DE2732741A1 - High temp. gas cooled reactor with top reflector cooling - by secondary gas flow of increased speed during fault condition - Google Patents

Abstract

A gas-cooled, high temp. reactor has a cooled top reflector, pref. composed of graphite blocks, with a downward flowing gas stream through the reactor core. Below the top reflector, and at some distance from it, there is a suspended roof contg. apertures, through which the stream flows downwards from a distribution chamber between the top reflector and the suspended roof. Pref., the upper face of the top reflector is cooled by a second gas stream. Specif., both the top reflector and the suspended roof are suspended from a common support frame cooled by the second gas stream. If a fault occurs and the reactor is shut down, e.g. due to failure of a blower, natural circulation builds up, causing reverse flow through the core and resulting in heating of the top reflector; heat is transferred from this to the second cooling circuit which thus supplies more heat to the steam generator and results in increased steam prodn. This operates the steam turbine at higher speed, resulting in the second blower being driven at higher speed, which provides sufficient cooling for the top reflector through the secondary cooling circuit.

Description

Ref lek tordeeke for iloch temperature reactor

The present invention relates to a gas-cooled high-temperature reactor with a cooled reflector cover and one directed from top to bottom through the cleavage zone first Kilhigasstrom. The cleavage zone preferably consists of a bed of spherical fuel elements that are cooled with helium. The heated helium gJbt its heat in process engineering systems or in a system for power generation off again. The gap zone is contained in a pressure vessel that is used to achieve the necessary tightness is provided with a lining that protects against from the heat emitted by the fission zone, as well as neutron and gamma radiation and needs to be cooled. In doing so, the ceiling of the pressure vessel represents because of the inside of it arranged measuring and control devices pose a particular problem to overcome it a reflector ceiling suspended from the pressure vessel ceiling is arranged, which in turn must also be cooled, especially to prevent failure of the reflector ceiling to avoid load-bearing components.

Even when the reactor is switched off, there is post-disintegration in the cleavage zone a considerable amount of heat is released, those via the first cooling circuit can be discharged when the associated blower is reduced. Will However, a failure of this fan:. It is assumed, it comes from natural convection to a reversal of the flow in the first cooling circuit and thus to an increased thermal load on the reflector ceiling, which is now exposed to heated gas, that in normal operation through the relatively cool entering the reactor Gas was swept. In the lecture by Dr. H. Reutler: "Residual heat removal without forced circulation in high-temperature reactors "^, held at the 1976 Reaktortagung, is a ceiling construction has been proposed in which this is designed as a heat exchanger itself and the heat absorbed by the ceiling by means of a circulating in nature Secondary coolant is discharged. This means that the coolant is high Must have heat capacity, d. That is, gases and especially helium are not in favor come into question. However, the use of water as a coolant is encountered, inter alia.

because of the neutron physical consequences (water acts as a moderator) in the event of possible damage to the reflector ceiling and thus the heat exchanger Concerns.

As a building material for a reflector ceiling is recommended because of its high chemical and heat resistance and because of its neutron physical properties primarily graphite, which is used in the form of shaped blocks. Because Inadequate tensile strength of the graphite must be built up and suspended from it Ceiling can be provided with a metal supporting structure, which in turn is in front of high Temperatures must be guarded.

The object of the present invention is a gas-cooled high-temperature reactor with a suspended reflector ceiling, which both in normal operation as well as with residual heat removal by natural circulation is sufficiently cooled and the In addition, the core to be heated is applied evenly to the gap zone Gas causes.

This object is achieved according to the invention in that below the reflector ceiling at a distance from it an intermediate ceiling provided with openings is all-ordained, the entry and distribution space with the reflector ceiling limited for the first cooling gas flow. That entering the reactor, proportionally cool gas is made optimally usable for cooling the reflector ceiling by all parts of it are evenly smeared by the gas before it is through the Openings in the false ceiling emerge into the space above the crevice zone. By an uneven distribution of the openings over the false ceiling can be localized different thermal loads of the ceiling can be met. Protects at the same time the false ceiling the reflector ceiling from heat radiation from the gap zone.

In a further embodiment of the invention, the top of the reflector ceiling cooled by means of a second cooling gas stream, which is in an independent circuit is guided and is preferably maintained by a fan that is equipped with a Heat engine is operated, its heat demand just the second cooling gas flow withdraws. This second cooling gas flow is retained even when residual heat is removed can then even be reinforced to counteract the increased thermal load on the reflector ceiling balance.

