JPS6379095A - Support lattice - Google Patents

Abstract

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

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a support grid for a fuel assembly loaded into a nuclear reactor.

"Prior Art" A fuel assembly loaded in a nuclear reactor is constructed as shown in Figure 4. That is, in Figure 4, this fuel assembly consists of an upper nozzle 1 and a lower nozzle 2 that are vertically spaced apart and arranged parallel to each other in the drawing, and a predetermined interval between them. A plurality of support grids 3.3... are disposed at the support grids 3.3... and these support grids 3.3...
It is inserted through a predetermined grid space 5°5...K between a large number of grids 9 formed in 4.4...K, and its upper and lower ends are connected to the upper nozzle 1 and the lower nozzle 2, respectively. The control rod guide tube that forms the framework of the fuel assembly6.6...
・A spring 8.8 is inserted into a predetermined lattice space 7.7 of the support lattice 3 as shown in FIG.
....

and are supported in parallel at predetermined intervals by dimples 9, 9, . It is composed of a plurality of fuels 1112, 12, . . . which are sealed.

The support grid 3 of such a fuel assembly is generally formed by using a large number of water-repellent straps 13 and assembling them vertically and horizontally. The strap 13 is made of a thin heat-resistant alloy plate formed into a belt shape, and pen-nib-shaped protrusions 14, 14 extending from the sides in the width direction are constant in the longitudinal direction of the strap 13. They are formed at intervals of . A slit 15.15 extending from the tip to the center of the strap 13 is provided at the center of the convex portion 14.14.
... is formed. As shown in FIG. 8, the convex portion 14 is formed at its center and divided into two parts by a slit 15, and each divided piece is bent toward both sides of the strap 13, as shown in this figure. The mixing vanes 16 and 16 are used as mixing vanes 16 and 16 to improve cooling efficiency by stirring the flow of coolant such as water flowing in the vertical direction of the support grid 3. Springs 8,8, . . . are formed at the slits 15, 15, . . . by protruding a portion of the strap 13 from one side of the strap 13. Oval throwers) 17, 17, . . . are formed on both sides of the springs 8, 8, . The springs 8.8, which are part of the strap 13, are located above and below the springs 8.8 in FIG.
A dimple 9°9... is formed that protrudes to the opposite side.

The straps 13 are formed into nine slits 15, 15, . The support grid 3 is shaped like a strap 13, and mixing vanes 16, 16, . . . protrude outward from the upper and lower ends of the support grid 3.

"Problems to be Solved by the Invention" By the way, the support grid 3F' When incorporated into a fuel assembly, it has the disadvantage of deforming due to contact with other objects. 9. The support grid 3 includes mixing vanes 1 that give a predetermined stirring effect to the coolant flowing within the support grid 3.
6.16... There are nine pieces bent at a certain angle.

If the nine mixing vanes 16, 16... are deformed, the support grid 3 may not be able to obtain the desired stirring effect.

Therefore, it is necessary to assemble, transport, and incorporate the support grid into the fuel assembly very carefully, and there is a problem that the handling and operability of the support grid 3 is very poor.This invention solves the above problem. The purpose of this invention is to provide a support grid with good handling and operability.

``Ninth Means for Solving the Problems'' The present invention is a support grid as described above, in which mixing vanes are located inside the upper and lower ends of the support grid.

Embodiment An embodiment of the present invention will be described with reference to Figures 1 to 3.

First example FIG. 1 is a diagram showing a first embodiment of the invention.

In FIG. 1, the same elements as those in FIG.

The support grid 18 shown in FIG. 1 is different from the support grid 3 shown in FIG.
The mixing vanes 20 of 9a and 19b are located inside the upper and lower portions of the support grid 18.

That is, as shown in Figure 1, the support lattice 18 is assembled in a lattice shape with the strap 19a with the mixing vane 20 facing up and the t-strap 19b with the mixing vane 20 facing down, each intersecting at right angles.
By aligning the tips of the vanes 0 and the upper and lower ends of the support grid 18 in the vertical direction, the mixing vane 20 is positioned inside the upper and lower ends of the support grid 18.

Strap 19a, 19bl'! % As shown in Fig. 2, pen tip-shaped protrusions 2 extend from the widthwise sides of the thin heat-resistant alloy plate strip 21 at regular intervals in the longitudinal direction.
2.22... is formed, and a slit 23.23... is formed in the center of the convex part 22 from the tip thereof at the center at of the strap 19a, 191), and the strip part 21 is made with Spring 8 #8..., dimple 9.9
..., slots 171l7... are formed. 22 protrusions.

Mixing vane 20.2 divided into two by slit 23
It becomes 0. As shown in FIG.
1 by bending them alternately on both sides. Further, the mixing vane 20 is formed so that the tip of the mixing vane 20 and the upper and lower shoulders of the support grid 18 coincide in the vertical direction when the support grid 18 is configured.

That is, the straps 19a and 19b are different from the conventional example and the MI
N spring 8.8..., dimple 9°9...
When configuring the support grid 18, the mixing vanes 20 are arranged so that the tip ridges of the mixing vanes 20 and the upper and lower ends of the support grid 18 coincide in the vertical direction.
．． The slit 231 [is made].

