LT5390B - Complete set for transportation of irrediated fuel assemblies of nuclear reactor - Google Patents

Abstract

Complete set for transportation of irradiated fuel assemblies of nuclear reactor applies to the nuclear techniques, namely to the protection against radiation during movement of irradiated fuel assemblies (IFA) for the after-burning purpose. The proposed complete set contains a container, which consists of a case with bottom and multifunctional valve, of a cover with tightness monitoring system, and of a damper, a jacket with supports for IFA and transport suspensions that used instead of standard IFA suspensions during transportation. The jacket is put inside the container along its length; the jacket consists of a bottom plate, top plate with head-band, a protective plate and the main part, which consists of a carrying tube around which seats are foreseen to place jacket tubes with IFAs. The head-band has a brake arrangement. Holders of transport suspensions designed as ball plugs.

Description

The invention relates to nuclear technology, namely to radiation protection by transferring irradiated heat release assemblies (SHEES). The invention can be applied to fuel combustion of nuclear reactors with two or more units of energy, and more particularly, the invention is directed to solving the problem of fuel combustion of a nuclear reactor resulting from stopping one of the units.

Namely, at the moment of reactor shutdown, for example, when the first power unit of the Ignalina Nuclear Power Plant is shut down for decommissioning, large quantities of LNG with burnout remain below the design burnout. Those REWS (about 1300 units) with a burn depth less than 07-0.8 average design burnout as proposed in Lithuanian Patents Nos. 4945, can be reused to charge the second power unit. This would not only reduce the amount of new heat sinks required for the operation of the second unit, but also reduce the amount of spent nuclear fuel that would have to be stored at the power plant.

For this purpose, it is necessary to create a set of equipment for transporting (transferring) the SHIR from one reactor power unit to another.

Analogous to the claimed technical solution may be RU patent no. 2189648, which discloses a protective container for the transport and / or storage of spent nuclear fuel consisting of a bottom housing, an inner and outer sealing lids and end damper elements, a housing enclosed in a housing cavity consisting of interconnected diaphragms for inserting assemblies elements mounted on the outer and outer diaphragms.

EP 0895250 also discloses a protective container for transporting and / or storing nuclear fuel, which consists of a cylindrical body with a bottom, at least one protective cover, a tray for containing fuel elements, as well as a vertical tubular channel and an absorber.

In essence, the closest is a protective container for the transportation and / or storage of spent nuclear fuel, known from RU patent no. 2 221 291, consisting of a cylindrical body with a bottom, protective covers, a tray with a removable spacer grille, a vertical tubular channel for pumping water, the lower part of which has a space above the bottom of the container, e.g. a socket and connection socket for connecting a vacuum system, which is mounted on the housing wall and has a radial aisle with an airtight valve.

The main disadvantage of the technical solutions mentioned is the lack of technical measures to ensure nuclear and radiation protection and non-destruction of the transported nuclear fuel.

The object of the invention is to ensure nuclear and radiation safety by maintaining airtightness during the transport of one unit of nuclear fuel for its combustion in another unit's reactor.

To accomplish this purpose, a kit for transporting the reactor EPIR is proposed, consisting of a container with a bottom housing, a sealing lid, a damper, a tray with an EPR spacer grille. What's new is that the kit additionally has transport hangers with assembly brackets that replace the stationary AHSR hangers during transport, said damper is mounted in a container under the lid, a container consisting of a bottom plate, a top plate with a nozzle and a main part consisting of a main a pipe connecting the nozzle to the bottom plate around which the tray grids are provided on the spacer grille and a guard plate inserted between the nozzle and the main body at a distance from the bottom plate of not less than the length of the NIR fuel module. The bottom plate has holes for draining water.

The bottom of the container is a thick-wall removable part fitted with a multi-function valve for draining water from the container, relieving excess pressure and supplying air to the container by decontamination.

The container lid is connected to the container body on the bayonet principle and has a leakproofness control system.

The nozzle has a flange housing and a stopping device consisting of a spring-loaded brake pad and a bushing.

The aforementioned transport suspension brackets are made in the form of ball plugs which, together with the flange on the top plate of the case, provide radiation protection for the personnel and locking the SHIR with the suspension in the case.

The transport hangers are shorter than standard and have a locking tray system using ball-shaped plugs.

In order to prevent damage to the nuclear fuel in the event of a cascade with the ASR drop, the casing has a stopping device and, in addition, a silencer fitted in the container. The second function of the tray-mounted braking device is to ensure that the tray with the AESR is secured in the container when transported by rail. The tray ensures a neat distribution of transported fuel and ensures a minimum of bending when moving the container from horizontal to vertical.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in the drawings, in which: Fig. 1 is a schematic of a kit, Fig. 2 is a diagram of a container, Fig. 3 is a valve, Fig. 4 is a damper, Fig. 6- tray nozzle, Fig.7 - Transport clamp with spherical plug, Fig.8 - Transport clamp.

