EP0367800B1 - Process and outlet sleeve for introducing gas into the outlet of a molten bath, in particular of a receptacle containing molten steel - Google Patents

Abstract

In the process described, gas heated to a least 1000 degrees Celsius, and preferably even to a temperature above the liquidus temperature of the molten metal, is blown into the outlet. This effectively prevents problems due to freezing and deposition in the outlet. Also described is an outlet sleeve (20) with a gas delivery duct (21) which leads to a gas-permeable insert (23) encircling the outlet (26) and which, in order to heat the gas, extends for a given length into the upper region of the sleeve in contact with the molten metal.

Description

The invention relates to a method for introducing gas into a pouring opening of a metallurgical container in order to prevent or reduce deposits or freezes in the pouring opening, and to a pouring sleeve for carrying out the method.

When pouring molten metal, in particular, from steel ladles or distribution vessels, it is known that, in particular, molten steel melts tend to form alumina deposits in the pouring spout, which lead to blockages and thus premature termination of the pouring. It is known from DE-PS 35 06 426 to combat such deposits by introducing gas. The gas is blown in at room temperature with a constant gas flow or pulsed.

In a further method (DE-PS 28 36 409) according to the type described above, in which a slide closure is arranged on the spout of the container, a flushing gas is inserted into the spout opening to prevent the melt from freezing in the opening when the slide is closed blown in.

With these known methods, the problems described could be combated with more or less success in practice.

Proceeding from this, the present invention is based on the object of improving gas inlets in such a way that the deposits or freezes mentioned in the pouring opening can be prevented in a simple manner over the required pouring time.

According to the invention, the object is achieved in that the gas is preheated to at least 1000 degrees Celsius, preferably even above the liquidus temperature of the molten metal, before entering the pouring opening. This allows the casting times or Extend temporary closing times for as long as you like without interrupting the pouring.

Due to the heated gas injection, the melt located in the pouring opening during the pouring does not experience any noticeable cooling in the temperature range which promotes the depositing of the deposit, or even a sticking to the opening wall due to solidification of the melt.

When using a sliding closure on the pouring spout of the container, the melt can freeze in the pouring opening in the closed position by blowing in heated gas can be completely prevented by a closing plate in the pouring opening provided the gas temperature is above the melt liquidus temperature.

In the method according to the invention, an inert gas, such as e.g. Argon, or a gas-solid mixture used.

The gas can be heated by means of an external heating device or by a pouring sleeve according to the invention, in which the cold gas is led over a certain length via a gas supply line into the upper sleeve area in contact with the molten metal and from there through a gas-permeable pouring opening enclosing insert is blown into the melt. In this way, the gas can be easily heated above the melting point of the melt and freezes as well as possible alumina deposits on the opening wall can be prevented over the entire required casting time.

Advantages to further variants of pouring sleeves according to the invention are explained in the following description.

Heated gas can of course also be blown into the elongated pouring opening in a corresponding manner by means of a pouring tube or a closure plate.

Fig. 1

Ein erfindungsgemässes Verfahren anhand einer in der Ausgussöffnung des Behälters angeordneten im Längsschnitt gezeigten Ausgusshülse,

Fig. 2

ein erfindungsgemässes Verfahren angewendet bei einem am Ausguss angeordneten, in Schliessstellung befindlichen Schiebeverschlusses,

Fig. 3

Variante einer Ausgusshülse im Längsschnitt,

Fig. 4

Querschnitt der Ausgusshülse nach Fig.3 gemäss der Linie IV-IV,

Fig. 5

weitere Variante einer Ausgusshülse im Längsschnitt,

Fig. 6

Querschnitt der Ausgusshülse nach Fig.5 gemäss der Linie VI-VI,

Fig. 7

vierte Variante einer Ausgusshülse im Längsschnitt und

Fig. 8

Draufsicht der Hülse nach Fig.7

Embodiments of the invention are explained below with reference to the drawing. It shows:

Fig. 1

A method according to the invention using a pouring sleeve shown in longitudinal section in the pouring opening of the container,

Fig. 2

a method according to the invention applied to a sliding closure arranged on the spout and in the closed position,

