WO2013014257A1

WO2013014257A1 - Coated blast furnace bricks

Info

Publication number: WO2013014257A1
Application number: PCT/EP2012/064747
Authority: WO
Inventors: Janusz Tomala; Christian Wiebel
Original assignee: Sgl Carbon Se
Priority date: 2011-07-28
Filing date: 2012-07-26
Publication date: 2013-01-31
Also published as: DE102011079967A1; TW201321334A

Abstract

The invention relates to a carbon brick for lining, more particularly internal lining, smelting and reduction ovens, more particularly blast furnaces, said carbon brick having a surface, one area of the surface providing a process side of the carbon brick that is brought into contact with liquid metal, more particularly crude iron, and/or slag during intended use, and the carbon brick having a base body containing a carbon material, with a surface. The invention is characterized in that, in order to prepare the process side of the carbon brick, a protective coating comprising a friction-reducing ceramic coating or formed therefrom is applied to at least one area of the base body surface.

Description

Coated blast furnace stones

description

The present invention relates to a carbon brick for the inner lining of melting and reduction furnaces, a melting and reducing furnace containing such a carbon brick and a method for producing such a carbon brick. In particular, these melting and reduction furnaces blast furnaces for the production of pig iron.

For example. have melting and reduction furnaces designed as blast furnaces several superimposed zones, wherein in the so-called melting zone, prevail in the temperatures in the range of about 1600 ° C, the molten pig iron and slag is.

Inner linings of smelting and reduction furnaces are often made in the region of the melting zone of carbon stones, which are usually constructed essentially of amorphous and / or graphitic carbon material and / or graphite.

The carbon stones in contact with the molten metal, eg pig iron, and the slag are subject to high chemical and mechanical wear, for example, caused by the solubility of the carbon in carbon-unsaturated pig iron, the penetration of metal, for example, pig iron into the pore system of Carbon stones, which causes cracks in the stones, by movement of the molten metal, for example, pig iron, and the slag and by reaction of the carbon with slag constituents and / or alkalis. The above-mentioned wear mechanisms significantly reduce the life of carbon bricks in melting and reduction furnaces. For example, in order to be economical, melting and reduction furnaces designed as blast furnaces should be able to operate for 15 years or more without major repairs. By premature wear even only some of the carbon stones in the melting zone but the life of the entire melting and reduction furnace is limited, resulting in a premature end of the furnace travel and thus reduced furnace efficiency. Therefore, carbon blocks must have a long service life at all positions in the furnace where they are used - even in the area of the highly stressed melting zone.

In the past, attempts have been made to improve the service life of carbon bricks for the inner lining of melting and reducing furnaces formed as blast furnaces, for example by adhering ceramic tiles to the carbon bricks on the process side in contact with the molten pig iron. Such solutions are known, for example, from US2005 / 025443 and EP1975258, where silicon carbide or alumina tiles are adhered to the carbon body and provide the process side of the carbon block. However, these solutions are complicated by the additional bonding step and therefore expensive. Furthermore, under the prevailing conditions, an adhesive bond is not permanently stable, as a result of which the tiles detach from the carbon base bodies, which significantly reduces the desired protective effect.

The solutions proposed in the past have not led to a satisfactory increase in the life of carbon stones for the inner lining of melting and reduction furnaces and were often also expensive to produce. The object of the present invention is therefore to propose a carbon brick for the inner lining of melting and reduction furnaces, which has an increased wear resistance.

The object of the invention is also to propose a melting and reduction furnace with extended life.

The object of the invention is also a method for cost-effective production of a wear-resistant

To propose carbon stone for the inner lining of melting and reduction furnaces.

The above objects are achieved by the features of independent claims 1, 12 and 15.

The idea of the invention is to increase the wear resistance of carbon bricks to the inner lining of melting and reduction furnaces in a reliable and cost-effective manner by applying to the surface of the base body in the region containing the molten metal, in particular pig iron, and / or to provide the slag with the process side in contact, a protective coating comprising a wear reducing ceramic topcoat is applied.

A coating is to be understood in this patent application at least one layer which is formed by applying a formless material on a substrate and firmly connected to the substrate.

