WO1997018335A2

WO1997018335A2 - Fireproof moulding plates with gas ducts

Info

Publication number: WO1997018335A2
Application number: PCT/DE1996/002149
Authority: WO
Inventors: Lorenz Dötsch
Original assignee: DÖTSCH, Marie-Luise
Priority date: 1995-11-14
Filing date: 1996-11-12
Publication date: 1997-05-22
Also published as: EP0862506A2; AU1866897A; TR199800852T2; CN1202122A; JP2000500527A; WO1997018335A3; DE19542446A1; CA2237628A1; KR19990067556A; IL124463A0; DE19542446C2; MX9803850A; BR9611717A

Abstract

In order to blow gases into hot chambers with fireproof linings and create a gas sink (6) with directional porosity, it is proposed that moulding plates should be used made from rolled green compacts permeated in their interior by gas through-flow ducts (3). The latter are produced during the rolling operation by rolling in or working in dimensionally stable foils of a material which can be melted out or burned out. Once the green compacts have been rolled, the foils are melted out or burned out.

Description

Fireproof molded panels with gas routing channels

The invention relates to a method for injecting gases into refractory-lined hot rooms or metallurgical vessels using refractory gas guide bodies with directed porosity, the gas guide channels of which open in the area of the hot side of the refractory lining.

In addition, the invention relates to a method for the production of refractory shaped plates for the injection of gases into refractory-lined hot rooms or metallurgical vessels and the use of such shaped plates.

Finally, the invention relates to a gas purging plug for metallurgical vessels, with a refractory molded block, a gas-tight sheet metal casing, consisting of a sheet metal jacket surrounding the lateral peripheral region of the molded block and a sheet metal base on the cold side of the molded block facing away from the melt and a gas supply pipe connected to the sheet metal base.

In the previously known methods and devices for injecting gases into refractory-lined hot rooms or metallurgical vessels, nozzle stones, gas purging stones or lances are used which can blow the gas into the hot rooms or vessels filled with a metallic melt only at certain points where the corresponding rinsers are used. This results in an uneven application of gas to the melt, for example, so that, for example, the desired metallurgical effect, cleaning or homogenization of the melt is only achieved with very long blowing times.

The invention has for its object to provide a method for injecting gases into such hot rooms or metallurgical vessels, with which the blowing times can be shortened. This object is achieved by the characterizing features of claim 1.

The thin-walled refractory mold plates used in this process can be produced by a process as stated in claim 2.

With such refractory shaped plates, which are inserted, for example, in the fireproof brickwork of a tundish, the entire molten metal can be charged with flushing gas or other gases very evenly.

The gas channels running inside the shaped blocks can run in the longitudinal direction of the refractory shaped plates, but they can also be comb-like and open on adjacent sides of the shaped plate. In addition, the channels can have different cross sections, which are formed by inserting strips of different thicknesses.

The mold plates according to the invention with the inner gas guide channels are also particularly suitable for the production of gas purging stones with directed porosity, as described in claims 4 to 9.

In the case of known gas purging stones with directed porosity, the gas passage channels are formed, for example, in that threads or tapes are worked into the shaped green body when filling the casting mold with pasty refractory material, which then have to be pulled out of the green body.

In another known gas purging plug, plates are put together to form the gas passage channels, in the surface of which several parallel grooves are incorporated.

In the known gas purging stones, however, it can be difficult to produce the gas passage channels with a constant cross section over their length, since the inner surface of the channels damaged when pulling out the inserted strips or the plates with the embossed grooves are difficult to place exactly on top of each other. In addition, the gas passage channels must be so narrow that molten metal does not penetrate into the interior of the channels in the unpressurized state and can solidify there.

In principle, the gas passage channels located in the interior of the mold plates allow the mold plates to be joined together in any way when the washing body is formed, since this no longer impairs the cross-sectional constancy of the channels. This considerably simplifies the production of the entire gas flushing plug.

The refractory shaped plates are made from rolled green compacts, so that the refractory material is comparatively highly compressed and a low porous material is produced which has a correspondingly high wear resistance.

The flushing body consisting of the individual shaped plates is preferably seen above a porous block of material which has an undirected porosity when viewed in the use position of the gas flushing block. This arrangement makes it possible to visually recognize the state of wear of the gas purging plug when it has been worked down to the area of the porous block. Then, in the bottom area of the pan, a circular, dark spot is formed, which is caused by the increased cooling effect of the inflowing gas.

Even with a full pan, the state of wear can be recognized by the fact that increased bath movements occur in the surface area.

A gas distribution space is expediently provided between the underside of the shaped block or the porous block and the sheet metal base, so that the gas to be fed in directly into the porous block or onto it without flow resistance subsequent sink can reach.

To form the flushing body which is gas-tight except for the gas passage channels, the shaped plates can already be connected to one another by rolling or pressing during the production of the green bodies. On the other hand, it is also possible to form the z. B. with the help of a refractory adhesive. The gas-tight connection of the individual mold plates is facilitated in that they are produced with the aid of a rolling process and as a result have very smooth and uniform surfaces. Form plates assembled in this way can also absorb the very high thermal stresses that occur much better, since any cracks that arise generally only extend to the outside of the neighboring plate.

The shaped plates produced by rolling preferably have a thickness between 1 and 10 mm and a width between 10 and 100 mm, so that the respective flushing bodies can be adapted to almost all gas flushing stone sizes.

The refractory mold plates can, for. B. consist of a mixture of A1 ₂ 0 ₃ , MgO and ZrO, which are mixed with water and whose pasty consistency is adjusted so that they can be shaped with the help of a rolling process.

