DE1083945B - Nuclear reactor screen - Google Patents

Description

GERMAN

The invention relates to a screen between a nuclear reactor and a heat exchanger group, which are contained in a common pressure vessel.

In the case of a nuclear reactor steam generation plant, in which the reactor and heat exchanger for the steam generation is present or installed together in a common pressure vessel, a screen must be placed between the reactor and the heat exchangers, which two Has main functions, namely

a) to prevent the activation of the heat exchangers by neutrons from the reactor and

b) To act as a gamma and neutron screen when the reactor is in operation, so that people can work in the area of action or in the vicinity of the reactor, and also as a gamma screen when the reactor is switched off, so that the heat exchangers for the operating personnel are accessible.

While the screen must have its shielding effect on the one hand, it must flow through on the other hand of the coolant without any significant pressure drop from the reactor after the heat exchangers. Placing a set or group of even channels through the screen would do the trick Make shielding ineffective due to the neutrons moving along these channels move. In the case of a series or series of bent or bent channels, the neutron flux blocked or held back, but the umbrella is very thick if sufficient protection is still guaranteed should be, making the channels long, and a significant pressure drop result to have.

These disadvantages are avoided in the screen of the type mentioned in that it is according to the invention has a solid center piece which is at least large enough to accommodate the To shield part of the moderator structure of the reactor containing the fuel elements and from one outer shield ring is surrounded so that partially annular flow paths between the inner piece and the outer ring of the shield arise, and that the partially annular flow paths through a further shielding ring on the heat exchanger side of the screen will experience a diversion.

A practical embodiment of the invention will now be based on the example reproducing it Drawings are explained, namely shows

Fig. 1 is a longitudinal partial section, while

Fig. 2 is a partial cross section along the line II-II of Fig. 1 reproduces.

From the drawing is a double-walled print

Applicant:

United Kingdom

Atomic Energy Authority,

London

Representative: Dipl.-Ing. E. Schubert, patent attorney,
Siegen, Oranienstr. 14th

Claimed priority:
Great Britain 5 July 1957

Herbert Chilvers Knights and Alfred Johnston,

Culcheth, Warrington (UK),

have been named as inventors

boiler 1 can be seen, which contains a gas-cooled reactor structure 2 and a heat exchanger group 3. The heat exchanger group, which consists of preheating, steam and hot steam zones, is shielded from the reactor structure 2 by a shield 4, which has a cylindrical inner piece 5, which is surrounded by an outer shield ring 6, which with the inner piece 5 partially annular coolant flow paths 7 through the shielding structure 4 results. The flow paths 7 overhang on the heat exchanger side of the shielding structure 4 through a further shielding ring 8, while the shielding ring 6 on the reactor side has a widening 9 which is shaped so that it allows a smooth entry of the coolant into the flow paths 7 and a radiation scattering through or via the flow paths 7 in connection with the shielding ring 8.

In detail, the double-walled pressure vessel 1 has an inner and an outer concentric wall 10 and 11, which are separated from one another by an annular gap 12. The inner wall 10 is composed of a number of cylindrical parts 13, each with their ends between the Rings 14 are welded, which act as spacers between the inner and outer walls 10 and 11. The rings 14 extend through the annular space 12, are at their edges the outer wall 11 is welded and provided with holes to allow the coolant to flow through

009 547/335

to enable the annular gap 12. Circumferential reinforcement struts 15 and longitudinal wedges or rails 16 are welded to the outer shell 11. A main support 18 has welded to it grooved support components 17 which hold the pressure vessel 1 by means of the longitudinal wedges 16. the Longitudinal wedges 16 are in operative connection with the grooves 19 of the support components 17.

The grooves 19 are provided with insert sheet metal shims 21 which are held in place by bolts or screw bolts 20 are laid out or fitted. Longitudinal movements of the pressure vessel 1 are made possible by sliding the wedges 16 in FIG the Abstützungsbaüteile 17 possible, while a radial thermal expansion of the pressure vessel 1 by the clearance 48 between the wedges 16 and the support members 17 is guaranteed.

The shield structure 4 is installed within a cylindrical mild steel housing 22, which stored concentrically within the pressure vessel 1 and held from the wall 10 at a distance to to give an annular gap 23. Between mild steel end plates 24, which within the Housing 22 are welded, Hegen alternating layers of graphite and boron steel 25 and 26, such, that the graphite layers 25 in the direction from the reactor to the heat exchanger of the shielding structure decrease in thickness and the steel layers 26 increase in thickness in this direction.

