DE2424518C2 - Nuclear reactor plant - Google Patents

Description

The invention relates to a nuclear reactor, in particular a pressurized water reactor, with a support for primary circuit components using pre-tensioned divider springs.

Primary circuit components are to be understood as meaning all parts of the nuclear reactor that carry the reactor coolant. These parts can be arranged in a fixed or displaceable manner, depending on whether they absorb thermal expansions are or not. In pressurized water reactors, for which the invention is primarily in question, are this is the steam generator and the main coolant pumps as well as the reactor pressure vessel itself.

So far, the disc springs should only give way, i.e. a movement of the primary circle components, for enable the case that due to changes in temperature about Längenändeiungen the lines between the reactor pressure vessel and the other primary circuit components or expansion of the primary circuit components are caused in themselves. Such springs are therefore made as soft as possible, so that changes in length are made be balanced without great forces, because it is the task of the resilient support, Avoid reaction forces.

In contrast, the invention is based on a completely different object. It deals with earthquake resistance of nuclear reactor plants. This question is with regard to the operational safety of nuclear power plants also to be investigated in Central European areas, although there only with fractional tremors is calculated from # (= acceleration due to gravity). Soiche In the case of the large masses of the primary circle components, accelerations that are inherently small can certainly be lead to forces with regard to the permanent strength of lines, fittings or components are no longer permitted. This is where the invention is looking for to create a remedy with as little effort as possible.

This is achieved according to the invention in the above-mentioned nuclear reactor plant in that the support comprises two opposite disc spring stacks and that the frictional force in each of the two disc spring stacks is greater than the earthquake force to be expected. The earthquake force is compensated by releasing pre-tensioned disc spring assemblies. This prevents earthquake movements relative to the support in the support direction, but allows displacements due to thermal expansion in directions perpendicular thereto, i.e. a movement of the primary circuit components! in the event that changes in the length of the lines between the reactor pressure vessel and the primary circuit components are caused by temperature changes. Forces that exceed the earthquake forces by more than 100% (GaU forces) overcome the supporting effect of the support, which is limited by the disc springs, and move the component towards the stops provided for this purpose.

Due to the influence of friction, it is a peculiarity of the Telierfederstapel, i.e. layered springs, that the preload force is reduced by a certain amount and practically without the occurrence of spring deflections can be raised again. The ratio of the minimum to the maximum spring force with no spring deflection occurs, lies between a very small value and the value 1 and is determined by the stratification number and given the coefficient of friction. Through a suitable arrangement of such spring stacks, it is possible when To prevent vibrations and relative movements of components in relation to the structure thus also the relative movements of the components with one another. So this is where the earthquake forces become transferred through the support with the help of the frictional force of the disc springs. The components can therefore do not shift against each other, so that the lines running between the components are free from stresses remain. Since the new support structure is in pairs opposite one another on one Component or the support foot is arranged, the compensation of the earthquake forces by practically pathless relaxation of the spring assemblies, which is only possible in one direction, also for the return oscillation direction guaranteed.

To maintain a suitable friction force of ζ. Β 50 000 N should be without an undesirably high spring tension te each stack include at least five disc springs. Several stacks of disc springs can also be used temäßig parallel to each other, for example for the purpose of he small disc spring dimensions or to reduce the effects of a single disc spring breaking.

In the implementation of the invention you can use a support plate before geous, with the game below The spring tension is supported against a base plate and its support width is a multiple of the spring rate knife is. The support plate forms the support for the primary circuit component to be supported.

The pre-tensioning of the disc spring stacks is preferably achieved by pre-tensioning screws, di < Support plate and base plate against the maximum fore

compress the clamping force. The preload may be partially applied by the pre-tensioning screws, while the remaining pre-tensioning takes place by thermal expansion of the component itself or a support foot provided thereon After installing the support, loosen the pre-tensioning screws so that the component or whose support foot is subjected to the pretensioning force.

The span, d. H. the distance between the abutments or guides that run between the support plate and base plate should therefore be a multiple of the diameter of the disc springs, so that lateral forces with simultaneous thermal expansion of the Component transverse to the support direction, for example in the plane of the support plate, does not have excessive moments can exercise the support plate.

