DE4325062A1 - Nuclear reactor fuel element - Google Patents

Description

The invention relates to a nuclear reactor fuel element with two holding plates and egg Nem holding rod held on both holding plates, the longitudinal axis of both holding plates penetrates at right angles and the one at one end of the rod, with which it passes through a Bushing in a holding plate grips from the inside of the holding plate, has a radial retaining nose on the outside, as well as one on an outside of the hal locking plate in which a coaxial from the holding rod Ab cover sleeve is displaceable in its longitudinal direction, has the following features:

• a) The cover sleeve loosely engages in one arranged above the locking plate Support disc,
• b) the cover sleeve has a compression spring which engages with a spring end the cover sleeve and with the other spring end on the support disc and is biased by a tie rod that attaches to the support plate and which engages on the support disc and loosely engages through it,
• c) the cover sleeve is one of its displaceability in the longitudinal direction on the holder plate to be limited stop on the locking plate or on the Support disc assigned.

Such a nuclear reactor fuel element is known from WO-A1-93 / 03487.

A holding structure for is located in the reactor core of a pressurized water core reactor such a nuclear reactor fuel element. The nuclear reactor is in this holding structure Fuel element on both a fuel plate forming a holding plate as also held on the other holding plate forming a fuel assembly head. To the Compensation for different thermal expansions of the holding structure in the reactor core on the one hand and the nuclear reactor fuel element in its longitudinal direction on the other hand are usually located on the holding plate forming the fuel assembly head the outside of structures that can be moved against a spring force and on which attacks the holding structure in the reactor core of the pressurized water core reactor.

In the known nuclear reactor fuel element, the compression spring that deals with one end of the spring on the cover sleeve and the other end of the spring on the support  disc supports, reach into the locking plate or even this locking reach through the plate. This compression spring can also be a plate spring, for example with relatively little travel. This means that the bodies on the concern the holding plate can be designed with a relatively low overall height. Des half can with a given holding structure in the reactor core of the pressurized water core reactor the fuel rods of the nuclear reactor fuel element a relatively large length ha ben, so that with the nuclear reactor fuel element a relatively small Power density in the reactor core results. This relatively low performance density means a relatively low temperature on the outer surface of the fuel rods so that boiling on the outer surface of these fuel rods is safe can be avoided. Therefore, the fuel rods on the outer surface ih As a rule, cladding tubes consisting of a zirconium alloy also a ver relatively little corrosion and hydrogen took so that the nuclear reactor fuel element has a relatively long service life in a pressurized water nuclear reactor.

In the known nuclear reactor fuel element, the implementation is in the holding plate an elongated hole. At one end of the longest diameter of this elongated hole is the holding rod, the radial holding lug at this end on the outside side of the holding plate rests.

To release the holding plate from the holding tube, use a tool between the Holding plate and the locking plate gripped and the distance between the Holding plate and the locking plate enlarged until the end of the holding tubes with the outside retaining lug from the locking plate in the direction the longitudinal axis of the nuclear reactor fuel element is pulled out. The whole Fuel element head with the holding plate, the locking plate and the support plate be, which are connected by the tie rod, is then transverse to Retaining tube moves until this retaining tube is in the slot from one end of the longest Diameter is moved to the other end. At this other end, the Example the cross section of the elongated hole should be so large that the end of the holding tube with the outside retaining lug moved through the slot and the Fuel element head with the holding plate are lifted off this pipe end can.

Moving the support tube from one end of the longest diameter of the Elongated hole to the other represents a movement transverse to the longitudinal axis of the  Nuclear reactor fuel element for which there is sufficient space when dismantling and Reassembly of the nuclear reactor fuel element in the irradiated state is required.

The invention is based, such disassembly and re-task to allow assembly even when transverse to such a movement There is no space along the longitudinal axis of the nuclear reactor fuel element. This can lead to Example in a compact storage rack for irradiated nuclear reactor fuel elements should be the case, since such compactly designed storage racks only have very narrow storage shafts for the nuclear reactor fuel elements.

To solve this problem, a nuclear reactor fuel element is mentioned at the beginning ten kind according to the invention, characterized in that the radial retaining lug on the Bears inside of the holding plate and that the compression spring by means of the cover sleeve one end of a tongue extending in the longitudinal direction of the cover sleeve under Forming a frictional connection between the holding plate and the holding rod on the Outside of the holding plate in the passage in the holding plate between the Holding plate and the holding rod presses.