In an advantageous embodiment of this inventive concept, reflector and false ceiling on a common, cooled by the second cooling gas flow Shoring suspended. The common suspension simplifies and makes the Konstrllktion, and the cooling by the second cooling gas flow, which is independent of the main operation and ensures sufficient cooling of the critical parts of the ceiling structure even if the main cooling gas tube fails.

According to a further feature of the invention, the support structure is im Entrance and distribution space within is spaced pieces that keep the distance bridge between reflector and false ceiling, so that the supporting structure of the action it is relatively cool, but absolutely very neat (approx. 3000C) in the reactor entering cooling gas is withdrawn. These spacers are useful as well as the ceilings themselves made of graphite.

To increase the thermal insulation of the reflector ceiling and thus the protection to improve the pressure vessel is proposed in a further embodiment of the invention, that the reflector ceiling consists of several, gas-filled on most of its area Interstices of separated layers consists. Since the ceiling is off anyway a large number of graphite blocks must be put together, can be made by appropriate Shaping the same can be achieved that the required spaces in shape be made of recesses on the blocks.

One made up of a large number of individual graphite blocks Reflector ceiling is characterized in a further embodiment of the invention, that the joints between the individual blocks are closed by sealing strips, which engage in grooves cut out on the side of the blocks. This will make both known way a circulation of the cooling gas through the gaps between the blocks through it (which leads to undesired mixing of the gases from the first and second Cooling gas flow would lead) and thus a risk to the pressure vessel wall is avoided as well as an additional safeguard against the falling of individual blocks created for the ceiling in the event that an element of the supporting structure should fail.

An embodiment of the invention is shown in the drawing, namely, Figure 1 shows a greatly simplified nuclear reactor and schematically the for Operation of its cooling circuits necessary auxiliary systems and Figure 2 on an enlarged scale Details of the ceiling construction according to the invention.

The nuclear reactor according to the invention consists of a pressure vessel 1, which encloses a cleavage zone 2, which from a large number of loosely poured onto one another spherical fuel assemblies and not using it in a known manner here illustrated devices can be regulated and switched off. The pressure vessel, which can be formed from prestressed concrete or from a number of gray cast iron blocks, is on its inside with a thermal insulation 3 (e.g. made of hollow ceramic bodies) which developed part of its protection from that in the fission zone 2 Heat forms. The tightness of the pressure vessel 1 is ensured by a thin steel Lining 4 (so-called liner) ensures that the individual, tightly together welded sheets is built up. From the ceiling of the pressure vessel 1 is a made of graphite reflector ceiling 5 suspended. The cleavage zone 2 is through a stream of helium cooled in a first cooling circuit 7 with the help of a first fan 9 is circulated, its heat in a heat exchanger 8 at here only indicated secondary cycles, where they can be used as process arms or for steam generation is used and that is finally cooled at the top of the reactor pressure vessel 1 re-enters this. In doing so, the charcoal is brushed Gas the Underside of the reflector ceiling 5 and thus contributes to its cooling. One below the reflector ceiling 5 arranged, also made of graphite and with openings provided intermediate ceiling 27 ensures an even distribution of the cooling gas and thus for a uniform loading of the gap zone 2. A Gap 29 between reflector ceiling 5 and intermediate ceiling 27 the entry and Distribution space for the cooling gas. The space between the reflector ceiling 5 and the pressure vessel 1 forms part of a second cooling circuit 10 through the reflector ceiling 5 and in particular its support structure described below be cooled down to permissible temperatures. The second cooling circuit 10 is kept going by a second fan 11. Since the second cooling circuit 10 under a higher pressure than the first cooling circuit 7, even if it is also is operated with helium, small leaks in the reflector ceiling have an effect 5 to the effect that gas from the second cooling circuit in the first cooling circuit 7 oozes. A penetration of radioactive substances from the first cooling circuit 7 in the second cooling circuit 10 is thus avoided. The former has a cleaning system 12, in which the gas can be freed from such fission products and the over a bypass line 25 is connected in parallel to the first cooling circuit 7. Of the Most of the cleaned gas is returned to the first cooling circuit via a line 26 7 fed in, whereas the excess is fed into a gas storage container by means of a compressor 14 is pumped, which in turn is under higher pressure than the second cooling circuit 10 and from which its gas losses are replaced, over the entire decay period of the fuel elements in the event of an accident even if as a result if of the first cooling circuit 7, the storage container 14 is not refilled during this time can be. The gas circulating in the second cooling circuit 10 drives either one Gas turbine, not shown here, which takes the place of those listed below Steam turbine would occur or will, as shown here, in a steam generator 15 used to generate steam. A turhine 16 is operated with the steam, which in turn drives the second fan 11. The steam emerging from the turbine 16 is condensed in a condenser 17 and stored in a water storage tank 22, can be compensated from the water losses of the water / steam circuit 21, so that its functionality is ensured over long periods of time, like them until the N3-c - rTallswYrme have subsided to a low value. The supply of the steam generator 15 with feed water is also carried out by a The feed water pump 20 driven by the steam turbine 16 is ensured.

