11.

FIG. 2 shows a second embodiment of the present invention. Front: c!
Instead of the fins 19 in the first embodiment, a heat collector 21 is provided on the inner surface of the heat insulating material 14 to maintain a gas flow space 20 of a required width between the heat insulating material 14 and the heat radiation promoting mechanism. .

In other words, as shown in FIG.
1 is installed, and the air flow from the air conditioning duct 16 is
The gas first flows through the gas flow space 20, passes through the heat collector 21, and is then led to the air conditioning duct 17.

As shown in FIGS. 3(a) to 3(c), the heat collector 21 is made of a regular polygonal tube material such as an equilateral triangular tube material 21a, a regular square tube material 21b, a regular hexagonal tube material 21c, or a cylinder. The heat from the safety container 10 is efficiently transferred by radiation, and when the air from the air conditioning duct 16 passes through the heat collector 20, it is efficiently transferred by convection. It is designed to remove heat well.

Next, the operation of this embodiment will be explained.

Heat from the safety container 10 is transferred to the heat collector 2 by radiation.
1, and heat is removed from the safety container 10.

Here, if the absorptivity is a1, the reflectance is ρ, and the transmittance is τ, then the following equation holds true for the total incident energy.

a+p+te-1 ・・・・・・・・・・・・
(1) When radiant heat is transferred from the safety container 10 to the heat collector 21, the reflectance ρ is a ratio of the area of the heat collector 21 as shown by the following equation.

Sl 182 However, Sl: Cross-sectional area of the heat collector S2: Cross-sectional area of the space inside the heat collector Therefore, the inverse 11 ratio ρ of the heat collector 21 is determined by reducing the thickness of the heat collector 21 and increasing its cross-sectional area St. If it is made small, it becomes possible to have a small value.

On the other hand, the heat that has reached the heat collector 21 flows through the heat collector 21 while being reflected multiple times.
It is absorbed by Yu, and some of it passes through.

At this time, by increasing the length of the heat collector 21 or increasing the emissivity of the heat collector 21, the absorption rate a of the heat collector 21 can be increased and the transmittance τ can be decreased. As a result, the facing insulation material 14
It is possible to suppress the temperature rise of the structure, simplify the structure, and reduce the thickness of the structure.

On the other hand, as shown in FIG. 2, the air discharged from the air conditioning duct 16 rises in the gas flow space 20, passes through the inside of the heat collector 20, is guided to the outer circumferential surface of the safety container 10, and is guided to the outer circumferential surface of the safety container 10. It rises along the outer peripheral surface and is guided to the air conditioning duct 17.

By the way, when the air from the air conditioning duct 16 passes through the high-temperature heat collector 21, its temperature increases due to convection heat transfer. becomes a heat transfer surface due to convection, a large heat transfer area is obtained, and the amount of heat removed can be increased. As a result of this heat removal, heat transfer from the safety container 10 due to radiation increases as described above, and sufficient heat removal from the safety container 10 can be obtained.

〔Effect of the invention〕

As explained above, in the present invention, the heat radiation promoting mechanism for promoting heat radiation from the safety container is provided on the inner side of the heat insulating material cover, so that the gas flow rate flowing through the annulus space can be increased. High cooling effect can be obtained. In addition, the temperature rise of the insulation cover can be suppressed, so
The insulation material can be made thinner without increasing the temperature of the reactor cavity wall.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view showing a reactor vessel wall cooling device according to a first embodiment of the present invention, FIG. 2 is a main part configuration diagram showing a second embodiment of the present invention, and FIGS. (C) is a perspective view showing the structure of a heat collector, and FIG. 4 is a longitudinal sectional view showing a conventional reactor vessel wall cooling device. DESCRIPTION OF SYMBOLS 1... Reactor core, 9... Reactor vessel, 10... Safety vessel, 11... Reactor cavity wall, 13... Liner, 14... Heat insulating material, 15... Annulus space, 16
．． 17... Air conditioning duct, 20... Gas flow space, 21
...Heat collector. younger brother t

Claims (1)

[Claims] A safety vessel is provided outside the reactor vessel, and an annulus space is formed between the safety vessel and the reactor cavity wall, and the gas flow in this annulus space cools the safety vessel and connects the reactor vessel with the safety vessel. In a reactor vessel wall cooling device that cools a reactor vessel wall by heat transfer with the vessel, a heat insulating material is provided on the inner surface of the reactor cavity wall, and a heat insulating material cover is provided on the inner surface of the heat insulating material. A nuclear reactor vessel wall cooling device characterized in that a heat radiation promotion mechanism for promoting heat radiation from the safety vessel is provided on the inner surface of the heat insulating material cover.