FR2650112A1 - Improvement to discontinuous screw elevators used in the processing of irradiated fuels - Google Patents

Abstract

The subject of the present invention is a discontinuous screw elevator, including in a vessel 15 a helical ramp 8 with vertical axis. In order to transport solid components, the said ramp 8 is subjected to a to-and-fro movement, about its axis and in a horizontal plane. According to the invention, the said ramp 8 has on its surface 10 which supports the said solid components, a row of steps 11 arranged so as to allow advance of the said components and limiting their recoil (backward movement). Such a screw elevator can be used in the processing of irradiated fuels.

Description

Improvement in helical elevators; shaking jacks, used in the reprocessing of irradiated fuels.

 The invention relates to an improvement to helical jerk elevators, used in the reprocessing of irradiated fuels.

 It has been described in patent FR 2 474 469 such a lift used in particular for dissolving the fuel contained in irradiated elements from breeder reactors.

 Figure 1 reproduces this device of the prior art.

The following figures relate to the invention.

 According to Figure 1, the elevator comprises a cylindrical tank (1) with vertical axis on the edges of LaqueLLe is fixed a helical ramp (2) of the same axis as the tank having turns. Through the chute (4) placed at the top of the tank are introduced the pieces of irradiated fuel (composed of a metal sheath containing the fuel in the form of more or less large fragments) which fall into the bottom of the tank where they are brought at the bottom (5) of the helical ramp thanks to the conical shape of said bottom (6).

 The ramp is moved back and forth around its axis and in a horizontal plane, having the effect of raising your pieces on the ramp when the advances and receipts are suitably chosen.

 The pieces thus assembled remain in the Liquid contained in your tank and The fuel which they contain is dissolved during this time. Only hulls (pieces of sheath) remain.

 These shells are rid of the residual liquid they contain during their passage in the emerged part of your ramp, in the upper part of the tank. They exit the elevator via La goulotte (7).

 Such a device is also used for the zincing of the hulls coming from fuel elements coming from various reactors (PWR, BWR, with fast neutrons ...), the dissolution of the fuel having previously taken place in another device.

 In these two applications, the elevator is placed in an area closed to people because the products treated are highly irradiating and / or contaminating.

The elevator ramp according to the prior art cited is set in motion by a motorization means (jack) arranged in
the area prohibited to persons; iL has at the end of its rod a connecting means fixed on the outside of the tank.

 However, in nuclear industry, it is preferable that the personnel have access to the motorization means to ensure regular maintenance or replacement, this access having to be allowed with all the guarantees of safety.

THE LIFTER ACCORDING TO THE PRIOR ART allows only remote intervention by remote handling since the jack is placed in a prohibited area; this implies operations that are more delicate to carry out and a choice of equipment Limited to those resistant to
Irradiation and corrosion, hence a higher cost of installation.

In addition, in the elevator according to the prior art, the rod of the jack ensuring the motorization having its end secured to the tank, one is forced to a large stroke of said rod so that the ramp reaches a sufficient speed in the direction of
The rising propeller (forward of the hulls) or so that the ramp has time to stop in the direction of the descending propeller, causing the minimum recoil of the hulls.

 However, it is desirable in nuclear industrial operation to reduce this stroke to limit the displacement of the ramp, or of the tank if the ramp is arranged on the internal wall of the tank.

Furthermore, it is not possible to tolerate the dissolving of irradiated combustibles accumulating beyond a certain threshold of fissile material which is not dissolved, nor in rinsing the circulating stop shells. The operator must therefore be able to guarantee a residence time for the solid compounds in the elevator, when it is used as a dissolver or guarantee an average flow rate in
The rinser application.

For all these reasons of guarantee of safety in industrial exploitation, we have been led to perfect the helical jerk elevator known according to the patent.
FR 2 474 469.

The present invention relates to a helicoSdal jerk elevator, comprising, to ensure the transport of solid compounds - in a tank, with vertical axis, located in an area inaccessible to personnel and containing liquid - a helical ramp, dale with vertical axis , at least partially submerged in said
Liquid; Said ramp being mounted on the internal wall of said tank and being subjected to a back-and-forth movement around its axis and in a horizontal plane, by at least one motorization means and a drive means characterized in what
Said ramp has on its surface supporting said solid compounds, stair treads (or steps) each comprising a flat surface and a stop; said staircase steps (or steps) being arranged so as to allow the advancement of said compounds and to limit their recoil.

Each stair step (or step) has a flat surface and a stop. The staircase steps (or steps) make it possible to stop the hulls (generally solid compounds) against their abutments in case they collect. The decline of these compounds on
The ramp is therefore Limited, The cylinder rod stroke is therefore reduced.

