DE2054394A1 - Gas cooled reactor fuel element - assembled in matrix of cylindrical holes in a graphite sleeve - Google Patents

Abstract

Equi-spaced fins on each fuel pin ensure stability - and a mitred seating face provides vertical support. Gas coolant flows through the annulus formed by the fuel pin and the hole. Vertical stacking and stability of the elements is ensured by a spigot and recess type face on the lower and upper faces of the element respectively. Fuel pin removal is carried out in a dismantling machine which pushes the pins out into guide tubes which in turn releases them to a transport skip. The shielded contaminant requirements for irradiated fuel removal are reduced and the fuel element design reduces handling risks.

Description

Fuel assembly of a nuclear reactor The invention relates to a fuel assembly For a graphite-moderated, gas-cooled, homogeneous atomic actuator, with the fuel Is edngellager in the moderator and the moderator forms a block in which holes are provided for the cooling gas flowing through and a device for exchange of fuel from the moderator block.

Fuel assemblies are known in which a graphite block is used as a moderator is used, which is provided with holes in which fuel is formed from Susse -, - en or Inner KUhL channels is used. Here is the fuel inserted into the cooling gas bores and by a graphite shell opposite the gas channels enveloped.

The disadvantages of the known design are primarily that the graphite block during the preparation of the fuel assemblies destroyed to facilitate the removal of the burned-out fuel. This is so a disadvantage, since in some cases the graphite block still shows no signs of wear shows, or brought with a little rework within the permissible tolerances could be. This disadvantage is caused by the fact that the rigidly inserted Fuel parts can only be separated from the graphite block by mechanical action can.

It is now the object of the invention to place the above Nachzu Avoid and find a solution to the problem of the moderator sheet of the fuel assembly can be used several times.

The object is achieved according to the invention in that the fuel tn cells are arranged, which are oriented in bores and are inserted loosely, with the cells on at least one projection and at least a groove are supported.

An advantageous embodiment of the fuel assembly according to the invention is characterized in that the fuel cells ar. the long side the outer shell are provided.

A device for exchanging the fuel from the fuel assembly it is clear that the fuel assembly is between a Slide support, consisting of one on one Swiveling support frame Bearing lift drive connected with perforated plate and slide as well as drive and one Stamp table, consisting of a stamp die, one over the stamp drive punch connected to the support frame, can be clamped and rotated around an axis of rotation (X) is rotatably mounted in the support frame.

An expanded embodiment of the device is designed in such a way that that guide tubes for the fuel cells are provided on the slide support.

An advantageous embodiment of the device according to the invention is characterized by the guide tubes, which have a smaller cross-sectional area in the overall shell bcan claim as the entirety of the arrangement of the fuel cells in the moderator bleek.

The advantages of the invention are that due to the simple separation of the cells from the moderator block, small transport containers in terms of volume for processing of the fuel can be built, which compared to the previously usual fuel element transport significantly lower weights have to be moved.

It is also advantageous that the cooling pool because of the space saving significantly smaller dimensions in the case of the safety containers or transport containers can have.

Another advantage can be seen in the fact that the residual heat is removed byc / h the reduced mass of the fuel assemblies is easier to cope with, and can thus be discharged, for example, in the cooling pool. So far it was necessary to cool down the fuel assemblies before they are placed in a spent fuel in order to improve the heat balance not to overload this basin.

Another advantage of the subject matter of the invention is to be seen in that in the storage of the spent fuel on the accumulation of a critical Mass no consideration needs to be senonmen, since fuel is separated from the moderator will.

The invention is described in more detail with reference to a drawing, which represents an embodiment of the fuel assembly.

It; shows: Fig.l a plan view of the fuel assembly Fig.2 a Section through the fuel assembly along the line AA, Fig.3 the structure of an individual Fuel cell according to section BB in Fig.2, Fig.4 and 5 a device for exchange the fuel cells.

In Figure 1, the fuel assembly 1 is shown, which through the moderator block 2 and the fuel inserts 3 is formed.

The fuel inserts 3 are inserted into the bores 4, with on the circumference cooling channels 5 are formed, which through the on the fuel inserts 3 arranged strips 6, the circumference of the same, and the cylindrical surface 4 'of the bores 4 can be limited. The gas and the heat can flow through the cooling channels 5 from the fuel inserts 3 and the surrounding parts of the moderator block 2.

The strips i of the fuel insert are even around the circumference vertt? il where one of them, namely the spring 6a, is larger in its right than the other two. The spring 6a is guided in the groove 7 which is in the bore 4 is arranged, the ware 16 of the groove and bar a rotation lock crgc ben. The two other strips 6 lie with their long surface 8 on the cylinder surfaces the hole 4.