By providing a protective coating comprising a ceramic top coat, the carbon material of the base body, and thus the carbon stone, can be effectively and inexpensively protected from wear in the melting and reduction furnace. Advantageous embodiments and further developments of the invention are specified in the subclaims.

For the purposes of the present invention, amorphous carbon is understood as meaning a carbon material which contains anthracite and / or coke and not more than 70% by weight of graphite and which was exposed in its entirety to a temperature of 2000 ° C. or less.

For the purposes of the present invention, graphitic carbon is understood as meaning a carbon material which contains more than 70% by weight of graphite and which was exposed in its entirety to a temperature of 2000 ° C. or less.

Within the meaning of the present invention, graphite is understood as meaning synthetic graphite or natural graphite or a mixture thereof.

If in the context of the present patent application of a blast furnace is talking, a blast furnace for the production of pig iron is to be understood.

However, there are also other melting and reduction furnaces which may be included in the invention. These may be, for example, melting and reduction furnaces for the production of ferroalloys, such as ferro-silicon, ferro-manganese, ferro-chromium, ferro-nickel,

Special alloys (including FeV, FeNb, FeW, FeMo), as well as for the production of non-ferrous alloys such as calcium carbide and Calzium-Siliziu act. The aforementioned ovens, which are not blast furnaces, are also referred to as so-called "Submerged Are Furnaces" (SAF).

According to a particularly preferred embodiment of the invention, it is provided that the protective coating additionally comprises an intermediate coating arranged between the surface of the main body and the topcoat, which in the temperature range from 20 ° C to at least 1600 ° C has a thermal expansion, which lies between the thermal expansion of the body and the ceramic topcoat.

By this preferred embodiment, the formation of cracks in the protective coating and the resulting flaking of the protective coating can be reduced, if not prevented, since high thermal stresses in the cover coating which comes into contact with the metal, for example pig iron, are reduced or even prevented.

Since a main body constructed essentially of carbon material generally has a lower thermal expansion in the temperature range from 20 ° C. to at least 1600 ° C. than a ceramic material suitable for the top coat, which is resistant to mechanical and chemical wear by molten metal, in particular pig iron, and / or slag can withstand carbon materials at 1000 ° C, for example, have a thermal expansion coefficient of about 3xl0 ⁶ / K whereas, for example, alumina at this temperature has a coefficient of thermal expansion of about 8.5xl0 ⁶ / K, can in a protective coating without intermediate coating in operation, high thermal stresses occur, which can lead to cracking in the top coat and thus to their premature failure. In the present embodiment, the intermediate coating serves as a buffer between the divergent thermal expansion behavior of carbon body and topcoat.

By the preferred embodiment, it is also possible to produce an optimal connection of the protective effect against the wear of molten metal, in particular pig iron, and slag providing top coat and the base body and Furthermore, the material for the top coat optimally select the specific task of protection.

The topcoat is preferably selected so that it fulfills at least one, preferably several and particularly preferably all of the following functions with respect to a carbon block which, apart from the absence of the protective coating, is constructed identically to the carbonstone according to the invention: higher resistance to liquid metal, in particular pig iron, higher resistance to alkalis, higher stability against oxidizing atmosphere, higher resistance to mechanical wear

Less infiltration of liquid metal, in particular pig iron,

Stronger formation of a "natural" protective layer of adherent metal, in particular pig iron, and / or slag

The intermediate coating is preferably selected such that, in addition to its thermal expansion in the temperature range from 20 ° C. to at least 1600 ° C. between that of the main body and that of the topcoat, it comprises at least one, preferably several and most preferably all of the following functions fulfilled: good connection to the surface of the main body good connection to the top coating permanent applicability at temperatures up to at least 1600 ° C, ie, for example, no structural changes, no phase transitions

A further particularly preferred embodiment of the invention provides that the protective coating is formed only of the intermediate coating and the top coat, i. According to this embodiment, the protective coating comprises no further coatings than the intermediate coating and the topcoat. In this connection, provision is made in particular for the intermediate coating to be applied directly on the surface of the main body and the ceramic topcoat directly on the intermediate coating.

