DE2430492C2 - Nuclear fuel assembly - Google Patents

Description

The present invention relates to a nuclear fuel assembly according to the preamble of claim 1. Such a nuclear fuel assembly is known from DE-OS 19 09 109.

In the case of the nuclear fuel cassette known from DE-OS 1909 109, the individual rod sections containing burnable neutron poison are made up exclusively of poisonous fuel tablets, and different ones Average poison concentrations in the individual rod sections are achieved in that the Poison concentration per unit volume in the individual tablets of these rod sections is different. It So fuel tablets with different concentrations of burnable neutron poison are required. The design for these known absorber fuel rods is based on the fact that the length of the continuous consecutive poisonous fuel tablets is very large in relation to their diameter.

In the case of absorber fuel rods Kei ^ fuel cassettes of the aforementioned type, the burnable neutron poison is distributed in such a way that the arial power distribution is improved that that caused by control rods radial power distortion vermin place and that the control rods with cold shutdown an increased Reactivity control component is given.

In the following, the abbreviation “BA” is used for the term “burnable neutron lift” for the purpose of simplification. The burnable neutron poison is the chemical compound Gd ₂ O ₃ , which contains atomic nuclei that act as burnable absorbers. The term "BA material" means a chemical compound or material that contains combustible neutron poison in a molecular mixture. An axially extending section of the nuclear fuel assembly with constant distribution and figuration of the ΒΑ material is referred to as the “ΒΑ zone”.

If one uses an axially variable distribution of the burnable neutron poison in a nuclear fuel assembly wants to come close to an optimal effect, it is important that a fine gradation of burnable neutron poison is achieved and that the initial neutron poisoning and Residence time for burnable neutron poison is roughly proportional to the energy consumption between behaves two fuel loads in the ΒΑ-zone in question. If so, almost all of them can be Compensate for excess reactivity in the fissure zone exclusively with burnable neutron poison, since the Neutron poisoning decreases linearly with time. The advantage of a wide-ranging application of burnable Neutron poison consists in the radial and axial power distortion caused by control rods can be significantly reduced, since you can use control rods to a larger extent without regulation can get along. So there are essentially the following two requirements for axially distributed burnable Neutron poison posed:

1. Neutron poisoning decreasing linearly with time in each BA zone,

2. the initial neutron poisoning in a ΒΑ zone should be proportional to the square root of the occurring Be a set of ΒΑ-kernels.

If you want to provide the absorber fuel rods in the axial direction with a fine gradation of the ΒΑ material in the nuclear fuel assembly according to DE-OS 19 09 109, this requires a large number of gifthalti gene fuel tablets with a different concentration of the burnable neutron poison.

The invention is based on the object of developing a nuclear fuel assembly of the type mentioned above, in which the fine gradation of the concentration of the burnable neutron poison in the axial direction absorber fuel rods with toxic fuel tablets are only possible in a single concentration.

To solve this problem, a nuclear fuel assembly according to the preamble of claim 1 is proposed, which according to the invention has the features mentioned in the characterizing part of claim 1.

Advantageous refinements of the invention are specified in the further claims.

By combining relatively low non-toxic and toxic-containing fuel tablets according to different Patterns can be made with fuel tablets with only one poison concentration.

Produce bigen different mean poison concentrations. The invention is based on the knowledge that when Gd ₂ O _{3 is used} as a combustible poison, the above-mentioned linearity in time is relatively independent of the height-diameter ratio

The axial distribution of the burnable neutron poison is thus achieved according to the invention in that different fuel pellets are combined in different ways in an absorber fuel rod. Through this one can see a zonal variation of the neutron poisoning and the residence time for combustibles Obtained neutron poison. The content of burnable neutron poison in the B Α material does not need to vary and all of the absorber rods of the nuclear fuel assembly may be the same.