In the inner piece 5 of the shielding structure 4, the graphite layers 25 are composed of square graphite blocks 27 together, while in the annular shielding ring 6 the graphite layers 25 made of graphite blocks 28 are composed, which have a partially annular cross-section (see. Fig. 2, from which the graphite layer 25 can be seen in a cross section along the line II-II in FIG. 1). the Steel layers 26, which are continuously welded and plate-shaped, extend through or over the entire area of the housing 22 and are pierced to the steady course of the coolant flow paths 7, which in the graphite layers 25 between the graphite blocks 27 and 28 run. The eight coolant flow paths 7 have mild steel linings 29 which extend between the end plates 24 and have their ends welded thereto. Each graphite layer 25 is fastened between two adjacent steel layers 26 by bolts 30; the last is an exception Graphite layer 25 on the heat exchanger side, which is secured by bolts 31 between the steel layer 26 and the end plate 24 is attached.

The shielding ring 8 has a shaped ring made of steel 32 and a composite graphite ring 33 on, which consists of an outer ring of partially annular graphite blocks 34 and an inner ring of smaller graphite blocks 35, also of a partially annular cross-section, composed. The graphite ring 33 is in a composite steel housing 36, which has two mild steel face plates 37, also Mold rings made of mild steel 38, which are welded with their edges to the end plates 37, and one Lining ring 39 made of mild steel, which is welded or seam-welded to the rings 38 in a seam-like manner is.

The extension 9 of the shielding ring 6 has a steel-lined ring of graphite plates 40 and a continuously welded steel ring 41. The expansion ^ and the shielding ring 8 are within the housing 22 by anchors screws 42 running longitudinally through the shield structure 4 run, held in their position. The anchor bolts 42 also serve to a To hold circular sieve or grid 43, which defines the limit or end position of the reactor structure 2.

The shielding structure 4 is held within the pressure vessel 1 by radial wedges 45, which in turn are held between the inner and outer walls 10 and 11 of the pressure vessel 1 and with longitudinal wedges 46 of the shielding structure 4 are in operative connection. A longitudinal movement of the shield structure 4 within the pressure vessel 1 is supported by brackets or locking devices 49, which with the inner wall 10 of the pressure vessel 1 are bolted, prevented.

In the operating state, the gaseous coolant flows, which was heated as it flowed through the reactor construction 2, through the shielding structure 4 through flow paths 7 (as in Fig. 1 is reproduced by the arrows 44) to the

^; Heat exchanger group 3. After the heat has been released, the coolant flows from the heat exchanger 3 back to the reactor structure 2 through the annular space 12 between the inner and outer walls 10 and 11 of the pressure vessel 1 and through the annular space 23 between the pressure vessel 1 and the shielding device 4 ( as shown in Fig. 1 by the arrows 47).
The shield structure 4 prevents the activation of the heat exchanger assembly 3 by neutrons from the reactor assembly 2 and acts as a gamma and neutron shield when the reactor is in operation, while allowing the coolant to flow between the reactor assembly 2 and the heat exchanger assembly 3 without causing a substantial pressure drop to have. The shield structure 4 also acts as a gamma shield when the reactor is switched off, so that the heat exchanger group 3 is accessible to the operating personnel.

Graphite is used because of its better resistance preferred to concrete against heat. The steel layers 26 in the shielding structure 4 absorb the gamma radiation, while the graphite which absorbs neutrons. The thicker steel layers towards the heat exchanger side of the Shielding structure 4 absorb the gamma radiation, soft by fast neutrons in the weaker steel layers 26 arise,

The graphite layers 25 are toward the heat exchanger side of the shield structure 4 made thinner, since the majority of the neutrons are absorbed by the thicker graphite layers 25 will.

Claims (5)

Patent claims: 1. Shield between a nuclear reactor and a heat exchanger group, which are in a common Pressure vessel are included, characterized in that the screen has a solid center piece, which is at least sufficient is large in order to shield that part of the moderator structure of the reactor which contains the fuel elements contains, and is surrounded by an outer shield ring that partially annular Flow paths are created between the inner piece and the outer ring of the shield, and that the partially annular flow paths through a further shield ring on the Experience a diversion on the heat exchanger side of the screen. 2. Screen according to claim 1, characterized in that the inner piece and the outer ring of the shield are made up of alternating layers of graphite and boron steel. 3. Screen according to claim 2, characterized in that the steel layers in the direction of the reactor side to the heat exchanger side of the screen increase in thickness, while the Graphite layers decrease in thickness in this direction. 4. Screen according to claim 1, characterized in that it is in a cylindrical housing is installed, which is mounted concentrically within the pressure vessel by longitudinal wedges, which at the inside of the pressure vessel are welded and in operative connection with grooves in the housing stand. 5. Screen according to claim 1, characterized in that the outer ring of the shield the reactor side has such a shape that there is a smooth entry of the flow into the partially annular flow paths permitted. 1 sheet of drawings I 009 547/335 6.60