LU87914A1 - ELECTROMAGNETIC LINGOTINE BREWING DEVICE - Google Patents

Abstract

A mould for continuous casting comprises: (i) a mould tube (14) for receiving molten metal (16); (ii) a cooling circuit surrounding the mould tube (14) for cooling it; (iii) an electromagnetic induction coil (32) for provoking a gyratory movement in the molten metal (16) in the mould tube (14) around its axis, this electromagnetic induction coil (32) being vertically displaceable w.r.t. the mould tube (14); and (iv) a cooling circuit (34, 36) for the electromagnetic induction coil (32). The electromagnetic induction coil (32) with its cooling circuit (34, 36) and the mould tube (14) with its cooling circuit form two separate units. The induction coil unit is mounted around the mould tube unit in a manner that enables it to slide axially as a block along the length of the mould tube (14). The method used to adjust the height of the induction coil unit is also claimed. A crane is used to slide the induction coil (32) unit in some vertical guidance shafts (50) along the length of the mould tube (14) and a mechanical system is used to support the induction coil (32) on the guidance shafts (50) in different predetermined vertical positions. A feature of this continuous casting mould is the use of a source of radiation for constant surveillance of the meniscus of the molten metal in the mould.

Description

ELECTROMAGNETIC LINGOTINE BREWING DEVICE

The present invention relates to an electromagnetic stirring device in an ingot mold for a continuous casting installation comprising a vertical shell receiving molten metal, as well as an electromagnetic inductor for generating a gyratory movement of the molten metal in the shell around the axis of it.

A device of this kind is known from document EP-A-0093068. Depending on the quality and nature of the cast products, two different casting methods are practiced. The open or free-jet casting process simply consists in letting the liquid metal flow into the shell through a calibrated nozzle at a more or less constant flow rate. The level of the steel meniscus in the ingot mold is controlled by adapting the extraction speed according to the extraction and according to the indication of a level measurement installation based on a radioactive principle. This process is mainly used for the casting of medium quality steel billets, since the casting is carried out in contact with air.

To improve the quality of the steel, an air-protected casting process is used, which is casting with submerged nozzles and powders. According to this process, the liquid steel is introduced into the shell through a nozzle which plunges into the liquid metal which is in the shell. Contact with air and oxygen is prevented by a layer of powder covering the surface of the metal at the pouring meniscus.

In this case, the casting takes place at a constant extraction speed. The level of the ingot mold steel is controlled by a buffer or a distributor drawer.

For the two casting methods it is also known to improve the quality of the steel by electromagnetic stirring which must however be adapted to the casting method chosen and to the targeted qualities of the steel. Thus, for example, in the case of free-flow billet casting, the major aim sought by the application of electromagnetic stirring in an ingot mold consists in improving the surface condition of the billets by eliminating the pitting and the slag inlays. To achieve this, the speed of rotation of the ingot mold steel at the meniscus must be very high, hence the importance of the location of the inductor relative to the meniscus on the surface condition of the billets.

On the other hand, in the case of pouring blooms with submerged nozzle and pouring powder, it is advantageous to reduce the speed of rotation at the meniscus to avoid as much as possible the entrainment of the pouring powder and reduce wear of the nozzle, while keeping a mixing intensity as high as possible below the meniscus. In other words, for free-jet casting it is preferable that the inductor is located in the upper region of the shell, while for casting with submerged nozzle, it is preferable that the inductor be placed at a lower level. This is the reason why, to take full advantage of the advantages offered by electromagnetic stirring in an ingot mold, it is preferable to have two different installations for implementing each of the two casting methods.

The object of the present invention is to provide a new electromagnetic stirring device in an ingot mold which allows the implementation of the two casting methods in the same installation.

To achieve this objective, the present invention provides an electromagnetic stirring device of the type described in the preamble, which is essentially characterized in that the inductor is arranged outside the shell and is movable vertically relative to the latter .

According to an advantageous embodiment, the shell is surrounded by a first coaxial steel tube which, in turn, is disposed inside a second coaxial tube around which the inductor is mounted, while the annular spaces between the two tubes and between the shell and the first tube are crossed by a coolant.

The device can be provided with a detector of the level of the steel in the shell, which consists of a cylindrical radiation source mounted inside the second tube and associated with a scintillometer mounted on the opposite side of said second tube. .

The radiation source is preferably located inside a cylindrical lead protective jacket provided with a radial slot and movable around the axis of said source between an angular position in which the slot is directed on the shell and an angular garage position in which the slot is directed on a cylindrical lead block extending along said jacket.

The ingot mold which consists of the shell, the inductor and the two tubes can be made up of a set of underlying rollers and can be dismantled as a unit. Other particularities and characteristics will emerge from the detailed description of an advantageous embodiment presented below, by way of illustration, with reference to the appended drawings in which: FIG. 1 schematically shows a vertical section of a device according to the present invention illustrating the inductor in position for free jet casting; Figure 2 shows a view similar to that of Figure 1, the inductor being in the casting position with submerged nozzle and Figure 3 shows schematically a horizontal section through the shell and the radiation source.

