POWDER-TRANSFER DEVICE WITH IMPROVED FLOW

Abstract

A device for transferring a given powder or a mixture of given powders contained in a container including a side wall and at least one discharge opening, the container with axisymmetric shape having an axis of rotation being arranged in the transfer device such that the discharge opening thereof is located in a lower portion of the container, the transfer device including rotating the container about the axis thereof, on which the discharge opening is located and control for controlling the rotation such that the rotation impose on at least one portion of the side wall of the container, referred to as movable portion, a first moving phase wherein an acceleration no lower than a minimum acceleration is capable of causing the powder to slide relative to the movable portion.

Claims

1-17. (canceled)

18. A transfer device for transferring a given powder or a mixture of given powders, the transfer device comprising a hopper intended to contain the given powder or the mixture of given powders, said hopper comprising a side wall and at least one discharge opening, said hopper having a axisymmetric shape and having a substantially vertical axis of revolution, said hopper being arranged such that its discharge opening is located in a lower portion of said hopper, the transfer device comprising device for displacing the hopper in rotation about its axis of revolution, whereon the discharge opening is located, and control unit of the device for displacing in rotation such that the device for displacing in rotation imposes on at least one portion of the side wall of the hopper, referred to as movable portion, a first moving phase wherein an acceleration greater than or equal to a minimum acceleration capable of causing the given powder or mixture of given powders to slide relative to the movable portion is applied to the movable portion.

19. The transfer device according to claim 18, wherein the minimum acceleration is greater than or equal to the product of the coefficient of static friction, of the force exerted by the powder on the side wall of the hopper and of the radius of the hopper divided by the moment of inertia of the powder.

20. The transfer device according to claim 18, wherein the control unit controls the device for displacing in rotation such that, during a second phase after the first phase, it maintains the movement in rotation of the movable portion in a given direction of rotation.

21. The transfer device according to claim 20, wherein the control unit is such that the device for displacing in rotation displaces the movable portion at a constant speed during the second phase.

22. The transfer device according to claim 18, wherein the control unit is such that device for displacing in rotation imposed on the movable portion a succession of first phases separated by phases at low or zero speed.

23. The transfer device according to claim 22, wherein the control unit is such that the device for displacing in rotation imposes a displacement of the movable portion such that its direction of rotation is inverted between two successive first phases, in such a way as to impose an oscillating rotating movement.

24. The transfer device according to claim 23, wherein the oscillating rotating movement is periodical.

25. The transfer device according to claim 24, wherein the oscillating rotating movement has a frequency between 5 Hz and 50 Hz.

26. The transfer device according to claim 18, comprising a dynamic sealing element between the movable portion and the fixed portions of the transfer device.

27. The transfer device according to claim 18, wherein the hopper is formed by a removable container.

28. A device for manufacturing nuclear fuel elements comprising a transfer device according to claim 18, a press provided with a table wherein at least one mould is formed and a device for compressing the powder in the mould, with the discharge opening of the hopper able to be placed facing said mould during a filling phase of the mould and able to be sealed off outside of a filling phase.

29. A method for transferring a given powder or a mixture of given powders that implements the transfer device according to claim 18, with the method comprising at least the step of: a) setting into rotation a portion at least of the side wall of the hopper about an axis whereon the discharge opening is located with an acceleration greater than a minimum acceleration causing the sliding of the given powder with respect to the side wall.

30. The method for transferring according to claim 29, wherein the minimum acceleration is greater than or equal to the product of the coefficient of static friction, of the force exerted by the powder on the side wall of the hopper and of the radius of the hopper divided by the moment of inertia of the powder.

31. The method for transferring according to claim 29, comprising a later step b) of maintaining the rotation movement of the side wall in a given direction of rotation.

32. The method for transferring according to claim 31, wherein during the step b), the movement of rotation is carried out at a constant speed.

33. The method for transferring according to claim 31, wherein the steps a) are repeated successively separated by steps at a low or constant speed.

34. The method for transferring according to claim 33, wherein the direction of rotation is inverted between two successive steps a).