Is in this nuclear reactor fuel element with the tool between the stops plate and the locking plate gripped and the distance between them parts enlarged, the locking plate is pulled off the tongue, and then the cover sleeve lies against the stop points on the lock gelungsplatte on, so that the tongue from the implementation in the holding plate under Release the frictional connection between the holding plate and the holding rod is pulled. Finally, the holding plate in the direction of the longitudinal axis of the holding can be subtracted from this holding rod without moving transversely this longitudinal axis is required.

The claims 2 to 12 are advantageous developments of this core reactor fuel element directed.

The invention and its advantages are based on the drawing of an embodiment Example explained in more detail:

Fig. 1 shows a highly schematic and side view of a core reactor fuel element according to the invention.

FIG. 2 shows the nuclear reactor fuel element according to FIG. 1 in longitudinal section.

FIG. 3 shows an enlarged detail III from FIG. 2.

FIG. 4 shows an enlarged detail IV from FIG. 2.

Fig. 5 shows the detail III in a changed position of individual parts.

The nuclear reactor fuel element according to FIG. 1 is be for a pressurized water reactor is right and has a fuel assembly 2 and a fuel element head 3, the Ab was from one another. The fuel assembly base 2 has a holding plate 4 and the fuel assembly head 3 has a holding plate 5 . The holding plates 4 and 5 are parallel to each other. Between their insides there are fuel-filled fuel rods, of which a single fuel rod 6 is shown. This fuel rod 6 is parallel to the longitudinal axis 7 of the nuclear reactor fuel element. Its rod ends are each Weil distance from the holding plate 4 and the holding plate 5 , to which the longitudinal axis 7 of the nuclear reactor fuel element is rectangular.

Two to the longitudinal axis 7 of the nuclear reactor fuel element also parallel, designed as control rod guide tubes support rods 8 a and 8 b have a longitudinal axis which penetrates the holding plate 4 of the fuel element base 2 and the holding plate 5 of the fuel element head 3 at right angles. At one end, the holding rods 8 a and 8 b are held on the fuel assembly base 2 and at the other end on the fuel assembly head 3 .

Between the inner sides of the holding plates 4 and 5 are located in cross-sectional planes of the nuclear reactor fuel element in the direction of the longitudinal axis 7 of the nuclear reactor fuel element viewed at a distance from one another grid-shaped spacers 29 , which are shown schematically in FIG. 1. Each of the two holding rods 8 a and 8 b is guided through a mesh of the grid-shaped spacer 29 , which is not recognizable, and these grid-shaped spacers 29 are positively held on at least one of the holding rods 8 a and 8 b. The fuel rod 6 , on the other hand, is guided through another mesh of the grid-shaped spacer 29, which is likewise not recognizable, and in each mesh in this mesh with the aid of a radially acting spring which is located in the mesh on a mesh wall and the fuel rod 6 against two, likewise in the mesh on two rigid knobs located on other mesh walls presses, non-positively held.

As shown in Fig. 2, in the same parts with the same reference numerals in Fig. 1 see ver, the two support rods 8 a and 8 b are at one end, at which they each have an opening with a small cross section, on the holding plate. 4 the fuel assembly base 2 screwed tight.

The fuel assembly 3 not only has the holding plate 5 , but on the outside of the holding plate 5 an overlying locking plate 9 on this outside.

With the other, open end, the holding rods 8 a and 8 b pass through the holding plate 5 in a bushing 10 . There, these two holding rods 8 a and 8 b each have an outer flange 11 a and 11 b, each representing a radial holding lug, on the inside of the holding plate 5 .

On the outside of the holding plate 5 facing the underside of the locking plate 9 sockets 12 a and 12 b are formed, in the parallel to the longitudinal axis 7 bushings 13 a and 13 b in the holding plate 5 . Furthermore, a on the inside of the holding plate 5 is supported, parallel to the longitudinal axis 7 of the nuclear reactor fuel element parallel tie rod 14 is provided, which is attached to the holding plate 5 and the locking plate 9 and a locking plate 9 located Liche 15 engages loosely. On the abge of the locking plate 9 facing the top of this support plate 15 , a nut 14 a is screwed onto the tie rod 14 , which abuts the support plate 15 . The support plate 15 is also provided with a closed collar 15 a, with which this support plate 15 loosely overlaps the one tel surface of the locking plate 9 . So that the support plate 15 is guided by the locking plate 9 .

