SU712050A3 - Device for capturing molten and structural fragments of exothermal assemblies of nuclear reactor - Google Patents

Abstract

1507039 Nuclear reactors WESTINGHOUSE ELECTRIC CORP 31 Oct 1975 [30 Dec 1974] 45443/75 Heading G6C In a nuclear reactor, for example a liquid metal-cooled fast breeder reactor, fuel elements 66 are supported on inlet units 52 through which coolant passes into the reactor core; the units extend through support plate 40 and at least some of the units include containers 112 made of high temperature resistant material for the collection or core debris resulting from melting of the core in the event of an accident. The containers 112 may be made of stainless steel, refractory metal, or ceramic material, or of an inner ceramic layer and an outer metallic layer; a layer of unenriched UO 2 may also be included in the container wall. Each unit 52 may include a number of receptacles 74 for supporting fuel elements, control rod ducts, and other peripheral assemblies. In normal use, coolant flows into the units at 104; some coolant passes through receptacles 74 into the peripheral assemblies, and some is by-passed through pipe 96 to enter receptacles 74 or 78 and flow upwardly through the fuel elements. In the event of melting of the core, debris will collect and be cooled in containers 112 without damage to the support plate 40.

Description

I

The invention relates to nuclear technology, in particular, to devices for trapping molten fuel and debris from heat-generating assemblies after an emergency has occurred.

A known nuclear reactor containing an active zone immersed in a coolant inside the reactor vessel and a platform for collecting fragments of heat-generating elements 1. The platform contains a set of open-top tanks with a central support column and a device for supporting tanks. The tanks are located at a certain distance from each other in several planes, while the tanks of each layer are shifted relative to the tanks of the other layers so that the upper tanks partially overlap the lower ones. In this case, the entire set of reservoirs completely covers the space into which fragments of heat-generating elements fall.

However, in view of the fact that the reservoirs for collecting fragments of heat-generating elements are located below the base plate of the active nuclear reactor zone, it may melt or deform when the molten fuel passes through it.

The closest to the invention in its technical essence is a device for trapping molten fuel and fragments of the design of fuel assemblies of a nuclear reactor, containing a number of modular input devices mounted on a supporting p-lite; the lower ends of the modular input devices are located below the base plate, with at least one heat release assembly 2 installed in each of the modular input devices.

In this device, in the event of an emergency, the molten fuel or the windings of the design of heat-generating assemblies may block the heat carrier supply path, which will cause further melting of heat-generating elements. The object of the invention is to increase the reliability of the core by collecting and cooling the molten fuel and debris of the design of heat-generating assemblies, as well as improving their supply to the container.

ylociHCJioTCH is a fuel. that the bottom of the case 1 / of the modular input devices is equipped with heat sinks (bags; containers Bbjiioj; nejiui made of stainless steel and ceramic material, while the containers are made with ceramic rim and metal outer shells, and contain a layer of non-enrichment uranium dioxide, the density of which is approximately equal to the density of the formation of melts; the container has a bunker in its upper part.

FIG. 1 shows a nuclear reactor with an on-plate and modular input devices, vertical section; in fig. 2

part of the support plate, top view; in fig. 3 shows the construction of a modular device for the introduction of a heat carrier, a base plate installed into the hole, a vertical section; in fig. 4 - the upper part of the modular heat carrier input device; in fig. 5 - Internal receiver of the modular device BBo; i, a coolant, vertical section; in fig. 6 external receiver modular input device (simplified view), vertical section; in fig. 7 — container, vertical section; in fig. 8 - container, view. above; in fig. 9 - lower part of the modular input device, partial section (another embodiment).

Nuclear reactor, contains a cylindrical body 1, working under d, advance. The coolant, for example, liquid sodium, enters Kcjpnyc under pressure through the inlet, - nozzles 2, and exits the corns from the top of UiCMO space 3 through the outlet nozzles 4. The housing has a thermal lining 5, which protects it from thermal influences and surrounds the output space and 3 () are located above and below the exit pathway. The reactor in the upper part has a lid attached by a bolt: un to the flange of the body. The upper inner parts of the body, which are mechanically fixed to the core 7 in the desired position, as well as the devices, are located in the core, ensuring the correct position of the regulator, the rods and the flow control in the exit space. The core components and the lower internal parts include ash 8 for storage of heat generating assemblies, core mandrel 9, protective 3 (p; i; K),) for removing 1) occupied devices 1.

