DE3921670C2 - - Google Patents

Description

The invention relates to a device for thermal shielding shear neutrons in a gas-cooled high-temperature reactor with the features of the preamble of claim 1.

Such a device is described in DE-PS 25 06 293 ben. The well-known device with the aim of a di direct neutron radiation from the hot gas collecting space into the Hot gas channels and thus an activation of the metallic one Preventing construction of the hot gas ducts consists of an in Height of the hot gas channels arranged in the hot gas collecting space Circular wall made of graphite covering the cross section of the hot gas ducts covers. Be between the sewer connections and the ring wall there is an annulus for the cooling gas flow, in which the Cooling gas passes through slots provided in the ring wall. The slots are offset from the duct connections. Bars made of shielding material (BäbeC) can also be be provided.

The hot gas ducts are either part of the main circuits and then each lead to a steam generator or other heat exchanger, or they belong to the auxiliary circuits and are in in this case connected to a post-heat exchanger. Because of the high temperature of the gas to be transported provide all hot gas ducts with thermal insulation hen be for their cover and other metallic components of the hot gas ducts requires high temperature resistant materials are. For this, there are primarily nickel-containing materials into consideration since cobalt is considered as an alloying component  for final disposal is not permitted.

As it turned out in recent material studies, alloys containing nickel at temperatures <600 ° C by thermal neutrons in their elongation at break and creep strength impaired. To avoid this material damage permissible limits, it is necessary to restrict the flow of the thermal leakage through the side reflector openings Neutrons so far that damage the hot gas duct insulation can be excluded with certainty. This leaves reach themselves with the help of a shield, for example with the ring wall described in DE-PS 25 06 293.

DE-OS 14 64 705 is also mentioned regarding the prior art, which affects a pipeline shielded from radiation. The Pipe leading out of a nuclear reactor vessel has an extension in the area of implementation, in which a shielding block is arranged. The shielding block covers the line cross-section, and the gas or liquid current flow is led around the shielding block. At the This type of shielding must have a cable cross-section in the area the implementation may be enlarged.

Furthermore, it is known from DE-OS 29 33 899, in a as Coaxial gas duct trained gas duct a shield to provide. This consists of a center in the gas channel built-in rotationally symmetrical displacement body and one this surrounding shield ring, the inner surface of the Kon is adapted to the displacement body. It is sufficient Leave space for the formation of a ring-like flow way on which the gas is redirected.

Starting from DE-PS 25 06 293, the invention is the Task based on a device for thermal shielding To create neutrons according to the preamble of claim 1  fen, their shielding effect compared to the prior art improved and also easier and cheaper to use pose is. In addition, the pressure losses of the hot gas be significantly reduced.

This object is achieved according to the invention by the features of characterizing part of claim 1 solved.

The advantage of the invention is that it is inexpensive in the construction of metallic components the hot gas area nickel-containing materials with the known favorable properties that they - because one Damage from thermal neutrons is excluded - about keep the entire operating time. Would have to use nickel-containing materials in the high temperature range extensive investigations into other, new ones Essential materials.

Boron is the main neutron absorbing material Consider, expediently as boron carbide. The boron carbide can e.g. B. in the form of rods in holes in the graphite body and Side stones of the side reflector may be used. It can also in the form of coated particles embedded in the graphite bodies are available.

Further advantageous refinements of those identified in claim 1 Drawn invention are the dependent claims and the follow the description of an embodiment in connection with the schematic drawings can be seen. The figures show in detail:

Fig. 1 the lower part of a gas-cooled high temperature reactor with a hot gas duct in the longitudinal section along the line II of Fig. 2,

Fig. 2 is a cross section along the line II-II in FIG. 1.

Fig. 1 shows a part of a prestressed concrete pressure vessel 1 in which a gas-cooled high-temperature reactor 2 with spherical fuel elements is placed in a central cavern. The bed of the fuel elements, through which a cooling gas (helium) flows from top to bottom, rests on a support structure 3 made of graphite blocks 4 , which at the same time forms the base reflector. Below the supporting structure 3 there is a hot gas collecting space, in which a multiplicity of columns 6 is arranged and which is therefore referred to as a column hall 5 . About the columns 6 , the Tragkon construction 3 is supported on a bottom layer 7 , which in turn rests on a thermal bottom plate 8 . This is supported by roller bearings 9 on the bottom of the prestressed concrete pressure vessel 1 .

