JP2016095156A - Graphite block - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a graphite block used for a pebble-bed nuclear reactor capable of being operated for a long period of time.SOLUTION: A plurality of graphite blocks 10 are built up to form a pebble storage space 20 loaded with a plurality of pebbles 4 that are fuel balls. The graphite blocks 10 are composed of base materials 11 and ceramic coatings 12 covering the base materials 11. The graphite blocks 10 have a plurality of holes 30 exposed to inner wall surfaces 13 of the graphite blocks 10 that face the pebble storage space 20, further include sleeves 40 disposed inside the holes 30, and is provided with opening ends 31 at portions of the holes 30 that face the inner wall surfaces 13. The graphite blocks 10 allow the pebbles 4 to be in no contact with corners of the ceramic coatings 12 covering the base materials 11 due to that sleeves 40 are inserted into the holes 30 that function as steps when the pebbles 4 move, thereby allowing the ceramic coatings 12 to be hardly damaged.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a graphite block for a pebble bed reactor.

  Graphite has a high neutron absorption cross-section and a large neutron moderating ability, so it has a high reduction ratio, high heat resistance, and large materials can be easily obtained. It's being used. In particular, it is an important material as a material for a moderator, a reflector, etc. of a gas cooling furnace such as a Magnox furnace, an improved graphite furnace (AGR furnace), a high temperature gas furnace.

  Patent Document 1 describes a graphite structure with improved strength by using ceramics to compensate for the brittleness of graphite itself without impairing the core properties and thermal properties of graphite as a moderator and reflector. The surface of the nuclear reactor structure such as moderator and reflector made of solid graphite was covered with heat-resistant ceramics such as silicon carbide (SiC) to improve the strength without impairing the core and thermal performance. Graphite structures have been proposed.

Japanese Utility Model Publication No. 61-206897

  The gas-cooled furnace includes a conventional furnace using carbon dioxide gas as a coolant such as a Magnox furnace and an improved graphite furnace, and a new furnace using helium as a coolant such as a high-temperature gas furnace. Since carbon dioxide used in conventional reactors causes a chemical reaction with the graphite of the core structure material, the temperature of the coolant at the outlet of the reactor is limited by the chemical reaction between the graphite and carbon dioxide. However, by using helium gas as a coolant, a chemical reaction between the coolant and graphite does not occur, and the operating temperature of the reactor can be increased.

  High temperature gas furnaces using helium as a coolant include a block type high temperature gas furnace and a pebble bed type high temperature gas furnace depending on the fuel shape. In a block type HTGR, for example, a hexagonal graphite block (fuel column) in which fuel rods are housed, a hexagonal graphite block (movable reflector) in which fuel rods are not housed, and those Consists of fixed reflectors surrounding the outside. The graphite structure of Patent Document 1 is a technique related to a block-type HTGR.

  On the other hand, in the pebble bed type HTGR, fuel balls (pebbles) formed by mixing coated fuel particles with graphite particles into a spherical shape are used, and a large number of these are stacked randomly in a space formed by graphite blocks. Form. The diameter of the fuel ball is about 6 cm. It is characterized in that the fuel balls with a lowered nuclear reaction are taken out from below during operation and are continuously exchanged by supplying new fuel balls from the top. Therefore, it is not necessary to stop the operation and change the fuel as in the case of the block type high temperature gas reactor, and the operation period of the nuclear reactor can be lengthened.

  However, since the pebble bed type HTGR can in principle be operated for a longer time than the block type HTGR, it can be operated for a long time by extending the replacement period of the graphite block used. To. For this reason, further life-up of the graphite block is desired.

  In view of the above problems, an object of the present invention is to provide a graphite block for use in a pebble bed reactor capable of long-term operation.

The graphite block and pebble bed reactor of the present invention for solving the above problems are
(1) A graphite block for a pebble bed type nuclear reactor, wherein the graphite block comprises a base material made of graphite and a ceramic coating for covering the base material, and is exposed to an inner wall surface facing the pebble storage space. And a sleeve disposed in the hole.
(2) The sleeve covers the open end of the hole.
(3) The ceramic coating is made of SiC.
(4) The sleeve is made of ceramic.
(5) The sleeve is made of SiC.
(6) A pebble bed nuclear reactor comprising the graphite block according to any one of (1) to (5).
(7) The hole is a pebble bed reactor exposed on a bottom surface or a side surface of a pebble storage space of the pebble bed reactor,
It is characterized by that.