Detailed reactor-physical calculations of the combustion process for burnable neutron poison in light water boiler reactor fuel showed that the first of the above-mentioned conditions is met if fuel rods containing combustible neutron poison are used, the Gd ₂ O ₃ in parts, finely distributed in UO ₂ , and burnable between them Segments containing neutron poison contain pure UO ₂ . The proven insensitivity to the height-diameter ratio of segments in absorber fuel rods containing burnable neutron poison is a consequence of the fact that the neutron-absorbing isotopes Gd-155 and Gd-157 have microscopic absorption cross-sections which decrease sharply at neutron energies exceeding 0.1 eV, and that Gd-157 burns much faster than Gd-155. A practical lower limit for the height-to-diameter ratio of a segment containing burnable neutron poison is 0.3. - _m

Calculations have shown that the above-mentioned second condition can be approximately fulfilled by a nuclear fuel assembly according to the invention, if each segment of pure UO ₁ y? gives a fuel rod a constant axial length l _u and only changes the individual axial extent / _{BA of} the segments containing burnable neutron poison, while the content of Gd ₂ O ₃ per unit volume is kept constant. Pure UO ₂ segments should have a height-to-diameter ratio of about 0.6. Segments containing combustible neutron poison and with the shortest axial extent consist of UO ₂ disks with finely divided Gd ₂ O ₃ . By choosing a height-to-diameter ratio of the disks of 0.3, the expression V / _BA / (/ _BA + Z ₀ ), which describes the initial neutron poisoning of combustible neutron poison, can be between 0.58 and 1.00 can be varied. If you use a ΒΑ zone with two short UO ₂ tablets between each B Α disk in an absorber fuel rod, the absorption area can be expanded somewhat.

It is thus possible, with nuclear fuel cassettes according to the invention, to obtain a favorable axial distribution of the burnable neutron poison with exclusively short UO ₂ tablets and ΒΑ disks with only one absorber content za. A B Α zone with maximum neutron poisoning would then consist of a large number of ΒΑ disks stacked directly on top of one another. In order to reduce the total number of fuel pellets in an absorber fuel rod, a further fuel pellet is advantageously used which has a height-to-diameter ratio of greater than 1

The invention will be explained in more detail with the aid of the examples shown in the figures. It shows

1 shows a longitudinal section through a fuel assembly along I-I according to FIG. 2,

FIG. 2 shows the cross section of the fuel assembly according to FIG. 1 along H-II and -1

3 shows six different tablet combinations which can occur in an absorber fuel rod.

The nuclear fuel assembly shown is intended for a light water boiler. However, the invention is not restricted to nuclear fuel assemblies for such reactors, but its principle can also be used in the case of nuclear fuel assemblies for nuclear reactors of other types. The main parts of the nuclear fuel assembly are a fuel rod bundle 1 and a box 2. The fuel rod bundle is arranged as a freely removable loose insert in the box. The box 2 consists of a jacket tube 3 with an essentially square cross-section and a bottom part, not shown, which is attached to the lower end of the jacket tube. In the bottom part, the square cross-section merges into a round, reduced cross-section. The jacket tube 3 has lifting eyes not shown at its upper end. The fuel rod bundle 1 consists of a plurality of fuel rods 4 which are arranged in a substantially square rod lattice, an upper end plate (not shown) with a handle and a lower end plate (not shown) which hold the upper and lower ends of the fuel rods in the intended positions. Each fuel rod f contains at least one nuclear fuel, for example! UO ₂ , in the form of fuel tablets 5. The fuel tablets are stacked on top of one another in a cladding tube which is hermetically sealed at the ends by end plugs (not shown). The tablet column ends at the top with a disc, not shown, made of zirconium dioxide. In the upper end of each fuel rod there is a cracked gas space (not shown) with a spring screw which axially compresses the tablet columns. A small number of fuel rods consists of so-called B A rods 7 (absorbs fuel rods) which, in addition to non-poisoned fuel tablets, also contain fuel tablets in which Gd ₂ O _{3 is} homogeneously dispersed as a burnable neutron poison