35. The method for transferring according to claim 34, wherein the direction of rotation is periodically inverted between two successive steps a).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] This invention shall be understood better based on the following description and on the annexed drawings wherein:

[0034] FIG. 1 diagrammatically shows an embodiment of a transfer device according to the invention,

[0035] FIG. 2 is a graphical representation of the force of friction between the powder and the wall of a hopper according to the force induced in the powder by the rotation of the wall of the hopper,

[0036] FIG. 3 is a graphical representation of the linear speed of the hopper according to two embodiments,

[0037] FIG. 4 is a diagrammatical representation of a device for manufacturing nuclear fuel pellets implementing a device for transferring powder according to this invention.

DETAILED DISCLOSURE OF PARTICULAR EMBODIMENTS

[0038] According to standard ISO 4490, a powder naturally flows through an orifice if it begins to flow when the opening is opened.

[0039] The invention relates to a device for transferring powder. This device can implement a hopper intended to fill recipients or to supply a manufacturing unit using a powder such as for example the moulds for producing nuclear fuel pellets. Alternatively, it can implement a recipient that is sought to be emptied, the latter being removable relative to the device.

[0040] FIG. 1 diagrammatically shows a device for transferring powder according to the invention. In the non-limiting example described the transfer device comprises an axisymmetric hopper 2 comprising an upper end 4 through which it is supplied with powder P and a lower end 6 through which the powder P is removed, and a side wall 8 between the upper end 4 and the lower end 6. The hopper comprises means 10 for temporarily sealing off the lower end 6. The hopper 2 has an axis of revolution X oriented vertically in the representation of FIG. 1.

[0041] The entire hopper can be set in rotation.

[0042] Alternatively, only an axial portion of the hopper can be set in rotation, in this case it is more preferably an axial portion located on the side of the lower end.

[0043] Preferably, means of dynamic sealing (not shown) with powder are provided between the hopper and the other fixed portions or then between the movable portion of the hopper and the fixed portion of the hopper.

[0044] The device also comprises means 12 for displacing the side wall of the hopper in rotation about its axis X and control means CU of the means 12. In this application, “rotation of the hopper” or more generally “rotation of the container” mean a movement of the hopper or of the container forms of complete revolutions or of a movement of oscillation between two angular positions, with the understanding that the two angular positions can be separated at most by more than 360°.

[0045] The means CU control the displacement means 12 such that the acceleration that they apply to the hopper is adjusted to a value greater than or equal to a minimum value a.sub.min about the X axis and that they then drive the side wall in rotation according a speed that is constant or not.

[0046] The minimum value of acceleration a.sub.min is chosen in such a way as to cause a sliding of at least one portion of the powder with respect to the side wall 8. The acceleration is such that it induces a force that is greater than or equal to the forces of static friction between the powder and the side wall.

[0047] In FIG. 2, the force of friction Fs or Fd and the force induced Fi by the rotation of the wall of the hopper can be seen. F.sub.s is the force of static friction and F.sub.d is the force of dynamic friction. It can be seen that beyond a certain value of force induced by the rotation of the wall, the force of friction is only dynamic and is weaker than the force of static friction, with this force not preventing the flow.

[0048] Indeed, before the setting into relative movement between the powder and the wall of the hopper, the forces of friction F between the powder and the wall are proportional to the normal component of the reaction (N) of the powder on the surface of the wall. The coefficient of proportionality is the coefficient of apparent powder/wall friction or coefficient of static friction μ.sub.s which depends on several parameters such as the surface condition and the roughness of the solids in contact.

[0049] The maximum value of the friction is given by the coefficient of static friction knowing the normal reaction of the wall on the powder:

F.sub.m=μ.sub.s×N

[0050] Generally, the coefficient of dynamic friction that corresponds to the forces of friction induced in the case where the powder and the wall are in relative movement in relation to one another. This coefficient noted as μ.sub.d is less than the coefficient μ.sub.s by about 10% to 20% in general.

[0051] The coefficient of static friction can be defined as follows:

[0052] μ.sub.s=tan θ.sub.s where θ.sub.s represents the angle with respect to the horizontal starting from which the powder is about to slide on the wall.

[0053] The coefficient of dynamic friction can be defined with the same expression but by using θ.sub.d the angle starting from which the powder slides continuously on the wall.

