NO146398B - ANALOGUE PROCEDURE FOR THE PREPARATION OF THERAPEUTIC ACTIVITY N1-GLUCUFURANOSIDE-6-YL-N3-NITROSOUR INGREDIENTS - Google Patents

Description

Support grid for thin, vertical rods of fissionable material.

The invention relates to a support grid,

where the fissionable material is arranged in the form of thin, vertical rods, which

extend next to each other and make up the fuel in a reactor core, and

where the support grid takes the form of a network of 'band material and holds the rods

centered in the lattice meshes weighted by means of spacers between the band material and

the staves.

At reafctor cores, if fissionable

material consists of 'long, thin rods,

e.g. poles with a length of 130 cm and

a thickness of 1.2 cm or rods that are in thin-walled tubes of similar dimensions and of a material that can withstand high temperatures, the rods or tubes must,

which in the following will be called brermstoff rods, are supported in their places. The support grids used must satisfy various requirements. Thus they must not exist

obstacle to the moderator refrigerant which

flows through the spaces between

the fuel rods. They must be mechanical

rigid to prevent the rods from changing their

'Position under operation. The contact between

the support grids and the fuel rods must

further 'reduced to a minimum and the grids

must not have any noticeable influence on

the neutron economy of the reactor cores. Finally

would a construction be suitable, where

the support grids exert a certain clamping force on . fuel-stems, so that -these spell with

safety is maintained in its fixed position.

The invention is to provide

a support grid that on the most advantageous

way satisfies the requirements and its

without having a simple construction. The invention is based on net-shaped support grids, where the strip material surrounds the fuel rods, which are passed through the grid's meshes, at some distance and where spacers are arranged between this strip material and the rods to keep the rods centered in the meshes. The net shape gives the support grids great rigidity, so that very thin strip material can be used here, e.g. tape with a thickness of 0.2 mm. Such thin bands offer almost no resistance to the flow of the moderator refrigerant. It has little influence on the neutron economy anyway. The descent pieces can easily be made so that they touch the fuel rods with a very small surface.

The spacers can be punched out of the grating's strip material in a manner known per se and, e.g. have the shape of tongues, which only 1 edge is connected to the grids and is bent towards the bars. In order to achieve a certain clamping force between the tongues and the fuel rods, the tongues can be bent in a circular or almost circular shape and extend at least half a circle. Because of this curved shape, the tongues become somewhat springy. For centering the fuel rods, tongues can advantageously be used, which in pairs at different heights are partially punched out of the grids' strip material, are turned in pairs towards each other, bent towards the rods and cross each other.

According to the invention, the support grid is distinguished by the fact that each support grid consists of one-sided meander- or zigzag-shaped bands, which extend next to each other and are mutually offset by half a pitch in the longitudinal direction of the bands and which are attached to each other with their opposite ; parts bordering each other and are equipped with support tongues, which extend into the meshes towards the rods and hold the rods; supported and centered in the meshes.

The support grids can be mounted in sleeves made of plate material and held in place by means of support rings that are attached to these sleeves. According to another feature of the invention, in such cases each support member consists of a bent plate:, the width of which is greater than that of the strip material in the support grids and whose surface is divided by means of incisions running parallel to the respective grid's plane into a middle section and end sections, and where said plate parts are bent so that the middle part extends in a radial direction to the support grid's circumference and secures this grid against radial displacement, as the end parts simultaneously extend above and below this circumferential surface and secure the grid against axial movement.

The invention will in the following! be described in more detail with reference to the drawings, which give examples of several embodiments according to the invention. Fig. 1 shows a sleeve with torennstoff rods 1 natural size, which is supported by means of grids according to the invention, seen from the front.

Fig. 2 shows the sleeve seen from above.

Fig. 3 shows from above and in an enlarged scale a part of such a support grid with fuel rods. Fig. 4 is a cross-section along the line IV—IV 1 fig. 3. Fig. 5 shows a modification of the support grid according to fig. 3. Fig. 6 shows details of a support grid.

Fig. 7 shows details of a grid.

Fig. 8 is a cross-section along line VIII

—VIII in fig. 7.

With 1 is denoted a sleeve of plate material, in which ide. honeycomb-shaped grids 2 composed of strip material are arranged 1 near the ends, which are held by means of support members 3, which are in turn supported by screws 4 which are placed in the wall of the sleeve 1. The bands, from which the gratings 2 are made, have in the design examples a hexagon shape and are mutually offset in pairs by half a pitch in the longitudinal direction of the bands and attached to each other with sims: oppositely bordering parts. They thus form a net-shaped grid with hexagonal meshes, through which the fuel rods consisting of thin-walled tubes 6 that are filled with fissionable material 5 are blown. Instead of the hexagon sides, the grids can also have square-rectangular, rhombus or another polygon shape on the meshes.

