WO2002076658A1 - Device for preventing a vortex effect in the discharge area of a metallurgical melting vessel - Google Patents

Abstract

The invention relates to a device comprised of a refractory ceramic material and provided for preventing a vortex effect in the discharge area of a metallurgical melting vessel. The device has a base part to which a cylindrical extension having at least one opening on the wall connects. The opening is arranged in such a manner that, after the device has been placed in the discharge area of the melting vessel, it is located at a distance from the bottom of the melting vessel and creates a connection to the discharge area of the melting vessel.

Description

 Device for preventing a vortex effect in the outlet area of a metallurgical

melting vessel

Description

The invention relates to a device for preventing a vortex effect in the outlet area of a metallurgical melting vessel. For example, in the outlet area of a so-called tundish (treatment vessel) for the treatment of molten steel, the phenomenon of so-called vortex formation can be observed again and again. When the molten steel is discharged, a vortex is formed. An uncontrolled flow of the melt occurs before and / or through the spout, with the result that particles of slag floating on the melt can be entrained. Preventing or at least reducing non-metallic inclusions in the molten metal is a primary goal, particularly in the field of secondary metallurgy. There has therefore been no lack of attempts to minimize or prevent the observed vortex formation by means of different measures. This includes the installation of refractory components in the outlet area, for example in the area of a freewheel nozzle.

Such a refractory body is proposed in US Pat. No. 5,382,003 A, which is placed on the base of the metallurgical vessel, around the spout. The body has the shape of a "tripod", the "legs" standing on the bottom of the metallurgical melting vessel.

The object of the invention is to show a possibility with which the vortex formation of a melt in the outlet area of a metallurgical melting vessel can be reliably prevented, at least under normal conditions.

The basic idea of the invention is to use a device made of a refractory ceramic material, which is arranged in the outlet area of the metallurgical melting vessel and covers the outlet area. In this way the ferrostatic pressure in the outlet area is reduced. Furthermore, the device should have one or more openings through which the melt located in the melting vessel can flow to the outlet region of the vessel, that is to say to the pouring spout.

A basic part of the device ensures that the melt is deflected on its way to the discharge area. An extension adjoining the base part serves as a “flow breaker”, that is to say the melt flow is divided into a plurality of separate partial flows. The openings are placed in such a way that they are at a distance from the bottom surface of the vessel in the assembled state of the device (in the metallurgical vessel) The distance from the floor level (= level from which the pouring opening runs) can be> 20 mm and <200 mm, for example 30 to 60, 60 to 80 or 70 to 100 mm.

This creates a kind of barrier for the melt. The device thus makes the use of a so-called starter tube superfluous. The melt filled in the vessel and / or a leading slag are prevented from flowing out via the spout until the melt level has reached the lower edge of the opening closest to the bottom of the vessel.

Overall, there is a simultaneous deflection and division of the flow of the metallurgical melt on its way to the pouring spout. In preliminary tests it was found that the aforementioned vortex formation can be practically completely prevented. In its most general embodiment, the invention relates to a device for preventing a vortex effect in the outlet area of a metallurgical melting vessel, with the following features:

- the device consists of a refractory ceramic material,

the device comprises a base part,

a cylindrical extension adjoins the base part with at least one opening on the wall,

- The opening is arranged so that it is at a distance from the bottom of the melting vessel after placing the device in the outlet area of the melting vessel and creates a connection to the outlet region of the melting vessel.

The aforementioned general structural specifications for the design of the facility can be implemented in a wide variety of concrete embodiments.

To the extent that one speaks of a “cylindrical” extension, this means “essentially cylindrical” and also includes, for example, bulbous shapes, polygonal cross sections or the like.

The device can be designed in the manner of a hood which is placed on the bottom of the metallurgical melting vessel, the outlet area being completely covered. In other words: a cavity formed below the hood has a horizontal one above the bottom of the vessel at least at one point Cross-sectional area that is at least as large as the cross-sectional area of the outlet area in the area of the surface of the bottom (the bottom level) of the melting vessel. On the upstream side this cavity is delimited by the extension mentioned, on the upper side by the base part of the device.

