DE2559151A1 - THERMAL INSULATING COVER FOR METALLURGICAL CONTAINERS, AND CONTAINERS PROVIDED WITH SUCH - Google Patents

Description

PATENT LAWYERS

DIETRICH LEWINSKY
Η ^: '.NZ-JO ^ CHlM HU8ER
RElNiR PRiETSCH
M ϋ NCHEN 2 1
GOTTHARDSTR. 81

Jean-Charles DAUSSAN ", Gerard DAUSSAN and Andre DAUSSAN OBE 1985

Thermal insulation coating for metallurgical containers, and containers provided with such.

The invention relates to a refractory lining for metallurgical containers for transferring liquid metals, especially in the iron industry. Such containers can are formed by ladles and casting vessels, which take baths of molten steel. In addition, the invention relates to also the metallurgical containers provided with such a refractory lining.

As is well known, the refractory linings of the containers for transferring liquid metals such as steel are very subjected to harsh operating conditions. Receive this feed namely, several tens of tons suddenly melted in a few minutes Metals, which e.g. come from a converter, and their temperature in the case of liquid steel between approximately 1400 ° C and 1650 ° E.

Although these chucks are preheated prior to receiving the molten insert, they are generally substantial Subject to thermal shocks. In addition, they experience erosion as a result of the formation of corrosive slag.

There are different solutions to the formation of the refractory Lining this container has been proposed. In certain known embodiments, the lining has several superimposed refractory layers made of clay-containing compounds

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fertilize, which is rich in sandy or containing silica Fireclay are, i.e. in the second case they have a high content of aluminum oxide (60 to 80%).

The porosity of these refractory layers must be as low as possible so that they can penetrate through the molten material Metal is not dangerous. The layers therefore have a high density and accordingly a medium-sized one Thermal insulation coefficient.

It has also been proposed to use so-called "noble" basic refractory materials, such as chrome and / or Magnesia, as well as silicon carbide. These materials have a low coefficient of insulation and are difficult to hold thermal changes of great amplitude, which the danger of cracking and bursting of the refractory layers bring yourself. In addition, their heavy weight makes the container considerably heavier. As a result, you practically cannot to be used.

The invention aims to overcome these disadvantages To help manufacture a refractory lining, which results in a coefficient of thermal insulation which is considerably greater than which is the known food.

The refractory lining according to the invention for metallurgical Container for transferring liquid metals, such as pouring ladles and pouring vessels, which are to be attached to the metal jacket of the container is determined and has a wear layer that comes into contact with the liquid metal, is characterized in that it has a heat insulating coating comprises, which is arranged between the wear layer and the metal jacket.

The inclusion of this insulating coating enables in particular the use of a thermally conductive wear layer. The wear layer can be produced with the help of magnesia stones, for example, which is the case with the known designs is not possible with soft the wear layer in particular consists of chamotte.

According to a preferred embodiment, this insulating coating is formed so that its density between about 0.6 and 1.1, and that it has an open porosity

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between 55 and 85 % "owns

You can therefore create a high-density wear layer of, for example, about 3, which is therefore a good heat conductor is.

The increase in the coefficient of thermal insulation obtained by this coating enables, among other advantages, introduce a molten metal at a lower temperature into the container. This will reduce the amplitude of the thermal Reduces fluctuations to which the refractory lining is exposed.

Furthermore, according to the invention, the metallurgical container is for transferring liquid metals, in particular liquid metals Steel, with a metal jacket to which a refractory lining is attached on the inside, characterized in that the refractory lining is formed by the above lining.

In case the container through a pouring ladle for liquid Steel is formed, the insulating coating can be applied directly to those attached to the bottom of the container Walls of the metal jacket are fastened, in particular by a refractory cement, a glue or by nailing, with this cover is covered with a protective layer made of fireclay, for example

This protective layer is in turn made up of a wear layer made of an acidic refractory material, ζ · Β · silica, or from a basic refractory material, e.g. chromium magnesia overdrawn. The reduction in the endurance of the feed Temperature fluctuations enable the appropriate use of a basic refractory material such as chromium and / or magnesia

The invention is explained below by way of example with reference to the drawing.

