DE2640918C3 - Arrangement for the heat-flexible storage of a reactor pressure vessel - Google Patents

Description

The invention relates to an arrangement for the heat-flexible storage of a reactor pressure vessel, the is provided with support parts at its lower end Holding parts of an abutment within a gap surrounding the reactor pressure vessel and him axially bracing anti-burst device, the reactor pressure vessel is mounted by means of spiral springs with reinforced end parts, which at one end are attached to the holding parts and at their other end to the support parts of the reactor pressure vessel, that it is due to the axial load of the reactor pressure vessel on train and due to its radial thermal expansion Bending are claimed, according to patent 24 32 011.

In the arrangement according to the main application, the Problem solved, a centering heat-movable storage on the holding parts of the abutment of a To ensure reactor pressure vessel and at the same time high axial bracing forces on the Permit reactor pressure vessel within its bursting protection. In particular, it is heat-movable Storage of the reactor pressure vessel carried out without complex sliding, pin or roller bearings, which at the great forces that occur would be difficult or impossible to control.

The present invention is based on the object, the arrangement according to the main application so further develop that the spiral springs themselves and their anchoring are simplified and special there are favorable loading conditions for the elements mentioned.

According to the invention, the set object is achieved in an arrangement of the type mentioned in the introduction, that the flexible springs are designed as tie rods and with the end parts on the one hand a ". unites the support parts of the reactor pressure vessel force-fit coupled anchor plate and on the other hand to inward to the Attack support parts cantilevered projections of the holding parts.

The advantages that can be achieved with the invention are mainly to be seen in the fact that none of the tie rods transversely need to be used their load direction penetrating fastening screws, but the Tie rods engage behind the anchor plate and the projections. According to a preferred embodiment of the invention are the tie rod expansion bolts circular cross-section, which in corresponding Locating bores of the anchor plate and the projections are threaded. Such expansion screws are Easily produced from rod material with a round cross-section. The reinforced end parts of the tie rods are expediently each attached to a threaded neck screwed nuts formed. According to a development of the invention, the tie rods and associated mounting holes arranged in several mutually offset rows. Let it go on this way accommodate a large number of tie rods that are sufficiently flexible in the lateral direction so that the free radial thermal expansion of the reactor pressure vessel within its suspension is not hindered. According to the main application, according to one embodiment, the holding parts form a box-shaped spring housing approximately U-shaped cross-section. With such a

Execution, it is particularly advantageous if the projections are designed as tapered cantilever beams of the same strength as the U-legs. For assembly, it is particularly advantageous if the holding parts are provided with lateral threaded bores for receiving adjusting screws, which can be brought into engagement with the anchor plate for assembly purposes in such a way that the latter can be radially deflected by -Ar when the reactor pressure vessel is cold, with the tie rod deflecting * whereby the adjusting screws can be brought out of engagement of the anchor plate after the ι ο assembly and the support parts , which shift by + Δγ when the reactor pressure vessel warms up, return the tie rods to their extended position. In this way, have the spiral springs or tie rods in? normal! 5 operating condition of the reactor the most favorable position for its tensile load.

In the following, the invention will be described in greater detail with reference to the drawing showing an exemplary embodiment explained in which shows

F i g. 1 in an elevation cross-sectional view and a section of a reactor pressure vessel with a frame on his lower end suspended by means of an arrangement according to the invention,

F i g. 2 the bearing arrangement according to FIG. 1 - however reversed - enlarged in detail and

3 shows a plan view of the bearing arrangement according to Fig. 2.

