FR2530366A1 - Gas tight encapsulation of fuel rods - Google Patents

Abstract

The container (16) used is gastight except for the charging opening, after the container has been charged a bell or hood (8) is lowered over the charging opening, the lower edge (8a) of the bell being below the opening; the water level within the bell is then lowered by expelling it from the bell, a vacuum attachment is then connected to the opening of the container (16) in gastight manner and the container is internally vacuum dried. The evacuating attachment is then disconnected from the container opening and the latter is closed with a gastight cover (10), the bell (8) being filled with gas during this period. Pref. during the drying process, the water surrounding the vessel is heated to promote drying. After vacuum drying the container may be filled with a gas, esp. air and/or carbon dioxide or an inert gas, esp. a noble gas. Pref. the vacuum drying is monitored with pressure and temperature sensors connected to the charging opening of the container (16). Used for charging a vessel with highly radioactive components, esp. used nuclear fuel rods, where water is used as the shielding during the process. By carrying this out under water in a dry hood, as described, the process is greatly simplified. Effective shielding is provided by the water throughout the operations.

Description

 Process for the gas-tight containment of radioactive elements and installation for the implementation of said process.

The invention relates to a process for the gas-tight confinement of radioactive elements, in particular irradiated fuel rods of nuclear reactors, in a container in which the radioactive elements are loaded under water and which is then dried. inside, as well as an installation for the implementation of said process
Such a process is already commonly used in nuclear power plants. It is in a swimming pool and underwater that the irradiated fuel rods of nuclear reactors or the fuel elements comprising such irradiated fuel rods are loaded into a container.

The container is then removed from the swimming pool, the water therein is emptied, the interior is dried and then closed in a gas-tight manner for subsequent storage of the bars or of the combustible elements which it contains.

 For the container placed outside the swimming pool, we are obliged, because of the bars or the radioactive combustible elements which it contains, to take special protective measures against radiation, these measures considerably complicating the emptying of water, drying and gas tight closure of the container.

 The object of the invention is therefore to eliminate these particular protective measures against radioactive radiation.

 This result is achieved with a method of the aforementioned type which is characterized according to the invention by the fact that a container is used which is closed in a gas-tight manner with the exception of a filling orifice, only after loading. under the water of the container, there is above the filling orifice a bell filled with gas in the lower opening which engages the filling orifice of the container, the bell lowering the level of the water surrounding the filling orifice below it, after which, under the bell, the filling orifice of the container is connected in a gas-tight manner to a vacuum device by which the interior is vacuum dried of the container and that after this drying, the vacuum device is detached from the filling orifice and, operating under the bell filled with gas, the latter is closed in a gas-tight manner by means of a cover.

 In this way, all the operations to be carried out on the container are executed without difficulty under the water which is in the swimming pool and serves as protection against the radioactive radiation emitted by the radioactive elements with which the container is or will be loaded.

 An installation for implementing this method is advantageously characterized in that on the bottom of a swimming pool, a cylindrical element with a vertical longitudinal axis is installed as a tube receiving an elongated container and, next to this cylindrical element , a vertical guide bar for a bell and that, on its underside, the bell has an opening facing the cylindrical element and, inside, a rotary plate with vertical axis of rotation which carries, on its underside , a device for the evacuation and complete drying of the container and another device for the airtight application of a cover on the filling opening of the container. After the bell filled with gas from this installation has been placed above the filling opening of the container, it can be handled without difficulty under the bell, dry it empty and then close it in a gas-tight manner.

The invention will be better understood using the description of an embodiment taken as an example, but not limiting, and illustrated by the appended drawing, in which
Figure 1 shows in longitudinal section a swimming pool of an installation for implementing the method according to the invention with side view of the bell and the cylindrical element serving as a receiving tube;
2 shows in partial longitudinal section a front view of the bell and the cylindrical element serving as a receiving tube according to Figure I;
Figure 3 shows a plan view of the bell according to Figure 2;
4 shows, in another partial longitudinal section, a front view of the bell according to Figure 2;
5 shows in partial longitudinal section a front view of a device installed in the bell according to Figure 4;
FIG. 6 represents in partial longitudinal section, a side view of another device installed in the bell according to FIG. 2.

In FIG. 1, the installation according to the invention comprises, immersed in a swimming pool 2 filled with water, a truss-carrying framework of which one can see two vertical tubes 3 and 4. By their upper ends, these vertical tubes 3 and 4 climb up to a work platform 5 arranged above the pool. The trellis supporting structure provided with the two vertical tubes 3 and 4 comprises a base plate 6 which rests by feet 7 on the bottom of the pool 2,
The vertical tube 4 of the truss-supporting structure serves as a guide bar for the bell 8 which is provided with a guide sleeve 9 associated with this vertical tube 4. On the upper part of the bell 8 is fixed a traction rod vertical 10 going up to the working platform 5 and allowing, using a crane not shown, to lower the bell 8 or to lift it up to the working platform 5. The lower final position of the bell 8 is in particular determined by a stop 11 placed on the vertical tube 4.