In principle, it would be possible to provide the entire surface of the base body with the protective coating. But this is not necessary and often not desired, since the protective coating on the one hand brings with it additional costs and on the other to surface sections where it is not needed, such as the top or the bottom of the carbon stone, where the stones for training the inner lining are stacked vertically, is more of a hindrance. A preferred development of the invention therefore provides that the carbon brick has the protective coating only in the region of its surface which provides the process side.

It is also conceivable that the carbon brick is provided in addition to the process side on the opposite side of the process side of its surface with the protective coating. This is particularly useful when the carbon stone is arranged in the region of the tap hole of the furnace formed as a blast furnace and reduction, since in this area liquid pig iron is tapped and from the interior of the furnace to the outside, the so-called. Cold side occurs. As a result, the cold side of the furnace comes into contact with the molten pig iron and is thus subjected to high wear. By providing the coating of the carbon brick both on its process side and on its side providing the outside of the furnace, the wear previously described can thus be reduced.

If the carbon brick comprises a tap hole, then another preferred embodiment of the invention provides that the interior of the tap hole itself has the protective coating already described.

In principle, it is conceivable that the intermediate coating is formed by one or more intermediate layers. Furthermore, it is conceivable in principle that the ceramic cover coating is formed by a single or by a plurality of ceramic cover layers. In this context, various combinations are possible. Thus, it is possible that both the top coat and the intermediate coat are each formed of only a single coat. It is also conceivable that the intermediate coating of a single layer and the top coat are formed of several layers. Further, it is possible that the top coat is formed of a single layer and the intermediate coat of multiple layers. In addition, it can also be considered that both the top coat and the intermediate coat are each formed from several layers.

The ceramic topcoat may include or be formed from one or more oxidic or carbidic or more carbidic or boridic or more boridic or nitricidal or more nitridic ceramic materials or mixtures thereof. Further, the intermediate coating may be one or more metals or one oxide or more oxide or one carbide or more carbidic or one boridic or more boridic or one nitridic or more nitridic Ceramic material (s) or mixtures thereof contain or be formed from it.

In this context, it is both possible that a cover layer of the top coat consists of a mixture of the above-mentioned materials as it is also possible, for example. In the case that the top coat is composed of several cover layers is possible that a cover layer of the top coat only one of the consists of the above materials and another cover layer of the top coat of another of the above materials or of several of the above materials.

The above considerations apply to the same extent for the intermediate coating, in which both an intermediate layer of only one or more of the above materials may be formed or may contain these materials, as it is also possible that an intermediate layer consists of only one material whereas another intermediate layer consists of several of the above-mentioned materials. Furthermore, it can be provided that the intermediate coating is formed from a single or a plurality of metals.

Accordingly, it can be provided that at least one intermediate layer is formed from a single material and / or at least one cover layer is formed from a single material.

An exemplary and non-exhaustive list of possible concrete embodiments for the intermediate coating and the top coat provides, for example, that the intermediate coating of a single layer of molybdenum and the top coating of a single layer of alumina are formed. It is also conceivable in this connection that the intermediate coating consists of a single layer of aluminum nitride and the top coating of a single layer Titanium carbide are formed. Further, it is also possible, for example, for the intermediate coating to consist of a single layer of tungsten carbide and the topcoat of a single layer of titanium diboride.

Preferably, the topcoat has a thickness in the range of 50 μπι to 1500 μπι, preferably 100 μηι to 1000 μπι, more preferably 400 μηι to 700 μπι. Experiments have shown that from layer thicknesses of more than 1500 μπι over thinner layer thicknesses no improvement in the protective effect more occurs, but rather a deterioration, since topcoats with such high layer thicknesses tend more to cracking than thinner. Furthermore, tests have shown that topcoats with layer thicknesses above 400 μm already provide adequate wear protection.

Preferably, the intermediate coating has a layer thickness in the range of 10 μπι to 600 μπι. In the case that the intermediate coating consists of several intermediate layers, the individual intermediate layers can each have a layer thickness in the range of 10 μπι to 200 μπι.