Fig. 1 shows, in a longitudinal section with parts broken away, a pouring ladle for liquid ferrous metal, which is provided with the thermal insulation coating according to the invention

Fig. 2 is a fragmentary sectional view broken away of parts, which corresponds to FIG. 1 and a pouring vessel for liquid ferrous metal shows.

In the execution shown in Fig. 1, the

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metallurgical vessel for transferring liquid metals formed by a ladle 1 for liquid steel in steelworks. The pan 1 has a frustoconical metal jacket 2, two trunnions 3 are welded to its upper part.

The bottom 4 of the pan 1 is provided with a sliding nozzle 5, which the emptying of the pan 1 after Filling permitted. The nozzle 5 is of a type known per se and is therefore not described in detail.

The pan 1 has an inside attached to the jacket 2 refractory lining 6 in which a shaft 7 is formed. This is connected to a channel 10, which is formed in a part 20 firmly connected to the chuck 6 is. The part 20 cooperates with the sliding nozzle 5, to allow the molten metal to flow out of the ladle 1 when the nozzle 5 is in an appropriate position opposite the channel 10 occupies.

The lining 6 comprises a heat insulating cover 8, 9 »which according to the invention by a mixture of organic fibers, mineral fibers, refractory grains, a flux and a binder is formed. The insulating coating is made with the help of stones, which directly are attached to the walls of the shell 2, which are connected to the bottom 4, and a truncated cone layer 8 form. In addition, the insulating coating above the bottom 4 has a layer 9 which is between two layers of Protection stones 11 and 12 lies.

The lower layer 12 in turn consists of two layers 12a, 12b, with the layer 12a directly above the Layer 9 is, while layer 12b, which is thicker than the Layer 12a is attached to the bottom 4 of the pan 1. The layer 8 of the inventive heat insulating coating is covered by a refractory layer 13 of protective stones, soft like the stones forming the layers 11 and 12 are. Finally, the protective layers 11 and 13 are from FIG refractory wear layers 14 and 15 coated.

The stones of the layer 8 of the insulating coating and those of the protective layer 12b can pass through the jacket 2 Gluing or nailing can be attached in a manner known per se.

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The layers 13 and 15 are firmly glued to one another and to the layer 8, and the layers 12a, 9, 11 and 14 are equally fixed to each other and to the layer 12b connected · Gluing can be done with the help of a commercially available refractory paste or insulating refractory cements take place, such as silicates or silica gel ο

The layers 8 and 9 of the heat insulating according to the invention Coating preferably have the following composition:

- 2 to 6% of an organic or mineral, natural and / or synthetic binder;

- 1 to 15 % fibers, which can have the following composition:

- 0.5 to 10% organic fibers, such as paper pulp, Cellulose;

- 0.5 to 10% mineral fibers, such as mineral wool, glass wool, asbestos fibers

- 97 to 59 % refractory grains, such as:

- Silica and / or aluminum oxide and / or Aluminum oxide silicate, based on chromium and / or magnesia, residues from the manufacture of metals such as aluminum, blast furnace slag;

- converter slag;

- 0 to 20 % of a flux, depending on the type of refractory material used, such as calcium fluoride, soda

According to a further characteristic of the invention, the coating forming layers 8 and 9 is open Porosity between 55 and 85%, and the proportions of its components are determined so that its density is between about 0.6 and 1.1. In other words, the porosity of the layers 8 and 9 is such that the two sides of each of them are connected to each other by between 55 and 85% of their Total surface lying surface are connected.

The protective layers 12a, 12b, 11 and 13 are preferred made of chamotte, while the refractory wear layers 14 and 15 expediently made of chrome and / or consist of magnesia, these latter materials being a

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Can withstand temperatures above 1650 degrees. the Layers 14, 15 can also be made from a refractory material such as silica.

The technical effects and advantages of the invention are as follows:

When you put molten steel in the ladle 1

pours, especially from a converter, are the wear layers 14 and 15 were the first to experience the thermal and dynamic shock caused by the impact of the liquid Steel beam is generated, the temperature of which is between 1550 ° C and 1650 ° C. The surface zones of the layers 8 and 9 of the insulating coating according to the invention can gradually be brought to a temperature of 1350 ° C.

