DE2211038A1 - Fuel unit for nuclear reactors - Google Patents

Description

Applicant: United States Atomic Energy Commission Washington D. C, USA

Fuel unit for nuclear reactors

The invention relates to a fuel unit for the Gore of a nuclear reactor, in particular for breeder reactors with be cooled and moderated with light water.

Breeder reactors generate energy and at the same time increase the stock of fissile material. During the fission, · neutrons and energy free. The stock of breeding material in the breeding reactor increases when breeding material such as B. Thorium-232 The neutrons released by the fission are absorbed. When a thorium-232 atom captures a neutron, it becomes thorium-233 converted because radioactively decays to protactinium-233. This in turn decays to the fissile uranium-233 · The vom Breeding material to be absorbed neutrons is mainly produced by fission of the fuel, to a lesser extent

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also through rapid cleavage of non-fissile material such as Thorium-232 and Protactinium-233 · For maintenance the chain reaction and the critical reactor state For every destroyed atom of the fissile material that releases neutrons, one neutron must be absorbed by the fissile material and at least one more neutron must be absorbed by the breeding material to create new fissile material to create. The ratio of neutron production by fission to neutron absorption by fissile material must therefore be at least 2 in order to avoid losses through trapping by the moderator, through building material, through cracking to balance products and impurities in the fuel, uranium-233 which is cooled and moderated with light water, fulfills this requirement, since the ratio of neutron production to absorption is greater than 2.

Breeder reactors with a germination or fission zone and a jacket or breeding zone are known. As a germination or cleavage zone denotes the area of fuel in which the predominant activity is the fission of fissile material. as Shell or breeding zone is the name of the fuel area in which the predominant activity in the conversion of Breeding material consists of fissile material. Fuel can refer to fissile material, breeding material, or both.

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At the start of operation, the seed zone contains a breeder reactor with a germ, and a cladding region as sufficient fissionable material and the mantle zone sufficient breeding material to the predominantly _v splitting "or breeding character of the zone concerned to shape. A self-sustained operation of such breeder reactors could with a placement of the seed - or fissure zone with uranium-233 and an equipping of the mantle or breeding zone with thorium-232, whereby several fuel units with a germination and a mantle zone are put together in a modular manner to form the core. The gore is often surrounded by a reflector jacket made of natural thorium oxide , see U.S. Patent 3,351,532 on the foregoing.

Also known are designs of the Gore with two germination zones and one or more jacket zones in a stepped arrangement. The fuel rods for the cladding zone usually consist entirely of thorium in a tightly packed arrangement or bundle. This has the disadvantage that the flow of the coolant is severely restricted and the jacket zone remains fairly dry. However, the dense packed arrangement is necessary in order to suppress parasitic neutron losses to the water in the mantle or breeding zone. The close arrangement of the fuel rods, however, causes great difficulties in terms of structure, support and the like. ^; '■

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The germination zones usually consist of loosely arranged fuel rods with greater water concentration and sufficient neutron moderation required for strong reactivity. The individual fuel unit consists of a movable and a fixed unit, due to their relative displacement the reactor is regulated. The movable unit consists of a central thorium jacket surrounded by a annular germinal zone. The fixed unit consists of three angled and equidistant around the movable unit arranged structural units, each of which has a stationary germination zone next to the movable germination zone and a jacket zone contains. Often a further stationary germination zone is also provided on the outer circumference of the stationary units. To the Separation of the germination zones and jacket zones, the structure must have channels, namely at least one channel for each germination zone. In addition, the first few fuel rods of the movable and stationary jacket or brood zones are at different longitudinal points Equipped with Thorium-232, so that a progressive formation is created from one row of bars to the other, so that when the moving fuel is lifted during the life of the gore, different thicknesses of the Neutron-capturing thorium material come to lie between the germinal zones and control excess reactivity. This fuel arrangement for reactivity regulation is also called an arrangement of neutron poison wedges from graded thorium see U.S. Patent 3,335,060. Now they have to

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placed fuel rods but each have two different diameters in order to avoid excessive neutron losses to the cooling water between the upper and lower mantle zones. The part of the fuel rods with the larger diameter forms the thorium mantle, while the part with the smaller diameter forms the germinal zone. The necessary design of the fuel rods results in two different diameters but difficult problems of manufacture, construction and Support.

The object of the invention is a fuel unit for the core of light water breeder reactors with a simplified structure and lower cooling water resistance.