If the reactor is switched off in the event of a malfunction and all of them are warped first cooling circuits 7 (only one of which is shown here), for example as a result of failure of the first fan 9, it is reversed as a result of natural convection reverses the direction of the gas flow in the pressure vessel, due to the decay heat Helium heated in gap zone 2 hits the reflector ceiling directly 5. The heat transfer through this also causes the gas in the second cooling circuit 10 more heated and is in the steam generator 15 through a larger amount of heat increased steam generation. As a result, the steam turbine 16 runs faster, drives that second fan 11 with increased speed and thus provides for cooling the Reflector cover 5 sufficient circulation of the gas in the second cooling circuit 10. Likewise a pump 19, which is also driven by the steam turbine 16, runs faster, whereby an increased water throughput takes place through a third cooling circuit 18, which ensures reliable cooling of the pressure vessel cladding 4 will. The third cooling circuit 18 closes an external heat sink 23, for example a cooling tower. The second cooling circuit 10 can, if the heat extraction in the heat exchanger 15 should not be sufficient, it should also be provided with an air cooler 24.

As FIG. 2 shows in more detail, the pressure vessel lining 4 is on their outside is provided with a number of cooling tubes 34, which are always alternating a base load cooling circuit that is no longer shown and operated with constant cooling capacity and belong to the third cooling circuit 18, which has a different cooling capacity is operated as a control load cooling circuit according to the changing heat accumulation. In addition to the ceramic insulation 3, there is one made up of cast steel blocks thermal shield 35 is provided. The reflector ceiling 5, the false ceiling 27 and a lateral reflector shield 36 are made up of individual graphite blocks 32.

The first two are made up of a steel tube made of tubes Support frame 6 held, in turn by Strcben 37 and anchor 38 on the pressure vessel 1 is attached.

The reflector ceiling 5 and intermediate ceiling 27 are made by spacers 30 (which, as shown here, can be molded onto the latter) kept at a distance, so that the inlet and distribution space 29 is formed for the cooled cooling gas from which it is fed through openings 28 in the intermediate ceiling 27 of the cleavage zone 2 will.

At the same time, the spacers 30 protect the corresponding Parts of the supporting structure 6 in front of the gas of the first cooling circuit 7. The individual Blocks of the reflector ceiling 5 are provided with recesses, once the formation allow of spaces 31 which are filled with stagnant gas and the Reduce heat transfer through the reflector ceiling, and the other enable the insertion of sealing strips 33 also made of graphite, on the one hand the exaggeratedly large gaps drawn here between the individual blocks 32 are sealed and on the other hand the same with each other be connected so that they can also be used in the event of failure of a single element of the supporting structures 6 can still be held.

To the heat transfer from the false ceiling 27 to the supporting structure 6 as possible, are arranged between the two ceramic washers 39.

L e r s e i t e

Claims (6)

Reflector cover for high-temperature reactor protection claims of gas-cooled High temperature reactor with cooled reflector ceiling and one from top to bottom first cooling gas stream directed through the cleavage zone, characterized in that below the reflector ceiling (5) and at a distance from it one with openings (28) Intermediate ceiling (27) is arranged, which with the reflector ceiling (5) has an entry and distribution space (29) for the first cooling gas.; flow (7) limited. 2. Reactor according to claim 1, characterized in that the top the reflector ceiling (5) is cooled with a second cooling gas stream (10). 3. Reactor according to claim 2, characterized in that the reflector (5) and intermediate ceiling (27) 3n a common through the second cooling gas flow (10) cooled supporting structure (6) are suspended. 4. Reactor according to claim 3, characterized in that Oas support structure (6) in the entry and distribution space (29) within the distance between the reflector (5) and intermediate ceiling (27) bridging spacers (30) is performed. 5. Reactor according to one or more of claims 1-4, characterized in that that the reflector cover (5) from several, on most of its area through gas-filled interstices (31) consists of separate layers. 6. Reactor according to one or more of claims 1 - 5 with liner Reflector ceiling constructed from individual ceilings, characterized in that the Joints between the individual blocks (32) are closed by sealing strips (33), which engage in grooves cut out on the side of the blocks.