 On the base plate 6 is installed, in addition to the tube 4, a cylindrical element 12 with vertical longitudinal axis 12a placed so that its upper end can engage in the opening 8a on the underside of the bell 8. This cylindrical element 12 has a double wall delimiting a hollow space which is filled with gas, preferably air, to reduce the thermal conductivity of the cylindrical element 12. Inside this cylindrical element 12 and on its bottom is installed a support ring 13 with vertical longitudinal axis which has the lateral openings 14 for the passage of water. On this support ring 13 is placed, with its vertical longitudinal axis, a connecting sleeve 15 in which is an elongated container 16, also with a vertical longitudinal axis, which is loaded with fuel rods or irradiated fuel elements from a nuclear reactor. At the upper end of the cylindrical element 12 is a collar 51 which is connected by connecting elements not shown to the lattice support frame of which the two vertical tubes 3 and 4 are part. This collar 51 is used for guiding radial of the connecting sleeve 15. Electric heating elements 41 and a pyrometric probe 42 are installed on the bottom of the support ring 13.

 Inside the bell 8 which has an opening 8a on its internal face, is mounted a compressed air supply tube 40 provided with a level switch and capable of injecting compressed air into the bell 8.

When the bell 8 is lowered to the stop 11, the compressed air injected under the action of the level switch causes the water level to drop below the upper end of the cylindrical element 12 and therefore also of the connecting sleeve 15 and the filling orifice at the upper end of the elongated container 16 which is also closed in a gas-tight manner. Instead of compressed air, carbon dioxide or an inert gas, preferably a rare gas, can also be injected into the bell 8 as a filling gas.

 In the bell 8 there is also a rotary plate 17 provided with a hollow gas-tight hub 18 which passes through the upper wall of the bell 8 and is rotatably mounted with vertical axis of rotation in a bearing 19 which is gas-tight and water placed on the upper wall of the bell 8. With the aid of a pivoting mechanism 20 and by means of a gear and the hub 18, the rotary plate 17 can be rotated around its longitudinal axis . Inside the bell 8 is also provided a pawl 21 for blocking the turntable 17.

 On the underside of the turntable 17 is installed not only a device shown in Figures 2 and 6, for the gas-tight application of a cover on the filling orifice of the container 16, but also, with an angular deviation relative to the axis of rotation of the hub 18, another device, shown in FIGS. 4 and 5, for evacuating and completely drying the container 16.

 As can be seen in particular in FIG. 5, the device for evacuating and drying the container 16 comprises an upper block 22 with which are associated two vertical guide rods 23 which are fixed on the underside of the rotary plate 17. On the underside of this rotary plate 17 is also a hydraulic cylinder 24 whose piston 24a is coupled to the upper block 22, On the block 22 are provided a suction and vacuum pipe 25 and a supply pipe of compressed air 27. On this upper block 22 are further installed sensors 28 and 29 for measuring the pressure and the temperature of the vapor in the container 16. Finally, the upper block 22 also includes sealing rings 52 which, during the evacuation and complete drying of the container 16, ensure the sealing of the upper block 22 placed on the filling orifice of the container 16.

 As illustrated in particular in FIG. 6, the device for the gas-tight application of the cover 30 on the filling orifice of the container 16 is also arranged in an adjustable manner in height on a vertical guide rod 31 placed on the underside of the turntable 17. For the height adjustment, the upper block 33 of this device further comprises a hydraulic cylinder 32 whose piston is connected to the underside of the turntable 17. The upper block 33 includes another pneumatic cylinder 34 for actuating the gripper 35 provided for handling the T-piece 30a mounted on the cover 30 of the container 16. On the upper block 33 is also installed a hydraulic torch 36 with, associated therewith, a height adjustment device 37 and a device 38 ensuring the drive in rotation about a vertical axis for welding the cover 30 on the container 16.

 After having loaded, for example, the irradiated fuel rods of a nuclear reactor into the container 16, this container 16 with the connecting sleeve 15 is lowered, using a crane not shown, into the cylindrical element 12 'that it is below the surface of the water. Then, the bell 8 filled with air is brought above this cylindrical element 12 and lowered so that it is also immersed and the water level in the bell 8, or in its opening 8a placed on its underside, be pushed back below the opening of the cylindrical element 12 emerging in this opening 8a.