It was already said at the beginning that forces in the case of the greatest accident that can be assumed (GaI 'forces) are not from the support, but from special attacks be included. This can still be ensured by means of shear pins with which the base plate is opposite a building enclosing the primary circuit component is supported.

In many cases it can be beneficial between the To arrange support and the component a slider adapted to a gap between the two. In order to is a piece of metal made of a particularly hard and smooth material, in particular made of hardened steel. that forms a sliding surface. The adaptation to dv_n gap. which is present at least in a cold state during installation should be, z. B. advantageously made possible by a wedge shape of the slider, the stepless up to the desired value of the gap can be adjusted. This gap between the slider and a The guide claw of the component should offer a clearance of 0 to about 0.5 mm when cold, depending on the Type of preload chosen. With this play, the support can be built in and, above all, through Loosening the preload screws can be adjusted without taking into account the weight forces that make up hundreds of tons in primary circuit components of reactor systems.

For a more detailed explanation of the invention, an exemplary embodiment is given below with reference to the drawing described. Here shows

1 shows a plan view of a nuclear reactor installation with a pressurized water reactor,

F i g. 2 shows a steam generator on a larger scale in a side view, in

F i g. 3 are details of the support according to the invention drawn in one section on an even larger scale, and the

4 shows a special design of the support.

The nuclear reactor facility is z. B. designed for 1300 MWe. The heat of almost 4,000 MWih required for this is generated in the reactor core, its reactor pressure vessel is denoted by 1. Eight pipe sockets 2 are distributed around the circumference of the reactor pressure vessel 1, which lead to 'ϊο the four steam generators 3 arranged as a primary cooling circuit outside the reactor pressure vessel 1 and the four main feeder pumps 4 in series with these lead, each through pipelines β are connected. For the sake of clarity, there is only one coolant loop 5 with a steam generator 3 and a pump 4 drawn.

The steam generators 3 have, as largely cylindrical, Siahlbehälier with a diameter of 3 to 5 m, heights of 15 to 20 m and weights of about 450 tons. They have to be moveable because the 10 to 20 m long primary pipes 6 heat up from the cold state of the reactor (about 70 C) to operating temperatures of 300 ^c C or more and can expand by several centimeters. The movements of the steam generator 3 caused by this are absorbed by a flexible support 7.

The support 7 is shown with details in particular in FIG. 2 shown, the steam generator 3 in a Side view shows. In the exemplary embodiment, it comprises two support lugs 8 which are of identical design and symmetrical to the connection line 9, called the "hot branch", between the steam generator and the reactor pressure vessel 1 are located. In addition to the support brackets 8, the steam generator 3 is also included a so-called guide claw IO set in a seismic support, which is designated as 11 as a whole is. The claws 8, 10 of the flexible support 7 are around the circumference of the steam generator 3 equally distributed. They are about the same steel structure 14, 15, 16 on the concrete 17 one Structure attached, which as a rigid body, the reactor pressure vessel 1 with the entire primary cooling circuit includes, to which four loops 5 each with a steam generator 3 and a main coolant pump 4 belong.

The guide claw 10 is, as FIG. 2 shows, supported with a loose anchor 19, supported by a tie rod 20 is formed with nuts 21 and 22 at the ends. The pull rod 19 is connected to the from via a tube 23 Sheets 24 composite steel structure 16 supported in concrete 17 so that the lower end 25 of the Pull rod 20 can follow movements of the steam generator 3 transversely to its longitudinal direction.

The lateral freedom of movement is at the guide claw 10 of the steam generator 3 by the so-called seismic support 11. the details of which in F i g. 3 can be seen on a considerably enlarged scale, limited to one direction. The support 11 is symmetrically constructed. It therefore comprises in duplicate a metallic base plate 30 with Brackets 31 and 32 is inserted into the concrete 33 supporting the base plate. Sitting on the base plate 30 a spaced from this support plate whose side facing away from the base plate 30 from the Figure has curved surface 36 visible. On the surface 36 the in FIG. 3 only punctuated Put on guide claw 10 indicated at 37 if a gap 38 / wipe the Surface 36 of the support plate and the guide prat / e 10. the by a wedge-shaped slider 40 in the cold Condition is narrowed to a small play of about 0.5 mm, was closed.

