DE1614916B2 - GAS-COOLED, GRAPHITE MODERATED NUCLEAR REACTOR - Google Patents

Description

The invention relates to a gas-cooled, graphite-moderated nuclear reactor with a concrete pressure vessel and standpipes for fuel feed passing through a wall of the pressure vessel pass through, each standpipe is attached to at least one further standpipe that one Axial movement between them is counteracted.

Such a nuclear reactor is known from GB-PS 9 66 409, for example.

Modern nuclear power plants of the AGR type have an access pipe for each fuel element channel, what the fuel feed compared to previous reactors, e.g. of the Magnox type, in which a single access tube was provided for a plurality of fuel element channels, simplified and accelerated. Each access pipe is formed at least in part from a standpipe which extends extends through the upper end of the concrete tank and at its upper end over the outer one Surface of the container ends, which forms the loading surface of the reactor. The top of each Standpipe is closed with a biological shielding plug while the reactor is in operation forms part of a fuel element component group and is removed when the component group is removed and after the insertion of a new fuel element component group is brought back into its place. So that the biological shielding plug in the standpipe can be locked in the sealing position during normal operation, the upper end portion of each standpipe has a larger diameter than the lower portions, and it is attached in the lower areas. Furthermore, for manufacturing reasons, the lower areas of each standpipe can consist of two or more sections that are attached to each other. So each standpipe can have at least three sections that go through Butt welds are connected.

The upper end piece of the concrete container is built up when the welded standpipes are in their correct grid positions. Due to the fact that a standpipe for each fuel element channel is present in the reactor core, the standpipes are arranged close together, and that Putting concrete mortar between the standpipes - with the added complication of its presence of prestressing tendons, cooling pipes for the standpipes and possibly casing pipes for the Standpipes - is a process that presents some difficulties. In case pouring concrete and be subsequent compaction is not carried out with great care, it is possible that a butt weld seam of the standpipe can be damaged by the fact that it is

J5 processing tool receives a blow. the Weld damage is then likely of the kind showing local weakening rather than total Rupture caused. Once the concrete has hardened in place, it is no longer possible to To carry out weld seam tests.

The consequences of a local weakening in a standpipe butt weld can be such that when a large temporary shear force s * acts on the standpipes, for example when ν seismic disturbances occur, the local weakening spreads and the entire weld is destroyed. Then, if the surface adhesion between the concrete and the standpipe is insufficient ^{to withstand the internal pressure (e.g. about 42 kg / cm 2} ) in the container, or if the destroyed weld is sufficiently close to the outer surface of the concrete, so could that the remaining thickness of the same is not sufficient to withstand the shear force resulting from the internal pressure in the container, the upper broken section of the standpipe are thrown up into the loading area areas and cause injuries to staff and damage to facilities.

The invention is based on the task of reducing the risk of the standpipe or one being thrown out Avoid fragments of the same.

This is achieved according to the invention in that each standpipe is a section of reduced outer diameter has where it emerges from the wall in such a way that an outer shoulder is formed, that a perforated plate is placed on the outside of the wall, each plate at least two holes, each of which accepts a corresponding standpipe, as well as a retaining ring has an inner diameter that matches the reduced outer diameter of the standpipe and below outwardly protruding approaches on the standpipe engages, and that each retaining ring on the underlying Plate is attached.

Each standpipe is expediently attached to three adjacent standpipes.

The invention will now be described with reference to the drawing showing it as an example, namely shows

F i g. 1 is a partial side view in section along line I-I the F i g. 2 while

Fig.2 shows a plan view of Fig. 1, wherein For the sake of clarity, a section has been omitted.

According to the embodiment shown, with a gas-cooled graphic-moderated nuclear reactor a plurality of standpipes 1 are provided in square grids in a concrete pressure vessel (where in

the drawing shows a complete grid of four tubes, while the complete reactor loading area consists of a multiple of the grid shown), and each standpipe consists of at least two sections as shown. The upper section 2 forms a section with an enlarged inner diameter for accommodating the sealing plug of a biological shield and sealing plug unit, together with the sealing and locking means of the sealing plug. Part 3 of the sealing plug is in Fig. 1 reproduced. The upper section 2 of each standpipe 1 is at 4 with the lower standpipe section 5 butt welded. More standpipe parts (not shown) can with each other and with the Part 5 be butt-welded below the part shown in the drawing.

