DE2842198B2 - Nuclear fuel element - Google Patents

Description

The invention relates to a nuclear fuel element according to the preamble of claim 1 of Main registration P 25 50 029.2.

According to patent application P 25 50 029.2, essentially pure zirconium, in particular, is advantageous Zircon with a content of less than 1000 ppm and more preferably less than 500 ppm Impurities door the protective layer used to protect the shell of the nuclear fuel element from damage to protect and at the same time reactions of the material of the protective layer with the shell material to avoid and due to the material of the protective layer only a low neutron absorption and a to have sufficient plastic deformability.

However, such a pure zircon is relatively expensive. The present invention was therefore the The object of the nuclear fuel element of the type mentioned above is the essentially pure To replace zircon according to patent application P 25 50 029.2 with a cheaper yet effective material. According to the invention, this object is achieved by the characterizing part of claim 1.

The protective layer of the fuel element according to the invention does not give rise to any noticeable problems with regard to neutron input, heat transfer or material incompatibility.

A particularly effective nuclear fuel element for use in the core of a nuclear reactor has a Sheath made of a zirconium alloy in which the components except zirconium in an amount of more present than 5000 ppm and the protective layer consists of zirconium sponge, which is metallurgical with the Inside of the shell is connected from the zirconium alloy. The composite shell obtained in this way closes the nuclear fuel material so that a gap remains between the fuel and the composite can. The protective layer shields the shell from the nuclear fuel material contained therein as well as the Fission products and gases. The protective layer makes up 1 - 30% of the thickness of the composite shell. One Protective layer less than about 1% of the thickness of the composite shell is commercially available in manufacture Difficult to maintain scale and gives a protective layer greater than 30% of the thickness of the composite shell with regard to the thickness exceeding 30%, none further benefits. The zirconium of the protective layer remains soft and minimized during the irradiation local stresses within the nuclear fuel element and thus protects the shell from stress corrosion cracks or liquid-metal embrittlement. The shell part of the composite shell is opposite to the usual Shell parts unchanged for this purpose and is made from the usual materials for this, such as zirconium alloys, selected.

The composite shell is produced in analogy to that described in patent application P 25 50 029.2 Procedure.

In the following the invention is explained in more detail with reference to the drawing. In detail shows

Fig. 1 is a partially cut-away sectional view a nuclear fuel cassette with nuclear fuel elements according to the invention, and

FIG. 2 is an enlarged sectional view of the nuclear fuel element according to the invention according to FIG. 1.

In Fig. 1 shows the nuclear fuel cassette 10, which has a tubular flow channel 11 generally square cross-section and on her upper end with a lifting bracket 12 and at its lower end with a nosepiece, not shown is provided. The upper end of the channel 11 is open at 13 and the lower end of the nosepiece is with Provided coolant flow openings. A number of fuel elements 14 are within the channel U enclosed and provided there by means of an upper and a lower (not shown) holding plate 15. The liquid coolant usually enters the lower end of the nosepiece through the openings, flows up along the fuel elements 14 and exits the cassette through the upper one Outlet 13 in the partially vaporized state with boiling reactors or in the non-vaporized state elevated temperature in pressure reactors.

The nuclear fuel elements 14 are sealed at their ends by means of end closures 18 which pass through Welding are connected to the jacket 17 and these terminations can have bolts 19 to the To facilitate assembly of the fuel elements in the cassette. At one end of the fuel element is a void 20 is provided to accommodate the longitudinal extent of the fuel material and the accumulation of To allow fuel material emitted gases. In this cavity 20 is a device in the form of a Spring 24 arranged to the axial displacement of the fuel column, especially during handling and the transport of the fuel element, to prevent as much as possible.

The fuel element is designed so that there is excellent thermal contact between the Composite shell and the fuel material, a minimum of parasitic neutron absorption takes place and the element is stable against deflection and vibration occasionally caused by the coolant flow caused at high speed.