The support lattice 18 is assembled into a lattice shape using the straps 19aaI9e. Namely.

The support grid 18 is made by orthogonalizing the strap 19a with the mixing vane 2o facing upward and the strap 19b with the mixing vane 20 facing downward by fitting the slits 23 formed in each of these into each other. The tip of the mixing vane 20 of the strap 19a (or 19b) and the strap 1 soc are connected to 19a
) in FIG. 1, which are arranged in a lattice shape, with the upper side portions (the outermost side is the lower side portion) aligned in the vertical direction.

Further, the support grid 18 is made by fixing the orthogonal portions of the strap 19a and the strap 196 by welding or the like.

The support grid 18 having the above configuration is incorporated as one of the components of the fuel assembly in the same way as the conventional support grid 3,
The Ilj @ rod guide tube 6 is inserted into a plurality of predetermined lattice spaces 5, and the fuel rods 12 are inserted into a plurality of predetermined lattice spaces 7 so that the fuel rods 12 are arranged parallel to each other at a predetermined interval. I support it.

Further, the mixing vane 20 stirs the coolant flowing through the support grid 18 when the fuel assembly is loaded into the reactor, thereby increasing the cooling efficiency.

According to the support grid 18, since the tips of the mixing vanes 20 and the upper and lower ends of the support grid 18 match in the vertical direction, the mixing vanes 20 can be positioned inside the upper and lower parts of the support grid 18. When assembling, transporting, and assembling the support grid 18 into a fuel assembly, there is no fear that the mixing vane 20 will come into contact with other objects and be deformed, making assembly, transport, and other handling of the support grid extremely easy. Therefore, the time for assembling the support grid 18 and the fuel assembly can be shortened, so that the cost of the support grid 18 and the fuel assembly can be reduced. If the mixing vane 20, which is bent at a constant angle, and the strap 19a (the strap 19b) perpendicular to it are fixed by welding or the like,
It can be reinforced by the mixing vanes 20 at the corners of the grid space 7, and the strength rζ of the entire support grid 18 can be increased.

Second example FIG. 3 shows a second embodiment of the invention.

In FIG. 3, the same elements as those in FIG. 1 are given the same reference numerals, and their explanations will be omitted.

The support lattice 24 shown in FIG. wE3 differs from the support lattice 18 shown in FIG.

That is, the support lattice 24 is constructed by assembling the straps 25a and 25tl in a lattice shape as shown in FIG.
A mixing vane 26 extending from one side of the band 20 is bent at a certain angle to the same side of the band 20. Further, the other configurations of the support grid 24 and the shapes of the straps 25 a * 25 b are the same as those of the support grid 18 and the straps x9a, x9b of the first embodiment, respectively, so their description will be omitted.

The support grid 24 having the above structure functions in the same manner as the support grid 18 of the first embodiment. As a precaution, we omit the explanation of the effect.

The effects of the column support grid 24 are the same as those of the first embodiment, as well as effects unique to the second embodiment.

The effects of the first embodiment have already been explained, so their explanation will be omitted. The following effects are unique to the second embodiment. That is, on the support grid 24.

The strap 19a of the first embodiment has the mixing vane 26 bent to the same side of the strip portion 21.

191), the processing of the straps 25a and 25b is simpler, and the cost of the support grid 24 can be reduced.

"Effects of the Invention" According to the present invention, in the support grid of the fuel assembly, the mixing vane is located inside the upper and lower ends of the support grid, so that the support grid assembly is improved. There is no fear that the mixing vanes will come into contact with other objects and be deformed during transportation, transportation, and assembly into the fuel assembly, making assembly, transportation, and other handling of the support grid extremely easy. Hence the set of supporting grids! And a set of fuel assemblies! Since the time can be shortened, the cost of the support grid and fuel assembly can be reduced.

[Brief explanation of the drawing]

Figure 1 is a partially cutaway perspective view of the support grid shown as the first embodiment of the present invention, Figure 2 is a front view showing the strap of the support grid, and Figure 3 is shown as the second embodiment of the invention. A partially cutaway perspective view of the support grid, FIG. 4 is a front view showing the fuel assembly, and FIG. 5 is a sectional view taken along the line v-■ in FIG. Figure 6 is an enlarged view of the main part of Figure 5. l! Figure 7 is a front view showing the straps of a conventional support grid;
a! FIG. 8 is a partially cutaway perspective view showing a conventional support grid. 3, 18, 24-- Support grid, 13.19a
. 19 b -25a a 25 b"・"・Strap, 15゜23...Slit% 16.2G, 26
...Mixing vane beginner Mitsubishi Nuclear Fuel Co., Ltd. Figure 4

Claims (1)

[Claims] A large number of straps are formed by forming a large number of slits cut into a strip-shaped thin plate at regular intervals in a direction perpendicular to the longitudinal direction, and plate-shaped mixing vanes on the sides in a direction perpendicular to the longitudinal direction. The supporting lattice is characterized in that the mixing vanes are located inside the upper and lower ends of the supporting lattice of the fuel assembly, which is formed by fitting the slits of these straps together and forming a lattice shape by interfitting the slits of these straps in a vertical and horizontal manner.