Patent Number: 
Section: description

Referring now to the figures of the drawing in detail and first, particularly, to FIG. 1 thereof, there is shown a reactor pressure vessel 1 situated beneath a surface 2 of cooling water in a boiling water reactor, while a handling machine 4 can be displaced over the surface 2 on a bridge or ramp 3. The handling machine 4 bears a mast 5 in the form of a telescopic arm, and on end of the mast 5 a hood 6 is disposed. In the reactor pressure vessel 1, fuel assemblies 7, 70 of the reactor are positioned on a lower fuel assembly grid 8. The hood 6, in a working position of the mast 5, being fitted over top fittings of the fuel assemblies 7 belonging to one division X, while the other fuel assemblies 70, belonging to a second division and other divisions, are divided. In accordance with FIG. 2, the hood 6 is divided by side walls 9 into individual cells 12, the side walls 9 resting on bars 10 of an upper core grid. Each mesh of the core grid contains a group of in each case four fuel assemblies, the hood 6 being divided by the side walls 9 into four cells, under each of which there is a group of fuel assemblies belonging to the division X. In FIG. 2, in each case only the first fuel assemblies A, Axe2x80x2 and the second fuel assemblies B, Bxe2x80x2 of the division X, which belong to a first group I and a second group II, are shown. The other two fuel assemblies C, D of the first group I and the fuel assemblies Cxe2x80x2, Dxe2x80x2 of the group II, as well as the remaining groups III and IV belonging to the division X, cannot be seen in FIG. 2. The hood 6 is disposed in a frame 13 that is positioned on the top fittings of the fuel assemblies 70 that are spatially adjacent to the division X. The frame 13 bears video cameras 14 that are directed toward an outlet end of filling-level test lines 15. The filling-level test lines 15 are initially configured as flexible hoses leading to a connection on a height-adjustment device 15a, vent tubes 15b being connected to the connections. The vent tubes 15b are attached to suction tubes 16a, which branch in the form of a two-pronged fork and form an end of flexible extraction lines 16 which are guided out of the water as a bundle. For reasons of clarity, the filling-level test lines 15a are only shown for the fuel assemblies A and Bxe2x80x2 in FIG. 2, but it should be noted that corresponding vent tubes are also disposed on the suction tubes which lead into all the other fuel assemblies. The vent tubes 15b and the suction tubes 16a are jointly lowered by the height-adjustment devices 15a until they are positioned precisely on the top fitting of the corresponding fuel assembly. The positioning may be effected, for example, as a result of the branching point of the fork-shaped suction tubes 16a resting on a bow 110 of a fuel-assembly top fitting 11 or the ends of the suction tubes 16a resting on upper rod-holding plate 112 of the corresponding fuel assembly. If gas is then pumped into the cells 12 (e.g. via the extraction line 16) beneath the hood 6, a water level 17a falls in the cells 12 until it reaches a lower opening of the vent tubes 15b. The vent tube 15b of a cell whose end is highest determines the water level 17a beneath the gas cushion formed in the cell 12, since further gas then escapes through the corresponding vent tube 15b, generating gas bubbles at the other end of the vent tubes 15b, onto which the television camera 14 is directed. Adjustment of the vent tubes 15b and the extraction tubes 16, which are attached to one another, ensures that the extraction tubes always extract water below the water level that has been set in this way. Furthermore, an edge 23 of the fuel assembly channel of each fuel assembly generally projects a relatively long way above its upper rod-holding plate 112. It is therefore generally possible, by adjusting the position of the extraction tubes 16 and the vent tubes 15b with respect to one another, to ensure that even in the case of fuel assemblies which (on account of different production dimensions or different radiation-induced growth) do not all end at the same level, the fuel assembly channels of one group always project slightly above the water level 17a below the gas cushion of the corresponding cell. Fission products that enter the water of a fuel assembly therefore cannot pass through the water to the extraction tube 16 of the other fuel assembly. Therefore, they are also unable to pass into the gas cushion, which is common to a plurality of fuel assemblies, since the water of the fuel assembly is extracted while the pressure difference is still being built up-during heating, and therefore the fission products are initially driven gradually out of a defective fuel rod. FIG. 3 illustrates the first fuel assemblies A, Axe2x80x2 and the second fuel assemblies B, Bxe2x80x2 belonging to groups I and II, which have already been shown in FIG. 2, and also the two remaining fuel assemblies belonging to the groups and the corresponding fuel assemblies belonging to two further groups III, IV of the first division X. Furthermore, there are the further fuel assemblies 70 which belong to another, second division Y. Otherwise, FIG. 3 shows only those components of the apparatus according to the invention that project above the water level of the reactor well. These include four degassing devices 17, which are connected to the extraction lines 16 via a corresponding extraction device 18. The gases that are released in the degassing devices 17 are each removed from an assembly 19 which includes a gas-delivery device and a detector device which is configured to record radioactivity in gases. The measurement signals from the detector devices are fed via line channels 20 to an electronic appliance 21 which evaluates the measured values, displays them on a screen 22 in the form of measurement curves and inputs them to a programmed control unit 25 via an output line 24. Control lines 26 lead from the control unit 25 and are used to control the extraction devices 18 and the delivery devices, by which the removal of the gases released in the degassing devices 17 and the recording of the radioactivity of these gases in the assemblies 19 are controlled. FIG. 3 shows the configuration that is activated during the preliminary testing in groups of the fuel assemblies in the first division X. FIG. 3 indicates that the extraction lines 16 of each extraction device 18 branch a number of times, with a shut-off valve 28, 28xe2x80x2, which is likewise actuated by the control lines 26 of the control device 25, being located in each branch. It can be seen from FIG. 3 that the water from the first fuel assembly