RU2743788C1 - Transport pack kit case for irradiated fuel assemblies - Google Patents

Abstract

FIELD: nuclear energy.

SUBSTANCE: invention relates to nuclear power engineering, to devices for handling spent nuclear fuel (SNF) of nuclear power plants (NPP) in form of irradiated fuel assemblies (IFA) and can be used for their placement in container during transportation and / or storage. Carrying bag for transport packing set with irradiated fuel assemblies comprises base, central pipe, sectional discs with holes, in which whole hexagonal pipes are installed in two circular rows relative to cover axis for IFA arrangement. Composite central pipe of cover is made of heat removal inserts. Between two adjacent sectional disks there are heat removal discs forming together with the section. Additional holes in the sections form channels. Hexagonal pipes of the case are three-layered; the inner layer is a cellular structure made up of spacer frames accommodating neutron-absorbing material tiles; ends of hexagonal pipes are sealed.

EFFECT: invention provides optimal nuclear-safe arrangement of 18 IFA in envelope dimensions.

7 cl, 6 dwg

Description

The invention relates to nuclear power, to devices for handling spent nuclear fuel (SNF) of nuclear power plants (NPP) with reactor plants VVER-1000/1200/1300 / TOI in the form of irradiated fuel assemblies (SFA) and can be used for their placement in container during transportation and / or storage.

Known cover for the container for the transportation and storage of spent nuclear fuel (SNF) (p.RF No. 2642853, publ. 01/29/2018), containing a central supporting pipe made of corrosion-resistant steel, on which sections fastened together are installed, each of which is made of two spacer grids made of stainless steel, between them there are hexagonal tubes for placing fuel assemblies, which have neutron protection and are installed relative to the axis of the central tube in two annular rows. The sections are installed on a base consisting of a spacer support with holes. Heat dissipating discs are installed parallel to the spacer grilles, and steel posts are installed parallel to the hexagonal pipes. The neutron shield is installed inside each pipe face in the form of a boron-containing composite plate.

The disadvantage of this cover is:

- execution in the form of a composite structure of sections, which during the operation of the container can lead to stepping on the inner surface of the hexagonal tubes of the cover at the joints between the sections;

- load-bearing elements of the cover structure are made of a material (aluminum alloy) with low strength characteristics under dynamic emergency impacts in the upper temperature range (up to + 350 ° С);

- uneven distribution of neutron-absorbing material along the height of the cover;

- the absence of sockets on the upper disk for guiding the spent fuel assemblies when they are loaded into the case;

- load-bearing structural elements of the cover made of aluminum alloy do not provide corrosion resistance to aggressive media.

As a prototype, a cover was chosen for placing and storing spent fuel assemblies of a VVER-1000 reactor (p.RF No. 2453007, publ. 10.06.2012), containing a central tube, spacer grids with twenty tubes, in which the spent fuel assemblies are located. The pipes are made in the form of a hexagon and they are installed in two annular rows relative to the axis of the central pipe, separated by an intermediate pipe. Pipes in a row mate with each other with ribs, and some of the edges are lined with radiation shielding on the outside.

The disadvantage of this cover is:

- load-bearing elements of the cover structure are made of a material (aluminum alloy) with low strength characteristics under dynamic emergency impacts in the upper temperature range (up to + 350 ° С);

- uneven distribution of neutron-absorbing material along the edges of the hexagonal tube;

- the absence of sockets on the upper disk for guiding the spent fuel assemblies when they are loaded into the case;

- load-bearing structural elements of the cover made of aluminum alloy do not provide corrosion resistance to aggressive media;

- Radiation shielding linings are made of expensive amorphous boron-based material.

The technical result consists in ensuring the optimal nuclear-safe location of 18 spent fuel assemblies in the dimensions of the canister, efficient heat removal from the area of the spent fuel assemblies due to the creation of thermal bridges in the heat-dissipating discs and inserts of the central pipe, heat-conducting contacts between the canister and the inner cylindrical surface of the container body, increased strength of the shell design for spacing SFA in case of emergency dynamic impacts due to the use of steel in the composition of all load-bearing elements of the jacket.