Outside on the lateral surfaces of the holding rods 8 a and 8 b there is an annular recess 111 a and 111 b, respectively, forming an annular bead 112 a and 112 b at the end of the holding tube 8 a and 8 b. The bead 112 a or 112 b is located within the bushings 12 a or 12 b, but fits through the respective bushing 10 in the holding plate 5 .

Inside the bush 12 a and the duct 13 a in the locking plate 9 is further guided to a holding rod 8 a coaxial open at both ends 16 a covering sleeve in its longitudinal direction. This cover sleeve 16 a engages loosely through the support plate 15 and presses two in the longitudinal direction of the cover sleeve 16 a he extending tongues 212 a with the formation of a frictional connection between the holding plate 5 and the holding rod 8 a on the outside of the holding plate 5 in the guide 10 in the holding plate 5 between the holding plate 5 and the holding rod 8 a. For this purpose, a compression spring 17 a encloses the cover sleeve 16 a and is supported at one end on the locking plate 9 facing the bottom of the support plate 15 and with the other end on the outer flange 18 a on the outside of the cover sleeve 16 a . The two tongues 212 a are advantageously formed on one end of the cover sleeve 16 a.

Within the implementation 13 a in the locking plate 9 , a shoulder 19 a is formed at a stop for the outer flange 18 a of the cover sleeve 16 a. This stop point formed from the shoulder 19 a limits the displaceability of the cover sleeve 16 a in its longitudinal direction to the holding plate 5 .

The tongues 212 a each have a first sliding bevel 312 a, each of which is located in a ring sector with respect to the longitudinal axis of the cover sleeve 16 a and is associated with an annular sliding bevel 412 a on the bead 112 a. Both sliding slopes 312 a and 412 a are aligned. Furthermore, the tongues 212 a in a ring sector have a second sliding bevel 512 a, which is associated with a further annular sliding bevel 612 a on the bead 112 a. The Abgleitschrä gene 612 a and 512 a are rectified.

As shown particularly in FIGS. 3 and 4 clearly show, the edge on the through guide 10 in the support plate 5 on the outer side of the holding plate 5 is a slope-shaped ringför 51st The end of the tongues 212 a also has an annular bevel 213 a, which is assigned to the bevel 51 at the edge of the passage 10 and which is oriented in the same way as this bevel 51 .

The tongues 212 a engage in the annular recess 111 a and there within the bushing 10 between the holding plate 5 and the holding rod 8 a. This Zun gen 212 a are curved about the longitudinal axis of the covering 16 a and lie flush against both the outer surface of the support rod 8 a and at the bevel 51 on the edge of the bushing 10 that the tabs 212 a to form a force fit firmly against presses the holding rod 8 a. Furthermore, the tongues 212 a are guided with little play on the outside of the bead 112 a and on the inside of the socket 12 a.

If a force occurs that acts in the longitudinal direction of the holding rod 8 a away from the socket 12 a and the holding force of the frictional connection between the tongues 212 a on the one hand and the holding rod 8 a on the other hand, then after a short stroke movement of the bead 112 a on the holding rod 8 a engaging part of the tongues 212 a with the bevel 312 on the bevel 412 a to form a positive fit, so that the holding rod 8 a is not separated from the socket 12 a.

In a manner similar to that of the holding rod 8 a, the outer flange 11 b of the holding rod 8 b that forms the holding lug lies against the inside of the holding plate 5 , as FIG. 4 shows particularly clearly. The holding rod 8 b is also guided through a guide 10 in the holding plate 5 . Within the socket 12 b, into which the guide 13 b passes into the locking plate 9 , similar to the cover sleeve 16 a in the bushing 13 a, another cover sleeve 16 b open at both ends is slidably arranged in its longitudinal direction, which is coaxial with Holding rod 8 b is and at one end two tongues 212 a corresponding tongues 212 b each with one of the bevels 51 on the edge of the bushing 10 assigned counter bevel 213 b which engage in an annular recess 111 b on the outside of the holding rod 8 b and there, under the action of a further compression spring 17 b, cause frictional engagement with the holding rod 8 b. These tongues 212 b also engage behind a bead 112 b corresponding to the bead 112 a on the outside at the end of the holding rod 8 b.

The cover sleeve 16 b has the outside also the outer flange 18 a of the Ab-covering sleeve 16 a corresponding outer flange 18 b, and one of the stop school ter 19 a corresponding stop shoulder 19 b of this outer flange 18b is located in the duct 13 b in the locking plate 13 .

