FR2769861A1 - Continuous casting ladle tube - Google Patents

Abstract

A continuous casting ladle tube comprises, in a downstream zone, a first part (3) with an essentially constant cross-section and, upstream of this first part (3), a second part (4) with a relatively diverging cross-section.

Description

Continuous casting ladle tube
The present invention relates to a continuous casting ladle tube.

Many types of tubes are known which are used in continuous casting installations to allow the flow of liquid steel between the continuous casting ladle and the distributor. Among the most widespread, there may be mentioned straight tubes, converging tubes, so-called "bell-shaped" tubes and tubes called "elephant foot".

To resist the aggression of molten steel, these tubes are made of high performance refractory materials. The flow of molten steel in such a tube is both very specific and of variable geometry. By this is meant in particular that this flow, which occurs in a non-uniform manner, often gives rise to delamination of the boundary layer, or even to zones of negative speed, and this at an overall average speed of the order of a meter per second. . All this depends on many parameters, including the hardware configuration at the head of the tube (presence of a pocket drawer in particular), and the detailed geometry of the tube. In addition, the dynamics of the jet on the bottom of the distributor has the effect of generating vibrations, stronger if the tube is convergent. These vibrations produce stresses which, adding to the aggressiveness of the environment, can result in the rupture of the tube, in particular if the latter is rigidly fixed (without degrees of freedom in rotation) on the pocket drawer.

However, a tube which no longer gives a satisfactory flow must be replaced, a delicate operation, and costly in terms of yield. This results in considerable practical difficulties.

The invention aims to provide an improved continuous casting ladle tube, avoiding these difficulties as much as possible.

In addition, when each ladle is in place, the tube must be able to be placed on the ladle drawer, which closes the outlet passage from the ladle to the tube.

Each pocket filled with steel contains a plugging mass, made of refractory sand, which is interposed between the molten steel and the shutter, obstructing the tap hole located at the bottom of the pocket. At the opening of the shutter, this blocking mass must be able to be completely evacuated, passing through the shutter and the pocket tube, and this, without the tube becoming blocked, to avoid any rebound of the pressure wave linked to the nascent flow of steel ("blow back").

The invention also aims to allow the drawer to be opened while the end of the tube is already immersed in the steel of the distributor and without risk of clogging.

More particularly, the invention also aims to ensure a reduction in the speed of injection of steel between the pocket and the distributor, while maintaining a given flow rate. The Applicant has observed that it is thus possible to eliminate the unsteady dynamic effects due to the impact of the jet on the bottom of the distributor, and thus limit or even eliminate the vibrations of the tube itself, and thereby the risk of it breaking. . In addition, it also promotes decantation (beneficial) in the distributor, by modifying the structure of the flow within it. The shape of the tube also makes it possible to avoid blockage of the sand constituting the blocking mass.

To this end, the subject of the invention is a continuous pouring ladle tube, characterized in that it comprises, in a downstream zone, a first part of substantially constant section and, upstream of said first part, a second part of relatively divergent section.

It will first be observed that the first part, the section of which is substantially constant, may however be slightly divergent or convergent. An example will be given below.

Regarding the second part, its section is relatively divergent, which means that it is more divergent than the first part. Its downstream internal cross section is identical to the upstream internal cross section of the first part, so as to form a regular passage.

Other characteristics and advantages of the invention will appear on examining the detailed description below, and the appended drawings, in which: - Figure 1 is a view in longitudinal section of a particular embodiment of a tube according to the invention, and - Figure 2 is an end view, along arrow A, of the tube of Figure 1.

The accompanying drawings are, for the most part, certain, and the invention involves forms. Consequently, the drawings could not only serve to make the description better understood, but also contribute to the definition of the invention, if necessary.

Figure 1 is an axial sectional view of a continuous ladle pocket tube comprising, in known manner, a flange 1 for connection to the ladle and a tubular conduit 2, here of variable circular section.

The tubular conduit 2 itself consists of a first downstream part 3, of substantially constant section, on the side of the distributor, and a second upstream part 4, divergent, on the side of the ladle. Parts 3 and 4 are connected in a plane 5 where their sections are identical, inside at least.

In fact, in the illustrated embodiment, the part 3, defined as having a substantially constant section, is here very slightly diverging from an apex angle of 2 ". The upstream part 4 is diverging from an apex angle of 10" .

