FR2629299A1 - System for stirring molten material - Google Patents

Abstract

Induction stirrer device 30 for molten material 20. The stirrer 30 consists essentially of parallel conducting windings 34 which create a polyphase gliding magnetic field which crosses the crucible 1 and modifies the natural stirring 23 of the molten material 20. Application to induction furnaces.

Description

BREWING SYSTEM OF MOLTEN MATERIAL
DESCRIPTION
The present invention relates to a melt brewing system produced in an induction furnace.

 The molten material, metal, oxide, ceramic or glass for example, is poured in the form of powder or debris in a generally cylindrical crucible, metal or refractory material and which is surrounded by an inductive coil.

 In the case of molten metals, it is found that the melt is the seat of a stirring, that is to say an upward flow in the center and down to the periphery, near the crucible. The free surface of the melt is the seat of diverging radial currents. This mixing is of essentially electromagnetic origin, because of the couplings between the induction magnetic field and the currents induced in the metal. In the case of other materials with higher resistivity, the brazing is of thermal origin and its direction is reversed: ascending at the periphery and descending in the center.

 The objective of the invention is to control and modify at will this brewing which has important consequences: by promoting the increase of heat exchange with the cooler wall of the crucible, it promotes a thermal regulation of the melt and limits the overheating; on the other hand, it favors the homogenization of the molten material as well as the circulation of any impurities to a slag; on the other hand, it thwarts the supply of powder that is poured above the free surface, because it is then rejected to the wall of the crucible and may remain there. Depending on the case, one may be led to want to accelerate the brewing, or on the contrary slow down or even reverse it.

 The invention makes it possible to achieve these ends, regardless of the direction of the stirring, by the creation of an additional electromagnetic field, superimposed on the field produced by the inductive coil, which creates localized forces in the melt and promotes brewing or opposing him. The invention also shows how this action does not corollary a harmful effect by electromagnetic coupling on induction heating performance.

 The invention adds to the induction device an apparatus that generates a polyphase electromagnetic sliding field exerting localized forces to a portion of the melt. These forces can be exerted on the periphery of the melt and are then vertical; they can also exercise favorably on the free surface and are then radial.

 The apparatus can be constituted in practice by linear electric motors.

We will now represent the various forms of the invention with the aid of the following figures given for illustrative and not limiting
FIG. 1 is a possible embodiment of the invention;
FIG. 2 is an embodiment equivalent to that of FIG. 1;
- Figure 3 is another embodiment equivalent to that of Figure 1;
FIG. 4 corresponds to another embodiment of the invention, and
- Figure 5 shows a construction detail that can be adopted for the embodiment of Figure 4.

 FIG. 1 firstly represents a crucible 1 consisting of a certain number of vertical elements 2, juxtaposed in the manner of the moats of a barrel and hollowed out with a cooling system composed of an inlet channel of liquid 4 and a coolant outlet channel 5, parallel channels, vertical, and joined at the top of the elements 2 by a junction 6. Two circular pipes 7 and 8 are established at the bottom of the elements 2 to serve respectively distributor and manifold to the channels 4 and 5 of each element 2 by connecting pipes 9 and 10. This crucible cooling system 1 is typical for elements 2 copper. In the present case, the crucible 1 is completed by a floor 11 that is axially movable downwards and that makes it possible to continuously withdraw a ingot of molten product 21 and then solidified.The hearth 11 is itself cooled by an annular channel 12 in which A coolant supply duct 13 and a coolant outlet channel 14 are opened. An induction coil 15 traversed by a high frequency current surrounds the upper half of the crucible 1. The material obtained in this furnace at induction comprises a zone of melt 20, at the height of the turn 15, which interests us more precisely here and which overcomes the solidified ingot 21 under the turn 15 and supported by the movable hearth 11.

The upper free surface 22 of the melt 20 is shown, in accordance with experience, for a molten metal, bent at the center and hollowed out at the periphery, near the crucible 1.

