DE2127240A1 - Nuclear reactor fuel rod - of fuel tablets stacked in sheathing tube - with metal lining layer - Google Patents

Abstract

Tablets of nuclear fuel material, esp. in ceramic form, are stcked in a tubular sheath. Between the two is a metal layer, esp. of foil, with smooth surface and perhaps gettering effect on substances which would corrode the sheath, to prevent damage due to relative thermal coeffs of expansion of the tablets and the sheath and to prevent binding between them. With a zirconium alloy sheath, a zirconium foil is used e.g. 0.025 mm (0.001 in) thick.

Description

Fuel rod for nuclear reactors The invention relates to construction of fuel rods ru nuclear reactors, in particular for use in heterogeneous pressure water reactors.

The prior art is detailed in U.S. Patents 3,089,830 and 3,100,742. There the known fuel rods are shown in which Hill pipes made of stainless steel, zirconium or zirconium alloy or aluminum alloy almost entirely with a nuclear fuel in pores of fuel pellets with radial Game are filled. Between the top of the column of nutritional tablets and there is a free space at the upper end of the cladding tube and the cladding tube is aur its length is divided into cells, each with a certain number of fuel tablets contain.

In these known fuel rods, friction or occurs as a problem the adhesion between parts of the school of fuel tablets and neighboring ones Inner wall of the Cladding tube. A continuous expansion of the column when heated to the operating state expressed itself when the fuel tablets come with the wall to engage, in an extension of the cladding tube to about the elastic limit beyond. After repeated alternation of heating and cooling This stretching effect can manifest itself as a kink or break in the fuel rod.

The task of the invention is to reduce the tendency to stretch or kink to make the cladding tubes of fuel rods as small as possible.

Another object of the invention is to provide a fuel rod, whose filling tube can be loaded more easily than before.

The invention solves these problems in such fuel rods by sine Metal layer between the Nüllrohr and the fuel, which has a relative movement between the column of fuel pellets and the cladding tube at different thermal Enables expansion.

The fuel rod according to the present invention consists of the usual one Shell made of stainless steel or other material, preferably made of Zirosloy that is closed at both ends and a column of fuel tablets contains. The improvement according to the invention consists in lining the pipe between the tube wall and the nutritional tablets. las lining can be the? orm of a closed Cylinder or a film that is adapted to the inner shape of the tube and whose opposite edges adjoin one another, so that one essentially closed Menbrane created between the Brenastofftabletten and the jacket tube is. The surfaces of the film are so smooth that there is a relative movement of the Er @ nn @ tofftabletten and the hell pipe gagen zie er @@@ te @ becomes. The slide can the end any suitable material, e.g. B. from beryllium, titanium or stainless Steel, but is z. Currently

preferably made of zirconium or zircaloy. The slide reduces the stretching of the Htllirohres due to the different thermal expansion the fuel pellets and the tube and facilitates the loading of the cladding tube with the fuel tablets. In addition, the film acts as a getter pump, its pumping surface reacts with gases and vapors in the fuel rod, leaving the possibility of reaction this GUe or vapors is reduced with the cladding tube itself. Also would the foil react with fission products that diffuse out of the fuel. With this getter effect, the film offers approximately twice the surface area that shell tube itself and is also at a higher temperature than the cladding tube, so that the getter effect is facilitated and a protection of the cladding tube is achieved.

From BR-PS 790 334 fuel sticks are already known where the metallic nuclear fuel is surrounded by a layer of niobium. However, will This layer is either sprayed onto the fuel, sprayed on or electrolytically applied applied and prevents a chemical reaction between the fuel and the Barrel.

The invention is described with reference to the accompanying drawings. The drawings show: FIG. 1: a side view, partially in section the fuel rod flat of the present invention; : gur 2s the foil from which the Lining is made; Figure 3: the lining and the cladding tube in the assembly position ; nd Figure 4: the fuel pellets in position to load the Lined Küllrohres The illustrated preferred embodiment of the winding consists of the usual shell tube 10 made of zirconium or preferably a zirconium alloy, like them 2 :. B.

is commercially available under the trademark Ziroaloy.

This alloy consists of zirconium and tin and some quantities iron and chromium and sometimes nickel are an embodiment of the invention The cladding tube is similar to those used in today's pressurized water reactors and Similar types of heterogeneous nuclear reactors can be used. It has a length of about 3 m and an outer diameter between 0.75 to 1.5 cm. The cladding tube is provided with an end closure 12, which is welded to a bath gan and pressure-tight is.

A zirconium or zircaloy sheet of suitable thickness, e.g.

approximately 0.025mm thick, will be cut to suitable dimensions, 80 that a substantially closed cylinder can be formed in the tube 10. In one embodiment of the invention, the opposite.

Edges of the film connected to one another in a suitable manner, e.g. B. by welding after wrapping the foil around the column of fuel pellets has been. The ends of the foil can be over the ends of the column of fuel pellets Folded up and the whole hall including the foil can be used as a unit inserted into the cladding tube.

The film offers the inside of the casing a smooth surface, so that the entire column with virtually no possibility of breakage of the fuel pellets and ck @ e loaded the possibility of the tablets jamming in the @ull tube can be.