Also in the illustrated embodiment, both part 3 and part 4 have a substantially constant divergence and therefore correspond to shapes in trunks of cones.

As for the interior shapes, other executions are possible, with a variable divergence: for example, instead of the straight generator of the truncated cone, one can consider an exponential generator, or more generally any, provided that it generally defines a diverge.

In addition, the wall thickness of the tube in zone 3 is preferably substantially constant. Preferably, it is the same for part 4. However, the external shape of the tube can be modified according to needs, or considerations other than those related to the flow.

It will also be noted that upstream of part 4, the illustrated ladle tube includes another part 6, bordering the flange 1, and which, like part 3, has a substantially constant section, also in fact very slightly divergent. The parts 4 and 6 are connected in a plane 7 where the downstream section of the part 6 is identical to the upstream section of the part 4, inside at least.

Finally, the left end of the tube is very advantageously sheathed externally by a sheet coating, which marries it.

Part 3 of the tube has a length preferably equal to approximately 3 times its downstream diameter. For its part, the part 4 has a length which is in particular a function of its angle of divergence, and of the desired outlet diameter.

The tube can be produced in particular from graphite alumina, or from other refractory materials which can be used in steelworks.

The Applicant has observed that the liquid steel entering the tube leaves it uniformly with a speed lower than its entry speed. The ratio of the average flow velocities is equal to the ratio of the sections and, therefore, equal to the square of the ratio of the diameters since the tube is here of circular section. In addition, due to the shape of the tube, no pulverulent or granulated solid mass (in particular plugging mass) can be blocked.

The present invention is particularly advantageous where a pocket drawer is used. The shape of the tube is advantageously arranged according to the characteristics of the flow leaving this drawer.

Although it is possible to manufacture it in one piece by isostatic pressing, at least in some cases, the Applicant currently prefers to manufacture the tube in two or more parts, then assembled in a known manner. At least some of these parts can be produced by isostatic pressing.

Although the forms, in particular the interior, are important, the present invention is not limited to the embodiment described, which can be adapted, in particular in dimensional terms, by a person skilled in the art.

Thus, in the particular embodiment described, said first part is divergent from an angle at the apex of the order of 2 ". But another angle, preferably small, in particular zero, or convergent, is possible, provided that 'we stay with an average angle below a threshold of the order of 2 ".

More generally, said second part is divergent by an angle at the apex comprised between approximately 1 "and approximately 20, preferably between approximately 3 and approximately 14", and advantageously between approximately 6 "and approximately 10.

Furthermore, the invention can be applied when the shutter is other than a pocket drawer.

By also generalizing the dimensions, said first part has a length of between approximately once and approximately five times its largest transverse dimension, preferably between approximately twice and five times, and advantageously between approximately twice and approximately four times its largest. transverse dimension.

The shape of the cross sections of the first and second parts of the tube, perpendicular to its axis, could be arbitrary, provided there is sufficient continuity.

However, it is preferably substantially oval, for example substantially elliptical, or more precisely substantially circular.

Claims (10)

CLAIMS 1. Continuous casting ladle tube, characterized in that it comprises, in a downstream zone, a first part (3) of substantially constant section and, upstream of said first part, a second part (4) of relatively divergent section. 2. Tube according to claim 1, characterized in that said first part (3) has an average apex angle less than a threshold of the order of 2 ". 3. Tube according to one of claims 1 and 2, characterized in that said second part (4) diverges from an apex angle of between approximately 1 "and approximately 20. 4. Tube according to claim 3, characterized in that said second part is divergent from an apex angle of between about 3 and about 140. 5. Tube according to claim 4, characterized in that said second part (4) is divergent by an apex angle of between approximately 6 "and approximately 10. 6. Tube according to one of claims 1 to 5, characterized in that said first part (3) has a length between about once and about five times its largest transverse dimension. 7. Tube according to claim 6, characterized in that said first part (3) has a length of between approximately twice and approximately five times its largest transverse dimension. 8. Tube according to claim 7, characterized in that said first part (3) has a length of between approximately twice and approximately four times its largest transverse dimension. 9. Tube according to one of claims 1 to 8, characterized in that at least one of said first and second parts has a substantially oval cross section. 10. Tube according to one of claims 1 to 8, characterized in that at least one of said first and second parts has a circular cross section.