[0054] A powder in a hopper exerts through its weight, a force against the walls of the latter. The minimum acceleration of the hopper is chosen in such a way as to be higher than the product of the coefficient of static friction, of the force exerted by the powder on the wall of the hopper and of the radius of the hopper divided by the moment of inertia of the powder.

[0055] For a UO.sub.2 powder in cylindrical column with an inner diameter of 10 cm containing a height of powder greater than 15 cm, the relative acceleration must be greater than 1.2 in order to not drive the powder in rotation with the duct. For the same UO.sub.2 powder contained in a duct with a diameter of 8 mm less than the diameter of the natural flow of this powder which is 10 mm, the relative acceleration must be greater than 5. It is sought to obtain a displacement between the powder and the side wall that is greater than the size of the particles of powder. For example, if the particles have a diameter of 100 μm, the displacement can be 500 μm.

[0056] This minimum acceleration therefore induces a sliding of the powder with respect to the side wall and a flow of the powder.

[0057] In an embodiment that is particularly suited to the manipulation of powder that flows naturally, the means of displacing in rotation are controlled such that, after having applied a minimum acceleration a.sub.min, they impose on the wall of the hopper a permanent rotating speed, preferably constant, and this regardless of the state of sealing of the discharge opening. By maintaining the rotation of the side wall of the hopper, a relative movement is maintained between the powder and the side wall, only the dynamic friction between the powder and the side wall is then to be considered and this whether the discharge opening is open or closed. The sliding between the powder and the side wall is maintained. As such, as long as the sliding is maintained, as soon as the discharge opening is open, the powder flows instantly with a constant flown rate.

[0058] FIG. 3 shows the linear speed V1 as a function of the time t for two examples of movements that can be imposed on the hopper subassembly.

[0059] The speed designated as V1 describes the linear speed in the case of a device suited for powders that flow naturally, the speed V1 is constant. Alternatively, the speed could be variable monotonously or not.

[0060] The speed designated as V2 designates the speed in the case of a device suited for powders that do not flow naturally, this method of operation shall be described hereinbelow.

[0061] The powder flows when the acceleration is higher than a certain acceleration of the side wall of the hopper. Since the speed of rotation cannot be increased indefinitely, the direction of rotation of the hopper is inverted. The change in the direction of rotation induces a reversal in the direction of shear of the powder close to the surface of the hopper. The coefficient of friction will then decrease to approach zero then will increase again. The flow is then as such facilitated. The acceleration increases then above the minimum acceleration. Preferably, the relative acceleration is greater than 5 for the UO.sub.2 powders that do not flow naturally in order to obtain a constant flow rate.

[0062] In an embodiment particularly suited to the manipulation of powders that do not flow naturally, the movement of the hopper is intermittent with successive phases of rotation comprising a starting at an acceleration a.sub.min, a rotation in one direction and a stopping. In FIG. 3, it is possible to see an example of a movement that can be imposed on the hopper, designated by V2, which is the linear speed. The latter has a sawtooth shape and changes sign periodically, illustrating a change in the direction of rotation of the side wall of the hopper. This movement is preferred but is not exclusive of other movements, such as for example non-periodical movements.

[0063] Starting at an acceleration a.sub.min causes a rupture of the arches that has reformed. A rotation of the hopper after the rupture of the arches maintains the flow as long as the arches have not reformed again.

[0064] Very advantageously, the direction of rotation of the side wall is inverted at each phase of rotation. A relative oscillating movement is therefore applied which makes it possible to create sufficient shear between the particles close to the wall and those that are farther away. This shear leads to a dilatancy of the powder that causes the rupture of the arches. This rupture allows the powder to flow.

[0065] More particularly, the oscillating rotating movement can be broken down into two phases:

[0066] When the arches have been reformed, the powder no longer flows.

[0067] The direction of rotation of the hopper is inverted. The forces of friction change direction. However, under the effect of inertia, the powder tends to retain the same direction of rotation. In this phase, the side wall of the hopper and the powder rotate in the opposite direction. The powder slides on the side wall of the hopper and the stresses generated between the particles that slide still with friction on the side wall of the hopper and those farther away lead to an intense local shear of the powder. This shear causes a dilatancy of the powder on the wall which breaks the arches and as such allows for the flow. When the forces of friction become greater than the forces of inertia, the powder is again driven in rotation by the side wall of the hopper. The direction of rotation of the container is then again inverted in order to retain the flow of the powder.