The object is achieved by the fuel unit of the invention solved with a movable part and a fixed part surrounding it in that the vertically movable part has several in Spaced fuel rods containing mainly fissile material with a seed or fission zone and at least has a jacket zone, and the fixed part has a plurality of spaced-apart jacket fuel rods with a predominantly with Breeding material and a small amount of fissile material stocked zone and at least one essentially with breeding material equipped zone contains.

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It is particularly advantageous in this design that the fuel rods only have one diameter and are packed loosely instead of tightly can be arranged. The structure improves the breeding performance, so that the structure was more agile in many ways because an abundant breeding capacity is available. A longer service life can also be achieved des gore, improved energy performance and improved fuel worth.

The drawings used for further explanation show:

FIG. 1 shows a single fuel unit for the germination or cleavage zone in cross section;

FIG. 2 shows, schematically in longitudinal section, a single fuel unit for the cleavage zone with the adjacent mantle with breeding and germination zones;

FIG. 3 shows a diagram of the shift for activity control during the life of the core of the reactor.

A particularly favorable embodiment shown in Figures 1 and 2 shows a fuel unit 20 with a hexagonal, central, movable arrangement or unit 22, enclosed by a stationary unit 24. The one with a external support 32 provided, central, movable unit

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22 is vertical in the casing 26 by means not shown movable, and forms with this cooling channels for the coolant flow. The "movable unit 22" consists of several axially extending through the entire active area of the core through fuel rods 36 with uniform Diameters. The tube material forming the fuel rods advantageously has good mechanical properties with higher Temperature and a low cross-section for thermal neutrons. An example of such a material is zirconium oxide.

The seed or fission zone lies entirely within the movable unit 22 between the ends of the fuel rods 36. The fuel in this zone consists of a mixture of the oxides of uranium-233 and thorium-232, in the U-233-O ₂ 5-15 % and preferably 7 »4% by weight of the mixture. The atomic ratio of hydrogen to uranium-233 in this nucleus zone 34 should be 30 - 60. Furthermore, in the zone are neutron poisons, e.g. B. Thorium, wedge-shaped. Above and below the zone 34 protruding ends of the fuel rods 36 form the upper cladding zone 38 and the lower cladding zone 40. B. Thorium-232 in oxide form and should have an atomic ratio of hydrogen to thorium of 0.9-3. The jacket zone 38 is designed to be complementary to the stepped part of the germinal zone 34- stepped.

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The fuel rods 36 forming zones J4, 38 and 40 can Contain a variety of germ and jacket fuel tablets. These are stacked on top of each other so that when reassembling of the fuel rods 36 is the stepped one shown in FIG Form emerges. A loose assembly of the fuel rods reduces the hydraulic resistance to the flow through Coolant. The fuel rods are inserted by known means, e.g. B. spacing grids axially in solid mutual Kept their distance. In contrast to the known fuel rods, they only have one diameter instead of two different diameters. The production is therefore much easier. When assembling several fuel units in a core, the germ or cleavage zones should total around 20 - 40% of the core volume.

An outer support 50 of the stationary unit 24 extends axially over the entire length of the core. The fuel rods 48 of this unit 24 form a uranium-containing cladding zone 42 and the upper and lower cladding zones 44-46 and consist e.g. B. from a zirconium alloy. Zone 42 contains a mixture of uranium-233 and thorium-232, each in oxide form, with U-233-Op ° >> ^8-3 µ * ¹ * ³ * preferably making up 1.7% by weight of the mixture and that The ratio of hydrogen to uranium-233 is 40 - 120. Small amounts of fissile materials, eg 1.7% by weight of U-233-O _2, do not change the character of zone 42 as a mantle or breeding zone, the predominant activity of this zone

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consists in converting breeding material into fissile material Material.

The mantle breeding material in the upper and lower mantle zones 44 and 46 consists of thorium-232 in oxide form and is said to have an atomic ratio of hydrogen to thorium-232 of 0.9 - 3 to have. The uranium-containing mantle zone 42 is stepped down. The lower jacket zone 46 is correspondingly stepped educated. The fuel rods 48 in the stationary unit 24 can contain several fission fuel pellets and breeding pellets Contained in stacking, so the step-shaped Receive training. The fuel rods 48 are loosely assembled to form the wet uranium-bearing cladding zone 42 and the wet upper and lower jacket zones 44 and "46. As in the movable unit 22, the fuel rods 48 are held at a fixed mutual spacing by known means " As a result of the loose arrangement of the fuel rods, the problems caused by the known compact arrangement of the Build-up avoided. All of the fuel rods 48 have only one diameter.