Each section 5 of the standpipes 1 has several (in the drawing only two are shown) push or Shear flanges 6, which are integral with the section 5 are formed, or has a plurality of shear rings which are firmly welded to the section 5.

The standpipes 1 extend upward through openings 7 in the wall 8 of the upper end piece of a Concrete pressure vessel through which the reactor core (not shown) contains. The openings 7 arise during the manufacture of the upper end piece of the pressure vessel by adding concrete in layers the standpipes are poured around and compacted, with the latter in their correct grid positions are arranged. So the shear flanges 6 or rings are used during the construction of the top end of the Embedded in the concrete. If casing pipes or support pipes close during concrete pouring are used, these will be in sections under, between and over the shear flanges 6 or rings intended. The upper ends of the standpipes 1 extend over the upper surface of the concrete wall 8 so that they are accessible to a fuel coating machine (not shown) of the reactor. A removable cover 9 is for keeping foreign matter away from the standpipes and sealing plugs provided when there is no fuel coating. For the sake of clarity, the cover 9 has been shown in FIG Fig. 2 omitted.

Each grid of the four standpipes has a device that connects the standpipes to one another attached that a relative axial movement is prevented. This facility consists of a square Plate 10 with four holes 11 that fit over the four standpipes, from a retaining ring 12 for each Standpipe 1 and four integrally molded lugs 13 on each standpipe, each in a radial Direction away from the periphery of the standpipe and extend evenly at intervals of 90 ° around these are arranged around. Each retaining ring 12 has four slots 14 in its inner wall, the size of which and the distance from one another are selected such that the rings 12 can be placed on the standpipes 1 and approaches 13 can happen. The plate 10 also has slots 15 in each of its holes 11, similarly the slots 14 of the rings 12. The plate 10 is arranged on top of the concrete wall 8 and has leveling screws 16 (Fig. 2), partly to compensate for any local irregularities in the level of the wall 8 and partly for a purpose that will be described below. The slots 15 in the holes 11 of the Plate 10 let this pass the approaches 13 when inserted from above. A retaining ring 12 is then placed on each standpipe 1, the slots 14 allowing each ring to pass the lugs 13. Each ring is then rotated by approximately 45 ° so that the parts of the ring 12 that are not grooved under the lugs 13 grab and hold the plate 10 in place. The retaining rings 12 are each in their shut-off Position held by means of an adjusting screw 17 which is screwed into a threaded hole 18 in the plate 10. If any looseness between the lugs 13, the rings 12 and the plate 10 can cause this the leveling screws 16 are eliminated.

Should a weld 4 be damaged during work, for example during concrete pouring or -compressing, and should any high shear stress that would be placed on the standpipes thereafter, For example, by an earthquake, tear this weld 4, so the section 2 of the relevant Standpipe, which would be detached from the section 5 of the standpipe if the weld seam 4 breaks, which held against axial movement by wedging by means of the shear flanges 6 or rings with the concrete is prevented from being pushed or ejected out of the pressure vessel, that's because it's using the three other stanchions in the group of four with the help of the just described plate 10, the rings 12 and the lugs 13 is connected. Should one be below on If the weld seam located on the standpipe fails, then together with the wedging by the shear flanges 6 or rings achieve double protection.

The expanded portion 2 of the standpipe 1 forms an annular shoulder 20, which in the case of a Lifting the standpipe 1 after a brief axial displacement on the underside of the retaining ring 12 and thereby prevents a broken standpipe section from being thrown out.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Gas-cooled graphite-moderated nuclear reactor. with a concrete pressure vessel and standpipes for the fuel feed passing through a wall of the pressure vessel, each standpipe is attached to at least one other standpipe so that an axial movement between they are counteracted, characterized by that each standpipe (1) has a section of reduced outer diameter there, where it emerges from the wall (8) such that an outer shoulder (20) is formed, that one with holes provided plate (10) is arranged on the outside of the wall (8), each plate (10) at least two holes (11), each of which receives a corresponding standpipe (1), as well as a retaining ring (12) with an inner diameter that corresponds to the reduced outer diameter of the standpipe (1) fits and engages under outwardly protruding lugs (13) on the standpipe (1), and that each retaining ring (12) is attached to the underlying plate (10). 2. Nuclear reactor according to claim I, characterized in that each standpipe (I) to three adjacent standpipes is attached.