The transport kit consists of the following main elements:

- container 1 (Fig. 1; Fig. 2) for the purpose of transporting the tray with the REFL, ensuring radiation protection;

- Shelter case 2 (Fig. 1; Fig. 5), ensuring proper arrangement of the sherry within the container, while allowing heat transfer from the sherry to the container body and ensuring nuclear safety;

- a damper 3 (Fig. 1; Fig. 4), which ensures that the dynamic loading of the tray and the REFL is reduced to the permissible values in case of an emergency due to the fall of the REW in the container;

- a set of transport hangers 4 (Fig. 1; Fig. 7; Fig. 8), the purpose of which is to prevent axial displacements by placing them in the liner, holding it in and removing it from the axle.

Container 1 (Fig. 1; Fig. 2) is a key element in the transport assembly of irradiated heat sinks irradiated in a nuclear reactor. It is a steel, thick-walled cylindrical body 5 with a casing with an REFL, which provides protection against ionizing radiation and retains radionuclides inside the container. The opening of the container 1 is closed by an airtight lid 6, which is sealed with seals, is connected to the container body by the bayonet principle and has a system for controlling the airtightness. On the sides of the middle part of the housing there are two necks 7 which are used to turn the container 1 from a vertical position to a horizontal position and vice versa.

The bottom 8 of the container 1 is provided with a multi-function valve (Fig. 3) in the opening 9, which is used to remove water entering the cavity of the container 1 from the unloading machine, to release excess pressure and to purge air by bubbling. The multi-function valve is in the form of a bronze plate 10. To drain the water, the valve plate 11 is pushed and screwed into the socket by means of a screw 11 rotating in the thread. The excess pressure is released through the valve 12.

In the upper part of the body 5 of the container 1 is mounted a damper 3 (Fig. 1;

FIG. 4) which is also the support for the tray. Its purpose is to reduce the dynamic loads on the tray 2 and the REWS to the allowable emergency levels associated with the tray 2 with

In the case of a drop in the AHSR into container 1.

Silencer 3 is a hollow cylindrical metal structure made, for example, of steel. The cylinder has, throughout its height, a system of regular notches arranged in chess. Single row slits are separated from each other by solid metal partitions forming a continuous strip. The cut-outs of two adjacent rows are arranged such that the rows of one row are located above the middle of the cut-outs of the adjacent row.

Inside the container body 1 is a tray 2 (Fig. 1; Fig. 5). The tray is for

AIR 8 for loading. Tray 2 consists of:

• Nozzle 13 • Main parts.

The main part consists of a main tube 14 connecting the nozzle and the lower plate 18, around which the spacers 16 are provided with sockets for accommodating several, for example six, tray tubes 15. The shield plate 17 is positioned at a distance between the nozzle 13 and the main portion not less than the length of the REF fuel module from the lower plate 18. The lower plate 18 has holes for drainage of water. The middle guard plate 17 from above engages the AHSR inside the case, thus providing a bio-guard. The tray ensures the correct arrangement of the transported fuel and ensures the minimum amount of bending allowed when moving the container from horizontal to vertical.

The casing nozzle (Fig.6) consists of a housing with a flange and a brake device.

The brake device consists of brake pads 19 (for example three), levers with a serrated sector 20 (for example three), springs 21, bushes 22. Reference 23 (FIG.

6) means the inner surface of a shaft or container. If, for any reason, the load on the clamping device is reduced, the spring 21 will stretch and rotate the levers 20 which push the brake pads 19 outside the housing. The brake pads 19, when in contact with the shaft or container wall, produce the required brake force.

In addition, the stopping device ensures that the tray 2 with the SHIR in the container is secured during transport by rail.

The transport clamp 4 (Fig. 7; Fig.8) consists of a housing 24 and a clamp 25. The clamp is intended for connection to the SHE main pipe. It enables the transport of the REWS by unloading-loading machine and other stationary equipment of the NPP, as well as the locking of the REWS in the case, preventing them from axial displacement. A spherical stopper 28 (Fig.7) and a nozzle 26 are mounted on the upper part of the suspension. The bushing 27 secures the clamp 25. The transport suspension plugs 28 together with the flange of the top plate of the tray 2 provide radiation protection. Transport suspension 4 standard construction with axial suspension.

The need to create a new transport hanger arose from the fact that the LAMR in the reactor is coupled to a standard suspension that is approximately the length of the LAMR fuel module. This means that the container length is almost doubled.