 Indeed, the molten metals are the seat of ascending currents in the center and descendants at the periphery that have been represented by the arrows 23 and which therefore result in a stirring of the melt 20.

 It is this stirring that is modified using the stirring device according to the invention and which will now be described. It is referenced globally by 30 and comprises a cylindrical magnetic yoke 31 consisting of ferrites which surrounds the induction coil 15. Its inner periphery 32 is cut parallel to parallel horizontal grooves 33 which house conductive wire windings 34 traversed by polyphase currents generated by A generator 40. Here is shown a three-phase network, so that windings 34a are traversed by an electric current to phase 9, other windings 34b by a current to phase T + (2S1 '/ 3) and the last 34c at a current at the phase f + (4i? / 3), and that the neighboring windings 34 are all phase shifted by 2/3, the sign of the phase shift being the same when moving in the same vertical direction . The windings 34 are almost a full turn and are powered by an external source at their ends 35 and 36 which are separated by an insulator 37.

 The stirrer device 30 is therefore in fact a linear motor that creates an electromagnetic field sliding upward or downward depending on the case. However, it is necessary that this electromagnetic field can pass through the wall of the crucible, that is to say the elements 2. It is therefore working at a relatively low frequency. It is possible to recommend frequencies of the order of 50 Hz which correspond to a penetration of 1 cm in copper.

 The electromagnetic field having penetrated through the crucible into the melt charge acts at the periphery thereof. If the sliding field is oriented upwards, it therefore induces upward forces at the periphery of the melt charge 20, which therefore hinder the stirring. Depending on the power involved, it is possible to slow down the stirring or to reverse it completely. The latter regime is sought especially when it feeds the interior of the powder crucible which must be melted. These powders are then rejected towards the center of the melt, in the hottest areas.

 On the contrary, a downward sliding field can be established to accelerate the mixing. We succeed then more quickly. to homogenize the melt charge 20 from a chemical and thermal point of view.

 It is very easy to modify the direction of the sliding field: it is enough to reverse the phases of two series of windings, for example 34b and 34c. This can be done by means of any switch.

 A problem related to this design is the creation of high frequency currents, induced by the turn 15, in the windings 34. To reduce the importance of these induced currents, it is necessary to isolate the windings 34 between them. It is also necessary to interpose filters 38 between the ends 35 and 36 of the windings 34 and the low frequency AC supply.

 It is sought to synchronize as far as possible the vertical speed in the melt charge 20 C at its periphery with the speed of the sliding field created by the stirring device 30. For this, the magnetic field created by the stirring device 30 must be as high as possible, if possible equal to several hundred gauss. This can be achieved in practice only with a high current which induces losses by electrical resistance. The stirring device 30 must therefore be refrigerated, which is carried out in FIG. 1 by means of a helix 39 surrounding the windings 34 and arranged in the magnetic yoke 31. This propeller 39 is traversed by water The velocity communicated to the periphery of the melt charge 20 is of the order of a few hundredths of the velocity of the sliding field created by the stirrer 30.

 A stirring device analogous to that which has just been described but which is more efficient has the reference 50 in FIG. 2. First of all, the windings 34 are each composed of several circumferential copper blades 51 superimposed and separated by insulating sheets. 52. The cooling system comprises a lower distributor 53 and a heated-water collector 54 at the top of the stirrer device 50.

The distributor 53 and the collector 54 respectively comprise a pipe 55 or 56, for the supply or the recovery of water, and a channel 57 or 58 opening into the pipe 55 or 56. The channels 57 and 58 are circumferential and located respectively just below the lowest of the windings 34 and just above the highest. They communicate with each other by means of vertical connecting channels 59, which are pierced through the conductive strips 51, the insulating sheets 52 and the shoulders 60 of the magnetic yoke 31 separating the neighboring windings 34.

 The ends 35 and 36 of the windings 34 are composed of several pins 37, each pin 37 being connected to a conductive blade 51 connected to the power supply.

