JPH04130099U - Fast breeder reactor sloshing prevention device - Google Patents

Abstract

(57) [Summary] (with amendments) [Purpose] Suppress sloshing and reduce liquid level fluctuations to prevent gas entrainment. [Structure] A partition wall 27 is provided on the inner side of the top plate 23 forming the ceiling of the reactor vessel 21, and is suspended from the top plate 23 and immersed in the liquid metal coolant M to a predetermined depth. The upper part of the liquid phase part L of the liquid metal coolant M is divided into a plurality of sections, and the gas phase part V of the liquid metal coolant M is divided into independent gases partitioned by the partition wall 27 and the top plate 23. A plurality of shared rooms Vi are formed.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

This invention relates to a sloshing prevention device for fast breeder reactors, and is particularly applicable to Suppresses sloshing of liquid metal coolant that occurs when the child reactor vessel is shaken. This invention relates to a sloshing prevention device for fast breeder reactors that reduces liquid level fluctuations.

0002

[Conventional technology]

In recent years, research has been progressing on fast breeder reactors that produce energy through nuclear fission of ²³⁹ Pu while also using neutrons generated in the reactor core to convert ²³⁸ U into ²³⁹ Pu to breed fuel.

0003 As shown in FIG. 3, in the fast breeder reactor 1, a container 2 formed in the shape of a cylinder with a bottom. and a top plate 3 that covers this and forms a section of the ceiling. Inside the reactor vessel 4, there is a reactor internal structure 5 consisting of a reactor core 11 in which a nuclear reaction mainly takes place. It is stored. In addition, liquid metal is contained in the reactor vessel 4 as a liquid metal coolant M. An internal reactor structure consisting of a reactor core 11 that is filled with thorium and in which nuclear reactions mainly occur. A gas phase portion V is formed above the liquid surface S in which the object 5 is immersed.

0004 Also, it is inserted through the top plate 3 and its end is immersed in the liquid metal coolant M. A hot leg pipe 6 is provided which hangs down as much as possible. Hot leg piping 6 is atomic An intermediate section that is bent into a substantially U-shape outside the reactor vessel 4 and provided adjacent to the reactor vessel 4. Liquid metal cooling inserted into the heat exchanger 7 and whose end is filled in the intermediate heat exchanger 7 It is suspended to be immersed in the material. Inside this hot leg piping 6 is liquid metal cooling. The material Ma is filled, forming a siphon connecting the reactor vessel 4 and the intermediate heat exchanger 7. There is. On the other hand, a pump 8 is provided adjacent to the reactor vessel 4 . For pump 8 Piping 9 is connected, and this piping 9 is bent into a substantially U-shape and extended, and is connected to the reactor volume. It is inserted through the top plate 3 of the reactor 4 and its end is connected to the reactor core 11. Port The pump 8 and piping 9 are filled with liquid metal coolant Mb, and the power of the pump 8 The liquid metal coolant Mb is configured to be transferred through piping 9 and supplied to the reactor core 11. ing. Further, another pipe 10 is connected to the pump 8, and this pipe 10 is an intermediate heat exchanger. The pump 8 is connected to the exchanger 7 and is filled with liquid metal coolant M. A siphon is formed between the intermediate heat exchanger 7 and the intermediate heat exchanger 7.

[0005] In such a fast breeder reactor 1, the heat generated in the reactor core 11 where nuclear reactions occur is The liquid metal coolant M that has absorbed the It is transferred to the intermediate heat exchanger 7 by a siphon connected to the intermediate heat exchanger 7. intermediate heat exchange The liquid metal coolant M in the vessel 7 is further connected to a pump 8 formed in another pipe 10 and intermediate heat It is transferred to the pump 8 by a siphon connected to the exchanger 7. Also, liquid metal coolant M is transferred through the pipe 9 by the pump 8 to the reactor core 11, and the atoms are removed from the reactor core 11. It flows out into the furnace vessel 4. In this way, the liquid metal coolant M passes through the core 11. The heat is then circulated through the reactor vessel 4, intermediate heat exchanger 7, and pump 8.

[0006]

[Problem that the idea aims to solve]

By the way, when the reactor vessel 4 is vibrated in the horizontal direction due to an earthquake, etc., the reactor vessel 4 is The liquid metal coolant M in the vessel 4 may resonate and sloshing may occur. slot When shing occurs, the liquid level S will undulate greatly like the liquid level fluctuation Sa, The lower end of the hot leg piping 6 may be exposed to the gas phase section V. For this reason, the relief A gas is connected to the siphon formed in the Treg piping 6 that connects the reactor vessel 4 and the intermediate heat exchanger 7. This is dangerous as the gas may become entangled and cause a siphon break.

[0007] In addition, the gas is circulated while being entangled in the liquid metal coolant M and passes through the core 11. It will also be done. It is very dangerous if a large amount of gas passes through the core 11 due to gas entrainment. It's dangerous. Therefore, sloshing occurs due to earthquakes, etc., and large liquid level fluctuations Sa occur. In order to avoid siphon break due to gas entrainment and gas passing through the core when The reactor was shut down.