 The plane surface of each mark is obviously incined with respect to the direction of the ramp; in other words, the planar surface has an angle of inclination (relative to a horizontal axis) greater than that presented by the ramp.

 The pitch (length of the plane surface), the inclination of this planar surface, the height of the stop and its angle with the plane surface, are chosen by a person skilled in the art according to the solid compounds to be treated, the flow rates to ensure and possible ramp speeds and accelerations.

Preferably, the flat surface and its stop cover the
Width of the ramp.

 Preferably also, all the stair treads or steps are identical on the ramp, but this arrangement is not compulsory.

 According to an advantageous embodiment of the invention, the ramp has at least one drainage duct open at the intersection between the stops and the plane surfaces.

This arrangement prevents accumulation against
The stops, fines, filings ..., alone or mixed with liquid.

Said small particles which are at the intersection of the abutments and flat surfaces, then flow, due to the inclination of the ramp, into the drainage conduit.

 To facilitate this flow, it is advantageous to tilt each flat surface towards said conduit. It is advantageous to arrange the conduit on the median axis of the ramp, and the flat surface is inclined on each side towards this conduit. The conduit is then formed, for example by a groove arranged on the upper surface of the ramp supporting the solid compounds.

 The conduit can be located on the edge of the ramp on the side of the tank, against which the solid compounds are pushed back under the effect of the accelerations created. In this case, it is advantageously constituted by recesses arranged between the ramp and the internal wall of the tank.

One or more ducts can be fitted as required. The conduit (s) extends over the entire
Length of the ramp. Each duct must have openings on the intersection zones between the stops and the plane surfaces. It can also be opened over its entire length.

According to another characteristic of the invention, the motorization means located in an area accessible to the person acts on the lower end of a shaft with the same axis as the tank,
Said shaft being solidified at the level of its lower part, situated in the area accessible to personnel, by means of motorization.

 Various means of motorization are possible: cylinders, eccentric motor, cam system ... Cylinders are preferred (pneumatic, hydraulic cylinders, servo-actuator). They are chosen as a function of their response time to a command, it is obviously advantageous to minimize this time in order to reduce the stages between the phases of the movement, advantageously for this reason pneumatic cylinders and servo-cylinders are preferred. On the other hand, their power may be insufficient when the elevator is of large size and / or When the flow rates are high, then the hydraulic cylinders are preferred.

Figures 2, 3 and 4 illustrate the invention
- Figure 2 shows the surface condition of the ramp.

 - Figure 3 shows the drainage conduit.

- Figure 4 shows the arrangement of the drive means -
motor and means.

 According to FIG. 2, the ramp (8) shows a lower incined surface (9) (inclination of the ramp) and a surface (10) supporting the solid compounds which has stair treads (11). These stair steps or steps have a flat surface (12) and a stop (13).

 The planar surface (12) is inclined (relative to a horizontal axis), its inclination g (relative to the horizontal axis) is obviously greater than the exLination ex presented by the surface (9). The length of this surface (12) is not called.

 Each surface has, at its lower end, a stop (13) extending over a certain height and making an angle with the surface (12) which is preferably 900. The angle must be sufficiently open so that the solid compounds can exit and to limit the accumulation against the stop when the propeller is raised.

 It is clear that the solid compounds move freely on the plane surface (12) and come to bear against the stop (13) when the ramp does not have sufficient speed to make them advance.

 Figure 3 shows a preferred embodiment with a drainage conduit (14), located on the median axis of the ramp (8).

 A bleeding was made on the surface (10) supporting the solid compounds and provided with stair treads (11). The steps were then machined so as to incline the plane surfaces (12) towards said groove. The surfaces (12) are also inclined (by an angle ss - a) relative to the inclination of your ramp.

 We could just as well have shifted the duct to one edge of the ramp, or plan several.

 It is obvious that the width of the conduit (14) is less than the smallest dimension of the solid compounds (diameter of the substantially cylindrical shells for example) so that these compounds do not fall into the conduit.

 The depth of the duct (14) is chosen by a person skilled in the art, it obviously depends on the thickness of the ramp.

 In FIG. 4, we have the tank (15) with its helical ramp (8) mounted on the internal wall of the tank. In (16), the bottom of said tank (15) is shown.

 The motorization means (19) is located in a zone (II) accessible to the personnel, separated from the zone (I) prohibited by a slab (21) of biological protection (The continuity of the biological protection is ensured at the level of the crossing slab by The tree (18)).