 As shown in FIG. 3, the single stirring device such as 30 or 50 may be replaced by several stirring devices 70 of the same general conformation, but which each extend over a reduced angular sector and not over the entire circumference of the turn 15. and the crucible. Several of these stirring devices 70 are then arranged in parallel around the turn 15. The main advantage of this arrangement is that the currents induced by the turn 15 on the windings 34 are very small in this case. It is therefore useless to seek to protect the power supply of the windings 34.

However, the action performed by stirrers 70 on the melt charge 20 is also lower, so that the velocity communicated at the periphery of the melt charge 20 is lower than that obtained when using brewers. tubular 30 or 50.

 A somewhat different configuration of stirring devices is shown in FIG. 4. In this case, it is not sought to create a vertical velocity component at the periphery of the melt charge 20, but a radial component at the upper free surface 22 of this charge.

 For this, the stirring device that surrounded the turn 15 was removed and replaced by a stirring device 80 disposed above the free surface 22 and which is composed of coplanar circular concentric windings 81 and disposed in the same horizontal plane. As before, a polyphase field sliding is created: moving in the same radial direction, outwards for example, successively meet windings 81a, 81b, 81c, then again 81a, etc., brought to phases T for 81a, 9 + (2 t / 3) for 81b and S + (4/3) for 81c.

 The windings 81 are interrupted only in the center of the crucible, where radial branches 82 which serve to support the windings 81, and which are themselves supported by a vertical post 83 suspended at a fixed point 84, meet.

 As in the other -conceptions, a sliding electromagnetic field can be created which, as the case may be, exerts an action which favors the mixing of the molten charge by superimposing on the natural mixing of the latter or opposes it by opposing it.

 As in FIG. 2, each of the conductive windings 81 may be formed of conductive strips 85 separated by insulating sheets 86, conductive strips 85 and insulating sheets 86 being arranged vertically (FIG. 5). Each conductive strip 85 ends at its ends by two vertical pins 87 and 88 which are connected to a power supply.

 The design of Figure 4 is however applicable more specifically to molten materials relatively high resistivity, and therefore require the creation of higher frequency magnetic fields to be brewed effectively.

It will therefore be used substantially higher frequencies than in the previous examples, of the order of a few hundred kilohertz to obtain sufficient penetration under the free surface 22 of the melt charge 20. With such frequencies, it becomes impossible to place a stirring device around the induction coil 15, because the magnetic field could then no longer cross the wall of the crucible 1.

 Whatever the embodiment adopted, it can however be applied to all melted materials, regardless of their direction of mixing the influence of the sliding field produced by the stirring device is the same.

Claims (8)

 A melt brewing system (20) contained in a crucible (1) and heated by induction, characterized in that it comprises a generator apparatus (30, 50, 80, 70) of a sliding polyphase electromagnetic field, equipment generating localized forces in the melt.  2. melt stirring system according to claim 1, characterized in that the apparatus is disposed around the crucible and generates vertical forces in the melt located near the crucible.  3. melt stirring system according to claim 2, characterized in that the apparatus is composed of several polyphase linear electric motors and distributed around the crucible.  4. Melt stirring system according to claim 2, characterized in that the apparatus is composed of a single linear electric motor surrounding the crucible.  The melt stirring system according to claim 4, wherein the linear electric motor comprises circumferential windings traversed by a phase-determined electric current, characterized in that the windings are formed of superimposed circumferential plates (51) and separated by insulating sheets (52), conductive plates and insulation sheets being pierced by coolant channels (59).  A melt brewing system according to claim 1, characterized in that the apparatus (80) is placed at a longitudinal end of the crucible and generates radial forces in the melt, located mainly near the apparatus.  Melting system according to claim 6, characterized in that the apparatus is placed above the melt (20) and generates radial forces located mainly near the free surface (22).  melted matter.  Melting system according to claim 7, characterized in that the apparatus comprises  conductive windings (81), each traversed by a  determined phase current and coplanar.