One of the nuclear fuel elements 14 is shown partially cut away in FIG. 1. This nuclear fuel

Fabric element includes a body 16 of nuclear fuel material, which in the present case excludes several fuel pellets made of fissile and / or breeding material, which within a composite shell 17 is arranged. In some cases :) the fuel pellets can have different shapes like that a cylinder or a sphere and in other cases different forms of fuel can also be used like particulate fuel. The physical form of the fuel for the present invention is';> insignificant. Various nuclear fuel materials can be used including uranium compounds, Plutonium compounds, thorium compounds and mixtures thereof. A preferred one Fuel is uranium dioxide or a mixture of r · uranium dioxide and plutonium dioxide.

The nuclear fuel material forming the central body 16 of the nuclear fuel element 14 is as shown in FIG Fi g. 2 can be seen, surrounded by a composite shell 17. This composite shell 17 includes the Kc-per 16 so,; ί that during the use of the element in a nuclear reactor, a gap 23 between the body and Composite shell is present. The composite shell consists of a shell 21 made of a zirconium alloy, which in a preferred embodiment is Zircaloy-2. With ■? "> The inner surface of the alloy shell is bonded to a protective layer 22 which provides a shield between the alloy shell 21 and the body 16 of nuclear fuel material contained therein forms. The protective layer consists of moderately pure) ■> Zirconium, such as zirconium sponge with low neutron absorption. The protective layer 22 protects the Shell part of the composite shell before contact and reaction with gases and fission products and prevents the occurrence of local stresses. ι ·

The level of impurities in the protective layer of moderately pure zirconium is important and serves to to give the protective layer special properties. The moderately pure zirconium contains at least 1000 ppm (by weight) and less than -w 5000 ppm of impurities and preferably less than about 4200 ppm. From these impurities oxygen is maintained in the range of about 200 to about 1200 ppm. All other impurities are within the normal range for ί> commercial sponge zirconium for nuclear reactors and have the following listed values:

Aluminum 75 ppm or less. Boron 0.4 ppm or less, cadmium 0.4 ppm or less, carbon 270 ppm or less, chromium 200 ppm or less, cobalt 20 ppm or less, copper 50 ppm or less less, hafnium 100 ppm or less, hydrogen 25 ppm or less, iron 1500 ppm or less, Magnesium 20 ppm or less, manganese 50 ppm or less, molybdenum 50 ppm or less. Nickel '">'> 70 ppm or less, niobium 100 ppm or less, nitrogen 80 ppm or less, silicon 120 ppm or less less, tin 50 ppm or less, tungsten 100 ppm or less, titanium 50 ppm or less, and uranium 3.5 ppm or less. <x)

In the composite shell of the nuclear fuel element of the present invention, the protective layer is with connected to the shell part in a firm bond. The metallographic examination shows that it is sufficient Diffusion between the materials of the shell- *> 5 part and the protective layer there to form a bond, but no diffusion away from the area of the Binding.

It was found that zirconium metal sponge forms a protective layer in the composite shell, which is shown in is highly resistant to radiation hardening and this allows the protective layer to do so prolonged exposure to maintain the desired properties, such as yield strength and hardness, the are considerably lower than in conventional zirconium alloys. The protective layer does not harden as much as common zirconium alloys when exposed to radiation and this along with their initially The low yield strength allows the protective layer to deform plastically and through pellets absorb induced stresses in the fuel element during temporary peak loads and to dismantle. The loads induced by pellets in the fuel element can, for. B. by sources of Nuclear fuel pellets are produced at reactor operating temperatures of 300-350 ° C, whereby the pellet comes into contact with the jacket.

It has further been found that a protective layer of zirconium sponge with a preferred Thickness of about 5-15% of the thickness of the composite shell and a particularly preferred thickness of 10% of the Composite shell, when bonded to the shell part made of a zirconium alloy, reduces stress and a protection that is sufficient. To prevent errors or failures in the composite shell.