The carbon material of the main body preferably contains or is preferably formed from, amorphous carbon such as anthracite and / or coke, graphitic carbon, synthetic graphite, natural graphite or a composition of several of the aforementioned materials. Further, in addition to the carbon material, the material composition of the base body may contain one or more ceramic constituents, the proportion of all ceramic constituents being lower in the material composition than the proportion of the carbon material. The material composition preferably contains more than 60% by weight of the carbon material. As ceramic constituents, for example, one or more oxidic (s), a or a plurality of carbidic, one or more nitridic, one or more boridic ceramic material (s), or mixtures of several of the foregoing materials.

In accordance with a further aspect of the invention, a melting and reducing furnace, in particular a blast furnace, designed as a shaft furnace, having a melting zone in which molten metal, in particular pig iron, and / or slag is present during operation of the furnace, is proposed. The shaft furnace has an inner furnace lining, which is in contact with the molten metal, in particular pig iron, and / or the slag during operation of the furnace in the region of the melting zone. According to the further aspect of the invention, it is proposed that the inner furnace lining at least in the region of the melting zone contains at least one carbon block according to the invention, which points with its process side into the interior of the shaft furnace.

In the area of the tap hole, liquid pig iron and / or slag is tapped off and exits from the so-called cold side of the furnace from the melting and reduction furnace designed as a blast furnace. As a result, the cold side of the furnace comes in contact with the liquid pig iron and / or the slag in the region of the taphole, whereby the carbon blocks arranged in this region come into contact with the liquid pig iron and / or the slag on the cold side. In order to reduce the resulting wear on the cold side, a preferred embodiment of the invention provides that in the region of the at least one taphole at least one further inventive carbon stone is provided with its process side at least partially the outside or cold side of the furnace in the Provides the tap hole area. According to this embodiment, the furnace therefore has a plurality of carbon stones according to the invention, of which at least one with its coated process side, the inside of the furnace and at least another with its coated process side provides the outside of the oven.

According to one of the o.g. Embodiment alternative embodiment is provided that at least one carbon brick, in addition to the coating on the process side, at least partially on the process side opposite cold side of its surface has a protective coating and that the at least one carbon stone in the tap hole is arranged so that the coated process side into the interior of the furnace and is in contact with the molten pig iron and the coated cold side provides part of the outside of the furnace in the region of the tap hole. Preferably, in this case, the protective coating forming part of the outside of the furnace is constructed the same as the protective coating of the carbon brick of the process side.

According to a third aspect of the invention, a method is proposed for producing a carbon brick for the inner lining of melting and reducing furnaces, comprising the following steps:

Preparation of a mixture containing a plurality of constituents selected from the group of anthracites, cokes, graphites, metallic or ceramic additives, binders from the group of tars, pitches, bitumen,

Shaping the mixture to obtain a green body,

Firing and optionally subsequently impregnating and / or graphitizing the green body to obtain a carbon body,

- Machining the carbon body to obtain a body of carbon with a surface Thawing the surface of the base body at least in the section intended to provide a later process side of the carbon stone,

Applying a protective coating to at least a portion of the roughened surface.

The shaping can be done for example by vibration compression (vibromolding) or extrusion. The firing of the green body can be carried out at temperatures in the range of about 800 ° C to 1300 ° C.

The metallic additives may be, for example, silicon (Si), titanium (Ti) or zirconium (Zr), which are at least partially converted into a ceramic material in the subsequent firing and / or graphitization process. The ceramic additives may, for example, be silicon carbide (SiC), titanium dioxide (T1O2) or aluminum oxide (Al2O3) or aluminum silicates. According to a preferred embodiment of the method according to the invention, the protective coating is applied by first applying an intermediate coating to at least one area of the roughened surface and subsequently applying a topcoat to at least one area of the intermediate coating.