The mutual fastening of the bands is provided by tongues 7, which are formed by incisions in the upper and lower edges of one band, and which are bent over recesses 8 in the upper and lower edges of the other band (Figs. 4 and 8 ). The fastening can also be provided in another way, e.g. by means of solid or hollow rivets, riveting, soldering, spot welding etc. 1. connecting means.

Both in the embodiment according to fig. 3, 4 and in the embodiment according to fig. 5, the support members 3 consist of bent plates, which are divided by incisions into a middle part and two end parts. In fig. 3 and 4, the middle part 9 is circular and bent with such a diameter that the grid in question is protected against radial displacement towards the sleeve 1. The end parts 10 are likewise bent in a circular shape, but have a larger diameter and grip the upper and lower edge of the grid to secure this against axial displacement. The support members according to 5 differ from the corresponding members according to fig. 3 and' 4 in that the central part for radial protection has tongues 11 which are bent outwards in a semi-circular shape and that the end parts 12 have an inward-facing U-shape. The support members, which are punched out of thin plate material, are lightweight and strong, and it is also easy to manufacture and attach them to the sleeve 1.

Within the grid's meshes, the fuel rods 5, 6 extend freely from the grid's hand material. The rods are kept centered in a manner known per se by means of spacers in the form of tongues which are partly pressed out of the grid's strip material and bent inwards.

In fig. 3 and 4 are shown tongues 13 which are

'bent rectangular and thus radially aligned. In the embodiment according to fig. 5, strips 14 are partially punched out of the strip material, which are connected at both ends

the bands 2. According to fig. 6, the tongue-shaped spacers 15 are curved in a circular shape and

in fig. 7, 8 tongues 16 are punched out which

are located in pairs at different heights and are directed towards each other. These tongues are

pushed obliquely inward and crossing each other. The tongues 16 are provided with bulges 17, which reduce the contact surface between the rods and the grid to one point. The spacers according to fig. 6, 7 and 8 have the advantage over the embodiments according to fig. 3, 4 and 5 that they are springy in the radial direction and can thus exert a certain clamping force on the rods 5, 6, whereby the latter are retained without

•clearance.

The mesh grids with accessories are easy to manufacture and as strong as they can be

are produced from relatively very thin strip material, e.g. tape material with a thickness of 0.2 mm. In the present case, the height of the grids can be chosen to 20 mm. Such

grids will, so to speak, offer no resistance to the moderator cooling medium that flows through the spaces between the bars 5, 6. They have

further little influence on the metro economy. The contact surfaces between the tongues 13,

14, 15, 16 and the bars 5, 6 can be a lot

small and with the help of the bulges 17 become

The spark is point-shaped, so that the amount of heat that is transferred through the rods

directly on the igltne becomes small and the grids without

danger can be made of a less temperature-resistant and thus less expensive material than

that which contains the fissionable material 5. The grids can be made of stainless steel, while the tubes 6 can consist of a

zirconium alloy.

The sleeve 1 with the grids 2 can be larger

cross section and thereby contain more fuel rods 5, 6 than what is shown in fig. 1

and 2. The reactor core is composed of

several such sleeves, which are arranged at specific locations of the core in some of them

distance to allow room for the control rods and

the measuring instruments. The cross-section of the sleeves does not have to be the same as the cross-section of the lattice meshes.

Claims (2)

1. Support grid for thin, vertical rods of fissionable material, which extend next to each other and constitute the fuel in a reactor core, where the support grid- ret has the form of a network of strip material, which surrounds the rods at some radial distance and keeps the rods centered in the lattice meshes by means of spacers between the strip material and the rods, characterized in that each support grid consists of uniform meander or zigzag-shaped bands, which extend next to each other and are mutually offset by half a pitch in the longitudinal direction of the tape and which are attached to each other with their parts bordering each other and are equipped with support tongues, which extend into the meshes towards the rods and keep the rods supported and centered in the meshes. 2. Support grids as stated in claim 1, where the support grids are mounted in sleeves made of plate material and are held in place by means of support members which are attached to these sleeves, characterized in that each support member consists of a bent plate, the width of which is greater than the strip material in the support grids and whose surface: by means of incisions running parallel to the plane of the grid in question is divided into a middle part and end parts, and by said plate parts being bent so that the middle part extends in a radial direction to the perimeter of the support grid and secures this grid against radial displacement, and that the end parts extend both above and below this circumferential surface and secure the grating against axial movement.