Each absorber fuel rod 7 contains three different types of fuel tablets, namely short fuel tablets 8 that do not contain any burnable neutrons and have a height-to-diameter ratio of less than 0.75, as well as fuel tablets 9 and 10 containing burnable neutron toxins, of which the latter because of their low height are also referred to as fuel disks. The fuel tablets £, n9 and 10, which differ from one another only in their geometrical shape, contain combustible neutron poison distributed in the fuel and have a height-to-diameter ratio that is at least 50% larger or at least 25% smaller than that of the short fuel tablet 8H A ΒΑ-stick contains in parts a maximum of six characteristic combinations of the above-mentioned three types of tablets, which are numbered I-VI in FIG. 3. Combination I consists exclusively of BA tablets 9. In combination II there is a short fuel tablet 8 between blocks of two BA tablets 9 each, and in combination III short fuel tablets 8 alternate with BA tablets 9. The combination IV contains two each

ΒΑ-disks 10 between short fuel tablets 8. The combination V contains alternating short ones Fuel tablet 8 and a BA disk 10. Finally, the combination VI contains a BA disk 10 between blocks of two short fuel tablets 8 each

S neutron poison stops almost simultaneously along the entire length of the B Α rod. No burnable neutron poison containing rod section is shorter than 2% of the rod length.

In a preferred embodiment, with a tablet diameter of 10.6 mm, the height of the BA tablets is 12 mm, the height of the short fuel tablets is 6 mm and that of the BA disks is 3 mm. The burnable neutron poison consists of Gd ₂ O _{3 dissolved in UO 2} . The Gd ₂ O ₃ content is the same in the BA

tablets and the ΒΑ slices. For practical use, the Gd ₂ O ₃ -Ge (IaIt is less than 10 percent by weight and is usually between 1 and 5 percent by weight. The following table shows the assumed decrease in initial neutron poisoning when the burnable neutron poison is diluted at levels of 2 and 4 percent by weight Gd ₂ O _3. The initial neutron poisoning is defined in such a way that it has the value 1 for combination I. For ideally axially distributed combustible neutron poison, according to Condition 2, the initial neutron poisoning must be proportional to - // _BA / (/ _BA + l _u ) . This proportionality is sufficient for practical use. For the combinations I-IV, which are attached centrally in Ba-bars and are therefore of the greatest importance, the proportionality is almost perfect.

For this purpose 2 sheets of drawings Comb. / ba / u I / ba Initial neutron poisoning j

'/ ba + / u weight percent Gd ₂ O ₃ i

I - 0 1.00 1.00 1.00

H 24 6 0.89 0.89 0.88

III 12 6 0.82 0.80 0.80

IV 6 6 0.71 0.70 0.70 V 3 6 0.58 0.60 0.63

VI 3 12 0.45 0.40 0.41

The axial distribution of burnable neutron poison is chosen so that the neutron poisoning due to the burnable neutron poison ceases almost simultaneously in a B A rod. The Gd ₂ O ₃ content is chosen so that the burnable neutron poison has the desired residence time. The number of BA rods in a fuel assembly is chosen so that a desired reactivity compensation is achieved in the cleavage zone. The ΒΑ-rods in a nuclear fuel cassette are preferably the same.

Claims (3)

Patent claims: 1. Nuclear fuel assembly with several vertically arranged fuel rods, all of which are contained in a cladding tube stacked fuel tablets are built up and of which a small number of absorber are fuel rods which additionally contain a burnable neutron poison in the form of Gd ₂ Oj in part of the fuel tablets, each absorber fuel rod having several rod sections with a different mean poison content, characterized in that the poisonous fuel tablets have the same amount of poison per unit volume at different tablet heights, wob-.i the rod sections, which have a lower mean poison content than the poisonous fuel tablets, consist of different patterns of non-poisonous and poisonous fuel tablets that are repeated in the axial direction. 2. Nuclear fuel assembly according to claim 1, characterized in that at least one of the Rod sections the poisonous fuel tablets have an axial length of at most 50% of the axial length of the non-toxic fuel tablets contained in this section, with the maximum axial length of the non-toxic fuel pellets (8) are no more than 75% of their diameter 3. Nuclear fuel assembly according to claim 2, characterized in that except in the absorber fuel rod the said toxic fuel tablets at least twice as large as the toxic fuel tablets axial length are included.