The following table gives the dimensions of one particular favorable embodiment. The lengths marked with letters refer to the corresponding reference symbols of Figure 2.

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TABLE I.

0 Pt. inch Total height 0 8th 6th Distance across the hexagonal faces 0 1 5 Diameter of the fuel rods for the seed zone O , 255 0.255 Distance between the firing rods for the germination zone , 070 0.070 Diameter of the fuel rods for the cladding zone , 576 0.576 Distance between fuel rods f. D. Mantle zone , 055 0.055 Length a 9.0 Length b 14.0 Length c 3.72 Length d 4.03 Length e 4.34 Length f 4.63 Length g 4.89 Length h 5.34 Length i 6.00 Length j 6.60 Length k 7.20 Length 1 7.80 Length m 8.50

As mentioned before, the task of stationary germination or fissure zones in known fuel units was for the movable ones Germ zones ensure acceptable fuel levels. In the arrangement according to the invention with a single seed

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or fission zone, the same effect is achieved by the fuel distribution in the uranium-containing jacket 4-2. This means that the stationary germinal zone and the channel required for it can be missing. The space released is available for additional breeding material. This results in a great increase in the breeding capacity of the fuel unit 20. This increased capacity in turn allows structural designs which were previously considered inadmissible because of their impairment of the breeding capacity. So is z. B. the reactivity s control with the fixed and movable fuel without fuel rods with two different diameters possible
Furthermore, the jacket fuel rods no longer need to be packed tightly, because of the improved breeding performance
the neutron losses associated with loose arrangement to the
Mantle water must be accepted.

The diagram in FIG. 3 shows the position in
that the moveable fuel assembly 22 becomes critical during the life of the gore; it also shows how far
this must be withdrawn in order to maintain the critical state during the life of the core. As FIG. 3 further shows, the controlled system is small during the Gore service life, ie the critical position of the movable fuel does not change significantly during this period. Improved service life and smaller controlled system

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are largely with the improved fuel fourth and the initial excess reactivity due to the separated form of the fuel unit with only one seed or fission zone. The higher fuel value is also of interest from a point of view other than that of the nominal power. In this way, the fuel setting required by 7mt can be achieved more quickly. This can be especially useful for switching off the reactor quickly.

Claims (10)

Claims (1st fuel unit for the gore of a light water breeder reactor with a "movable" and a "surrounding it" fixed part, characterized in that the vertically movable Part (22) a plurality of spaced apart fuel rods (36) containing mainly fissile material Seed or cleavage zone (34) and at least one jacket zone (38, 40) and the fixed part (24) has a plurality of spaced-apart edge fuel rods (48) with a predominantly with Breeding material and a small amount of fissile material stocked zone (42) and at least one substantially with breeding material equipped zone (44, 46) contains. 2. Fuel unit according to claim 1, characterized in that that the mantle rods contain thorium-232 as breeding material and their distance is so large that the atomic ratio from hydrogen to thorium-232 is 0.9-3. 3. Fuel unit according to claim 1, characterized in that the zone of the jacket rods containing a small amount of fissile material contains 0.8-3% by weight of TJ-233-O ₂ . - 14 - 209840/0679 4. Fuel unit according to claim 1, characterized in that the fissile material in the germination zone is uranium-233 and the distance between the seed zone fuel rods is so large that the atomic ratio of hydrogen to uranium-233 is in the range from 30 - 60. 5. Fuel unit according to claim 4, characterized in that the fuel rod parts forming the seed zone contain _{S - 15% by weight of U-233-O 2.} 6. Fuel unit according to claims 1-5, characterized in that the fuel rods of the seed and jacket zone respectively have only one diameter and are loosely arranged. 7. Fuel unit according to claims 1-6, characterized in that that the individual germinal zone tapers gradually. 8. Fuel unit according to claim 7, characterized in that that a jacket zone of the movable unit is designed to be stepped in a complementary manner with the gradation of the germination zone. 209840/06 7 9 9 · Fuel unit according to claim 1, characterized in that that the jacket zone containing a small amount of fissile material tapers in a stepped manner and the substantially mantle zone equipped with breeding material is formed in a complementary stepped manner with this. 10. Fuel unit according to claim 1, characterized in that the K ^ imzone PO - 4-0 vol.9o make up the fuel fineness.