In order to achieve an inflow of the melt through this hood to the outlet area, the openings / openings mentioned are provided in the wall area. According to one embodiment, several such openings are arranged regularly distributed in the wall area.

An optimization of the flow distribution, i.e. a breakdown of the flow of the molten metal into individual partial flows, is achieved if the device is designed to be rotationally symmetrical, namely rotationally symmetrical with respect to an imaginary axis running through its center of gravity (axis of symmetry). The symmetry can also be defined in relation to an imaginary central longitudinal axis of the extension or the entire device.

The following description of the figures discloses details of possible embodiments.

The base part of the device can be convexly curved with respect to the extension or the outlet area, so that the hood takes on a kind of bell shape, the wall area of the extension being able to adjoin the base part in a substantially cylindrical manner. The hood design includes embodiments in which the device is designed in the manner of a spherical segment, in the manner of a cuboid, in the manner of a pyramid or in the manner of a cylinder. Unsymmetrical shapes and cross-sections are also possible, or hoods with a concave top surface (based on the outlet area). The openings can be designed as channels with different slopes.

The geometric design of the device and its parts can vary within wide limits and depends on the respective application. The openings (connecting channels) can have a semicircular or circular cross section, rectilinear or curved, optionally also involute in the direction of an area around the central longitudinal axis of the device. Likewise, the openings can be designed as slots which run essentially in the axial direction of the device (axial direction of the spout). Symmetrical and asymmetrical shapes and cross sections are possible.

According to one embodiment, the cross-sectional area of the entirety of the openings should be larger than the cross-sectional area of the outlet area at the level of the surface of the bottom of the melting vessel.

The device can be conically tapered at the end opposite the base part. Is the shape corresponding (to the inner) shape of the spout, the device can be easily placed in the pouring area, for example also mortared or glued. A positive connection is also particularly tight. Profiles on the outer surface of the end part of the device are helpful. The figures show examples.

An essential feature of the invention is that the device can be in one piece and can be produced in one process step. This applies even to a version with a tapered end part. Reference is made to the known production processes such as slip casting (for porcelain) or the burning out of temporary inserts to form cavities.

The distance between the base part and the spout at the level of the floor is usually up to 250 mm. The cross-sectional area of the base part should be selected so that it covers the mentioned inlet of the spout on all sides by at least 20 mm, a degree of coverage of 100 mm being generally sufficient.

Further features of the invention result from the features of the subclaims and the other application documents.

The invention is explained in more detail below with the aid of various exemplary embodiments.

Here show - each in a highly schematic representation -: Figure 1: a longitudinal section through part of a metallurgical melting vessel in the bottom discharge area with two alternative designs of a device according to the invention

Figure 2: an analog representation as Figure 1, but for a third embodiment.

In the figures, the same or equivalent components are shown with the same reference numerals.

In FIG. 1, reference numeral 10 designates a base of a metallurgical tank, here a distributor (tundish). The base 10 formed from refractory material of the usual type is delimited on the outside (underside) by a steel jacket 12. In the bottom 10, two pouring stones 14 are shown schematically, each having a central outflow opening 16, which is funnel-shaped at its upper end facing a molten metal 18. This results in a diameter “d” of the outlet openings 16 in the region of a surface 10 of the base 10.

Each outlet area 16 is covered by a device 20, the device 20 shown on the left in the figure being explained first:

This is designed like a hood and has a base part 20b which is convex with respect to the pouring stone 14 and which is adjoined by a substantially cylindrical extension (wall section 20w) which stands with its (lower) free end on the surface 10o of the base 10. In the wall area 20w, a plurality of openings 22 with a circular cross section are arranged in a uniformly distributed manner. The distance to the ground level lOo is indicated by "h" and is 72 m.

The molten metal 18 is deflected on its way to the outflow opening 16 around the base part 20b and, according to the number of openings 22 (here: eight pieces, which are evenly distributed over the circumference of the wall part 20w), is divided into eight partial flows, which form a common cavity 20h open, which is delimited at the top by the base part 20b, laterally by the wall part 20w and partly by the bottom 10 below.

Due to this subdivision of the flow, vortex formation is reliably prevented and the molten metal 18 is fed to the outflow region 16 without swirling.

