WO2009012994A1 - Device for cleaning a steel melt - Google Patents

Abstract

An insert of a refractory material for a tundish, with a surface that comes into contact with a metal melt during operation, is improved for cleaning the melt of nonmetallic impurities, because the surface is provided with elevations and/or depressions in a structured manner.

Description

Device for cleaning a molten steel

The present invention relates to a weir plate for cleaning a molten steel in a tundish with the features of the preamble of claim 1.

The removal of non-metallic impurities from a molten steel is essential to the quality of the melt-cast billet or billet.

During the casting process, liquid steel is poured from a ladle into a tundish distributor (intermediate vessel), on the underside of which, in turn, a discharge opening for the melt is provided. A first removal of non-metallic impurities occurs already in that slags and other materials due to the lower density in the tundish rise to the surface, while the specific denser melt is present at the bottom disposed opening and runs there. The process is, however, a total of turbulent, so that even lighter impurities can pass through the turbulence in the area of the outlet and thus get into the product or deposit in the area of the drain, the free passage for steel narrow and it comes to deposits, which in addition to the known problems in the cast product (poor degree of purity) can also lead to casting problems (smearing) and resulting Gießabbruch.

One way to keep this turbulence out of the drain is on the one hand in the installation of baffles or weirs in the tundish and on the other hand in the arrangement of

Internals. A weir divides the tundish into a first area into which the melt is filled and a second area containing the outlet. Such a plate may be provided with flow openings and protrudes upward beyond the level of the melt. The melt can run from the first region of the tundish, in which the material is filled, only through these openings or under the plate into the second region of the tundish, so that there is a limitation of the flow cross-section and thus a calming of the melt. Non-metallic impurities remain in the area and are deposited especially on the surface which has flown over, but especially at the holes and around the holes.

More elaborate devices for cleaning the melt are known, for example, from JP 59035614. Here, porous pipes are inserted into the drain, which the

To trap impurities on its surface while the melt flows from the outside of the tube through the porous material to the inside of the tube, which communicates with the outlet. From the publication JP 7268437 a device is known in which a porous filter body is provided within the melt with a motor drive and is rotated in the melt. The centrifugal force causes the melt to flow through the filter body from the inside to the outside, thereby actively filtering it. These devices are already very expensive due to the additional drive. There are also others known for a tundish having a textured surface with rib, protrusions and recesses. Examples are given in the following documents: DE102004011883B4, DE2643009A1, EP0463257B1 and FR1081253. The internals shown in these documents are primarily intended to prevent the spattering of metal at the beginning of the casting process. They are installed at the bottom of the tundish. These are not weir plates. Conventional weir plates have a flat surface.

It is therefore an object of the present invention, a

To provide a device for the removal of impurities from a melt, which ensures an improved result compared to the conventional weir plates with little effort.

This object is achieved by a device having the features of claim 1.

Because the tundish weir plate has a textured, raised or dimpled surface, flow parallel to the surface is slowed down and non-metallic contaminants contained in the flow are likely to be deposited on the surface structure thus formed. The built-in part is used in the form of a baffle plate or weir in the tundish, so that a forced flow from one side of the insert to the other side of the insert takes place. The surface structure is then provided in particular near the openings through which flows on the side of the tundish into which the melt is introduced.

The structure is preferably formed by projections, in particular hemispherical projections or frustoconical projections. The projections can also cuboid or cube-shaped, which is however more expensive to manufacture, especially during demolding.

The mold for the production of the insert is only slightly more expensive than the known forms, when the surface structure is applied substantially in the vicinity of the flow openings. For a large-area effect but can also be provided that the entire surface of the insert facing the filling area is provided with this structure. A particularly preferred embodiment is a weir plate, which is installed trapezoidally over the cross section of the tundish and provided with flow openings. The weir plate is made in a conventional manner from a refractory material.

When the protrusions or recesses forming the structure are arranged in a distribution which does not have continuous parallel rows, disturbing rectilinear flow paths between the structural elements can not occur.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Show it:

Fig. 1: an insert in the form of a weir plate in a plan view;

Fig. 2: the weir plate in a perspective view in cross section along the line II-II of Fig. 1; such as

FIG. 3 shows a weir plate according to the invention without flow openings.

FIG. 1 shows an insert in the form of a weir plate for a tundish. The weir plate 1 has an upper side 2, a lower side 3 and two outer side surfaces 4 and 5. Together with a visible in Fig. 1 front 6 and a non-visible back 7, these surfaces define a substantially plane-parallel plate with trapezoidal shape. The plate is designed so that it can be inserted into a tundish as a separation between two adjacent areas of the interior. The outer shape is accordingly adapted to the specifications of the tundish, in which the plate is to be used.