Fig. 3

Variant of a pouring sleeve in longitudinal section,

Fig. 4

Cross section of the pouring sleeve according to Figure 3 along the line IV-IV,

Fig. 5

another variant of a pouring sleeve in longitudinal section,

Fig. 6

Cross-section of the pouring sleeve according to Figure 5 along the line VI-VI,

Fig. 7

fourth variant of a pouring sleeve in longitudinal section and

Fig. 8

Top view of the sleeve according to Fig. 7

1 shows a container 10 containing molten metal in the pouring area, in which the pouring spout is formed by a refractory pouring sleeve 20, to which schematically illustrated refractory closing plates 15 and 17 of a sliding closure known per se are connected. The partially shown container 10 can, for example, be a molten steel pan or an intermediate distributor and essentially consists of a steel jacket 14 and a refractory inner lining 12, in which the pouring sleeve 20 is embedded. With the lower sealing plate 17 pressed against the upper sealing plate 15, the amount of the melt can be poured off in an adjustable manner by its displacement. In the position shown, in which the openings of the closure plates 15 and 17 overlap with the pouring opening 26, the closure is fully open.

The pouring sleeve 20 made of refractory material has an annular gas-permeable insert 23 which surrounds the pouring opening 26 and is surrounded on the circumference by a metal capsule 25, an annular space 27 being provided in between, which ensures a uniform distribution of the gas flowing out from the gas supply line 21. To heat up the gas to be blown into the pouring opening 26 according to the invention, the gas supply line 21 is led into the upper region of the pouring sleeve 20, there in a coil-like manner around the Poured opening 26 and then heated heated through the insert 23 into the melt to be poured. The in the upper region of the pouring sleeve 20 formed like a gas supply line 21 'is in a glued to the sleeve refractory attachment 22, which should consist of very good heat-conducting material, for example. Electrographite, embedded. Due to the dwell time in this attachment 22, which is in contact with the molten metal and very quickly takes on the temperature of the melt, the gas also experiences a very rapid heating, which approximately corresponds to the melting temperature. The gas supply line 21 consists of a highly heat-resistant steel or a refractory ceramic tube.

In particular to prevent freezing in the pouring opening 26 when the sliding closure is closed, the gas heated in the pouring sleeve 20 is passed through an additional line 21˝, which is only shown in broken lines in FIG guided and blown into the pouring opening 26 from there. In this way, for example, if the closure is temporarily closed for the purpose of changing the pouring tube or otherwise, the melt can freeze in this opening successfully.

According to FIG. 2, in order to prevent freezing in the case of a closed slide closure 33, which is also only shown schematically, the heated gas is introduced through a gas-permeable stopper 35 fastened in a slide plate 34 and in the closed position under the pouring opening 26. The gas is guided from a gas source G (not shown) via a heating device 30 and a heat-resistant gas supply line 31 into the plug 35, the latter having holes for the purpose of being effective Blowing. In a corresponding manner, the inserts surrounding the pouring opening can also contain such bores.

With the closure 33 open, the method according to the invention can, depending on the application, also be used with a pouring tube 36 connected to the closure 33, the pouring opening 37 of which has an insert 38. The gas is heated in the heating device 30 and passed through a heat-resistant line 32 into this insert 38 and thus into the pouring opening. The heating device 30 is also only shown schematically and it can be a known instantaneous water heater. The slide closure 33 is arranged on the spout of the container 10 and consists essentially of three refractory plates 34, 39 and 41, the upper and lower plates 39 and 41 being fixed, while the middle plate 34 is guided to be longitudinally displaceable.

A variant of a pouring sleeve 40 in the container 10 according to FIGS. 3 and 4 consists of a refractory body 42 and a porous insert 43 embedded therein. The porous insert 43 in turn encloses the pouring opening 26. The gas supply G takes place through the sleeve 40 molded-in slot line 44, which in turn is guided into the upper sleeve region. The line 44 comprises a first and second annular slot 44 'around the pouring opening 26 and a slot 44' guided into a space 45 surrounding the insert 43. In this variant, too, the gas can be heated to the required temperature.

