DE1261606B - Reflector inserted between the thermal shield and the core of an atomic nuclear reactor - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

G21c

German class: 21g-21/20

Number:
File number:
Registration date:
Display day:

S 83855 VIII c / 21 g
February 22, 1963
February 22, 1968

The invention relates to one between the thermal shield and the core of an atomic nuclear reactor Inserted reflector with a cylindrical cavity stacked in layers on top of one another enclosing, from the outside by means of over the entire height of the reflector continuous, vertical rods and elastic components inserted between these and the thermal shield under elastic, in radial direction acting pressure held graphite blocks of circular ring sector-shaped cross-section.

A reflector for nuclear reactors constructed in this way is disclosed in British patent specification 868,677 described. In this reflector, however, the individual graphite blocks lie along their entire length directly to one another, and the overall arrangement is such that the individual blocks under Maintaining the necessary cohesion retain enough freedom of movement that they outward and internal mechanical loads such as the Wigner effect or temperature changes can give way in the course of the reactor operation without being destroyed. requirement for So this construction principle is that around the blocks there is a free space into which they can move can expand. However, such an expansion space cannot be provided in all cases, see above that a reflector structure with such freedom of movement of the individual blocks is not always is applicable.

The German Auslegeschrift 1118 900 describes a reflector structure that takes this aspect into account, in which a change in shape of the Reflector stack is prevented under the influence of internal or external forces. This dimensional stability of the reflector stack is achieved in that the side surfaces of the individual graphite blocks are recessed in such a way that a contact of adjacent blocks in a layer takes place on the side surfaces only along a short strip at the block ends. Such a reflector structure but is associated with a double stress on the block ends, as these on the one hand the absorb forces occurring as a result of its own change in shape and, on the other hand, the forces caused by the Reduction of the effective cross-section must withstand increased surface pressure. Such a one mechanical stress that is already exposed to the greatest thermal and radiation stress However, blocking ends is extremely unfavorable for their service life and thus for that of the entire reflector.

Reflector inserted between the thermal shield and the core of an atomic nuclear reactor

Applicant:

Ste des Forges et Ateliers du Creusot, Paris

Representative:

Dipl.-Ing. R. Beetz

and Dipl.-Ing. K. Lamprecht, patent attorneys,

8000 Munich 22, Steinsdorfstr. 10

Claimed priority:

France March 12, 1962 (890744)

The invention is therefore based on the object of specifying a reflector in which while maintaining the dimensional stability of the entire reflector stack no part of the graphite blocks forming the stack is exposed to impermissible mechanical stress, especially internal ones Ends of these graphite blocks are mechanically relieved at all.

This object is achieved in the above-mentioned reflector in that according to the invention the ends of the blocks facing the enclosed cavity parallel to their horizontal and vertical boundary surfaces extending gaps are provided in such a way that adjacent one another Blocks only outside a circle from one that exceeds the inner diameter of the reflector Touch the diameter.

In a further embodiment of the invention, one can use the side built according to the above principle Reflector through a lower reflector in the form of a flat bottom part made of two layers of cuboid Add graphite blocks whose longitudinal direction differs in one position from that in the other position.

In the drawing, a special embodiment of a reflector according to the invention is illustrated. It shows

1 shows a vertical axial section through the reflector
Fig. 2,

along the section line I-I of the

809 509 / 2S1

3 4

F i g. 2 a plan view of the reflector, in which the layers a, b, c .. .s, t of graphite blocks,

Part broken open and in section along the stepped which form the side reflector 1 are in Section line ΙΙ-Π of FIG. 1 is created in the following way:

F i g. 3 on a larger scale, a section along "Each of these layers consists of a larger section line III-III of FIG. 1, 5 number of blocks Nl, N2 ... Nn, which with their

F i g. 4 shows a section along the section line IV-IV vertical side surfaces r to a rim close to FIG. 3, are joined together, namely in the ray-like

F i g. 5 shows a section along section line V-V of the arrangement as shown in FIG. 2 shows. The graphite F i g. 4. blocks are made from cuboid graphite bars

As the F i g. 1 shows, the side reflector is cut io. A single one of the vertical side surfaces from a hollow cylindrical body 1, which is marked by ra (Fig. 3) is machined in the required oblique direction superimposing a larger number of layers in order to join the roughly ringed α, b, c ... s and t is established. Each of these sector-shaped blocks in the ray-like arrangement layers consists of a larger number of voltages to make possible. In the case of the surface joints, the graphite blocks, which are described below, when two vertical side surfaces are joined together. of the blocks arise, butt surfaces change -ra (in

The side reflector 1 will lie together in the roughly cylindrical two machined surfaces) with a hollow space between the aluminum abutment surfaces rb (which are not machined),
standing reactor vessel 2 and the lateral thermal In the middle part of the lateral reflector

see shield 3 introduced, which consists of a steel jacket 20 between the two thermal insulation 24 form. The lateral reflector 1 rests on a steel ring 4 perpendicular to the outer surfaces / graphite blocks, which in turn extends over supports 5 to the vertical abutment surfaces rb vertical ^a f ^η ϊ " ^ntere \ ^therm i ^sc _f ^he . ^N ₁ ^{S. C} ₊ ^{hiId 6} ™ ^S } ^ai ? ^ab 'circumferential surfaces of a prism with i-prism sides, trimmed. Over several supply lines 8 flows from ^ö 2'

at the bottom cooling air, which by means of the cylindrical ring 25 reduces that into a cylinder with a circular base

gap 9 between the side reflector 1 and the is written.

