DE1263939B - Device and method for regulating or shutting down a nuclear reactor with a pile of spherical operating elements - Google Patents

Description

Apparatus and method for controlling or shutting down a nuclear reactor with a bed of spherical operating elements The present invention relates to a device for regulating or shutting down a nuclear reactor with a bed spherical operating elements, in their area rod-shaped control or shutdown elements be retracted and extended and a method for operating this device.

From the magazine "Die Atomwirtschaft", September 1959, p. 377 bis 384, is already a gas-cooled bulk material nuclear reactor with a negative temperature coefficient known in which the reactivity reduction required to shut down the reactor is made with the help of rod-shaped shutdown elements within special internals arranged in the reactor are performed, for. B. in noses or Guide tubes. The performance of such a nuclear reactor is achieved by taking advantage of the negative temperature coefficient by changing the fan speed for the cooling gas circuit regulated.

However, such a type of power control is not available for all nuclear reactors This type of construction is sufficient, as the individual performance levels are related Reactor temperatures would differ too greatly. These temperature differences can, however, be avoided by adding suitable control elements to the reactor be built in, which allow the reactivity of the reactor to be reproducible and to change it in sufficiently small steps. The entire reactivity change moves in a range of only a few percent.

The rod-shaped required for the operation of the known nuclear reactor Control and shutdown elements can also be combined in a combined device which is used both to regulate and to shut down the nuclear reactor. To with the help of the known device the necessary high negative reactivity influences To achieve shutdown of the nuclear reactor, the rod-shaped shutdown elements must be introduced near the axis of the reactor, with special for their guidance Internals, e.g. B. pipes, noses or ring walls made of graphite, used in the crevice zone will. However, the known device has very significant disadvantages because the internals mentioned have high mechanical, thermal and radiation loads exposed and therefore very prone to failure.

The materials withstanding such stresses are great expensive and difficult to work with.

Is also taken into account that a real shutdown of the nuclear reactor, d. H. a subcritical run at low temperature, only rarely occurs, so falls the effort to be carried out in the construction of the crevice internals in particular heavy weight. On the other hand, however, must take place for the in the event of an accident Emergency shutdown of the nuclear reactor constantly a sufficiently large shutdown reactivity are available to lower the reactivity of the reactor as quickly as necessary.

US Pat. No. 2,812,303 discloses another type of bulk nuclear reactor known, which can be cooled either with a gas or with a liquid. The reactor is controlled by means of an absorber rod located in the Cleavage zone moved within a guide made of graphite or beryllium. For this tour The same disadvantages apply as above for the exclusively gas-cooled Nuclear reactor were asserted; d. H. it must be high mechanical, thermal and withstand radiation exposure. moreover, everyone brings through the crevice leading channel, if it touches areas of high neutron flux, considerable neutron losses with himself.

The present invention has the task of providing a device and to provide a method by which it is possible to measure the reactivity of a bulk nuclear reactor for the purpose of regulation or disconnection, without this in the Gap zone fixtures required for the rod-shaped shutdown or control elements are.

This object is achieved according to the invention in that the rod-shaped Elements are conically pointed at their end penetrating into the bed and moved directly through the bed while displacing the operating elements will.

This device solves the problem in a very simple manner resolved the influencing the reactivity of a bulk nuclear reactor to be able to make without any particular construction or material problems appear. The advantage of the device can be seen in the fact that none Internals of the cleavage zone are required, and on the other hand, that it is a good one Owns neutron economy. This is mainly of then. great importance if the method tied to the device for influencing the reactivity of Converter: or breeder reactors should be used. By eliminating the gap zone fixtures, like guide tubes or the like, none of the bulk material free occur in the cleavage zone Channels more on and connected to such a channel leading through the gap zone Neutron losses are also eliminated.

When the rod-shaped elements are immediately retracted in the channels that form the fissure zone close again by themselves as soon as the elements have been removed from the cleavage zone.

The method associated with the device described above permits In addition, apart from control elements that regulate the output and switch off the Nuclear reactor and therefore contain neutron absorbing substances, all possible Types of test elements, irradiation samples or the like in the fissure zone of a bulk material nuclear reactor without tubes or channels being provided in the cleavage zone and the Impair the neutron budget. Such samples are made into rod-shaped elements introduced and driven directly into the bulk material, at any desired Place of the cleavage zone. The reactivity of the nuclear reactor is only influenced as long as how the samples are located in the cleavage zone; since, as already described, those when the rod-shaped elements, which act as carriers, are moved into the gap zone resulting gaps or channels immediately after removing the rod-shaped elements close again by themselves.

According to the method associated with the apparatus described above the emergency shutdown of the nuclear reactor takes place in stages, initially in one first stage, the rod-shaped shutdown elements are arranged outside the gap zone are and under the influence of gravity through a reflector up to be introduced into the bulk material to a specified depth and a "prompt" Cause a reduction in reactivity and then through in a next stage Use of external forces to overcome the penetration resistance of the bed a further introduction of the shutdown elements into the bulk material up to their end position occurs, with an additional, "slow" weakening of reactivity.

The procedure is based on the knowledge that there is also an emergency shutdown in a nuclear accident, the last part of the necessary To change the reactivity by a "slow" lowering of the reactivity. The shutdown procedure is therefore structured in several stages, with the first stage there is a "prompt" reduction in reactivity, and possibly one after the incident Occurring increase in reactivity, as z. B. in the presence of one with water fed secondary circuit can result from a water ingress, neutralized. Such a "prompt" reduction in reactivity is achieved by the rapid running in of the Rod-shaped shutdown elements reached in the bulk material, the shutdown elements under the influence of gravity to a predetermined depth ir the crevice zone penetration. This is followed by a significant «change in reactivity due to the further Introducing the shutdown elements into the bulk material, with an external forced drive is applied. The degree of delay with which the reactivity change occurs is freely selectable by the speed at which the shutdown elements can be introduced into the bulk material.