 For the complete drying of the internal space of the container 16, the rotary plate 17 is then rotated so that, in accordance with FIG. 4, the upper block 22 can be lowered from the complete vacuum and drying device and apply it to the filling opening of the container 16. Using the electric heating elements 41, the water located inside the connecting sleeve 15 is then heated. This also has the effect of heating the container 16 and the water it contains relative to the rest of the pool water. By creating a depression using the tubing 25, the state of saturation of the water in the container 16 is lowered below that of the water surrounding the latter. The intervening temperature gradient between the water surrounding the container 16 and the water contained in the latter causes a transfer of heat inside the container 16. The water vaporizes in the container 16 The vapor which forms is evacuated by the pipe 25 and can be condensed again in a condensation chamber 44 placed outside the bell 8 and cooled by the water in the swimming pool 2.

 After all of the water in container 16 has been evaporated, the temperature inside this container 16 equilibrates with the temperature of the water surrounding it.

It therefore deviates very appreciably from the saturation temperature of the water vapor corresponding to the internal pressure of the container 16. This can be seen using the pressure sensor 28, the temperature sensor 29 as well as the using the pyrometric probe 42. Via the compressed air supply pipe 27 and the suction pipe 25, it is possible to repeatedly bring air to the container 16 and expel it to remove any residual steam # it contains.

  After lifting the upper block 22 of the complete vacuum and drying device to move it away from the filling orifice of the container 16, the rotary plate 17 is made to rotate around the axis of rotation of the hollow hub 18, and this, until the upper block 33 of the device for the gas-tight application of the cover 30 on the container 16 has been lowered, this cover 30 being able to be engaged in the filling orifice of the container 16 at the using this device, then be welded in a gas-tight manner to this container 16.

 After this operation, the bell 8 is lifted along the tube 4 using the pull rod 10 and it is pivoted to the side so that the container 16 closed by the cover 30 can be removed from the cylindrical element using the crane not shown, then transported to a storage area.

Claims (10)

 1. Method for the gas tight confinement of radioactive elements, in particular irradiated fuel rods of nuclear reactors, in a container in which the radioactive elements are loaded under water and the interior of which is then dried, characterized by the fact that a container (16) is used which is closed in a gas-tight manner with the exception of a filling orifice, that after the container (16) is loaded under water, there is above the filling orifice a bell (8) filled with gas in the lower opening (8a) from which engages the filling orifice of the container (16), the bell bringing down the level of the water surrounding the filling opening below it, after which, under the bell (8), the container filling opening (16) is connected in a gas-tight manner to a vacuum device by which it is dried at empty the interior of the container (16), and after this drying, the vacuum device is detached from the filling orifice and, operating under the bell filled with gas, this filling orifice is closed in a gas-tight manner by means of a cover (30).  2. Method according to claim 1, characterized in that during vacuum drying, the water surrounding the container (16) is heated externally.  3. Method according to claim 1, characterized in that after the vacuum drying, a filling gas is introduced inside the container 16.  4. Method according to claim 3, characterized in that as filling gas is used air and / or carbon dioxide.  5. Method according to claim 3, characterized in that as filling gas an inert gas is used, preferably a rare gas.  6. Method according to claim 1, characterized in that the vacuum drying is monitored using a pressure sensor (28) and a temperature sensor (29) connected to the orifice. filling the container (16).  7. Installation for implementing the method according to any one of claims 1 to 6, characterized in that on the bottom of a swimming pool (2), a cylindrical element (12) with a longitudinal axis (12a) is installed ) vertical as a tube receiving an elongated container (16) and, next to this cylindrical element (12), a vertical guide bar (4) for a bell (8) and that, on its underside, this bell ( 8) has an opening (8a) facing the cylindrical element (12) and, inside, a rotary plate (17) with a vertical axis of rotation which carries, on its underside, a device for evacuating and the complete drying of the container and another device for the airtight application of a cover (30) to the filling opening of the container (16).  8. Installation according to claim 7, characterized in that the cylindrical element (12) has a double wall defining a hollow space filled with gas.  9. Installation according to claim 7, characterized in that the cylindrical element (12) contains for the container (16) a connecting sleeve (15) which rests with its vertical longitudinal axis on a support ring (13), which is also located with its vertical longitudinal axis in the cylindrical element (12), this support ring comprising lateral openings (14) for the passage of water and containing heating elements (41) for heating it this.  10. Installation according to claim 7, characterized in that the vacuum device and complete drying of the container (16) are associated with a pressure sensor (28) and a temperature sensor (29).