Refractory grains and the mineral pastes of layers 8 and 9 allow them to be at the above temperature endure, even in the event of cracking of the adjacent refractory coating

During normal operation, the wear layers 14, 15 and the protective layers 11, 13 keep the attack from the liquid metal sufficiently well to prevent any penetration of the same up to the layers 8, 9 of the heat-insulating coating. Experience has shown, however, that if the wear layers 14, 15 and the protective layers 11, 13 break the layers 8, 9 can withstand, according to their thickness, for a period which is at the temperature of the molten Stahls, which is of the order of 1600 C, can reach several hours. When touching the liquid Metal, the layers 8, 9 are not decomposed and resist the metal · As a result, there is a risk of perforation of the shell of the container through the liquid steel, which occurs in the known embodiments, in the heat-insulating coating according to the invention is practically excluded. The safety of handling the container containing the liquid metal is therefore increased accordingly.

Tests have shown that the coating forming the layers 8, 9 has a high coefficient of thermal insulation owns. This compensates for the low coefficient of thermal insulation of the wear layers 14, 15, which allows the V / poor

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leaked through the chuck 6 and the metal jacket 2 through decrease about 50%. You can therefore in certain cases Introduce a bath of liquid steel with a temperature of about 1550 ° C instead of 1650 C in the previous practice. this enables the residence time of the molten metal in the ladle 1 to be increased and the corresponding homogenization the temperature of the bath. The dangers of bursting and cracking of the wear layers 14, 15 due to the thermal shocks are avoided in this way, which increases the service life of the refractory lining 6

The lowering of the temperature of the bath when it is poured into the pan 1 also offers the advantage that To reduce amplitude of heat fluctuations, which the verses lead ßschichten 14, 15 are exposed. As a result, you can these are made of a basic "noble" refractory material v / earth, such as chromium and / or magnesia, what is known in the case of the refractory materials was not possible. In addition, the reduced thickness of the wear layers 14 and 14 decreases the total weight of the feed 6

Decrease in temperature of introduction of the liquid metal in the pan 1 prevents the formation of hoisting on the bars in the case of the usual pouring · On the other hand one observes when the wear layers are out made of an acid refractory material, reducing their wear and tear under the action of the slag · Man also notes that the wreaths are made of solidified slag the upper circumference of the bath have disappeared, and that the better homogenization of the temperature in the container prevents the so-called "pan bottom faults".

One of the most important advantages of the invention is in that it enables the usual wear layer of chamotte to be replaced by a wear layer of magnesia

The above advantages, in particular the use of basic coatings such as magnesia for the wear layers 14 and 15 in conjunction with the use of sliding nozzles of the type shown at 5 enable the circulation to be increased the container and, accordingly, the increase in its loading

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utilization coefficient. It can namely, the intermediate heating as well as the accelerated cooling with water cease to exist, which have been used in previous practice to enable the casting plug to be restored. The elimination the preheating and cooling also offers the advantage of saving the refractory coatings of the lining 6 thermal shocks, thereby reducing the risk of cracking and bursting

The reinforced thermal insulation of the pan 1

very considerably reduces deformations, such as raptures, which on the handle pin of the pan 1 due to the deformations of the metal jacket 2 can occur. Since these are precisely adapted to the hooks of the overhead traveling cranes, this becomes apparent the handling of the ladle 1 facilitates.

As a non-limiting example, the following are the thicknesses of the various layers of the refractory Putters 6 for a ladle 1 for about JO tons indicated:

- insulating layer 8 about 50 mm

- fireproof protective layer 13 about 20 mm

- Wear layer 15 about 20 to

50 mm

- Layer 12 about 20 mm

- insulating layer 9 about 30 mm

- Protective layer 11 about 20 mm

- Wear layer 14 about 210 mm

It should be noted that the clarity

for the sake of the sections corresponding to the thicknesses mentioned above

^D on the drawing ^ of the layers of the lining 6 / are not complied with. The thickness of the insulating layer 9 can be between approximately 10 and 100 mm, as the case may be, its compressive strength allowing it to withstand ^{pressures of 5 to 20 kg / cm 2.}

In the embodiment shown in Fig. 2, the metallurgical container according to the invention is a pouring vessel 16 for liquid steel with a metal jacket 17 »to which a handling bracket 18 is attached. The coat 17 is covered with a refractory lining 19, which has a pouring nozzle 21 in a known manner, which by a plug, not shown, is closed. The nozzle 21

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opens at an opening 22 formed in the jacket 17 for emptying the vessel 16.