The ball bed is laterally delimited by a side reflector 10 , which is also assembled from graphite blocks 11 . It also encloses the pillared hall 5 and is in turn - surrounded by a thermal side plate 12 - forming an annular space 13 . In the reactor cavern - on a pitch circle around the high-temperature reactor 2 - several steam generators and post-heat exchangers are installed, each of which is connected by a hot gas duct to the column hall 5 , the hot gas duct being connected to a breakthrough in the side reflector 10 . In Fig. 1 only the steam generator 14 and the associated hot gas duct 15 and breakthrough 18 are shown.

The hot gas duct 15 is angled by 90 ° and has an obliquely installed perforated plate 26 at the deflection point in order to even out the hot gas flow. It is supported on a cast shield 16 and is provided with thermal insulation 17 on the inside. In order to protect the thermal insulation 17 from irradiation with thermal neutrons, the high-temperature reactor 2 has a device for shielding these neutrons, which is shown in more detail in FIG. 2.

The device includes a number of aerodynamically designed Graphite body, the material with a high capture area for thermal neutrons included, e.g. B. Boron carbide. In the ge showed example is the boron carbide in the form of coated Particles embedded in the graphite bodies.

Fig. 2 shows the opening 18 in the side reflector 10 for the connection of the leading to the steam generator 14 Heißgaska nals 15 ; Furthermore, here is an opening 19 Darge that ver binds a hot gas duct with a post-heat exchanger. The graphite body for shielding the opening 18 and the opening 19 are designed differently. Common to them, however, is that their height is at least equal to the height of the opening 18 or 19 and that they cover the cross section of the respective opening completely, alone or in combination. The graphite blocks of the side reflector 10 , of which the openings 18 , 19 are immediately limited (hereinafter referred to as side stones 20 and 21 , respectively) also contain material with a high capture cross section for thermal neutrons.

The shielding of the opening 18 is carried out with the aid of two graphite bodies, namely of an elongated gra phite body 22 , which is arranged in the column hall 5 , and a second elongated graphite body 23 , which is located inside the opening 18 and is in the radial direction extends. The side stones 20 , which delimit the opening 18 and each consist of several graphite blocks, have a streamlined shape.

For the opening 19 , three graphite bodies are provided, of which the two graphite bodies 24 have a circular cross section and are arranged in the column hall 5 , while the third graphite body 25 projects into the opening 19 and is at a gap with respect to the two graphite bodies 24 . In order to keep the flow losses low, the graphite body 25 has an egg-shaped cross section. The side stones 21 have no special shape; ie breakthrough 19 is straight.

Claims (6)

1. Device for shielding thermal neutrons in a gas-cooled high-temperature reactor ( 2 ), the

• a) a cooling gas flows from top to bottom,
• b) rests on a supporting structure ( 3 ) made of graphite blocks ( 4 )
  • b1) is supported on pillars of a pillar hall ( 5 ) serving as a hot gas collecting space
  • b2) from a graphite blocks ( 11 ) existing side reflector ( 10 ) is limited in which
  • b3) a plurality of openings ( 18, 19 ) are provided for connecting hot gas ducts ( 15 ) leading to steam generators ( 14 ) and post-heat exchangers, which are protected by the device against direct neutron radiation,

characterized by the following features:

• c) the device consists of aerodynamically shaped graphite bodies ( 22, 23, 24, 25 ),
  • c1) the z. T. in the portico ( 5 ) before the openings ( 18, 19 ), z. T. are arranged within the openings ( 18, 19 ),
  • c2) whose height corresponds at least to the height of the respective opening ( 18, 19 ),
  • c3) which completely cover the cross section of the openings ( 18, 19 ) and
  • c4) contain material with a high capture cross section for thermal neutrons;
• d) which directly limit the openings ( 18, 19 ) of the graphite blocks ( 20, 21 ) of the side reflector ( 10 ) (side stones) also contain material with a high capture cross section for thermal neutrons.

2. Device according to claim 1, characterized in that the openings ( 18 ) for the leading to the steam generators ( 14 ) leading hot gas channels ( 15 ) one in the column hall ( 5 ) arranged, elongated graphite body ( 22 ) sen and within each of these Breakthroughs ( 18 ) a white elongated, but in the radial direction he extending graphite body ( 23 ) is provided. 3. Device according to claim 1, characterized in that the openings ( 19 ) for the hot gas channels leading to the heat exchangers ( 15 ) each have a combination of two in the column hall ( 5 ) arranged graphite body ( 24 ) circular cross-section with a gap between them have third graphite body ( 25 ) egg-shaped cross section, the third graphite body ( 25 ) z. T. is located in the respective breakthrough ( 19 ). 4. Device according to claim 1, characterized in that the openings ( 18 ) delimiting side stones ( 20 ) are aerodynamically shaped. 5. Device according to claim 1, characterized in that the material with high capture cross section for thermal Neutrons in the form of be embedded in the graphite bodies layered particles is present.