lateral thermal shield 3 flows through and in the zones of thermal insulation 24 are the

on the upper part of the reflector by lines 10 outer surfaces of the graphite blocks opposite those

exit. the middle, not thermally insulated zone in this way

The bottom part of the reflector 1, which sets the lower 30 back so that the required space for reflector 11 is formed, is obtained by laying the heat insulation on top of one another. The two layers u, ν formed by graphite blocks, the inner end faces of the graphite blocks, which are described to the Reweiter below. The lower reflector vessel 2 are facing, after the Zutor 11 rests on a steel plate 12, which is processed by dismantling each block layer, they are support elements 13 on the lower thermal 35 in a cylindrical surface.
Shield 6 is supported. The blocks of the different layers are in

The graphite of the lower reflector 11 is offset from one another by the circumferential direction, so that a

two covers 14 and 15 thermally insulated, from direct superimposition of vertical butt

which one between the steel plate 12 and the surface in two adjacent layers verthermischen Shield 6 and the other between the 40 is avoided.

upper layer ν and the support plate 16 of the reactor- In each of the layers the graphite blocks are with-

Gef äßes 2 is arranged. each other by cylindrical graphite connecting wedges

In the lower reflector 11 (cf. also Fig. 2) 25 connected or fixed to one another, the zy-

are on the one hand a central passage 17 through which cylindrical recordings 26 are inserted, their a feed line 18 passes through which there are heavy axes in the vertical plane of the connecting surface

res water flows into the reactor vessel 2, two adjacent blocks are on the other,

on the other hand three passages 19 are provided in which the surface contact between the blocks of two

Lines 20 for the drainage of the heavy water of superimposed layers and the contact

lie. The cylindrical annular space 21 to the between two adjacent blocks of the

Flow line 18 is over coming from below cooling 5 ° same layer does not extend over the entire

air lines 7 air supplied. The cooling air flows along the radial length of the blocks.

from here into the space 22 between the lower Re- As the F i g. 3 shows are at the vertical

flektorll and the support plate 16 of the reactor surfaces of the blocks offset gates in front of

vessel 2 and then see into the cylindrical annular space 23 so that between the narrowed inner

between the vessel 2 and the side reflector. 55 ends of the blocks narrow, gap-like intermediate

Two cylindrical thermal insulation 24 are evacuated, for example over a

extend on the one hand at the lower, on the other hand at the upper by thirds of the length of the blocks and from the

catch part of the side reflector provided. internal surfaces go out. This intermediate

The cooling that is provided by the circulation of air in rooms or crevices extends to the receptacles 26

the outer cylindrical annular gap 9 is achieved, 60 of the cylinder wedges 25.

It allows the temperature in the middle height to be maintained. Because of the thermal insulation between the inner ends of these blocks 24, the cooling will occur at the significantly colder slot-like interspaces B (FIG. 4). End parts of the reflector structure are reduced in order to limit the back effects of the Wigner effect given by the slots A and B , the shifting of the beginning of the surface contact between, as is well known, the greater the lower the temperature of the blocks to a diameter D which is wesentperatur. borrowed is larger than the inner diameter of the lateral

5 6

Reflector, leads to a reduction in the radial reflector, the cap screws 38 are each around Stretching of the block layers, loosened by the Wigner a certain amount, so that the pressure, Effect and temperature changes are caused by the disc springs 32 exerted on the rod 27, since the circle in which this contact begins is transferred in one through these to the block layers. Zone lies in which the neutron flux and the tempe- 5 The radial cohesive forces that exist in each rature are already much smaller than on the inner block layer only to a limited number of Circumference of the reflector. On the other hand, spread blocks are exercised gradually on the radial expansions in two directions opposite to one another, the other blocks of the layer over the cylinders, and their effects are little transmitted.

larger than it would be when stretched in a single A certain flexibility that the rods 27

umpteen direction. is peculiar, allows these rods to be accurate at all times

The vertical elongation, which by the slot-like follow the deformations that are in the corresponding

Gaps B is kept small, prevents corresponding generators of the side reflector from entering

that the reflector structure undesirably large deformations,

experiences in its vertical direction. 15 The circumferential angular distance between the bars

In order to prevent radial expansions, 27 is as regular as possible, but taking on which still persist, the cohesion of the presence on the one hand of a diffusion blocks in the different layers in-kolonne, which in a certain direction in one pregnant, are arranged around the lateral reflector space C (see. F i g. 1 and 2), and a number of resilient holding devices on the other hand, the horizontal experimental channels Provisions are provided that are essentially identical to those of the reactor, which are not shown Distances from each other. These must be put together.