[0008] Therefore, the purpose of this invention is to solve the above problems, suppress sloshing, and To provide a sloshing prevention device that reduces surface fluctuation and prevents gas entrainment. It is in.

[0009]

[Means to solve the problem]

In order to achieve the above objective, the present invention has developed a top panel that forms the ceiling of the reactor vessel. The inner part of the plate is suspended from this and is immersed in the liquid metal coolant to a predetermined depth. This partition wall divides the upper part of the liquid phase of the liquid metal coolant into multiple sections. At the same time, the gas phase of the liquid metal coolant is separated by this partition wall and the top plate. A plurality of independent gas phase chambers are formed.

0010

[Effect]

With the above configuration, multiple Each liquid metal coolant within a compartment will have its own natural frequency; The frequency appears as a function of the size of the compartment, so adjusting the size of the compartment is This is compared to the natural frequency of the entire liquid metal coolant filled in the reactor vessel. It can be changed to a higher side compared to the current value. Therefore, sloshing occurs throughout the liquid metal coolant. The liquid metal coolant in each compartment does not slosh even when subjected to vibrations that cause Does not occur. Also, the liquid metal coolant in each section has its own natural frequency. Therefore, when vibration close to this natural frequency is applied, the slots will be generated independently in each section. Although sloshing may occur, this independent sloshing occurs throughout the liquid metal coolant. Both the wavelength and wave height are smaller than the sloshing that occurs in This can be minimized by appropriately determining the depth of wall immersion. In other words, liquid gold caused by earthquakes, etc. Sloshing of metal coolant can be suppressed.

[0011] In addition, multiple compartments at the top of the liquid phase that are adjacent to each other across the partition wall are located below the bottom end of the partition wall. They communicate with each other. Of these lots, two adjacent lots and these The lower portion of the tube communicates with the lower portion of the tube approximately forming a U-shaped tube. The reactor vessel When vibration is caused by an earthquake, etc., two adjacent sections lined up in the direction of vibration and the area below them are Movement of liquid inside the U-shaped tube that occurs when the U-shaped tube is vibrated at the communicating part The liquid moves between these two sections, causing the liquid level to alternately fluctuate up and down. trying to wake up However, there are partition walls and top plates above the liquid level in these two compartments. Since independent gas phase chambers are formed which are divided by The internal pressure of the chamber rises and falls in proportion to the vertical movement of the liquid level, and This will result in a reaction force. Therefore, the gas phase gas in the gas phase chamber acts like an air spring. This serves to regulate the vertical movement of the liquid level due to the movement of the liquid. Lined up like this The effect of regulating the vertical movement of the liquid level in two adjacent compartments is superimposed, and all the compartments are The vertical movement of the liquid level in the image will be regulated. In other words, liquid metal caused by earthquakes, etc. Fluctuations in the liquid level of the coolant can be reduced.

0012

【Example】

Hereinafter, one embodiment of the present invention will be described in detail based on the accompanying drawings.

[0013] As shown in FIG. 1, the reactor vessel 21 of the fast breeder reactor is formed into a cylindrical shape with a bottom. Sealed by the container 22 and the top plate 23 that covers it and forms a ceiling section. It is organized into a structure. Inside the reactor vessel 21 is a reactor core 24 where nuclear reactions mainly occur. A reactor internal structure 25 consisting of the following is housed. In addition, liquid gold is contained within the reactor vessel 21. Liquid metal sodium is filled as a metal coolant M to form a liquid phase portion L. The reactor internals 5 consisting of the reactor core 24, where nuclear reactions mainly occur, are immersed in this. A gas phase portion V is formed above the liquid surface S in both cases.

[0014] Also, it is inserted through the top plate 23 and its end is immersed in the liquid metal coolant M. A hot leg pipe 26 is provided which hangs down as much as possible. hot leg piping 26 is bent into a substantially U-shape outside the reactor vessel 24, and although not shown, the reactor vessel 2 It is inserted into the intermediate heat exchanger installed adjacent to 4, and its end is inserted into the intermediate heat exchanger. It is suspended to be immersed in a filled liquid metal coolant. This hot leg distribution The pipe 26 is filled with liquid metal coolant Ma, which connects the reactor vessel 24 and the intermediate heat exchanger. It forms a siphon that connects the

[0015] The inside of the top plate 23 that forms the ceiling of the reactor vessel 21 has this structure. A partition wall 27 is provided which is suspended from the wall and immersed in the liquid metal coolant M to a predetermined depth. There is. As shown in FIG. 2, the partition wall 27 is formed in the shape of a bottomed cylinder of the reactor vessel 21. It is shaped so as to be in contact with the inner circumferential wall of the container 22 and extend in the radial direction so as to be in contact with the side surface of the reactor internal structure 5. has been completed. Similarly, a partition wall 27 is provided axially symmetrically on the opposite side of the reactor internal structure 5, Further, it is perpendicular to these partition walls 27, 27 and is suspended from the top plate 23. It extends in the radial direction in contact with the inner circumferential wall of the container 22 and in contact with the side surface of the reactor internal structure 5. A pair of partition walls 27, 27 are provided. That is, these partition walls 27 are Air vents are provided radially around the reactor core 11 and formed in the upper part of the reactor vessel 21. The phase portion V is divided into a substantially cross shape to form a plurality of independent gas phase chambers Vi. Furthermore, since these partition walls 27 are immersed in the liquid metal coolant M to a predetermined depth, The upper part of the liquid phase part L of the liquid metal coolant M is divided into a plurality of sections Li by the wall 27. become.