In another embodiment of the invention,. @@ e slide on one end essentially zylin @@ i? @@@ l @ and this end inserted into the duct. The opposite edges of the slide won't connected, but approach each other as closely as possible. The rolled up end the film is inserted into the jacket tube 10. Then the entire foil is 14 in the cladding tube pushed, whereby it automatically rolls up and the inside of the Adapts envelope tube. The corners of the foil at the end that first inserted into the tube 10 will be cut off as at 16 for ease of introduction. As in As shown in FIG. 4, the film 14 is dimensioned somewhat longer than the tube 10, so that after the front end of the film reaches the rear end of the tube 10 has, which is determined by the termination 12, a part 18 of the film from the tube 10 reaches out. As shown in Figure 3, the cover tube 10 is through the stop 21 positioned at one end thereof and by the stops 22 on its sides. The partially preformed film 14 is guided in the V-shaped trough 24, around the Insertion into the casing tube 10 to facilitate.

After inserting the film into the cladding tube, the part 18 still protrudes, a number of fuel tablets 26 in the guide wsnne 28 with arranged in line with the cladding tube and then through the slightly enlarged protruding one Part 18 of the now cylindrical film 14 up to the end of the cladding tube towards the end 12 pushed. This creates a column of fuel pellets that hold the Hüilrchr 10 is essentially completely filled and the film 14 forms a membrane between the fuel pellets and the cladding tube. The fuel tablets, their cylindrical The outer surface is carefully sanded and made from low-enriched uranium dioxide are pushed into the tube as a complete column instead of individually.

After inserting the fuel pellets, the protruding one becomes Part 18 of the film 14 cut off.

The open end of the charged cladding tube 10 is then closed off 30 sealed gas and pressure-tight.

Between the end of 30 and the end of the one-offs 26 combined column of fuel tablets, the space 32 is left, the different thermal expansion between the fuel pellets and the tube 10 allows. The space 32 also serves as a chamber for the Spaltges and can, if necessary, contain a compression spring (not shown). As As can be seen from FIG. 1, a cladding tube 10 has been produced in this way, in which a lining or a metallic foil is the column of fuel tablets 28 from the interior of the cladding tube 10, the ends of which through the closures 12 and 30 are sealed. For ease of illustration are the radial dimensions and distances has been shown enlarged in FIG. With a cladding tube for today's standard Pressurized water reactors with an outside diameter of 0.76 to 1.0 cm exist radial distance of approximately 0.11 to 0.20 @@ between the fuel pellets and the inner surface of the cladding tube. The film 14 is arranged in this space and has contact with the ionic surface of the cladding tube at some points and at others Place or the same with the outward appearance of the fuel dahlettes.

This structure arises regardless of whether the fuel drains Zwvor packed in the foil and then loaded or first the foil and then the fuel tablets are loaded.

In either case, there is only a slight possibility.

Break the ceramic fuel pellets while charging or to jam the fuel tablets in the casing tube and thus the loading operation to interrupt.

Because of their manufacturing process. this is usually a cold rolling process the surfaces of the film are very smooth, they are even slightly smoother than the inside of the cladding tube, leaving the possibility that the fuel pellets get stuck with their edges on the inner surface of the shell tube, reduced is and thereby the relative movement of the fuel pellets against the cladding tube Due to thermal expansion is facilitated. This manifests itself in a reduction the possibility of stretching or kinking the cladding tube.

Under certain conditions, hydrogen can move inside the Brennitabes due to moisture or hydrocarbons.

substance impurities are located. The hydrogen can chemically with react to the Ziroaloy cladding tube. whereby ZrH is formed as a reaction product, which in turn the mechanical properties of the cladding tube impaired. The slide between the fuel pellets and the cladding tube reacts with or "gettert" the gases or Vapors in the fuel rod, reducing the possibility of a reaction with the cladding tube itself. In addition, one expects that the film with the fission products itself reacts, which diffuse out of the fuel and the cladding tube in front this reaction is protected. With regard to the getter effect, it is noted. that the film offers approximately twice the surface area of the cladding tube itself and also because it is closer to the fuel. has a higher temperature, so that the reactions with gases and vapors within the fuel rod are preferred with the foil and not with that colder Hüilrohr happen.

Annex B P a t e n t a n a p r ü c h e 1 sheet of drawings with 4 characters

Claims (1)

P a t e n t a n s p r ü c h e 1.) Fuel rod for nuclear reactors with a cladding tube to accommodate a column of stacked nuclear fuel tablets, characterized by a metal layer between the cladding tube and the column which a relative movement between the column and the jacket tube with various thermal Enables expansion. 2.) Brennatab according to Claim 1 ,. characterized in that the cylindrical cladding tube contains cylindrical ceramic fuel pellets and that the metal layer prevents the tablets from binding to the tube. 3.) Fuel rod according to claim 1, characterized in that the metal layer as one of the tablets loosely surrounding film is formed 4.) fuel rod according to claim 1, characterized by that the metal layer is tubular. 5.) fuel rod according to claim 1, characterized in that the surface the metal layer is smoother than the inside. area of the cladding tube and a binding of the tablets to the tube prevented. 6.) fuel rod according to claim 1, characterized in that the metal layer consists of one material. that for substances that are corrosive to the cladding tube, has a getter effect. 7.) Brannstab according to claim 1, characterized in that the Metal layer made of a zirconium foil and the filling tube made of a zirconium layer consists. 8.) Brannstab according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the column of the fuel pellets has an outside diameter of 0.11 up to 0.20 mm (0.0045 to 0.008 inch) smaller than the inner diameter of the cladding tube is that the film is approximately 0.025 mm (0.001 inch) thick and in the space between the Column of the fuel tablets and the cladding tube is arranged.