The core mandrel is welded with a thick horizon. A basic support 12, which MONOLI1PO is attached to the body when the conical slab 13 is inverted. The support plate has a hole thickness 14 (cf. Fig. 2). These openings are interconnected by lateral passageways 15 in the base plate, as well as with side channels 16,

leading to the periphery of the base plate. Into the holes in the base plate, the plates 17 having the form of hollow cylinders are inserted. The plates are rigidly bonded to the base plate. A modular input device 18 is installed in each cover.

Each lining has a row of inlet openings 19 located below the support plate and serving for the entry of heat transfer fluid coming to the lining from the entrance space (see Fig. 3). The lining has side holes 20 which communicate with the side passages in the base plate.

The lower part of the plate has a protrusion 21 into which the pin 22 of the leveling device 23 is installed, which serves to fix the modular input device. Each lining serves as a receiver for a modular input device. The leveling device may have a different shape for different modular input devices. A disk 24 is attached to the bottom of the plate, which serves to distribute the coolant flow and prevent clogging.

In a fast neutron breeder with liquid metal cooling, which is considered as an example, there are two main types of modular input devices, one of which can serve as a receiver for heat generating assemblies, and the other receiver of control rods. By their own interior, modular input devices differ from each other depending on their purpose and requirements for the flow rate of the heat transfer fluid. Each modular insertion device is a hollow hexagonal head 25 and a hollow cylindrical holder 26. The holder is tapered in its lower part in order to guide the modular input device and has an opening 27. The upper part of the angle head has a plurality of holes in which it is mounted and 28 different types of receivers are attached (see Fig. 4). Each receiver, as a rule, has the shape of a hollow cylinder, the internal dimensions of which are chosen so that they correspond to the dimensions of the input channel of the heat-generating assembly 29 or of the channel of the control rods. Typical receivers are shown in FIG. 3, and additional details are shown in FIG. 5 and 6. Each receiver has slots 30 corresponding to slots 31 in the channel of the fuel assembly, piston rings 32 or other seals located above and below the slots of the receiver. These seals minimize the leakage of coolant that enters the receiver slots and, therefore, minimizes the potential danger of pressure growth in the low pressure area immediately below the channel. The bottom of the receiver is a hollow cone, which passes into the spacer 33 in the form of a hollow cylinder. The receiver is attached by gripping the strut with the shoulders of a star 34, which is attached to the head of the modular input device. To prevent leakage of coolant, there are seals 35. The stars' shoulders in the lower part have protrusions 36 to which plate 37 is fixed, which has openings and serves to distribute coolant flow and prevent foreign particles from entering the receivers.

The star has a collecting cavity 38. The floor of the inner part of the strut is connected to the inside of the corresponding receiver and with the collecting cavity.

The star cavities communicate with a branch tube 39 that extends the entire length of the modular input device and has an opening in the space 40 between the lower end of the modular input device and the plate. The branch pipe also has side holes 41, which communicate with the side channels in the base plate through the side holes 20 in the lining and through the holes 42 in the cylindrical holder of the modular input device (see Fig. 1).

The cylindrical holder of the modular input device has openings 43 for introducing the heat transfer medium, above and below which seals 44 are provided, in this case piston rings. During normal operation, the high pressure coolant in the inlet space flows through the holes up the holder, through the filter plate and serves to disperse the flow plate and the slits and then enters the channels.

To regulate the flow of the heat transfer fluid, the modular input devices may include packages of perforated plates at the base of the holder. The perforated plates 45 (see Fig. 6) can be located in the receivers, as well as directly above the filter plate (not shown), which serves to distribute the flow.

In the event of an emergency, breakdowns of the heat generation assemblies and melting of the fuel are possible. A container 46 is installed in each modular input device to collect the melts. The recommended container variant is shown in FIG. 7 and 8. The container is able to retain its shape when debris of the structure of heat-generating assemblies and fuel from the core having an elevated temperature gets into it. Since the container is included in most modular input devices, it also serves to disperse debris and minimize the possibility of forming a critical mass.