The support plate 35 has several screws guided against lateral forces, the screws are fastened in an intermediate piece 42, which in turn is attached to the base plate 30 with screws 43. The intermediate piece 42 also serves as a Fcderteller fm several distributed over the area of the support plate 35! Stack 45 of disc springs 47, which have a relative b ·. · «« ' supply between the Stützplaltc 35 and the Grunüpkun 30 enable.

The compressibility of the disc springs 47 er leaves i.a. an expansion of the line 9 / between the reactor pressure vessel 1 and the steam cr / cugc

i when heated to the operating temperature of more than 300 ^° C. The frictional force between the individual springs 47 of the plate spring stack 45 is, however, dimensioned so that it is greater than the earthquake forces assumed according to regulations or agreements with accelerations of z. B. 0.1-0.5 g. In the case of a steam generator 3 weighing 450 tons, this means that the frictional force of the plate spring stacks 45 taken together is greater than 45 to 200 tons. For example, a value of 300 tons will be chosen for the Rcibkrafl. This results in the following mode of action:

In normal operation, the line 9 expands, as does the reactor pressure vessel 1 and also the steam generator 3 off when heated. This results in a displacement of the guide claw 10 in the direction of Axis of the line 9 by z. B. 3 centimeters. This shift can be as well as thermal stretching the claw 10 itself received through the gap 38 between the support plate 35 and the intermediate piece 42 will. With further thermal expansions or with the so-called GalJ forces, which e.g. as Radiant force arise when a leak occurs, the disc spring stacks 45 can be compressed, because the relevant forces are a multiple of the aforementioned earthquake forces. Through this thermal expansion results in a slow shift that is not dangerous for the components between the steam generator 3 and the reactor pressure vessel 1. In the case of GaU forces, additional, Not shown stops effective.

If, on the other hand, a shock is exerted on the nuclear power plant during an earthquake, there is no relocation between the reactor pressure vessel 1 and the steam generator 3 is possible because it is to be regarded as rigid Reactor building with the concrete wall 17 of the

ίο Steam generator 3 taken along via the disc spring stack 45 will. Here, the plate spring stacks 45 therefore act as an inelastic, that is to say rigid, support because the frictional force occurring when the disk spring stack moves is greater than the earthquake force. Vice versa expressed the frictional force is not overcome by the occurring earthquake forces, so that the rigid cohesion of the components is guaranteed.

In the embodiment according to FIG. 4 is the base plate 30 of the support U for the claw 10 with Shear pins 52 fastened in a frame 53. The shear pins are designed to be smaller than the GaU forces, so that the support 11 is only effective in the case of earthquake forces while attacks not shown in the GaU case absorb the components with means for limiting tion of the forces are provided.

For this purpose 4 sheets of drawings

Claims (7)

Patent claims: 1. Nuclear reactor, especially pressurized water reactor, with a support for primary circuit components using pre-tensioned disc springs, characterized in that the support (11) has two opposite Includes disc spring stacks (45) and that the frictional force in each of the two disc spring stacks (45) is greater than the expected earthquake force. 2. Nuclear reactor plant according to claim 1, characterized in that each stack (45) at least five plate springs included. 3. Nuclear reactor plant according to claim 1 or 2, characterized in that several stacks (45) are arranged in terms of force parallel to each other. 4. Nuclear reactor plant according to claim 1, 2 or 3, characterized by a support plate (35) with Game is supported under spring tension against a base plate (30) and its support shaft is a multiple of the spring diameter is. 5. Nuclear reactor plant according to claim 4, characterized in that the base plate (30) opposite a building (17) enclosing the primary circuit component is supported via shear pins (52) is. 6. Nuclear reactor plant according to claim 4 or 5, characterized in that between the support plate and the component is arranged in a slider adapted to a gap between the two. 7. Nuclear reactor plant according to claim 4, 5 or 6, characterized in that between the base plate and a screw connection is provided for the support plate.