A belonging to group I together with the water from the second fuel assembly B and the further fuel assemblies belonging to group I is fed via the extraction lines 16 to one of the four extraction devices 18, namely a device 181, connected to a degassing device 171 and an assembly 191 (detector device), the shut-off valves 28 in these lines being set to pass (i.e. being open). FIG. 3 also shows that the same extraction device 18 which is connected to the first fuel assembly A belonging to group I is also connected to three further extraction lines 16xe2x80x2, the shut-off valves 28xe2x80x2 of which are in a blocking position. The extraction lines 16xe2x80x2 are provided in order, in the configuration shown in FIG. 4, to switch the corresponding extraction device in each case to a first fuel assembly belonging to one of the other groups II, III and IV as desired. This is because if neither the detector device of the assembly 191 nor any of the other detector devices on any of the channels reveals any significant increase in the radioactivity, the testing of all the fuel assemblies belonging to the first group I has ended. Then, the extraction hood 6 is raised by the handling machine, all the shut-off valves are opened by the control device 25 and all the lines are purged with pool water via the extraction devices 18. The extraction hood 6 can then be positioned at a new position above a further division of fuel assemblies, and the testing of the fuel assemblies belonging to a new division is commenced by purging the degassing devices 17 with fresh air via the extraction devices 18 and initially delivering fresh air beneath the hood 6 which has been fixed at the new position via the extraction lines 16. However, if a measurement channel, for example for group III, records a significant increase in the radioactivity, there is a leak in a fuel assembly in group III associated with the channel, and the leak has to be identified. For this purpose, as shown in FIG. 4, the devices which have already been used during the preliminary test are now assigned to the fuel assemblies in a different way by their shut-off valves 28 and 28xe2x80x2. For example, the extraction device 181, which in FIG. 3 was connected to the further fuel assemblies belonging to the first group I, is switched over so that it is only connected to the first fuel assembly belonging to group III which has the significant radioactivity, and likewise in each case one of the further extraction devices is switched over to in each case one fuel assembly belonging to the significant group III. In this way, each individual fuel assembly can be individually tested by extraction, degassing and detection, the corresponding measurement curve in the display 22 now allowing the defective fuel assembly to be identified. The extraction devices are assigned to the individual fuel assemblies in a program-controlled manner via the control device 25 through actuation of the shut-off valves 28. FIG. 5 shows a water circuit above the level of water 40 in which the fuel assemblies to be tested are positioned. A water circuit feeds the water 40, which has been sucked out beneath one or more hoods 6 in accordance with FIGS. 3 and 4, and returns the water 40 via the overflow line 16a after the degassing, to a collection vessel of the degassing device 171 via the extraction line 16 and an extraction pump 181. A line 41 that is used to suck in ambient air, for example via a pump 42 and an air filter 43, opens into the collection vessel of the degassing device 171. However, a throttle valve can also be used to introduce nitrogen or any other non-radioactive gas out of a pressure vessel into the collection vessel of the degassing device 171. The carrier gas bubbles through the collected water in the collection vessel of the degassing device 171 and collects all the gases that are dissolved and released in the extracted water. In this example, the release of the gases is facilitated by a pump 191a that, together with a corresponding outlet pump 181a, generates a vacuum in the collection vessel. The pumps, compressors and similar delivery devices 181, 181a, 191a and 42 illustrated here are controlled synchronously with an evaluation device 21 of a detector device 191b by the control device and are in this case only symbolically illustrated for corresponding devices which the person skilled in the art will provide at any time in order to ensure that, during the testing of a fuel assembly, suitable pressure conditions for extracting the water from the fuel assembly and for transferring the fission products which are released and are mixed with the carrier gas are ensured in the collection vessel 171. In the situation illustrated, the detector device 191b contains a xcex2 counter 19a and a xcex3 counter 19b, the sensitivity spectrum of which is specifically adapted to the energy spectrum of the fission products that are most frequently produced. The person skilled in the art selects the number and type of detectors in accordance with those isotopes that are primarily expected to form in the interior of the fuel rods. A disposal line 44 on the one hand connects the inlet of the detector device 191b to the outlet of the degassing device 171 and on the other hand connects the outlet of the detector device 191b to an outgoing-air duct of the nuclear power plant. Before water samples from the fuel assemblies are tested, the configuration is purged with water that, although it originates from the same pool, is not removed beneath the hood that has already been fitted over a fuel assembly that is in the heat-up phase. At this time, therefore, only fission products that are already present in the extracted water and form a constant xe2x80x9cradioactivity backgroundxe2x80x9d for the subsequent measurement are released in the extracted water. If a fuel assembly that is beneath the hood connected to the line 16 is now heated and the radioactivity recorded in the detector configuration rises, the rise is attributable to fission products escaping from the fuel assembly which is in the heat-up phase, and the measured values rise by the extent to which the discharge of fission gases increases. As a result, defects in the claddings of the fuel rods are detected at an early stage, and it is possible to start measuring further fuel assemblies at an early stage. The invention is not restricted to boiling water fuel assemblies and positions in the reactor pressure vessel. Rather, the function of the fuel assembly channel of an assembly of this type may also be performed by other containers or, for example, by corresponding shafts of a storage rack for pressurized water fuel assemblies.