The container has the shape of a hollow cylinder, with a hopper 47 having a funnel shape at its top clean (see Fig. 7). J The container has a lower segment 48, an upper segment 49, and a shoulder 50 serving for landing. The lower segment of the container usually has a cylindrical shape and a flat or rounded lower part. The upper segment of the container has a cylindrical shape and a cutout 51 (see Fig. 8), and also the inlets 52 for the heat transfer fluid, which correspond to the inlets in the facing and the modular input device, respectively. The upper segment has holes

j 53 outlets communicating with the openings of the outlet tube, lining and modular input device, respectively. A landing arm at the upper end of the segment provides suspension for the container to the head of the modular input device. AT

The ZO at the junction of the upper and lower segments of the container has an opening 54 through which the outlet tube passes. In the case of melting of fuel or structural elements of heat-generating materials, materials flow down under the force of gravity. The flow of these materials is opposite to the flow of coolant. First of all, these materials pass through the upper part of the receivers, then come out of the slots of the receivers, pass

0 through holes in the shoulders of the star, the latter can partially melt or completely, due to high temperature. The particles formed as a result of melting and fuel are directed into the container using a hopper and enter the "working area of the container, i.e., into the inner space below the inlet holes of the heat carrier of the container, and will be cooled as a result of heat removal through the container walls of the modular inlet device and covers. The possibility of particles accumulating in the working zone with the formation of a critical mass is minimized due to their relatively small number in any of the containers compared to the minimum critical mass. The volume of the container can be varied by changing the length of the container, the modular input device and the lining so that they contain the minimum amount of fuel in order to maximize the likelihood of satisfying the nuclear safety requirements for providing a subcritical state and proper cooling.

Another advantage of the invention is that the molten particles are drawn away from the horizontal support plate. The material from which the container is made must withstand temperatures in excess of 5000 ° F (2760 ° C), and the container itself must not be deformed. The container can be made of stainless steel, ceramic, or a layered combination of metal and ceramic. Other suitable metals include molybdenum, tantalum, niobium and tungsten, or other refractory and refractory metals. The container can be made in the form of a single structure or consist of many parts that are securely interconnected. One embodiment of the container is a metal container consisting of a series of riveted parts joined together butt-end and forming the outer surface of the container and joined with an overlap on the inner surface. Alternatively, additional parts may be incorporated into the container to facilitate cooling. A high density material having a high melting point may serve as a lining for the entire inner surface of the container or part of it. In the ideal case, a material having the same density as the fuel, for example, non-enriched uranium dioxide, can be used.

As mentioned, modular peripheral input devices may contain perforated plates. Under the action of Tij3 K, formed in the cut, during the melting stage, the plates are melted: and the fragments can descend. Alternatively, a container and a modular input device can be used, shown in a simplified form in FIG. 9 {lining, modular input device and container). In this embodiment, the lower perforated plates are covered by the casing 55. Arrangements are provided for securing the casing to the modular input device and for communicating with the side tube.

In any of the described embodiments, there is a possibility that some of the particles formed as a result of melting will fall into the side tube, in which case the particles either melt the tube and enter the container or solidify in the tube. Both the one and the other will most likely occur in the thinner part 56 of the side tube (see FIG. 3) and will not prevent you from

half of its functions in case of unforeseen emergencies.

Claims (6)

1. A device for trapping molten fuel and siblings of a nuclear reactor fuel assembly containing a series of modular input devices mounted on a base plate, the lower ends of the modular input devices are below the base plate, with each of the modular input devices installed at least At least one heat generation assembly, characterized by that, in order to increase the reliability of the core by collecting and cooling the molten fuel and debris of the design of heat-generating assemblies, containers of heat-resistant material are installed in the lower part of each of the modular input devices. 2. Device Under item 1, characterized in that the containers are made of stainless steel. 3. The device according to claim 1, characterized by the fact that the containers are made of ceramic material. 4. The device according to claim I, characterized in that the containers are made with ceramic inner and metal outer shells.  5. A device according to claim 1, characterized in that the containers contain a layer of uranium dioxide enriched, the density of which is approximately equal to the density of the melts formed. S 6. The device according to PP. 1-5, characterized in that, in order to improve the supply of molten fuel and debris to the construction of heat-generating assemblies in a container, it has a bunker in its upper part. Sources of information taken into account in the examination 1. For France No. 2241850, MKI G 21 C 13/02, 3/30, published. 1974. 2.Patent of France No. 2284169, cl. G 21 S 15/00, publ. 05/07/76 (prototype). J2 sixteen Piiz.Z -W /five /