According to FIG. 1, the reactor pressure vessel 1, the central axis of which is denoted by la, is provided with support parts 9 at its lower end. These support parts 9 are usually referred to as a stand frame The burst protection surrounding the container I and axially bracing it is stored The burst protection is formed by the biological shield 5 Ljs prestressed concrete with casing part 56 and bottom part 5a and the cover bracing 8, furthermore from the layers 25, 26, 25 ', 26', as will be explained below . The cover bracing 8 consists of pendulum supports 8a distributed over the circumference of the cover Xb , which engage the actual cover Xb via a catch ring Ic and a catch cover Xd and are supported at their other end against a bearing Sb which is attached to inwardly inclined surfaces. The inwardly inclined inclined surfaces 8rs sit on an annular box part 5c, which is connected to the biological shield 5 via the axial tie rods 5d with the interposition of centering elements Se . The actual cover tension, consisting of non-illustrated cap bolts and nuts, is denoted by Ie by which the lid Xb against the flange Xf of the reactor pressure vessel bottom part is pressed, the pendulum supports 8a of the catch ring Ic pivotably mounted (pivot bearing% d) and hydraulically by means of of the actuator 8e can be pivoted into or out of engagement with respect to their bearing surfaces 8f. The space 56 defined by the annular gap 6 is filled by a layer 25 of insulating concrete blocks, which lie directly on the container f and can be stacked and removed for the purpose of repeat testing. Furthermore, the annular space 55 between this insulating concrete layer 25 and the biological shield 5 is filled with a layer 26 made of granular, insulating material, preferably ceramic or coarse-grained gravel, with a sheet metal skin 27 being arranged between the layers 26 and 25, which by means of anchors 27a in the biological shield 5 is anchored. Corresponding layers 25 '(insulating concrete layer) and 26' (fill) are arranged on the bottom side of the container 1 The fillings 26 and 26 'are cooled by blowing in cooling air through the cooling air ducts 28 and 28' With 29 is one of the main cooling air ducts 28 and 28 'cooled One of the main coolant lines is designated by 29, the further explanation of which is not necessary for an understanding of the present invention. The layers 25, 26 are closed on their upper side by a sealing membrane 30 and a retaining ring 31. At 32, a core container suspended from the flange Xf is indicated.

The reactor pressure vessel 1 is mounted on the holding parts 12 of the abutment 13 by means of flexible springs 14 or hung with the spiral springs 14 with their one Endp 14.2 on the support parts 9 of the container 1 so are attached so that they pass through the axia "'* st of the container 1 be subjected to tension and bending due to its radial thermal expansion. The axial load of the Container 1 is given by its weight and by the tensioning forces exerted by the cover 8 be exercised when the container 1 has expanded axially and radially in its (warm) operating state

The flexible springs 14 are designed as tie rods according to the invention and with their reinforced end parts 14.2, 14.1 (see also Figs. 2 and 3) on the one hand on an anchor plate 33 positively coupled to the support parts 9 of the reactor pressure vessel 1 and on the other hand on the inward to the support parts 9 cantilevered projections 12a of the holding parts 12 arranged attacking The bending springs referred to below as tie rods are designed as expansion screws with a circular cross-section and are threaded into corresponding receiving bores 33a of the anchor plate 33 and X2b of the projections 12a. The reinforced end parts 14.1, 14.2 of the tie rods 14 are each provided with nuts 141 screwed onto a threaded neck 140, the upper nuts being provided with slots 142 for attaching screwing tools. In this way, by tightening or loosening the nuts 141, the height of the anchor plate 33 can be adjusted so that all the anchor plates 33 distributed over the circumference are at the same level or tolerance compensation can be made with respect to the frame 9 of the reactor pressure vessel 1 . For this purpose, a polygonal extension 143 is worked on the upper end of the tie rods 14, which is used to attach a tool preventing the tie rods 14 from rotating when the nuts 141 are rotated as mentioned for the purpose of adjustment. The tie rods 14 are provided in the vicinity of their end parts 14.1, 14.2 with reinforcements 144 with which they are axially guided in the bores \ 2b of the projections X2c and 33a of the anchor plate 33. That is, apart from the threaded neck 140 and the reinforcements, the remaining parts of the tie rods 14 are slimmer or turned off.

As Figure 3 shows, in particular, the tie rods 14 and the associated receiving bores X2b of the projections 12a and, accordingly, the hole 33a in the anchor plate 33 in a plurality of mutually versetiWn rows rl, r2 arranged. As can be seen, two rows rl, r2 of tie rods 14 are arranged on both sides of the support parts or stand frame 9,

so that there is a practically symmetrical support. The anchor plate 33, see. Fig. 2, has in Axial direction a considerable cross-section, since strong pressure and shear forces are exerted on them.

The holding parts 12 are as a box-shaped; Spring housing with an approximately U-shaped cross-section educated. It is useful if, as shown, the projections 12a are tapered Cantilever beams of the same strength of the U-legs are formed. These cantilever beams are also due to high Pressure and shear forces are stressed and are accordingly deminished.