In Figure 2 is a section through the moderator block 2 is shown, wherein a fuel insert 3 is likewise arranged in section in one of the bores 4 is. The groove 7 but extends the entire length of the bore 4. At the lower end the bore 4 sid projections 10 are provided, on which the two in the ohe smaller The strips 6 rest with the inclined end face 9 of the same. This will make the Fuel insert supported, the long surface of the tongue 6a on the groove base 17 is present. This results in a three-point support of the fuel inserts in ien Holes 4. The advantage of this arrangement brings, lies in that the fuel cells remain stable in their installation position and vibrations between the cells can be annihilated.

The moderator block 2 is on its outer circumference 11 with a centering strip understand, which is designed in such a way that the opposing shapes on the upper and underside of the cross-section of the moderator block 2 fit into one another. Preferably the procedure i ″ is carried out on the side on which the fuel inserts 9 are introduced a protruding ring 12 is formed this ring 12 is in the opposite of the same Recess 13 inserted on the underside of the overlying block 2, so that a full support is created that is sealed against the flow of cooling gas.

The fuel inserts 3 are assembled from individual cells 14> each individual moderator block 2 carrying the entire load of the fuel inserts 3 wearing. Advantageously, the bottom 19 of the cell 14 can be made concave, so that a stable support wipe the cells 14 is achieved.

In Figure 3 is an embodiment of a single fuel insert 3 shown. For example, the cells 14 can be screwed together as a whole inserted into the bore 4 of the orator block 2. Cell 14 shown here has at its Aussenulnfang 15 the aforementioned strips 6, which at Insertion into the moderator block 2 on the one hand in the groove 7 of the holes 4 engage and on the other hand rest on the projections 10 with the end face 9. However, another embodiment for the cells can also be selected, for example can these be made in one piece or also cooling channels within the Have cell.

The configuration of the moderator block can also be changed, so that, for example, the cooling gas ducts through separate holes in the moderator lock themselves are formed and further bores are arranged to the fuel inserts to record.

In Figure 4, the fuel cell exchange device is shown, the i; l essentially consists of two separate tables, namely slide supports 16 uno stamping table 17, consists. The stamping table 17 is formed by the so-called Stamp die 18 and the associated stamp 19 and the drives 20, 21 on the stamping table 17 is the fuel assembly 1 after being pulled out of the core of a Turned off nuclear reactor.

The slide support 16, which consists of the slide 22, the perforated plate 23 and the drives 24 and 25 exists, is swiveled out and located at this point in time above the fuel assembly 1, the slide suprrt 16 being pivotable on a pin 26 is stored.

For the sake of simplicity, only differentiated between table 17 and support 16.

The pin 26 is on a table 17 and support 16 in sufficient Spacer supporting frame 27 arranged, rotatable about a horizontal axis, which is given by a shaft 28. On the support 16. is a hydraulic piston 29 provided, the stroke of which can be adjusted so that the fuel assembly 1 between Support 16 and table 17 is clamped. The perforated plate arranged on the support 16 22 has bores which are offset in the same way as those in the fuel bundle 1. The perforated plate 22 is displaced in the state shown, so that the holes both in the support 16 and in the perforated plate 22 or closed against each other at least some are blocked.

Guide tubes 30 through which the fuel cells are introduced into the transport sleeve 31. The transport sleeve 31 is below of the rotatable table 17 arranged in an aligned axis, and on a height adjustment 32 attached. The punch 19 can through the bores of the punch die 18 by means of a mechanical pressing device 33, this is moved by the guide column 34, which is fixed on the support frame 27 and the drive 20 of the screw spindle 35 carries, formed.

When emptying, the fuel cell replacement device.

in particular table 17 and support 16, rotated by 1800 about axis X. Then the transport bushing 31 is raised so that the guide tubes 30 up to the inside of the bottom 36 of the same extend.

Figure 5 shows the same device, but in plan view Figure 1, the support 16 is shown in a pivoted position. On the table 17 the fuel core block 1 is parked, the holes 4 with the holes match in the table.

In the swiveled-out part of the fuel cell exchange device the guide tubes 30 are shown in cross section in plan view, with opposite the arrangement of the bores 4 in the fuel assembly 1, the guide tubes 30 in cross section are racked together, so that the distances between the guide tubes 3 rn certain extent compared to the fuel assembly 1 are reduced.

This has the advantage that with orderly filling of the.

Cells in the sleeve 31 a higher degree of filling than in the case of disordered Including the cells in the transport sleeve 31 is achieved * The operation of the The machine is explained in more detail below.