  In the graphite block obtained by the present invention, since the sleeve is inserted into the hole that becomes a step when the pebble moves, the pebble does not contact the corner of the ceramic coating that covers the base material. Can be difficult.

The schematic diagram which shows an example of the pebble bed type | mold reactor in which the graphite block which concerns on this invention is used. The schematic diagram which shows an example of the pebble storage space where the graphite block which concerns on this invention is used. The schematic diagram which shows the contact condition of the hole vicinity of the graphite block which concerns on this invention, and a pebble. The perspective view of the graphite block which concerns on this invention.

  Hereinafter, a preferred embodiment of a graphite block according to the present invention will be described in detail with reference to FIGS.

  FIG. 1 is a schematic diagram showing an example of a pebble bed reactor. In the pebble bed type reactor 1, a reactor core 3 is housed in a reactor vessel 2, and a plurality of pebbles 4 that are fuel balls are loaded in the reactor core 3. The core 3 is formed with a pebble storage space 20 having an upper portion, a lower portion, and a periphery constituted by a plurality of graphite blocks 10. In addition, the core 3 is configured by stacking a plurality of graphite blocks 10 to minimize the amount of neutron leakage to the outside. A coolant pipe 5 is connected to the lower part of the reactor vessel 2 and is connected to a power converter 6 having a generator at the upper part, a gas turbine or compressor at the center, and a cooler at the lower part.

  FIG. 2 is a schematic diagram illustrating an example of a pebble storage space 20 configured by the graphite block 10 of the present embodiment.

  The pebble 4 loaded in the pebble storage space 20 has a spherical shape with a diameter of about 6 cm. For example, the pebble 4 is a fuel composed of a number of coated fuel particles containing uranium oxide as a nuclear fuel material and a graphite matrix containing the particles. The region is surrounded by a graphite shell. Then, the pebble 4 is mixed with the graphite powder and filled into a spherical mold in order to contain the coated fuel particles in the graphite material as the neutron moderator. The primary sphere is secondarily pressed together with the graphite powder to form spherical particles with a shell, and the surface is ground to make it into a true sphere, and then completed through preliminary firing and firing steps.

  The graphite block 10 constituting the pebble storage space 20 includes a base material 11 made of graphite and a ceramic coating 12 covering the base material 11. Moreover, the graphite block 10 has a substantially quadrangular prism shape including a cylindrical surface as an example in the present embodiment, and has an inner wall surface 13 that forms a pebble storage space 20, an upper and lower surface 14, and a side surface 15. . The cylindrical surface does not have to be a complete cylindrical surface. For example, the inner wall 13 facing the pebble storage space of the graphite block 10 is configured as a flat surface, so that the pebble storage space 20 is a polygonal column. You may comprise by the wall surface.

  The ceramic coating 12 is preferably SiC. Since the pebble 4 is formed by solidifying particles in which nuclear fuel is coated with pyrolytic carbon or SiC, the pebble 4 is hard and has a high ability to wear the graphite block 10. Therefore, by covering the graphite block 10 with the same material as the hardest SiC contained in the pebble 4, it is possible to make the graphite block 10 difficult to break even when pressure is applied from the pebble 4. Moreover, since SiC absorbs little neutrons, it has little effect on the fission chain reaction.

  Further, the ceramic coating 12 may cover the entire surface of the base material 11 of the graphite block 10 as shown in the present embodiment, or may be applied only to the inner wall surface 13 facing the pebble storage space 20. good.

  In the present embodiment, the graphite block 10 has a plurality of holes 30 exposed on the inner wall surface 13 facing the pebble storage space 20 of the graphite block 10, and further includes a sleeve 40 disposed inside the hole 30. . An opening end 31 is provided at a portion of the hole 30 facing the inner wall surface 13.

  Further, the hole 30 formed in the graphite block 10 is exposed on the bottom surface 21 or the side surface 22 of the pebble storage space 20 of the pebble bed nuclear reactor 1. When the hole 30 is in the bottom surface 21 or the side surface 22 of the pebble storage space 20 of the pebble bed nuclear reactor 1, the sleeve 40 can be preferably used because the pressure of the pebble 4 is particularly applied.

  FIG. 3 is a schematic diagram showing the contact condition between the vicinity of the hole 30 of the graphite block 10 and the pebble 4.