In the event of an operational shutdown of the nuclear reactor, the for such a case required reactivity lowering also with the help of rod-shaped shutdown is made slowly and without any hindrance can be introduced into the bulk material to a predetermined depth. Special fixtures in this case, too, do not need to guide the shutdown elements in the gap zone to be present.

The speed of the falling shut-off elements is measured in such a way that that when they penetrate the bulk material, the spherical operating elements do not to be damaged. The special shape of the ends entering the bed The shutdown element also helps prevent damage to the operating elements be avoided.

Another retraction of the rod-shaped shutdown elements into the bulk material can advantageously be effected in that the shutdown elements of a certain Depth of penetration from the removal and addition of spherical operating elements alone or set in motion in addition to other types of drive.

If the nuclear reactor has a ceiling reflector, the shutdown elements are advantageously housed above this ceiling reflector. To the shutdown elements To be able to introduce into the gap zone, the ceiling reflector has corresponding channels on, in or above which the rod-shaped elements are arranged. So with small ones Deviations of the rod-shaped elements from the vertical position no torque that would cause additional frictional forces are the elements suspended in a suitable device.

The neutron absorbing substances are beneficial inside the housed rod-shaped elements, and the exterior of the elements consists of one Metal jacket.

The rod-shaped disconnection elements are expediently on their surface Equipped with cooling fins to prevent the penetration of the elements into the bulk material to be able to dissipate heat generated in the element better. The cooling fins should be there those that inevitably occur when coolant is passed through the bulk material Enhance the cooling effect. On the one hand, namely by increasing the rod surface the heat transfer between shutdown element and coolant improves while on the other hand, by attaching ribs, the heat exchange between a shutdown element and the operating elements adjacent to it because of their smaller contact area reduced. That an inevitable cooling effect occurs on the shutdown elements, if a coolant flows through the bulk material from top to bottom, it could be experimental be detected. It is based on the fact that the cooling is in the vicinity of a smooth wall increases noticeably, since there the bulk density is considerable decreased. Added to this is the fact that the power of the switch-off element immediately adjacent Operating elements as a result of the lowering of the flux in the vicinity of the shutdown rod likely will be less than the average power of the operating elements.

Another advantageous possibility, rod-shaped disconnection elements To cool, consists in the shutdown elements with one over their entire Equip length extending cavity and her in the bulk material penetrating end as well as at a point on its surface that is also at one up Shutdown element retracted to the maximum depth still above the surface of the bulk material is to be provided with one or more wall openings.

Here, the pressure drop of the coolant between the upper and lower wall openings of the retracted shutdown element exploited to a To allow part of the coolant to flow through the interior of the element. pre-condition is, however, that at a higher temperature in the cleavage zone at least one Part of the fan for the coolant circulation is in operation.

The particular advantage of this cooling method is that the Amount of the coolant flowing through the shutdown element according to the size of the between the coolant pressure drop prevailing in the upper and lower wall openings of the shutdown element directs. As long as the shutdown element is outside of the bulk material, will there is hardly any coolant flowing through it, while one is retracted to its end position Element the maximum cooling effect is achieved.

Expediently, those located in the ends of the disconnection elements have Wall openings have such a shape that they are not affected by the operating elements can be covered. You can e.g. B. a cross-section tapering into several grooves own.

Claims (7)

Claims: 1. Device for regulating or switching off a Nuclear reactor with a bed of spherical operating elements, in their area Rod-shaped regulating or shut-off elements are retracted and extended, thereby g It is not shown that the rod-shaped elements are attached to their in the bed penetrating end are tapered and displacing the operating elements be moved directly through the bed. 2. Procedure for operation a device according to claim 1, characterized in that the emergency shutdown of the nuclear reactor takes place in stages, initially in a first stage the rod-shaped Shutdown elements are arranged outside the gap zone and under the action the force of gravity through a reflector to a predetermined depth in collapse the bulk and in a next stage by an external forced drive to overcome the penetration resistance of the bed advanced to its end position will. 3. A method for operating a device according to claim 1, characterized in that that the operational shutdown of the nuclear reactor by continuous running-in the rod-shaped shut-off element up to a predetermined depth in the bed he follows. 4. The method according to claim 3, characterized in that of a predetermined Penetration depth from the switching elements by removing and adding the bulk material be set in motion alone or in addition to other types of drive. 5. Device according to claim 1 for the shutdown and regulation of a nuclear reactor a ceiling reflector, characterized in that channels are provided in the ceiling reflector are, in or above which the rod-shaped elements are arranged in a suspension are. 6. Apparatus according to claim 5, characterized in that the rod-shaped Elements from a neutron absorber located inside the elements and from consist of an outer metal jacket. 7. Apparatus according to claim 6, characterized in that that the rod-shaped elements are provided with cooling fins on their surface. B. Apparatus according to claim 6, characterized in that the rod-shaped elements have in their interior a cavity extending over their entire length and have several wall openings, some of which are located in the Bulk immersed rod end and the other part at one point on the rod surface is located, even with the rod-shaped element retracted to the maximum depth lies above the surface of the bed. Considered publications: U.S. Patent No. 2,812,303; Die Atomwirtschaft, September 1958, p. 377 bis 384.