The AHSR transport kit described above is used using a special conveyor. A special safety chamber consisting of a shaft located above the container 1 site and a movable biological guard is used for transferring the sheath with the REWS between the reactor hall and the container.

The SHIF transport kit is delivered to the first power unit, placed underneath the shaft and loaded into a container 1 for the SHE. For this purpose, the reactor hall crane is lowered into the container 1 by means of an internal shafts trap, and is connected to a tray 2 thereon by means of a crane in the inner shafts, lifting the empty (without SHE) tray 2 into the shaft loading device inside the shaft captures. Tray 2 unloads - loading machine one at a time to load ready READ. Preparation of the REWS for loading into the tray is done by separating the fuel module from the standard rack on a special bench and connecting it to the transport rack 4. After loading, the tray 2 is lowered from the reactor hall down and fully loaded into container 1 and ready for transport. The stopping device of the tray nozzle 13, together with the damper 3 of the container 1, ensures that the fuel is not damaged in the event of a crash in the tray. Container 1 is moved from vertical to horizontal position. In order to ensure the airtightness of the container 1 during transport, the container opening is closed with an airtight lid 6. The lid 6 of the container 1 is located on the conveyor platform and is connected to the body 5 of the container 1 on a bayonet principle. The available leakage control system performs a leak test on the lid 1 of the container 1. It then measures the radiation level of the kit, the radioactive contamination of the surfaces and performs decontamination if necessary. check the vehicle for radioactive contamination and, if necessary, deactivate it. It is then transported to the next block.

In the second power unit, a conveyor with a container 1 and a tray 2 at a designated location below the shaft in the building. Prior to opening the lid 6, through the connection 12 of the multifunctional valve valve, the flexible hose connected to the special ventilation system transfers to the ventilation system any excess pressure that may be generated in the cavity of the container 1. Opens the container lid 6, opens the valve 9, sets the platform horizontally and raises the container 1.

In order to discharge the SWR, the reactor hall crane, through the inner shield tract 10, lowers the bar with the clamp and connects the tray 2 there with the SWR. Using a crane, lift the tray 2 into the loading device and lock it there. Unloading - loading machine unloads one at a time from tray 2. After unloading the REWS, the tray from the reactor hall is lowered back down into the container 1 through the inner shafts, then the kit is inspected, the surface is checked for radioactive contamination, decontamination if necessary, and the transport kit ready for the next trip.

The creation of a transport kit for the combustion of irradiated heat-generating reactor assemblies without damaging them and ensuring radiation and nuclear safety has two objectives:

· Economic;

• ecological.

The economic objective is achieved by the use of fissionable materials in the nuclear power plant during decommissioning of the reactor. Ecological expediency is achieved by reducing the amount of used heat sinks that should be stored in containers.

Claims (7)

A kit for transporting irradiated heat release assemblies (REFs) 5 comprising a container (1) comprising a housing (5) with a bottom (8), a sealing lid (6), a damper (3), and a tray (2). with the SHIFT spacer grille, characterized in that the kit additionally has transport shackles (4) with SHIFF brackets that replace the standard SHIFF shackles during transportation, the abovementioned damper (3) is mounted in the container (I) under the lid, The tray 10 (2) is lengthwise mounted in the container (1) and has a bottom plate (18), an upper plate having a nozzle (13) and a main portion consisting of a main pipe connecting the lower plate (18) and the nozzle (13). 14), around which the spacer grille (16) is provided with sockets for mounting the tray tubes (15) and a guard plate (17) placed between the nozzle (13) and the main body at least 15 as the distance from the lower plate (18) of the AHS fuel module. 2. A kit according to claim 1, characterized in that the bottom of the container (8) is a removable thick-walled piece having a multi-function valve in its opening (9) for deactivating water from the container (1), venting excess pressure and supplying air to the inner cavity of the container (1). years. 20th 3. Kit according to any one of the preceding claims, characterized in that the lid (6) of the container (1) is connected to the container body (5) on the bayonet principle and has a leakage control system. 4. Kit according to any one of the preceding claims, characterized in that the bottom plate (18) has holes for drainage. 25th 5. Kit according to any one of the preceding claims, characterized in that the nozzle (13) comprises a flange body and a stop device consisting of brake pads (19), levers (20) with a serrated sector, a spring (21) and a bushing (22). 6. Kit according to any one of the preceding claims, characterized in that the transport suspension holders are made as ball plugs (28) which, together with The 30 bushings on the top plate provide radiation protection. 7. A kit as claimed in any one of the preceding claims, wherein the spacer grille (16) has six socket tube sockets.