The gas passage channels running inside the refractory mold plates are produced according to the invention during the rolling process of the green compacts or a corresponding endless strip, which is divided after the rolling, in that a desired number of strips made of a burnable or meltable one are compared to the deformation forces occurring during the rolling are comparatively dimensionally stable. After the subsequent melting or burning out, these film strips form the later gas passage channels in the interior of the individual shaped plates with a very precise and uniform cross section. The film strips can be continuously fed to the roll gap in a very simple manner in the mentioned rolling process, the rolling process being e.g. B. can be done in that the roll gap two different tapes of pre-prepared refractory material run or the material is introduced in the form of a single strand in the roll gap. Such rolling processes can be found, for example, in EP 0 536 584 A2 or DE-PS 41 33 712 C2.

The resulting shaped plates are solidified by a heat treatment to be carried out after the rolling, with melting or burning out of the film, and can then be installed in the interior of the gas purging plug in a known manner while encapsulating with pasty refractory material.

The invention is illustrated in the drawing, for example, and is explained in detail below with reference to the drawing. Show it:

1 is a perspective view of a mold plate with a comb-shaped gas passage,

2 is a perspective view of a mold plate with three gas passage channels,

3 shows a perspective view of a washing body composed of a plurality of shaped plates,

Fig. 4 shows a section through a gas purging plug with rinsing body and porous lower block and

5 shows a partial section through the gas purging plug according to FIG. 4.

The illustrations in FIGS. 1 and 2 show shaped plates 1 and 2 produced by rolling with gas passage channels 3 running in the longitudinal direction, the shaped plate 1 according to FIG. 1 having a comb-shaped gas passage channel 3 and the shaped plate 2 according to FIG. 2 showing three gas passage channels 3 on- points.

The number or dimensions of the gas passage channels 3 are based on the available injection areas or the desired gas throughputs and pressures.

3 schematically shows a flushing body 4 formed by gluing the individual mold plates 2, on the hot side 5 facing the melt of which a plurality of gas passage channels 3 open.

The gem in the sectional view. Fig. 4 shown gas sink 6 consists of a refractory material 7, which is surrounded laterally by a conical sheet metal jacket 8 and a lower sheet metal base 9. A gas feed pipe 10 is welded to the sheet metal base 9.

A gas distribution space 12 is located between the underside 11 of the refractory material 7 and the sheet metal base 9.

In the interior of the gas purging block 6, the purging body 4 is arranged, which is traversed by a multiplicity of gas passage channels 3.

Below the purging body 4 there is a gas-permeable block 13 with non-directional porosity, which forms an optical wear indicator when the gas purging plug 6 is in the appropriate processing state.

5 shows the position of the flushing body 4 inside the gas flushing block 6. O 97/18335 PC17DE96 / 02149

Fireproof molded panels with gas routing channels

Reference list

1 molded plate

2 molded plate

3 gas passage

4 sink 5 hot side

6 gas purging plug

7 refractory material

8 conical sheet metal jacket

9 sheet metal base 10 gas supply pipe

11 bottom

12 gas distribution room

13 gas permeable block

Claims

claims

1. Process for the injection of gases into refractory-lined hot rooms or metallurgical vessels using refractory gas guide bodies with directed porosity, the gas guide channels of which open in the area of the hot side of the refractory lining, characterized in that thin-walled refractory shaped plates (1, 2 ) are used with inner gas guide channels (3) which open on narrow sides of the mold plates (1, 2), that the refractory mold plates (1, 2) are spaced apart from one another and / or inserted one after the other when the refractory lining is delivered and that the gas routing channels (3) are connected to a gas supply space which is formed in the interior or on the cold side of the refractory lining and which is acted upon by pressurized gas.

2. Process for the production of refractory shaped plates for the injection of gases into refractory-lined hot rooms or metallurgical vessels, characterized in that the shaped plates (1, 2) are formed by rolling a plastic refractory mass for the production of green pieces, the green pieces being formed in the Flat strips are burned out of a burn-out or meltable, comparatively dimensionally stable film, which strips are then burned out or melted out under the application of temperature to form the gas guiding channels (3).

3. Use of refractory molded plates (1, 2) produced according to claim 2 for the production of gas purging stones with directed porosity for metallurgical vessels.

4. Gas purging plug for metallurgical vessels, with a fire solid molded block, a gas-tight sheet metal cladding, consisting of a sheet metal jacket surrounding the lateral circumferential area of the molded block and a sheet metal base on the cold side of the molded block facing away from the melt and a gas supply pipe connected to the sheet metal base, gas guide channels being provided in the molded block interior to form a directed porosity are, which open on the hot side, characterized in that the gas guide channels (3) pass through a rinsing body (4) arranged in the interior of the molded block, which is gas-tightly assembled from refractory molded plates (1, 2) which are produced according to claim 2.

5. Gas purging plug according to claim 4, so that the purging body (4) is arranged above a block (13) consisting of gas-permeable, refractory material with undirected porosity.

6. Gas purging plug according to claim 4 or 5, d a d u r c h g e - k e n n z e i c h n e t that a gas distribution space (12) is provided between the underside (11) of the refractory material (7) and the sheet metal base (9).

7. Gas purging plug according to one of claims 4 to 6, since - characterized in that the Form¬ plates (1, 2) are connected to each other by rolling or pressing the green bodies to form the washing body (4).

8. gas purging plug according to one of claims 4 to 6, that a ¬ d u r c h g e k e n n z e i c h n e t that the Form¬ plates (1, 2) are connected by gluing with a refractory adhesive.

9. gas purging plug according to one of claims 4 to 8, d a ¬ d u r c h g e k e n n z e i c h n e t that the Form¬ plates (1, 2) have a thickness between 1 and 10 mm and a width between 10 and 100 mm.