The zirconium alloys which can be used as alloys for the shell include Zircaloy-2 and Zircaloy-4. Zircaloy-2 contains approximately 1.5% tin, 0.12% iron, 0.09% chromium and 0.005% on a weight basis Nickel and is used extensively in water-cooled reactors. Zircaloy-4 contains less Nickel as Zircaloy-2. but more iron than this.

The composite shell used for the nuclear fuel elements according to the invention can be according to one of the the following processes:

1) A hollow collar made of zirconium sponge is inserted into a hollow billet made of a zirconium alloy and the whole thing explosively. The composite is then at an elevated temperature extruded from about 540 to about 750 ° C using conventional pipe extrusion techniques. The extruded composite is then subjected to a process including conventional pipe necking exposed until the desired size of the composite shell is reached.

2) The zirconium sponge is inserted into a hollow billet made of the zirconium alloy and that Whole for z. B. 8 hours on z. B. 750 ° C heated to to obtain a diffusion bond between the collar and the billet. The composite is then extruded in a conventional manner and the extruded composite including a process subjected to the usual constriction of the pipe until the composite envelope is of the desired size is preserved.

3) A hollow collar made of the zirconium sponge is inserted into a hollow billet made of the zirconium alloy and the whole is extruded by conventional pipe extrusion techniques. Thereafter the extruded composite is subjected to a process known as tube constriction until the desired composite envelope size is obtained.

The aforementioned method for the production of the composite shell for the nuclear fuel according to the invention

stoffelcmcni result in economic advantages over other methods of manufacturing such composite casings, such as electroplating or the Vacuum deposition.

For the production of the nuclear fuel element according to the invention, one obtained as described Composite shell made a container that is open at one end. Then you fill the container with a Nuclear fuel body. a gap between the body and the inner wall of the container and leaving a cavity at the open end. A holding device is inserted into the cavity of the nuclear fuel, closes the open end of the container, whereby the cavity is in Leaves connection with the nuclear fuel and then connects the closure to the end of the container, to create a gas-tight seal between them.

The nuclear fuel element according to the invention has various advantages for a long service life, including the reduction of the chemical interaction with the shell, the minimization of local ones Load on the shell made of the zirconium alloy, the minimization of stress corrosion and expansion corrosion the envelope and reducing the likelihood of failure of the envelope Chipping. The invention further prevents the nuclear fuel from expanding to one direct contact with the shell made of zirconium alloy, which in addition to avoiding the occurrence local tension in the envelope initiating or accelerating stress corrosion of the envelope and prevents the bonding of the nuclear fuel to the shell.

An essential point in the composite shell of the nuclear fuel element according to the invention is that the the aforesaid improvements can be achieved without a significant disadvantage in terms of neutron absorption is to be accepted. Such a composite shell is easily accepted for nuclear reactors, because it does not do anything during a coolant failure or an accident in which the control rod falls Would form eutectic. In addition, the composite shell has only a slightly poorer thermal conductivity on as an element in which a separate film or liner is used.

1 sheet of drawings

Claims (4)

Patent claims: 1. Nuclear fuel element consisting of a central body made of a nuclear fuel material in a sealed shell made of metal, such as stainless steel or zirconium alloys, which on its wall side facing the nuclear fuel has a protective layer made of metal, which metallurgically is connected to the shell wall, this protective layer consists of zirconium, according to patent application P 25 50 029.2, characterized in that that the zirconium of the protective layer impurities in an amount of at least Contains 1000 ppm to less than 5000 ppm 2. Nuclear fuel element according to claim 1, characterized in that the zirconium Protective layer is present in the form of a sponge. 3. Nuclear fuel element according to claim 1 or 2, characterized in that the oxygen content of the zirconium of the protective layer is in the range of 200 to about 1200 ppm. 4. Nuclear fuel element according to one of claims 1 to 3, characterized in that between there is a gap (23) between the protective layer (22) and the body (16) of nuclear fuel material.