  In a nuclear reactor, various gaseous fission products are generated with fission. A component that reacts with graphite may be generated in the gaseous fission product. The pebble 4, which is a fuel ball used in the pebble bed nuclear reactor 1, contains a large amount of high-density elements such as uranium and moves while rolling on the surface of the graphite block 10, so that the pebble 4 and the graphite block 10 At the point of contact, high pressure is concentrated at one point. For this reason, when the coating is broken, the graphite and the fission product react to deteriorate the graphite block 10.

  In the pebble bed nuclear reactor 1, a plurality of graphite blocks 10 are stacked to constitute a core 3. The pebble storage space 20 has a large number of holes 30 in the inner wall surface 13 for control in addition to holes 30 through which helium as a coolant passes. The fuel pebble 4 is a high-density sphere formed by solidifying particles such as uranium coated with SiC or pyrolytic carbon. When the pebble 4 is taken out from the lower part of the pebble bed reactor 1, the pebble 4 moves downward from the upper part. Since the pebble 4 is a high-density sphere, chipping may occur if there is a step in the hole 30 as it moves.

  As shown in FIG. 3, the graphite block 10 of the present embodiment has a sleeve 40 inserted into a hole 30 that becomes a step when the pebble 4 moves. Since the pebble 4 does not contact, the ceramic coating 12 can be made difficult to break.

  That is, since the sleeve 40 is inserted into the hole 30 formed in the graphite block 10, the impact of the spherical pebble 4 is reduced by the sleeve 40, and the pebble 4 can roll on the inner wall surface 13 smoothly. .

  The sleeve 40 is disposed so as to cover the open end 31 of the hole 30. If the opening end 31 of the hole 30 is covered, the ceramic coating 12 formed on the opening end 31 can be reliably protected.

  FIG. 4 shows a perspective view of the graphite block 10.

  A sleeve 40 is inserted into and fixed to the inside of the plurality of holes 30 exposed on the inner wall surface 13 of the graphite block 10, and the sleeve 40 covers the ceramic coating 12 formed also at the opening end 31 of the hole 30.

  The sleeve 40 is preferably made of ceramics. When the sleeve 40 is made of ceramic, it has high heat resistance and strength, so that it can be suitably used.

  The sleeve 40 is preferably made of SiC.

  The pebble 4 is formed by solidifying particles in which nuclear fuel is coated with pyrolytic carbon, SiC or the like. For this reason, the pebble 4 is hard and has a high ability to wear the graphite block 10, but the graphite block 10 is covered with the same material as the hardest SiC contained in the pebble 4, and the sleeve 40 is made of SiC. Even if pressure is applied from 4, the ceramic coating 12 can be made difficult to break. Moreover, since SiC absorbs little neutrons, it has little effect on the fission chain reaction.

  Although the graphite block 10 having a substantially quadrangular prism shape including a cylindrical surface has been described, the hexagonal prism shape may be used, and the shape is not limited as long as a strong and stable core is formed.

  In addition, this invention is not limited to embodiment mentioned above, A deformation | transformation, improvement, etc. are possible suitably. In addition, the material, shape, dimension, numerical value, form, number, arrangement location, and the like of each component in the above-described embodiment are arbitrary and are not limited as long as the present invention can be achieved.

  The graphite block according to the present invention is applicable to the use of a nuclear reactor that uses pebble.

1: Pebble bed type reactor 2: Reactor vessel 3: Core 4: Pebble 10: Graphite block 11: Base material 12: Ceramic coating 13: Inner wall surface 30: Hole 31: Open end 40: Sleeve

Claims (7)

A graphite block for a pebble bed reactor,
The graphite block is composed of a base material made of graphite and a ceramic coating that covers the base material, and has holes exposed on the inner wall surface facing the pebble storage space,
A graphite block further comprising a sleeve disposed inside the hole. The graphite block according to claim 1,
The sleeve is a graphite block that covers the open end of the hole. The graphite block according to claim 1,
The ceramic coating is a graphite block made of SiC. The graphite block according to any one of claims 1 to 3,
The sleeve is a graphite block made of ceramic. The graphite block according to claim 4,
The sleeve is a graphite block made of SiC.   A pebble bed nuclear reactor comprising the graphite block according to any one of claims 1 to 5. The pebble bed nuclear reactor according to claim 6,
The hole is a pebble bed reactor that is exposed on a bottom surface or a side surface of a pebble storage space of the pebble bed reactor.

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