5 and 6 show a pouring sleeve 50 embedded in the container 10 as a further variant of the invention. This sleeve 50 is a refractory concrete cast in a sheet metal casing 51. The gas supply G takes place via a line 52 cast into the sleeve, which in turn is guided in a coil-like manner in the upper part of the sleeve 50 around the pouring opening 26 and from there into a sheet-metal-coated porous insert 55 also poured into the sleeve. Again, the residence time of the gas in the coils 52 'and 52 und results in sufficient heating of the gas.

The pouring sleeve 60 shown in FIGS. 7 and 8 consists of a fully porous refractory body 61 with a pouring opening 26 and a sheet metal jacket 62 surrounding the body 61. Between the body 61 and the sheet metal jacket 62, an annular space 63 is provided, in which the heated Gas is introduced through a line 64 connected to a gas supply G. The gas supply line 64 has a loop 64 ', which is outside and around the sleeve 61 in contact with the molten metal and therefore consists of a refractory ceramic tube.

The invention can also be applied very well to non-ferrous metals, for example aluminum melts, in which the melt temperature is relatively low and the gas therefore does not have to be heated as much.

The pouring sleeves described can also be perforated bricks which are known per se and are mortared in steel ladles.

Claims (11)

1. Method of introducing gas into an outlet opening of a vessel containing a metal melt, particularly steel melt, for preventing or removing deposits or frozen portions in the outlet opening, characterised in that the gas is preheated before entry into the outlet opening (26) to at least 1000 degrees Celsius.

2. Method as claimed in claim 1, characterised in that the gas to be introduced into the outlet opening (26) is preferably preheated above the liquidus temperature of the metal melt.

3. Method as claimed in claim 1 or 2 in which the gas is blown in during pouring through a gas-permeable insert surrounding the outlet opening, characterised in that the gas, heated by a heater (30) or by heat-exchanging means (21′, 44′, 52′, 64′) in the outlet sleeve (20, 40, 50, 60, 36) is blown in during pouring through the gas-permeable insert (23, 43, 55, 61, 38).

4. Method as claimed in claim 1 or 2 in which the gas is blown in through a valve plate forming part of a sliding gate valve arranged at the outlet of the vessel and situated in the closed position, particularly for preventing freezing of the melt in the outlet opening, characterised in that the gas, heated by means of a heating device (30) or by heat-exchanging means (21′) provided in the outlet sleeve (20), is blown in through the valve plate (34 or 16).

5. Method as claimed in one of the preceding claims, characterised in that an inert gas, e.g. argon, or a gas-solid mixture is used as the gas.

6. Refractory outlet sleeve for a metallurgical vessel for carrying out the method as claimed in one of claims 1 to 5 with a gas-permeable insert surrounding its outlet opening or wholly comprising gas-permeable refractory material to which a gas supply line is connected, characterised in that for the purpose of heating the gas the gas supply line (21, 44, 52, 64) extends over a certain length before discharging into the gas-permeable insert (23, 43, 55, 61, 38) in the upper region (21′, 44′, 52′, 52˝, 64′), which is in contact with the metal melt, of the outlet sleeve (20, 40, 50, 60).

7. Outlet sleeve as claimed in claim 6, characterised in that the gas supply line (21, 44, 52) is constructed in the upper region of the outlet sleeve (20, 40, 50) in the manner of a coil around the axis of the outlet opening (26).

8. Outlet sleeve as claimed in claim 6 or 7, characterised in that it has an annular refractory cap (22) which is in contact with the metal melt and which comprises a very good thermally conductive material, preferably electrographite, in which the line (21') comprising a heat-resistant material is embedded.

9. Outlet sleeve as claimed in claim 6 or 7, characterised in that the gas supply line (64), comprising a small refractory ceramic tube, extends out of the upper sleeve region in a loop (64′) through the metal melt.

10. Outlet sleeve as claimed in claim 7, characterised in that the gas supply line (21, 52) is moulded into the sleeve (20, 50).

11. Outlet sleeve as claimed in claim 7, characterised in that moulded-in slit-shaped spaces (44, 44′, 44˝) in the sleeve (40) constitute the gas supply line (44).

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