The holding parts 12 are provided with lateral threaded bores 12c for receiving adjusting screws 12c /. These can be brought into engagement with the anchor plate 33 for assembly purposes in such a way that the latter can be radially deflected by -Ar when the reactor pressure vessel is cold, with the tie rod 14 deflecting. In Fig. 2 the warm, steady-state operating state of the arrangement is already shown, where a practically symmetrical arrangement is present. If, however, the reactor pressure vessel is still cold, then its stand casing 9 (shown in phantom in FIG. 2) is to be thought of as being radially displaced by the distance -Ar, and, since the reactor is mounted in the cold state, the anchor plates 33 are supported by the Screws 12c / shifted by -Ar each time. After assembly, the screws 12c / are then disengaged from the anchor plate 33. The support parts 9 or stand frame parts, which move by + Ar when the reactor pressure vessel 1 warms up, then guide the anchor plate 33 and with them the tie rods 14 into their positions in FIG. 2, the extended position shown, with the container resting against the layers 25, 25 'and thus providing a so-called zero-travel burst protection in the warm state.

With 34 retaining screws for the retaining parts 12 are also designated, the corresponding holes 12 / "of Pass through holding parts 12 and screw them into threaded blind holes 17a of steel ring 17 (see also FIG. 1) are. The steel ring 17 is anchored to the lower part 5 a of the biological shield 5 via a plate 35. the end F i g. 3 still shows the slight curvature of the support parts 9, which have a small circumferential area paint over each of the reactor pressure vessels.

It can be seen that the arrangement according to the invention is very easy to maintain and assemble, since the Insertion of the tie rods 14 into their bores 12a, 33a, the adjustment of the nuts 141 and the adjusting screws 12c / is possible in a pin-fold manner. The one at the bottom The nuts 141 arranged at the end of the tie rods 14 do not need to be readjusted, as they are unique It is sufficient to unscrew it before or after threading it into the bores 33a. Through the one on the nuts 141 Resting weight including the tensioning forces is a very effective anti-rotation lock caused by frictional engagement given.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Arrangement for the heat-flexible storage of a reactor pressure vessel, which is provided with support elements at its lower end, on holding parts of an abutment within a burst protection surrounding the reactor pressure vessel with a gap and axially bracing Din, wherein the reactor pressure vessel is supported by means of flexible springs with reinforced end parts, soft with their one end is attached to the holding parts and the other end to the support parts of the reactor pressure vessel in such a way that they are subjected to tension by the axial load of the reactor pressure vessel and to bending by its radial thermal expansion, according to patent 2432 011, characterized in that the flexible springs ( 14) are designed as tie rods and the end portions (14.2,14.1) on the one hand to one with the support parts (9) of the reactor Jruckbehälters (1) anchor plate frictionally coupled (33) and secondly projecting and inward joi the supporting parts (9) towards projections ( i2a ) attack the holding parts (12). 2. Arrangement according to claim 1, characterized in that the tie rods (14) are expansion screws of circular cross-section which are threaded into corresponding receiving bores {33a) of the anchor plate (33) and (\ 2b) of the projections (12a). 3. Arrangement according to claim 2, characterized in that the reinforced end parts (14.2,14.1) of the tie rods (1 M each of nuts i 141 screwed onto a threaded neck (14)) are formed. 4. Arrangement according to claim 3, characterized in that at least one end (14.2) of the Tie rods (14) and a polygonal shape (143) are incorporated which is used to attach a tool that prevents the tie rods (14) from rotating, when the nuts (141) are turned for adjustment. 5. Arrangement according to one of claims 1 to 4, characterized in that the tie rods (14) with reinforcements (144) in the vicinity of their end parts (14.2 14.1) in the bores (33a) of the anchor plate (33) and (12i>; the holding parts (12) are axially guided. 6. Arrangement according to one of claims 1 to 5, characterized in that the tie rods (14) and the associated receiving bores (33a, i2b) are arranged in a plurality of mutually offset rows (r \, r2) . 7. Arrangement according to one of claims I to 6 with holding parts which form a box-shaped spring housing approximately U-shaped cross-section, characterized in that the projections (\ 2a) are designed as tapered cantilever beams of the same strength of the U-legs. 8. Arrangement according to one of claims 1 to 7, characterized in that the holding parts (12) are provided with lateral threaded bores [\ 2c) for receiving adjusting screws (12c / J, which with the anchor plate (\ 3) for assembly purposes in such a way Can be brought into engagement that the latter can be radially deflected in the cold state of the reactor pressure vessel (I) by -Ar with bending of the tie rods (14), the adjusting screws (\ 2d) being able to be disengaged from the anchor plate (33) after assembly and the Return the tie rods (14) to their extended position with the support parts (9) displacing + Ar with the reactor pressure vessel warming up.