The figures. 1 and 2 show an ingot mold 10 contained in a metal casing 12. The ingot mold 10 essentially comprises a vertical tubular shell 14 containing liquid metal 16 which is poured from a not shown tundish. The molten metal 16 gradually solidifies in this shell and the metal blank is extracted there by passing through a set 18 of underlying guide rollers and for forming the metal blanks. According to a preferred embodiment of the invention, the set of rollers 18 is solid with the ingot mold 10 and can be dismantled in block with the latter.

The shell 14, which generally consists of a copper tube, is surrounded by a coaxial steel tube 20 which forms with the shell an annular cylindrical space 22 in which circulates a coolant from the shell 14. Another space cylindrical 24 is delimited around the tube 20 by a second tube 26. This space 24 is closed downwards by an annular plate 28 fixed to the two tubes 20 and 26. The cooling water enters the circuit at 30 and then into the annular gap 22 between the shell 14 and the tube 20. This space is very thin to ensure rapid circulation and efficient cooling in the shell 14. The cooling water thus rises along the shell to overflow through the top of the tube 20 and fill the annular space 24. The cooling water leaves this space 24 by overflowing in a vertical pipe, not shown, arranged along the inner wall of the tube 26 and then through s an outlet pipe.

Around the outer tube 26 is an electromagnetic inductor 32, known per se, for carrying out the electromagnetic stirring of the metal 16 in the shell 14. The electromagnetic device 32 can consist of one or more inductors.

In accordance with the present invention, the inductor 32 is not fixed, but can be moved vertically between an elevated position according to FIG. 1 for free jet casting and a lower position according to FIG. 2 for casting with submerged nozzle. The means for moving the inductor 32 can be constituted by any suitable means known per se, for example three vertical threaded rods which support the inductor 32 and which can be rotated synchronously by a suitable motor.

According to a simple and effective embodiment the inductor 32 slides vertically in several, for example three guide rods 50, the vertical maneuver being carried out by a crane not shown. In the example shown, the rods 50 are designed to position the inductor 32 in three different vertical positions defined by three upper radial perforations 52 and two lower notches 54.

When the inductor 32 is raised to the position according to FIG. 1, it can be retained there by manually engaging a claw not shown in the upper notch 54 and wedged using a not shown key engaged through the upper perforation. .

In the lower position the inductor 32 rests on the bottom of the mold 10 and can be keyed by the lower perforation 52. If the illustrated embodiment allows a third intermediate position, not shown, it is, of course, possible to n '' plan only two or plan more. The inductor 32 can also include a separate cooling circuit, which is symbolized by the arrows 34 and 36 for the inlet and outlet of cooling water.

Another feature of the present invention is monitoring the level of the meniscus of the liquid metal in the shell 14. This monitoring is carried out using a radiation source 38, for example with cobalt, arranged in the upper region of the annular space 24 which is associated with a scintillometer 40 disposed on the opposite side of the shell 14. To reduce the risk of radiation from the personnel, this source of radiation 38 is located inside a cylindrical protective jacket 42 , as shown in more detail and enlarged in Figure 3. This protective jacket 42 which can, for example, be made of lead, has a vertical slot 44 for the passage of the rays. This protective jacket 42 can be rotated around a vertical axis between an operating position shown in FIG. 3, in which the slot 44 is directed on the shell 14 and a garage position, not shown, in which the slot 44 is directed against a vertical absorption block 46. Thanks to this arrangement, an operator can carry out work on the shell 16 without being exposed to radiation from the source 38, this radiation being absorbed by the protective block 46.

The actual level measurement will not be explained in more detail since the use of a radiation source for level measurement is known per se.

Claims (6)

1. Electromechanical stirring device in a mold for a continuous casting installation comprising a vertical shell (14) receiving molten metal, as well as an electromagnetic inductor (32) to generate a gyratory movement of the molten metal in the shell ( 14) around the axis thereof, characterized in that the inductor (32) is arranged outside the shell (14) and is vertically movable relative to the latter. 2. Device according to claim 1, characterized in that the shell (14) is surrounded by a first coaxial tube (20) of steel which, in turn, is disposed inside a second coaxial tube (26 ) around which the inductor (32) is mounted and in that the spaces (22), (24) between the shell (14) and the first tube (20), respectively between the first tube (20) and the second tube (26) are crossed by a coolant. 3. Device according to claim 1, characterized by a metal level detector in the shell (14), said detector consisting of a cylindrical radiation source (38) mounted inside said second tube (26) and associated a scintillometer (40) mounted on the opposite side of said second tube (26). 4. Device according to claim 3, characterized in that said source (38) is located inside a cylindrical protective jacket (42) made of lead provided with a vertical radial slot (44) and in that said sleeve (42) is movable around the axis of said source (38) between an angular position in which the slot (44) is directed on the shell (14) and an angular position in the garage in which the slot (44) is directed on a cylindrical lead block (46) extending along said jacket (42). 5. Device according to any one of claims 1 to 5 characterized in that the mold consisting of the shell (14), the inductor (32) and the two tubes (20), (26) is integral with a set (18) of underlying rollers and can be dismantled as a unit therewith. 6. Device according to claim 1, characterized in that the inductor is movable vertically in three guide rods (50) comprising means for supporting the inductor (32) in different predetermined vertical positions.