 The means (17) of connection between the bottom (16) of the tank and the shaft (18) are remotely removable to be able to remove the coupling and the mechanical link between said bottom and said shaft.

 The removal of the shaft is carried out from its lower part located in zone (II) after removal of the motorization means (19).

The invention provides an advantageous embodiment of the coupling and its mechanical linkage for easy disassembly of
The tree (18).

According to this detailed realization figure 4, The means
(17) ensuring the connection between the bottom (16) of the tank and the shaft
(18), are constituted by Liai mechanical sounds (22) and (23), joining an intermediate piece (24) to respectively the bottom (16) of the tank and the shaft (18). This part preferably comprises a plate (25) situated under the bottom (16) and preferably of the same dimension, and a cylindrical part (26) substantially of the same diameter as the shaft (18) and of the same axis as said shaft.

 The means (23) can be removed remotely (by remote manipulators, for example placed in zone (I)), so as to remove the mechanical connection between the part (24) and the shaft (18).

 In this advantageous embodiment, the locking of the part (24) and of the shaft (18), for a safe drive of the tank and the maintenance of the mechanical connection in the event of loss of the connections (23), is ensured by a rod. (27) provided at its upper end with a key (28).

In the part (24) and the shaft (18), recesses are arranged allowing the sliding of the rod with its end in the form of a key (28), and allowing the support of the key (28) on the lower edge. of the recess in the room (24) to block
Said rod.

 Advantageously, this key (28) has a rectangular shape, it suffices to turn the rod 900 to block it; the rectangular side coming along its entire length resting on the lower edge of the recess arranged in the intermediate piece (24). Any other form of key having the same functions would be suitable.

 A removable clamping means (29) is placed at the lower end of the rod (for example a nut which is screwed onto a thread of the rod), to ensure the locking of the rod mounted in place in the device.

 Such an improved device makes it possible to significantly improve safe operation in a nuclear environment.

 The bottom (16) is secured by means (17) to the shaft (18) of the same axis as the tank which constitutes the drive means of the ramp.

 The motorization means (19) advantageously consists of a jack acting on a plate (20) fixed to the end of its rod, said plate being secured to the lower end of the shaft (18).

Claims (8)

Limit their recoil.  1.Helical shaker elevator, comprising, to ensure the transport of solid compounds - in a tank (15), with vertical axis, located in an area (I) inaccessible to the person and containing liquid - a helical ramp (8) to vertical axis, at least partially submerged in Ledit Liquide; Said ramp (8) being mounted on the internal wall of said tank (15) and being subjected to a reciprocating movement around its axis and in a horizontal plane, by at least one motor means (19) and a drive means (18) characterized in that said ramp (8) has on its surface (10) supporting said solid compounds, stair treads (11) each comprising a flat surface (12) and a stop (13 ); Said stair steps (11) being arranged so as to allow the advancement of said compounds and to  2. helical elevator according to claim 1, characterized in that on the ramp (8) is arranged at least one drainage conduit (14), open at the intersection between the stops (13) and the flat surfaces (12 ).  3. Helical elevator according to claim 2, charac terized in that the planar surfaces (12) of the stair treads (11) are also inclined towards said conduit (14).  4. Helical elevator according to one of claims 2 or 3, characterized in that said conduit (14) is located on the median axis of the ramp (8).  5. helical elevator according to one of claims 2 or 3, characterized in that said conduit (14) is located on the edge of the ramp (8), close to the inner wall of the tank (15).  6. helical elevator according to any one of the preceding claims, characterized in that said drive means consists of a shaft (18) of the same axis as the tank (15), secured at its upper part to the bottom of said tank (15) by means remotely removable and secured at its lower part, located in the area accessible (II) to personnel, by means of motorization (19).  7. héîicoidaî elevator according to claim 6, characterized in that said shaft (18) is secured to the bottom of said tank (15) by means of an intermediate piece (24) located in the axis of said tank (15); Said intermediate piece (24) comprising on the one hand a plate (25) located under the bottom of said tank (15) and secured to it by mechanical means (22) and on the other hand a cylindrical part (26) , secured to the upper end of said shaft (18) by mechanical means (23); and in that said intermediate piece (24) and said shaft (18) are locked by a rod (27) provided at its upper end with a key (28) and at its lower end with a clamping means (29 ); said rod being housed in recesses arranged on the axis of said shaft (18) and said intermediate piece (24).  8. helical elevator according to any one of the preceding claims, characterized in that said motorization means (19) is a cylinder chosen from pneumatic, hydraulic or servo-cylinders.