JPS61186895A - Fuel storage rack - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention 1] The present invention relates to a fuel storage rack for storing fuel assemblies, and more particularly to a high-density fuel storage rack for storing fuel assemblies by removing their tunnel boxes.

[Technical use of the invention and its problems] Recently, due to delays in the reprocessing of spent fuel assemblies and improvements in the efficiency of fuel storage facilities, it has become necessary to increase the efficiency of spent fuel assemblies in nuclear reactor facilities. There is a need for high density fuel storage racks that store densely.

FIG. 3 shows such a conventional high-density fuel storage rack. In the figure, reference numeral 1 indicates the outer frame of the square fuel storage rack, and this outer frame 1 is divided by a number of partition plates 2. has been done. Note that a neutron absorbing plate (not shown) made of a neutron absorbing material is attached to the outer frame 1 and the partition plate 2. In the space formed by the outer frame 1 and the partition plate 2,
Square tubes 3 accommodating fuel assemblies are arranged at regular intervals, and a water gap 4 is formed between the square tubes 3 .

In the fuel storage rack constructed in this way, a fuel assembly 5 as shown in FIG. 4, for example, is accommodated and stored in the rectangular tube 3.

The fuel assembly 5 shown in FIG. 4 is constructed by bundling a large number of fuel rods 6 using a base υ-7, an upper tie plate 8 and a lower tie plate 9 to form a bundle, and housing this bundle in a channel box 10. It is configured.

A pad 11 and a fastener 12 are formed on the channel box 10, and a handle 1 is formed on the top of the bundle.
3 is formed.

That is, in such a fuel storage rack, the inner dimensions of the rectangular tube 3 are formed to be almost the same as the outer dimensions of the channel box 10, and there are holes (not shown) at positions corresponding to the pads 11 and fasteners 12 of the fuel assembly 5. Fasteners and pads are formed. Furthermore, the rectangular tube 3 located on the inner circumference has two sides adjacent to the partition plate 2 or the neutron absorption plate formed on the outer frame 1, and the other two sides adjacent to the water gap 4. .

In other words, in such conventional fuel storage racks, the idea of suppressing the neutron multiplication effect of the fuel storage rack by introducing an excessive amount of water into the fuel storage rack has not been considered, and the introduction of water is inevitably This increases the distance between the bundles, which is an obstacle to increasing the bundle storage density.

[Object of the invention] The present invention has been made in response to such conventional circumstances,
The present invention aims to provide a fuel storage rack with a higher density than the conventional one.

[Summary of the Invention] That is, the present invention is a fuel storage rack characterized in that a large number of rectangular tubes having an inner surface dimension that is approximately the same as the inner surface dimension of a channel box of a fuel assembly are arranged adjacent to each other.

"Embodiment of the Invention" Hereinafter, an embodiment of the present invention will be described in detail as shown in the drawings.

FIG. 1 shows an embodiment of the fuel storage rack of the present invention. In the figure, reference numeral 1 indicates a rectangular outer frame surrounded by a neutron absorption plate (not shown). This outer frame 1
is divided into four by a partition plate 2 having a neutron absorption plate (not shown).

A large number of rectangular tubes 3 are arranged adjacent to each other in each space. The inner dimensions of the rectangular tube 3 are approximately the same as the inner dimensions of the channel box 10 of the fuel assembly 5. The rectangular tube 3 is made of a material that absorbs neutrons, such as stainless steel, boron-added stainless steel, boron-added aluminum steel (boral plate), etc.

FIG. 2 is a partially enlarged view showing the broken line part in FIG. There is. Further, between the rectangular tubes 3, a measurement tube 14 for monitoring subcriticality is arranged to insert a radiation detector and a neutron source as necessary to monitor the subcriticality of the fuel storage rack.

In the fuel storage rack configured as described below, a large number of rectangular tubes 3 having almost the same inner dimensions as the inner dimensions of the channel box 10 of the fuel assembly are arranged adjacently! This eliminates excess water between the rectangular tube 3 and the bundle, saving space and allowing high-density storage of the fuel assembly 5. Furthermore, since there is no excess water, the neutron multiplication effect can be suppressed.

However, in conventional fuel storage racks, the fasteners 12
Since the channel box 10 having the pad 11 was housed in the rectangular tube 3, excess water was introduced and the neutron multiplication effect became large. However, in the present invention, the excess water can be removed. , the neutron multiplication effect can be suppressed, and the density of the fuel storage rack can be increased.

In addition, in the embodiment described above, an example was described in which the outer frame 1 of the fuel storage rack was divided into four rectangular spaces by the partition plates 2. Neutron multiplication effect can be effectively suppressed.

In addition, since the fuel storage rack configured as described above can only be used after removing the channel box 10 in the fuel assembly 5 of a boiling water reactor, the fuel storage rack constructed adjacent to the reactor pool cannot be used. Therefore, it is not desirable to use the fuel storage rack of the present invention for all fuel storage racks. That is, when the fuel assembly 5 is temporarily removed for periodic inspection and reloaded into the core, it becomes necessary to attach and detach the channel box 10, so it is preferable to use it in conjunction with the fuel storage rack shown in FIG. .

Furthermore, since the channel box 10 is normally removed when the fuel assembly is stored in a transport container from this pool and transported to another pool, the fuel storage rack of the present invention is suitable for storing bundles without a channel box 1o. There is.

In other words, pressurized water reactors (PWRs) or advanced converter reactors (ATRs) do not handle bundles with a tunnel box or equivalent tube.
The fuel storage rack of the present invention allows fuel removed from a nuclear reactor to be stored immediately.

Note that for a bundle having a circular cross section such as an ATR, the rectangular tube may be replaced with a cylinder.

Effects of cn light As described above, according to the fuel storage rack of the present invention, a large number of rectangular tubes having an inner surface dimension that is almost the same as that of the channel box of the fuel assembly are arranged adjacently, so that the fuel storage rack has a very high construction cost. Dense fuel storage racks can be facilitated. This makes it possible to further improve the efficiency of the fuel storage facility.

[Brief explanation of the drawing]

FIG. 1 is a top view showing an embodiment of the fuel storage rack of the present invention, FIG. 2 is an enlarged top view of the fuel storage rack shown in FIG. 1, and FIG. 3 is a conventional fuel storage rack. The top view and FIG. 4 are external views showing a fuel assembly of a boiling water reactor. 1...Outer frame 2...Partition plate 3...Square tube 5...Fuel assembly 10...Channel box agent patent attorney Satoshi Suyama - Figure 1 Figure 2 Figure 3 Figure 4

Claims (3)

[Claims] (1) A fuel storage rack characterized by having a large number of rectangular tubes arranged adjacent to each other, each having an inner surface dimension that is approximately the same as the inner surface dimension of a channel box of a fuel assembly. (2) The fuel storage rack according to claim 1, wherein the square tube contains a neutron absorbing material. (3) The fuel storage rack according to claim 1 or 2, wherein a neutron absorbing material is arranged between the rectangular tubes.