The sections 20s between the openings 22 and the bottom surface 10o prevent melt or slag from flowing out in an uncontrolled manner, in particular when pouring on.

The device 20 shown on the right in FIG. 1 likewise comprises a base part 20b which is designed in the manner of a circular plate from which a cylindrical extension 20w projects in the direction of the base 10 of the melting vessel, this wall region 20w again on the surface lOo of the floor 10 stands up. In the area of the extension (the wall area) 20w, a plurality of openings (connection openings) 22 are arranged analogously to the exemplary embodiment described above, which are designed in the manner of a channel with a circular cross section and each have an incline directed obliquely upwards into the cavity 20h, as by the angle α symbolizes (α = 35 °).

The effect that can be achieved with this device essentially corresponds to that of the device shown on the left in FIG. Here, too, the melt 18 is divided into partial flows, which are led through the connection openings 22 into the cavity 20h and from there through the outlet area 16. The wall sections 20s ensure that the device can take over the function of a starter tube.

FIG. 1 shows in both embodiments that the respective base part 20b of the devices 20 runs at a distance above the bottom 10 and the extensions 20w surround the outlet opening 16 for the molten metal on all sides at a distance, the distance from the edge region of the outlet opening 16th to the inner wall surface of the extension 20w is larger than the diameter d of the outlet opening 16 in the area of the surface 10o of the base 10.

FIG. 2 shows an alternative embodiment, as can also be used in a melting vessel according to FIG. 1. The device 20 according to FIG. 2 is similar to the right variant in FIG. 1 with the following special feature: the (horizontal) cross section is smaller and an end section 20e adjoins the cylindrical wall section 20w, which is open at the bottom and tapers conically. The outer contour of the end section 20e corresponds approximately to the inner contour of the upper pouring part, so that the device 20 can be positively placed in the upper pouring part, a mortar layer 50 compensating for tolerances. A surface profile 20p of the end section 20e optimizes the connection. A small hole 60 in the base part 20b makes it possible to remove gases which could otherwise collect in the cavity 20h. The hole 60 can be formed by burning out a filling part inserted in situ during manufacture.

The devices described can be cast refractory parts. It is also possible to press or stamp the parts, depending on the design. The selection of the respective refractory grade depends on the respective application. There are no special requirements for the refractory material. It must be temperature-resistant in the usual way and as erosion-resistant as possible and should also have favorable ductility properties.

Claims

Device for preventing a vortex effect in the outlet area of a metallurgical melting vessel Patent device for preventing a vortex effect in the outlet area (16) of a metallurgical melting vessel, with the following features: 1.1 the device consists of a refractory ceramic material, 1.2 the device comprises a base part (20b), 1.3 to the base part (20b) is a cylindrical extension (20w) with at least one wall-side opening (22), 1.4 the opening (22) is arranged such that it is at a distance from the bottom (10) of the melting vessel after the device has been placed in the outlet region (16) of the melting vessel and creates a connection to the outlet region (16) of the melting vessel. 2. Device according to claim 1, wherein a plurality of openings (22) regularly distributed in the wall area of the Extension (20w) are arranged. 3. Device according to claim 1, which, relative to the longitudinal axis (L) of the extension (20w), is rotationally symmetrical. 4. Device according to claim 1, wherein the base part (20b) with respect to the extension (20w) is convex. 5. The device according to claim 1, wherein the cross-sectional area of the entirety of the openings (22) is larger than the cross-sectional area of the outlet region (16) at the level of the top (10o) of the bottom (10) of the associated melting vessel. 6. Device according to claim 1, wherein the openings ^" (22) have a circular cross section. 7. The device according to claim 1, wherein the openings (22) are formed slot-like. 8. Device according to claim 1, wherein the extension (20w) merges into a conically tapering end part (20e). 9. Device according to claim 8, in which the end part (20e) is designed corresponding to the shape of the outlet region (16) of the melting vessel. 10. The device according to claim 8, wherein the end part (20e) is designed profiled on the outside. 11. The device according to claim 1, in which the base part (20b), extension (20w) and optionally the end part (20e) are formed in a material-locking manner.