While the cover sleeve 16 b with one end with the tongues 212 b as the tong gene 212 a engages in the passage 10 between the holding plate 5 and the holding rod 8 b, this cover sleeve 16 b has at the other end outside a coaxial, displaceable in the axial direction engages cap sleeve 20, which loosely, the supporting plate 15 and by the disc of the locking plate 9 facing bottom of this support 15 having an outer flange 21 engages behind. On this outer flange 21 is also supported one end of the cover sleeve 16 b, from egg ner coil spring compression spring 17 b, the other end of which is supported on the outer flange 18 b of the cover sleeve 16 b.

Finally, in order to avoid a double fit of the holding tubes 8 a and 8 b to the holding plate 5 , an additional compression spring 23 consisting of a helical spring is provided, which has one end in a recess on the underside of the support disk 15 and the other end in a recess the top of the locking plate 9 supports. This compression spring 23 can also enclose a cover sleeve together with the associated compression spring.

The compression springs 17 a, 17 b and 23 advantageously consist of a nickel base alloy with the trade name "Inconel 718". This "Inconel 718" has the following alloy composition: 50 to 55% by weight of Ni, 17 to 21% by weight of Cr, 2.8 to 3.3% by weight of Mo, 4.75 to 5.5% by weight of Nb + Ta, 0.65 to 1.15 Ti, 0.2 to 0.8% by weight Al, maximum 0.08% by weight C, maximum 0.1% by weight Co, maximum 0.006% by weight B, maximum 0.35% by weight Mn, maximum 0.35% by weight Si , maximum 0.3% by weight Cu, maximum 0.015% by weight P, maximum 0.015% by weight S and the rest Fe. A coil spring made of this alloy can be made particularly short and with a special small diameter.

The support plate 15 can be moved against the spring forces of the compression springs 17 a, 17 b and 23 on the holding plate 5 , so that the support structure in the reactor core of a pressurized water core reactor can easily attack this support plate, in which the nuclear reactor fuel element on the fuel element base 2 and on the Brennele mentkopf 3 is supported.

To release the holding plate 5 from the holding tubes 8 a and 8 b is gripped with a work tool between the holding plate 5 and the locking plate 9 and the distance between the holding plate 5 and the locking plate 9 is increased. In this case, who initially deducted the sockets 12 a and 12 b in the direction of the longitudinal axis 7 of the nuclear core fuel element from the ends of the tongues 212 a and 212 b. Then the flanges 18 a and 18 b abut against the stop shoulders 19 a and 19 b, and the distance between the cover sleeves 16 a and 16 b from the holding rod 8 a and 8 b is increased. The ends of the tongues 212 a and 212 b are thereby pulled out of the guides 10 in the holding plate 5 . Now these tongues can spread radially outwards and slide over the bead 112 a or 112 b outside on the control rod guide tube 8 a or 8 b. Finally, the position shown in FIG. 5 for the cover sleeve 16 a with the tongues 212 a is reached, in which the holding plate 5 can be removed from the ends of the holding rods 8 a and 8 b with the annular bead 112 a or 112 b. A corresponding position but not shown 5, Fig. 16 b also has the cover sleeve with the tongues 212 b achieved.

To assemble the fuel assembly head 3 , proceed in the opposite order, that is, the holding plate 5 is pushed with its bushings 10 over the ends of the holding rods 8 a and 8 b. The ends of the tongues 212 a and 212 b are under the action of the compression springs 17 a and 17 b outside the book sen 12 a and 12 b and therefore slide with radial expansion on the beads 112 a and 112 b, finally grab in the annular recesses 111 a and 111 b on the holding rod 8 a and 8 b and finally in the bushings 10 between the holding plate 5 and the holding rod 8 a and 8 b. Finally, the bushings 12 a and 12 b are pushed as far as possible on the outside of the holding plate 5 over the ends of the tongues 212 a and 212 b, so that a frictional connection between these ends of the tongues to a 212 a and 212 b and the Holding rod 8 a and 8 b is produced. So that the fuel assembly 3 sits firmly at the ends of the support rods 8 a and 8 b.

Through the cover sleeves 16 a and 16 b, a control rod can be inserted into the holding tube 8 a or 8 b in a pressurized water core reactor from the support disk 15 , who belongs to a control element. The union nut 20 can catch the falling control element when the pressurized water reactor is switched off quickly.