The technical result is achieved by the fact that the cover for a transport packaging set with irradiated fuel assemblies contains a central pipe, a base (frame), with sectional disks with holes located on it, into which whole hexagonal pipes are installed in two annular rows relative to the cover axis for placing spent fuel assemblies ... The composite central tube of the cover is made of heat-dissipating inserts. Between two adjacent sectional discs there are heat dissipating discs, which together form sections, fastened together by fasteners. Additional openings in the sections form channels that ensure uniform filling of the internal free volumes of the container with a moderator in emergency operating conditions. The hexagonal tubes of the cover are made of three layers, the inner layer is a cellular structure composed of spacer frames, in which tiles of neutron-absorbing material are located, while the ends of the hexagonal tubes are sealed.

Hexagonal tubes, sectional disks, clamping devices, fasteners are made of corrosion-resistant steel, heat-dissipating disks and central tube inserts are made of aluminum alloy, which provide heat removal from the SFA installation zone (hexagonal tubes) to the outer cylindrical surface of the jacket. At the base of the cover, under the hexagonal pipes, there are clamping devices that provide pressing of the empty and loaded cover in the inner cavity of the container in horizontal and vertical orientation. A removable adapter for a load gripper is provided on the top disk of the cover. Each hexagonal tube is equipped with a bell for guiding the spent fuel assemblies when they are loaded into the casing. The cover has grooves to prevent its rotation relative to the container.

The three-layer construction of the hexagonal tubes of the cover allows to accommodate the required amount of neutron-absorbing material, ensures its uniform distribution in the volume of the hexagonal tube and excludes its exit from the sealed volume in normal and emergency operating conditions.

The geometry and perforation of the sectional and heat-removing disks with the formation of channels ensures uniform filling of the internal free volumes of the container with a moderator (water, ice, snow, steam) in emergency operating conditions.

The presence of contacting surfaces between the heat-dissipating inserts of the central pipe and the heat-dissipating disks of the jacket makes it possible to ensure efficient heat removal from the area of the SFA installation to the inner cylindrical surface of the container body.

The peculiarity of the execution of the hexagonal tubes of the cover in the form of a one-piece continuous structure and the presence of sockets increased the operational characteristics of the cover. The steel construction of the hexagonal tubes of the cover allowed to set the optimal number of heat dissipating discs while maintaining the rigidity of the cover as a whole.

FIG. 1 shows the design of the cover of the transport packaging for irradiated fuel assemblies; in fig. 2 is a top view of FIG. one; in fig. 3 - construction of a hexagonal pipe; in fig. 4 - the design of the heat sink disc; in fig. 5 - design of the clamping device; in fig. 6 - the design of the cover in a volumetric image.

The cover is a metal structure consisting of eighteen hexagonal pipes 1, nine stacked sections of sectional disks 2 and heat-dissipating discs 3, a composite central pipe of heat-removing inserts 4, upper 5 and lower 6 discs, lead-in ring 7, plate 8, eighteen pressure devices 9, bells 10 above each hex pipe 1 and gripper 11.

The material of the hexagonal pipes, discs, clamping devices - corrosion-resistant steel 12X18H10T, heat-dissipating discs and inserts - aluminum alloy AMg3.

Each face of the hexagonal tube of the cover (Fig. 3) is a three-layer structure. The inner layer 12 consists of two triangular profiles, forming a hexagon with a turnkey size of 243 mm. The outer layer 13 consists of two triangular profiles, forming a hexagon with a turnkey size of 279 mm. A layer of boron carbide-based neutron-absorbing material is placed between the inner and outer layers of the pipe. Structurally, this layer is a honeycomb structure composed of spacer frames 14, in which tiles 15 made of boron-containing composite are located. Sealing of this volume is ensured by welding the end caps 16 and longitudinal welding of the outer and inner layers of the hexagonal tube of the cover.