[0016] Next, the operation of the embodiment will be described.

[0017] In the reactor vessel 21 of the fast breeder reactor provided with the partition wall 27 as described above, the partition wall 27 is In the plurality of sections Li above the liquid phase portion L of the liquid metal coolant M divided by the wall 21 Each liquid metal coolant M will have a natural frequency. This natural frequency appears as a function of the dimensions of the compartment Li, so the reactor vessel 21 is filled with This is higher than the natural frequency of the liquid metal coolant M as a whole. Therefore , even if vibrations that cause sloshing are applied to the entire liquid metal coolant M. No sloshing occurs in the liquid metal coolant within each section Li. In addition, each section L Since each liquid metal coolant in i has a natural frequency, this natural frequency As shown in Fig. 3, when a vibration close to Although sloshing may occur, this independent sloshing is Both the wavelength and wave height are smaller than the sloshing that occurs in the body, and The immersion depth of the partition wall 27 can be minimized by appropriately determining the immersion depth. In other words, due to earthquakes, etc. Sloshing of the liquid metal coolant M can be suppressed.

[0018] In addition, the plurality of sections Li above the liquid phase portion L that are adjacent to each other with the partition wall 27 in between are separated by the partition wall 27. They communicate with each other below their lower ends. Among these plots Li, adjacent The two sections Li that fit together and the part that communicates below them approximately constitute a U-shaped pipe. It becomes. When the reactor vessel 21 is vibrated due to an earthquake, etc., the reactor vessel 21 is In the two sections Li that fit together and the part that communicates below them, it is as if a U-shaped pipe was added. These two compartments L As the liquid moves between the points i, the liquid level Si alternately changes up and down as shown in Figure 3. do. However, the partition wall 27 and the top plate are located above the liquid surface Si in these two compartments Li. Since independent gas phase chambers Vi partitioned by 23 and 23 are formed, this The internal pressure of these gas phase chambers Vi rises and falls in proportion to the vertical movement of the liquid level S, and the liquid level increases due to the movement of the liquid. A reaction force will be generated against the vertical movement of S. Therefore, the air in these gas phase chambers Vi The phase gas acts like an air spring and regulates the vertical movement of the liquid level Si due to the movement of the liquid. It will be controlled. The upper and lower liquid levels S in these two adjacent compartments Li The effect of regulating the movement is superimposed, and the vertical movement of the liquid level Si is regulated in all sections Li. It will be controlled. In other words, the liquid level fluctuation of the liquid metal coolant M due to earthquakes etc. can be reduced. can do.

[0019] As described above, according to the configuration of the present invention, the wavelength and wave height of sloshing can be reduced. It has the effect of reducing the amount of liquid that is caused by the movement of the liquid, and the effect of reducing the liquid level fluctuation caused by the movement of the liquid. These effects work synergistically to suppress liquid level fluctuations. Therefore, hot leg piping The lower end of 26 is prevented from being exposed to the gas phase part V, and the gas winding of the liquid metal coolant M is prevented. Crowding can be avoided. In this way, gas entrainment of the liquid metal coolant M is avoided. Therefore, even if the reactor vessel 24 is shaken due to an earthquake, etc., there will be no siphon break or gas leakage. Core passage does not occur.

[0020] In addition, in the embodiment of the present invention, four partition walls 27 are provided to form four partitions. However, it is of course possible to have two or more divisions.

[0021]

[Effect of the idea]

The present invention exhibits the following excellent effects.

[0022] (1) The safety of fast breeder reactors will be improved as much as possible.

[0023] (2) Nuclear reactor shutdown due to earthquakes, etc. can be avoided.

[Brief explanation of drawings]

FIG. 1 is a schematic side sectional view showing an embodiment of the present invention.

FIG. 2 is a sectional view taken along line AA in FIG. 1;

FIG. 3 is a schematic cross-sectional view showing liquid level fluctuations in an embodiment of the present invention.

FIG. 4 is a schematic partially fragmented sectional view showing a conventional example.

[Explanation of symbols]

21 Reactor vessel 23 Top plate 27 Bulkhead L Liquid phase part Li section M Liquid metal coolant V Gas phase part Vi vapor chamber

Claims (1)

[Scope of utility model registration request] Claim 1: In a reactor vessel of a fast breeder reactor containing a liquid metal coolant inside, the liquid metal coolant is suspended from the inner side of a top plate forming the ceiling of the reactor vessel. A partition wall immersed in the coolant to a predetermined depth is provided, and the partition wall divides the upper part of the liquid phase portion of the liquid metal coolant into a plurality of sections, and the partition wall and the top plate are provided in the gas phase portion of the liquid metal coolant. A sloshing prevention device for a fast breeder reactor, characterized in that a plurality of independent gas phase chambers are formed, each of which is partitioned by - and -.