Claims (12)

1. Nuclear reactor fuel element with two holding plates ( 4 , 5 ) and one on both Hal teplatten ( 4 , 5 ) held holding rod ( 8 a, 8 b), the longitudinal axis of which penetrates both holding plates ( 4 , 5 ) at right angles and that at one end of the rod which it grips through a bushing ( 10 ) in a holding plate ( 5 ) from an inside of the holding plate ( 5 ), has a radial holding lug ( 11 a, 11 b) on the outside, and has an on an outside of the holding plate ( 5 ) located locking plate ( 9 ) in which a to the holding rod ( 8 a, 8 b) coaxial cover sleeve ( 16 a, 16 b) in its longitudinal direction is slidable, which has the following features:

• a) The cover sleeve ( 16 a, 16 b) loosely engages in a support disc ( 15 ) arranged above the locking plate ( 9 ),
• b) the cover sleeve ( 16 a, 16 b) has a compression spring ( 17 a, 17 b) which is supported with one spring end on the cover sleeve ( 16 a, 16 b) and with the other spring end on the support disk ( 15 ) and is prestressed by a tie rod ( 14 ) which is fastened to the holding plate ( 5 ) and which engages on the support disc ( 15 ) and loosely engages through it,
• c) the cover sleeve ( 16 a, 17 a) is assigned a stop point ( 19 a, 19 b) on the locking plate ( 9 ) or on the support plate ( 15 ) to be limited in the longitudinal direction on the holding plate ( 5 ),

characterized,
that the radial retaining lug ( 11 a, 11 b) rests on the inside of the holding plate ( 5 ) and that the compression spring ( 17 a, 17 b) by means of the cover sleeve ( 16 a, 16 b) one end of a in the longitudinal direction of the cover sleeve ( 16 a, 16 b) extending tongue ( 212 a, 212 b) forming a non-positive connection between the holding plate ( 5 ) and the holding rod ( 8 a, 8 b) on the outside of the holding plate ( 5 ) in the passage ( 10 ) in the holding plate ( 5 ) between the holding plate ( 5 ) and the holding rod ( 8 a, 8 b) presses. 2. Nuclear reactor fuel element according to claim 1, characterized in that the edge of the bushing ( 10 ) on the outside of the holding plate ( 5 ) has a slope ( 51 ) and the end of the tongue ( 212 a, 212 b) outside one of these slopes ( 51 ) have assigned counter bevels ( 213 a, 213 b). 3. Nuclear reactor fuel element according to claim 1, characterized in that the tongue ( 212 a, 212 b) engages a bead ( 112 a, 112 b) outside at the end of the holding rod ( 8 a, 8 b). 4. Nuclear reactor fuel element according to claim 3, characterized in that the tongue ( 212 a, 212 b) engages in a recess ( 111 a, 111 b) on the outside of the holding rod ( 8 a, 8 b). 5. Nuclear reactor fuel element according to claim 3, characterized in that the tongue ( 212 a, 212 b) has a sliding slope for the bead ( 112 a, 112 b). 6. Nuclear reactor fuel element according to claim 3, characterized in that the bead ( 112 a, 112 b) has at least one sliding slope ( 312 a, 512 a; 312 b, 512 b) for the tongue ( 212 a, 212 b). 7. Nuclear reactor fuel element according to claim 1, characterized in that an additional compression spring ( 23 ) is provided which is between the support disc ( 15 ) and the locking plate ( 9 ) with a spring end on the support disc ( 15 ) and with the other spring end on the locking plate ( 9 ) supports. 8. Nuclear reactor fuel element according to claim 1, characterized in that the cover sleeve ( 16 b) on the outside has a coaxial, in the longitudinal direction of the cover sleeve ( 16 b) displaceable union sleeve ( 20 ) which loosely engages through the support disc ( 15 ) which the the locking plate ( 9 ) facing underside of this support disc ( 15 ) and on which the cover sleeve ( 16 b) associated compression spring ( 17 b) is supported with a spring end. 9. Nuclear reactor fuel element according to claim 1, characterized in that the support disc ( 15 ) loosely engages over the outer surface of the locking plate ( 9 ) with a collar ( 15 a). 10. Nuclear reactor fuel element according to claim 1, characterized in that the compression spring ( 17 a, 17 b) consists of a nickel-based alloy, preferably of the nickel-based alloy Inconel 718. 11. Nuclear reactor fuel element according to claim 7, characterized in that the additional compression spring ( 23 ) consists of a nickel-based alloy, preferably of the nickel-based alloy Inconel 718.