EP0916436A1 - Monolithic, refractory, ceramic well brick - Google Patents

Abstract

The monolithic refractory hole block with top and bottom faces (20, 22) and a hole (12) between these faces has ceramic matrix consisting of at least two sections of different ceramic materials arranged in the radial direction (perpendicular to the axis (14) of the hole) next to one another.

Description

The invention relates to a monolithic refractory ceramic perforated brick with a first, upper end face and a second, lower end face, and one Through opening between the end faces.

Such a perforated stone is used, for example, to accommodate one Gas purging stone. In this case, the through opening has - analogous to the shape of the gas purging plug - often one Truncated cone shape.

Perforated stones of the type mentioned are also part of Slider locks known.

Lochstein" subsumiert werden.So-called perforated stone sleeves, which, like the previously mentioned gas flushing stones, are summarized below under the term, have an essentially analogous structure to the mentioned perforated stones

Lochstein "are subsumed.

A perforated brick usually consists of one or more less dense ceramic matrix. The perforated brick can poured, pounded or pressed.

The perforated brick is usually installed in a wall or a floor of a metallurgical melting vessel, for example a steel ladle. One (upper) end face of the perforated brick faces the molten metal. This end is also called that hot end ". The opposite end of the perforated brick, which is outside after installation, is the so-called cold end ".

In operation, it happens between the hot end "and cold end "to form a temperature gradient in the axial direction of the sink (corresponding to the central longitudinal axis of the through opening).

This uneven thermal stress often leads to horizontal cracks, i.e. cracks that run parallel to the end faces of the perforated brick. These cracks are usually at a distance of 5 to 20 cm from the hot end "of the perforated stone. As the perforated stone in particular towards the cold end "sintered only after a delay, the crack propagation is relatively fast and can take place until the Perforated stone head ", that is to say the section of the perforated stone facing the melt. A weakening of the cement bond can also be responsible for the crack formation and the progress of the crack in this thermally stressed region, provided that the perforated stone consists of a cement-bound mass.

In addition to these horizontal cracks, vertical cracks (i.e. parallel to the central longitudinal axis of the through opening) are also observed, which are usually known as so-called Form cross cracks ", that is to say run radially outward from the through opening or from one end face to the other end face.

In any case, the Service life of the perforated brick.

With cast perforated bricks in particular, attempts have been made to to extend the service life by adding steel needles. The Effect of steel needles, which are isolated as discrete elements is present in the matrix material, but is at best very low.

The invention is based on the object, one To offer perforated brick of the type mentioned, the less sensitive is against crack formation and its service life conventional perforated stones is improved.

The invention is based on the knowledge that this Task to be solved in an amazingly simple way can, by the perforated stone - radial to the central longitudinal axis of the Through opening viewed - from different ceramic materials is built. Although a total monolithic, for example cast or stamped Perforated stone is available which includes ceramic Matrix material different sections (zones) different materials (types).

Specifically, this means that between the through opening and a first section of the outer walls of the perforated brick is arranged from a ceramic material A, the one second section made of a ceramic material B follows. This can extend up to the outer walls of the perforated brick extend or for example from a third section be followed, which in turn from material A or one third variety C.

As a result, a kind Composite body "is formed, the individual layers (sections, zones), however, forming a monolithic body with one another and overall, although it is not excluded that interface regions are present between the individual zones (sections) even after sintering. To that extent the term refers overall monolithic body "insists that the individual zones (sections) are not separated from each other and next to each other, but complement each other to form a uniform, continuous body, a uniform, continuous matrix.

However, the different materials have the consequence that also different within the corresponding zones physical properties that can be set in With regard to the crack behavior of the perforated bricks from are essential.

It is particularly about the physical Properties of the corresponding ceramic materials or sections formed therefrom.

The term physical properties "includes, for example, thermal shock resistance, corrosion resistance, thermal conductivity, degree of sintering, density, or the like.

For example, a relatively dense layer follows one less dense layer in which a crack towards the dense layer runs, so the crack progress at Reaching the denser layer is interrupted spontaneously or slowed down.

If, for example, a layer that sinters at 900 ° C follows a layer that sinters only at 1100 ° C, it is obvious that a crack that forms in this area, for example at a temperature of 1,000 ° C, is relative easily through the still can pass through "zone that sinters only at 1,100 ° C, but is then stopped or reduced in the progress of cracking when the already sintered layer is reached.

Thereafter, the invention relates to its most general Embodiment a monolithic ceramic perforated brick with a first, upper end face and a second, lower end face and a through opening between the end faces, made of its refractory ceramic matrix at least two, in the radial direction (perpendicular to the Center longitudinal axis of the through opening) side by side arranged sections from different ceramic Materials.

As stated, the ceramic materials of the Sections in particular in their physical properties differentiate.

Since the crack formation and the crack progress significantly from that depends on the respective structure of the ceramic material an embodiment before, the sections of ceramic Form materials that have a different structure exhibit or under the influence of temperature develop different structures.

The sections mentioned can be between the End faces run. Since the cracking - as stated - but especially in that of the first (upper) end face neighboring section is also observed, the mentioned sections in this area of the perforated brick to arrange and for example the lower part of the perforated brick (adjacent to the lower end face) continuously from and to design the same ceramic matrix material.

To effectively influence crack propagation should reach the minimum thickness (radial to Considered the central longitudinal axis of the through opening) mentioned sections are 1 cm. As a rule, the Sections have a thickness of several cm each.

The sections can - in the direction of the central longitudinal axis of the Through opening viewed - straight (flat) surfaces exhibit.

According to one embodiment it is provided that the sections are stepped between the end faces. On in this way there is an additional influence on a any crack propagation and its positive guidance at least in sections in the axial direction.