On the other hand, holding devices ensure the upright position. The presence of such horizontal experiments

Preserving the shape of the outer surface of the lateral animal ducts can lead to the blocking layers

Reflector, which should remain a surface of rotation, must have 25 different strengths and also the

the axis of which coincides with that of the container 2. certain mutual angular displacements of the

Each of the holding devices consists of blocks of certain layers, so that they are different

a vertical metal rod 27 of rectangular shape the axes of these channels on the one hand in the horizontal

Cross-section, which over the entire height of the lateral contact planes of two superimposed

union reflector extends. The rod is with one 30 of the layers and the other as far as possible in

certain side play (Fig. 3) lie in a vertical groove 28 the vertical planes of contact. To this

inserted, which on the circumference of the reflector structure avoids stronger weakening of the im

is incorporated. The rod 27 lies on the floor area of these channels lying blocks,

this groove on. Furthermore, the mutual angular offset

Each rod 27, on the other hand, is secured by elastic tongues of the blocks of certain layers through the Pressure elements supported from the outside which were influenced by the presence of vertical channels There are vertical distances on the outer circumference that are to be provided in the reflector, for example are (Fig. 1), in order to expand the channels for the production of isotopes, to absorb conditional forces. Here, too, are the vertical planes of contact

Each of these elastic pressure elements contains 40 then placed in such a way that local weaknesses of the one in the inner shell 29 of the concrete casing of the blocks are largely restricted.
Reactor welded threaded nut 30, into which the layers u and ν of the lower reflector 11 legs a socket 31 is screwed, each of which is made up of a relatively long cuboid column of disc springs 32 is used for support. The printing blocks. From one position to the other, the force of the disc springs acts on a plunger 45 blocks in two different directions, which is guided in the socket 31, and is arranged by, either perpendicular to one another or in such a way that this plunger has a pivotable horizontal transfer their longitudinal axes a certain angle mitein-pressure support on the rod 27. Include the pressure others as shown in FIG. 2 shows
The support consists of two support parts 34, 35 connected to one another by a thread The diameter of the position ν is essentially one in the rod 27 and the other in the borrowed greater than that of the position u. The layer b of the seit-pressure stamp33 is embedded (see Fig. 4). Between the borrowed reflector has a correspondingly enlarged side 37 allow the distance between th inner diameter.

the support surface of the disc spring column 32 on the 55 The equally spaced holes Bushing 21 and the outer surface of the rod 27 on 39, through which winches, not shown, are passed set the desired value. The initial grips that support the vessel 2 of the reactor and position of the rod 27 relative to the axis of the reactor - in turn on the bottom 6 of the thermal shield The vessel is rested with the aid of cap screws 38, which are arranged in such a way that their axes are in that go through the rod and in the 60 the two layers of the lower reflector in each case thermal shield are screwed. The vertical contact planes of two neighboring ones Development of the compressive stress of the disc springs 32 takes place blocks.

by means of the support parts 34, 35, whose common In each of the two layers and ν, the Length taking advantage of the connecting blocks of the group of four blocks around the zendenden Thread can be changed so that the 65 tral opening 17 lie around, through four cylindrical Deflection of the springs held the desired initial wedges 40 together and utilized against each other achieved. bars, the arrangement of which is shown in FIG. 2 for the top

When building the individual block layers of the layer ν is shown.

Claims (8)

Patent claims: 1. Reflector inserted between the thermal shield and the core of an atomic nuclear reactor with stacked one on top of the other, enclosing a cylindrical cavity, of outside by means of vertical rods running through the entire height of the reflector and between elastic components inserted into these and the thermal shield under elastic, in radial direction acting pressure held graphite blocks of circular ring sector-shaped Cross section, characterized in that facing the enclosed cavity Ends of the blocks running parallel to their horizontal and vertical interfaces Columns are provided in such a way that adjacent blocks only outside of one another Circle with a diameter exceeding the inner diameter of the reflector. 2. Reflector according to claim 1, characterized in that the cavity-side ends of each Block are narrowed at least along a horizontal and a vertical interface. -3. Reflector according to claim 1 or 2, characterized in that the enclosed Void opposite end of the column between adjacent blocks, only one at a time Block layer penetrating, vertical connecting wedges are inserted. 4. Reflector according to one or more of claims 1 to 3, characterized in that the vertical joints between adjacent blocks of each block layer against those of the immediate overlying or underlying layer are offset. 5. Reflector according to one or more of claims 1 to 4, characterized in that the rods are made of metal and worked into the blocks on the outer edge of the reflector Continuous grooves inserted and over a plurality of horizontal elastic support elements are supported against the thermal shield. 6. Reflector according to one or more of claims 1 to 5, characterized in that the bars have inherent elasticity. 7. Reflector according to one or more of claims 1 to 6, characterized by a Thermal insulation that surrounds the top and bottom of the outer edge of the stack of blocks. 8. Reflector according to one or more of claims 1 to 7, characterized by a Bottom part made of two layers of cuboid graphite blocks, the length of which is in one Position differs from that in the other position. Considered publications:
German Auslegeschrift No. 1118 900;
German patent specification No. 868 677. 1 sheet of drawings 809 509/261 2.68 © Bundesdruckerei Berlin