[0068] Preferably, the side wall of the hopper has a periodical movement.

[0069] The amplitude of the relative displacement of the powder with respect to the side wall of the hopper is according to the acceleration of the side wall of the hopper, of the inertia of the powder and of the friction between the powder and the side wall of the hopper. This relative displacement provokes the forming of shear stress in the powder in the vicinity of the walls which create a dilatancy of the powder, which drives the rupture of the arches which may have formed and prevents the forming of new arches.

[0070] The frequency of the oscillating movement is chosen preferably in order to obtain a permanent flow, i.e. the direction of rotation is inverted before the flow is interrupted by the forming of arches.

[0071] For example frequencies between 5 Hz and 50 Hz make it possible to have a permanent flow for UO.sub.2 powders.

[0072] It could however be provided that the direction of rotation be inverted only when the stopping of the flow is detected, in the case of a flow sensor, for example optical, would inform the means of displacement.

[0073] In the case of a powder flowing naturally, it can be provided to apply to the hopper an oscillating rotating movement which has for effect to increase the flow rate of the emptying of the powder.

[0074] This invention implements a rotating movement that generates on the particles forces that are mostly directed tangentially in relation to the surface of revolution which causes the appearance of an intense shear in a zone close to the wall, contrary to the forces caused by implementing ultrasound or a system of the woodpecker type which are, primarily normal to the surface. In the case of an oscillating rotating movement, the thickness affected by the shear is advantageously much lower than that which is when a system of the woodpecker type is used. This low shear volume has the advantage of not allowing the powder to thicken significantly contrary to what happens under the effect of the vibrations caused by a system of the woodpecker type. Compacting the powder and therefore penalising the flow is thus avoided.

[0075] The rotation means 12 can be formed by a motor indexed in position of which the shaft is coaxial to the axis of the hopper and is secured in rotation to the means for suspending the hopper. The means for suspending are then directly engaged with the shaft of the motor. As such a setting into rotation of the shaft causes a displacement in rotation of the hopper. The motor is controlled by the control means in acceleration or in speed and in amplitude of angular displacement in the case of the transfer of powders that do not flow naturally.

[0076] The control means are formed for example by a computer comprising the control programs of the motor, the control program is chosen according to the powder or the mixture of powder to be transmitted. The computer can for example be connected to a power source of the motor.

[0077] The device for transferring powder can be used to supply for example the press mould or moulds of a device for manufacturing nuclear fuel elements.

[0078] Such a device for manufacturing nuclear fuel elements is shown diagrammatically in FIG. 4. It comprises a press 27 provided with a table 28 wherein at least one mould 30 is carried out, preferably several moulds. In the example shown, the evacuation end of the hopper 2 is open in order to fill the mould 30 and is directly sealed off by the surface of the table during the compaction of the powder and the ejection of the compacted powder. The evacuation end slides on the table 28 and when it is facing the mould, the latter is open. Thanks to the invention, the powder flows instantaneously into the mould 30 at a substantially constant flow rate. The powder is then compacted. As such it is possible to obtain a homogeneous filling of the mould at each step of filling and to obtain pellets of which the characteristics are substantially identical. The delay in the flow that is generally observed during the filling of the dies of the press is suppressed, the speed of the flow is increased and the quantity of material poured into the mould is homogeneous over the entire height of the mould thanks to the mass flow which is constant. The invention makes it possible to increase not only the speed of production by decreasing the filling time but also the quality of the product after compaction since the latter is in part a function of the homogeneity of the material obtained after filling.

[0079] The two embodiments apply to the filling of moulds for the manufacture of nuclear fuel pellets.

[0080] Preferably, the putting into rotation of the side wall begins prior to a series of fillings of moulds in order to be sure that the powder will flow as soon as the evacuation end is opened.

[0081] In the example described, the element containing the powder to be emptied is a hopper, but this could more generally be a container intended to contain powder that is sought to be emptied, with the container intended to be filled while it is in place in the transfer device, such as a hopper or with the container being filled beforehand then set in place in the transfer device and on which the means for displacement 12 apply a relative movement according to the invention.

[0082] The device for transferring powder according to the invention is suited for the transferring any type of powder in all fields of activity that implement powder.