The plate carries a number of through holes, indicated generally at 10. The passage openings 10 have a circular cross-section and extend from the front side 6, which in operation is the flowed surface, to the back 7 of the plate. Likewise, a semicircular recess 11 is provided which represents a breakthrough between the front 6 and the back 7 in the region of the bottom 3.

The front side 6 of the plate 1 is provided with a structure comprising a plurality of frusto-conical projections 13. The projections 13 are evenly distributed over the front side 6 of the plate. They rise above the front 6 and thus are in the installed position of the plate 1 in the tundish into the first area, which is bounded by the plate 1.

Fig. 2 shows a cross section along the line II-II of Fig. 1 in a perspective view. The same components bear the same reference numbers.

It can be seen on the cross-sectional area that the main body of the plate 1 has a uniform thickness throughout perpendicular to the front side 6, apart from the knob-shaped projections 13 which rise above this surface. The plate 1 is made entirely of a refractory material, as is known in the art.

For use, the plate 1 is installed in a tundish in such a manner that the front side 6 is aligned with the area in which the molten metal is filled. The back side 7, which in this embodiment has a smooth surface, faces the region in which the outlet of the tundish is arranged. The side facing away from the flow may be smooth or in any way fully or partially napped.

When filling the melt this first passes through the opening 11 and then with increasing level through the through holes 10 in the second part of the tundish. The openings 10 and the opening 11 cause a flow of the melt, which at least partially has a component in the direction parallel to the front side 6. This flow is slowed down by the structure of the surface 6 in the form of the projections 13, so that specific lighter inclusions can rise here on the one hand and are not taken into the second area of the tundish. On the other hand, non-metallic inclusions in the melt may also be caught on the surface structure of the front side 6, so that they are held back and do not reach the second area of the tundish. Both effects cause the melt in the second region of the tundish and in the spout to contain a lower level of non-metallic impurities than would be the case if a conventional double faced smooth weir plate were used.

Figure 3 shows an inventive weir plate in eienr embodiment without Durchströmoffnungen. Otherwise, this weir plate corresponds to the embodiment shown in FIG. When used In a tundish distributor, the impurities are trapped on the surface structure 13, while the melt can flow under the weir plate due to the distance between the underside 3 of the weir plate 1.

The surface structure of the front side 6 can alternatively be configured differently. For example, it is not absolutely necessary for the projections 13 to be distributed over the entire surface. It is sufficient if a number of projections 13 are arranged around the passage openings 10 and the aperture 11, although the embodiment described is preferred.

The projections 13 may also have a different shape, for example, be hemispherical, cylindrical or truncated pyramidal.

It has proven in practice to be particularly advantageous if the projections are oriented at right angles to the surface of the weir plate within the manufacturing accuracy. The projections are then cuboid or cube-shaped. With this geometry, a particularly high degree of separation of non-metallic impurities is achieved.

In another embodiment, the surface structure of the front side 6 may be formed so that no protrusions are formed, which extend beyond the plane of the front 6 addition, but that on the contrary recesses or indentations are provided, the depressions in the plane of the front 6 inside represent. Even such depressions slow the flow in the region of the openings 10 and 11. However, in this embodiment there is no "baffle surface" beyond the front side 6, which in the case of that described in FIGS Embodiment protrudes into the flow parallel to the front side 6.

Claims

claims 1. Use in the design of a weir plate made of a refractory material for a tundish, with a in use a molten metal contacting surface (6,7), characterized in that the surface is structured with elevations (13) and / or depressions. 2. Use according to claim 1, characterized in that the insert with a number of openings through which can flow (10) is provided. 3. Use according to claim 2, characterized in that the surface structure (13) is provided in particular near the through-flow openings (10) on the side of the tundish, in which the melt is filled. 4. Use according to one of the preceding claims, characterized in that the structure is formed by elevations, in particular of hemispherical projections or frustoconical projections. 5. Use according to one of the preceding claims 1 to 3, characterized in that the projections are cuboid or cube-shaped. 6. Use according to one of the preceding claims 1 to 3, characterized in that the projections are formed in a truncated pyramid. 7. Use according to one of the preceding claims, characterized in that the entire filling area facing surface (6) of the insert with the structure (13) is provided. 8. Insert according to one of the preceding claims, characterized in that the structure (13) forming projections or recesses is arranged in a distribution which has no continuous parallel rows.