Each of the nine stacked sections of the cover consists of four disks of complex shape: two sectional and two heat-removing disks (Fig. 4). The section disks are fastened together by fasteners made of corrosion-resistant steel (not shown in the figure). The sections are installed at a certain distance one above the other. Structural elements of the case made of aluminum alloy carry out heat removal from the area of the spent fuel assembly to the inner cylindrical surface of the container. Sectional disks 2 ensure optimal placement of spent fuel assemblies in the inner cavity of the container. The upper 5 and lower 6 discs provide additional rigidity to the cover structure in the horizontal and vertical position. The upper disk 5 is provided with a removable gripper 11 for a load gripping device (not shown in the figure).

The cover has grooves 17 (Fig. 2) required to prevent its rotation about the container axis.

The bell 10 is a metal structure made of six petals welded together. The funnel serves to guide the spent fuel assemblies when they are loaded into the case.

The gripping device (Fig. 5) provides gripping of the empty and loaded cover in the inner cavity of the container in its horizontal and vertical orientation. The clamping device consists of a sleeve 18, an axis 19, a central spring 20, a set of springs 21, a movable disk 22, a cage 23. In the cage 23 six slots 24 are made to enable the SFA to be installed in six orientations with an angle of 60 °.

The claimed cover of the transport packaging for irradiated fuel assemblies is operated as follows:

- the cover with the help of a load-gripping device (not shown in Fig. 1), fixed on the grip 11, is installed vertically in the inner cavity of the container intended for transportation and storage of irradiated fuel assemblies of the VVER-1000/1200/1300 / TOI reactor plant. The cover is installed in a certain angular position using grooves 17, into which the guides of the container go; the lead-in ring 7 simplifies the installation of the cover;

- the SFA is installed in the shell under water in a predetermined sequence using a special load-gripping device. To guide the spent fuel assemblies during loading, 10 sockets installed on the upper disk 5 of the case are used. The spent fuel assemblies are installed in the hexagonal tubes 1 of the jacket on the clamping devices 9.

The cover is transported in a horizontal position.

Removing the cover from the container cavity is carried out in order to carry out routine maintenance.

The combination of these design solutions ensures the nuclear safe placement in the canister of 18 spent fuel assemblies from a VVER-1000/1200/1300 / TOI reactor with an initial enrichment of up to 5% in ²³⁵ U both taking into account its burnup in the reactor and under the conservative assumption of unirradiated fuel transportation in accordance with the requirements IAEA SSR-6 and NP-053-16.

Claims (7)

1. A cover of a transport packaging set for irradiated fuel assemblies (SFA), containing a central tube, a base (frame) with sectional disks with holes located on it, into which one-piece hexagonal tubes are installed in two annular rows relative to the axis of the cover to accommodate irradiated fuel assemblies, characterized in that the central pipe is made composite and has heat-dissipating inserts, heat-dissipating discs are placed between two adjacent sectional discs, forming together sections, fastened together by fasteners, heat-dissipating and sectional discs have channels, hexagonal pipes are made of three-layer, the inner layer is a cellular structure, composed of spacer frames, in which tiles of neutron-absorbing material are located, while the ends of the hexagonal pipes are sealed. 2. The cover according to claim. 1, characterized in that at the base of the cover under the hexagonal pipes, clamping devices are installed that provide pressing of the empty and loaded covers in the inner cavity of the container in horizontal and vertical orientations. 3. A cover according to claim 1, characterized in that the hexagonal pipes, the upper disc, the lower disc, sectional discs, clamping devices, fasteners are made of corrosion-resistant steel, the heat-dissipating discs and inserts of the central pipe are made of aluminum alloy, which provide heat dissipation from the installation area SFA (hexagonal tubes) to the outer surface of the canister. 4. A cover according to claim 1, characterized in that a removable gripper for a load gripping device is provided on the upper disc. 5. A cover according to claim 1, characterized in that the upper disk has a funnel for guiding the spent fuel assemblies when they are loaded into the cover. 6. A cover according to claim 1, characterized in that it has grooves to prevent its rotation relative to the container. 7. A cover according to claim 1, characterized in that the tiles of the neutron-absorbing material are made on the basis of natural (natural) boron carbide.

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