A fuel assembly 1 that came out of the core of the nuclear reactor is placed on the table 17 by means of a crane. The rule rod bore is thereby or the receptacle on the perimeter of the block is used for centering. Of the In this position, Suzport 16 is the same as that in Figure 5 and must then be swiveled, that is, needed in that position where the bores are aligned face.

After fixing this position, the support 16 is by the hydraulic Piston drive 25, 29 pressed against the fuel assembly, so that the block 1 between Support 16 and table 17 is held immovably. Then the rotary drive is activated 27, 28 put into operation and the location of the entire facility including the fuel assembly 1 changed by turning around 1800.

The perforated plate 22 of the support 16 still blocks this tent point the holes of the same, so that the individual cells au; the webs of the perforated plate 22 sit up. Then the transport sleeve 31 is placed on the lifting device 32 placed and raised srweit that the guide tubes 30, which the bushing interior fill in, almost touching the bottom 36 of the bump 31.

Then the perforated plate 22 is moved and the fuel cells slide out of the bores 4 of the fuel assembly 1 under their own weight the perforated plate 22, the slide 23 and the guide tubes 30 in the transport sleeve 31 where they are stacked. With rortschreltender or after filling the transport sleeve 31 this is lowered so that the cells can be moved into the sleeve 31 continue to stop.

But should fuel cells in the holes 4 of the Moderato: '- block 1 be blurred, these are easily removed by the stamp 19, which is from up through the punch die 18 in the table 17, into the bores 4 of the fuel assembly 1 penetrates. The advance of the punch 19 is controlled by the screw spindle drive 20th and 33 to 35 regulated. After the punch 19 has passed through the holes 4 and has transported any remaining fuel assembly cells into the guide tubes 31, it is brought back to its original position. The perforated plate 22 is simultaneously with the resetting of the punch 19 in the position blocking the bores 4 returned.

The block still clamped between table 17 and support 16 becomes then turned back to its original position. For this it is necessary to use the transport sleeve 31 completely lower, so that the guide tubes 30 from the hollow cylinder of the transport bay ' 31 have moved out. The support 16 is now released from the emptied block 1 and pivoted again, after which the block 1 detected and elnr load lifting machine can be transported away.

For special cases, the emptied block 1 in the so-called Emptying position according to Figure 5 are detected by a lifting machine, wherein after lowering the table 17, the support 16 is pivoted.

The transport sleeve 31 is then also in the normal course transported away and after the closure of the same brought into a cooling basin.

The empty moderator block 1 is expediently hot Measure the cell and refill it with fuel cells if there is sufficient dimensional accuracy. This can be done very simply because the block in the installation position can be filled from above. This manipulation can either be done by hand or by large Number of fuel cells done by means of a machine.

Claims (9)

P a t e n t-a n s p r U c h e 9 fuel element for a graphite-moderated, gas-cooled homogeneous Nuclear reactor, where the fuel is stored in the moderator and the moderator forms a block in which bores are provided for the cooling gas flowing through, characterized in that the fuel is arranged in cells (14) which are in Bores (4) are direction-oriented and inserted loosely, the cells (14) are supported on at least one projection (10) and at least one groove (7). 2. Fuel assembly according to claim 1, characterized in that the Fuel cells (14) are provided with strips (6) on the long side of the outer shell (15) are. 3. Fuel assembly according to claim 1, characterized in that the Strips (6) together with the groove t7) and the surface in between (15) the fuel cell (14) and the bore () form a cooling channel (5). 4. Fuel assembly according to claim 1, characterized in that: the Moderator block t2) after removing the fuel cells (14) and measuring the geometric shape is filled with unused fuel cells (14). 5. Device for exchanging the fuel from the moderator block according to claim 1, characterized in that the fuel element (1) between a Slider support (16), consisting of a pivotable on a support frame (27) Bearing lift drive (25,26,29) connected to perforated plate (22) and slider (23) as well as drive (24) and a stamping table (17) consisting of a stamping die (18), one connected to the support frame (27) via the punch drive (20,33,34,35j) Stamp (19), can be clamped and rotated about an axis of rotation (x) in the support frame (27) is stored. 6. Apparatus according to claim 5, characterized in that in f1uchtendr Axherrichtung of the bores (4) of the fuel assembly (1) one at a height adjustment (32) arranged transport sleeve (31) is provided. 7. Apparatus according to claim 5, characterized in that the slide support (16) guide tubes (30) for the fuel cells (14) are provided. 8. Vorrichting according to claim 7, characterized in that the guide @ ears (30) as a whole occupy a smaller cross-sectional area than the whole the arrangement of the fuel cells (14) in the moderator block (1). L e r s e i t e