The production of a perforated brick of the type mentioned can be as can be done as follows:

In a perforated stone form, a template for the Through opening and one or more self-supporting Separators used. These separators can for example, have a cylindrical shape. you will be spaced from the template for the through opening or to the inner walls of the mold and spaced arranged to each other. This way, different Zones formed, which then with different ceramic materials. It offers itself to use ceramic casting compounds, albeit for example, ramming compounds can also be used.

The chemical mineralogical structure of the masses is practical any; the only decisive thing is that different masses in neighboring sections (zones).

After the mold has been filled in this way, the Separators, provided they are not made from a combustible Material exist, pulled out again so that the refractory ceramic materials in adjacent zones lie directly next to each other.

As soon as the perforated stone has sufficient green stability has been removed from the mold and in a known manner processed or used.

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

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

Figur 1:

einen vertikalen Längsschnitt durch eine erste Ausführungsform eines Lochsteins,

Figur 2:

eine Aufsicht auf den Lochstein nach Figur 1,

Figur 3:

einen vertikalen Längsschnitt durch eine zweite Ausführungsform eines Lochsteins,

Figur 4:

eine Aufsicht auf den Lochstein nach Figur 3.

Here show - each in a schematic representation -

Figure 1:

2 shows a vertical longitudinal section through a first embodiment of a perforated brick,

Figure 2:

2 shows a top view of the perforated brick according to FIG. 1,

Figure 3:

a vertical longitudinal section through a second embodiment of a perforated brick,

Figure 4:

a top view of the perforated brick according to Figure 3.

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

Reference numeral 10 denotes a perforated brick all in all. Like every perforated brick, the ones in the Figures shown perforated stones a central Through opening 12, which here has a truncated cone shape and the later inclusion of a correspondingly shaped one Gas flushing stone is used. The central longitudinal axis of the Through opening 12 bears the reference number 14.

As can be seen from FIGS. 2, 4, the perforated stones 10 a square base, whose outer walls with 10a to d are marked.

Between the through opening 12 and the outer walls 10a to d, the perforated brick 10 consists of a monolithic Refractory ceramic body 16, which according to Figures 1, 2nd in two sub-zones 16.1 (adjacent to the passage opening 12) and 16.2 (adjacent to the outer walls 10a to d) is.

While the zone 16.1 inside - according to the shape of the Through opening 12 - is the shape of a truncated cone Outer wall of section 16.1 cylindrical.

The border area to the outside is indicated by a dotted line Section 16.2 shown.

Sections 16.1 and 16.2 are in fact immediate to each other and form a common, continuous, monolithic matrix.

In the illustrated embodiment (Figures 1, 2) section 16.1 made of a refractory ceramic Material that sinters at 1,100 ° C while the outer one Section 16.2 made of a ceramic refractory material exists that sinters at 900 ° C.

Forms - as shown schematically in Figure 1 - of a crack 18 from the inner wall of section 16.1 (vertical to the central longitudinal axis 14 of the through opening 12), see above The crack 18 reaches the interface at a given time to section 16.2.

If one assumes that at this point in the area of Cracks 18 a temperature of, for example, 1,000 ° C prevails, this means that layer 16.1 is not yet is sintered while layer 16.2 is already sintered is. Consequently, the crack 18 can not easily in the Continue layer 16.2; rather it becomes in the border area stopped between layers 16.1 and 16.2. Either ends then the crack here, or at best it settles decelerated speed in the outer layer 16.2.

The embodiment of Figures 3, 4 differs differs from that of Figures 1, 2 in that the monolithic Body 16 is divided into a total of three zones here are marked with 16.1, 16.2 and 16.3.

Layers 16.1 (through opening 12 adjacent) and 16.3 (adjacent the outer walls 10a to d) of the same ceramic material while the one in between arranged, cylindrical layer 16.2 from another refractory mass.

Regarding the crack behavior, the perforated brick corresponds to the Figures 3, 4 essentially that of Figures 1, 2, wherein here however an additional interface between the Layers 16.2 and 16.3 is formed.

Of course, for further optimization it is possible layer 16.3 of a different refractory grade than that of layer 16.1.

In addition to the illustrated embodiments, it is possible for example, the outer wall of layer 16.1 after To design the embodiment of Figure 1 differently.

So the outer wall between the upper end face 20 of the Lochstein 10 and the lower end face 22 also step-like be formed.

Claims (8)

Monolithic refractory ceramic perforated brick (10) with a first, upper end face (20) and a second, lower end face (22) and a through opening (12) between the end faces (20, 22), the refractory ceramic matrix (16) of at least two, in Radial direction (perpendicular to the central longitudinal axis (14) of the Through opening (12)) arranged side by side Sections (16.1, 16.2, 16.3) from different ceramic materials. Perforated brick according to claim 1, wherein the ceramic Materials of the sections (16.1, 16.2, 16.3) in their distinguish physical properties. Perforated brick according to claim 2, in which the ceramic Materials of the sections (16.1, 16.2, 16.3) in their Differentiate structures. Perforated brick according to claim 2, in which the ceramic Materials of sections (16.1, 16.2, 16.3) with regard to differentiate their sintering temperature. Perforated brick according to claim 1, wherein the ceramic Materials of the sections (16.1, 16.2, 16.3) in their distinguish chemical mineralogical structure. Perforated brick according to claim 1, wherein the sections (16.1, 16.2, 16.3) continuously between the end faces (20, 22) run. Perforated brick according to claim 1, wherein each section (16.1, 16.2, 16.3) a minimum thickness (radial to Central longitudinal axis (14) of the through opening (12)) from FIG. 1 cm. Perforated brick according to claim 1, wherein the sections (16.1, 16.2, 16.3) between the end faces (20, 22) have gradations on the circumference.

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