The refractory lining 19 comprises:

- A first protection, e.g. made with the help of firebricks; layer 23;

- A second layer 24, which is formed by stones of the heat-insulating coating according to the invention and attached to layer 23;

a third protective layer 25, which is designed like the first layer 23 and attached to the second layer 24 is and

a fourth wear layer 26 attached to the third layer 25.

The above four layers 23 and 26 are with each other glued, the layer 23 on the jacket 17 by means of a refractory cement or glue or by nailing can be attached. The protective layers 23 and 25 are e.g. made of fireclay The wear layer 26 can be made of a basic refractory material such as chromium magnesia , or from an acidic refractory material such as silica.

The invention can be modified. In particular, the formation of the lining of the bottom 4 of the pan 1 can be applied to the coating of the walls of the jacket 2 adjoining the bottom 4, in which case the heat-insulating "Coating is arranged between two protective layers 13.

Furthermore, the binder used for the heat-insulating coating 8, 9 or 24 can be a plastic glue Phenol-formol resin or a formol-aldehyde resin or as the case may be by a refractory cement, soda and / or a sulphite liquor are formed. The invention is also suitable for coating other containers, such as mixers and pouring channels for martin ovens, applicable·

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Claims (8)

2559Ί51 - no ~ PATENT CLAIMS 1. Refractory lining for metallurgical vessels for transferring liquid metals, such as pouring ladles and Casting vessel which is attached to the metal jacket of the container and at least one of which is in contact with the liquid metal has upcoming wear layer, characterized in that that there is a heat-insulating coating (8, 9) arranged between the wear layer (14, 15) and the metal jacket (2) having. 2. Lining according to claim 1, characterized in that the heat-insulating coating (8, 9) is designed in such a way that that its density is between about 0.6 and 1.1; and that it has an open porosity between 55 and 85%. 3. Feed according to claim 1 or 2, characterized in that that it has the following composition: - 2 to 6% of an organic or mineral, natural and / or synthetic binder, - 1 to 15 % fibers, which can have the following composition: - 0.5 to 10% organic fibers, such as paper pulp, Cellulose, - 0.5 to 10% mineral fibers, such as mineral wool, glass he, asbestos fibers, - 97 to 59 % refractory grains, such as: - Silica and / or alumina and / or alumina silicate, based on chromium and / or magnesia, residues from the production of metals such as aluminum, blast furnace slag, - converter slag, - 0 to 20 % of a flux corresponding to the type of refractory material used, such as calcium fluoride, soda. 4 · Metallurgical container for transferring liquid metals, especially liquid steel, with a metal jacket (2), to which a refractory lining (6) is attached inside, characterized in that the refractory lining (6) according to one of claims 1 to 3 is formed. 609827/076 1 5 · Container according to claim 4, which by a ladle for molten steel is formed, characterized in that that the heat-insulating coating (8) directly on the walls connected to the bottom (4 ·) of the container of the metal metal (2) is attached, in particular by means of a refractory cement or glue or by nailing, and that this coating is covered with a protective layer (13) consisting, for example, of chamotte. 6. Container according to claim 5 »characterized in that the bottom and the side walls of the metal shell (17) covering lining has a heat-insulating coating (24), which is between two, for example, made of chamotte Protective layers (23, 25) is arranged. 7. Container according to claim 6, characterized in that that the protective layers (25) are coated on the inside with wear layers (26), which in particular consist of basic refractory materials such as chrome and / or magnesia 8. A container according to claim 4, which is formed by a ladle for, liquid steel, thereby marked Q. 3.3 draws that / the one connected to the bottom of the pan Refractory lining (6) covering walls has a heat-insulating η coating (9), which is between two e.g. made of fireclay produced protective layers (11 and 12a) is arranged, wherein the inner protective layer (11) with a basic or acidic wearing layer (14) is coated. 9 · Container according to claim 4, which is formed by a pouring vessel for liquid steel, characterized in that that its refractory lining (19) a first, attached to the metal jacket (17) by gluing or nailing Protective layer (23), a second, formed by the heat-insulating coating and attached to the first layer, e.g. by gluing Layer (24), a third protective layer formed like the first layer (23) and attached to the second layer (25), and a fourth, attached to the third layer and made in particular from chromium-magnesia or from magnesia Comprises wear layer (26). 609827/0761