The surface to be coated of the carbon body obtained after the firing process and the mechanical processing can be roughened by sand blasting, for example. Methods for applying the intermediate layer and the cover layer may be, for example, methods such as plasma spraying, flame spraying, chemical vapor deposition (CVD), physical vapor deposition (PVD) or the like. In this context, it is, for example, conceivable that a suspension is provided for the production of the ceramic topcoat and / or the intermediate coating, which is applied, for example, by a coating, spraying or dipping process on the area of the surface of the base body to be coated and below for the conversion of the suspension in the topcoat or the intermediate coating is subjected to a temperature treatment. The suspension may in this case, for example, contain a polymeric liquid and ceramic particles.

The invention will be explained below with reference to two drawings. It show the

Figure 1 shows an embodiment of an inventive

Carbon stone in side view,

Figure 2 shows a reduction and melting furnace according to the invention in

Longitudinal section.

FIG. 1 shows a carbon brick 1 for the inner lining of melting and reduction furnaces. The shown carbon brick 1 has a surface 2, which provides a process side 3 of the carbon brick 1 on a section. When the carbon brick 1 is used as intended, the process side 3 is brought into contact with molten metal, in particular pig iron, and / or slag.

The illustrated carbon brick 1 has a base body 4 containing a carbon material with a surface 5 on which a protective coating 6 is applied in an area 5 ^' for providing the process side 3. The protective coating 6 shown in the present embodiment is characterized by a wear-reducing ceramic top coat 7 and a between the surface 5 of the base body 4 and the top coat 7 arranged intermediate coating 8 is formed.

In the present case, the intermediate coating 8 as well as the ceramic top coating 7 are each formed by a single layer, wherein the intermediate layer 8 forming intermediate layer of the metal molybdenum and the cover layer 7 forming cover layer of the ceramic is alumina.

The intermediate coating 8 and the top coat 7 are adjusted so that in the temperature range of 20 to at least 1600 ° C, the thermal expansion of the intermediate coating 8 is greater than the thermal expansion of the base body 4 and smaller than the extent of the ceramic top coat. 7

In the present case, the intermediate coating 8 is applied directly to the surface 5 of the main body 2 and the ceramic top coating 7 is applied directly to the intermediate coating 8. The top coat 7 of the present embodiment has a thickness of about 500 μπι and the thickness of the intermediate coating 8 is about 100 μπι.

In the present case, the base body 4 is produced from a mixture which contains about 40% by weight of anthracite, about 40% by weight of graphite, about 10% by weight of silicon and about 10% by weight of aluminum oxide in the dry mixture , wherein the green body produced therefrom was burned at about 1200 ° C for the production of the carbon body.

In the present exemplary embodiment, the carbon brick is provided with the protective coating 6 only in that section of its surface 2 which provides the process side 3. 2 shows a reduction and smelting furnace 9 according to the invention, which is designed in the present embodiment as a blast furnace in shaft construction.

In a blast furnace pig iron is obtained by reduction from iron ores, which serves as an energy source and reducing agent predominantly coke and the slag formation and lowering of the melting temperature various additives such as quartz sand, lime are buried. The blast furnace 9 has in its lower part a designated as a stop 10 and as a frame 1 1 section, which in the present case surrounding the molten zone 12 of the blast furnace 9. In the molten zone 12 is in operation molten pig iron and slag. In this case, a temperature in the range of about 1600 ° C. prevails in the molten zone 12. During operation, hot air is blown through so-called wind nozzles 13 in the molten zone 12, which are supplied via a loop 14. The slag is passed through a tap hole 15 and the pig iron is fed out of the molten zone 12 via a tap hole 16. In the illustrated blast furnace 9, the entire molten zone 12 is enclosing interior lining, i. the directed into the furnace interior side at least partially, preferably completely constructed of the carbon bricks 1 according to the invention.

Furthermore, in the region of the two tap holes 15 and 16, the external wall forming the outside of the blast furnace 9 is formed at least in sections by carbon blocks 1 according to the invention, which with their process side 3 provide the outside of the blast furnace in the region of the tap holes 15 and 16.

Claims

claims

1. carbon brick for lining, in particular interior lining, of melting and reducing furnaces, in particular blast furnaces, wherein the carbon brick has a surface and an area of the surface provides a process side of the carbon brick which, when the carbon brick is used with liquid metal, in particular pig iron, and / or slag is brought into contact and the carbon brick has a carbon material-containing base body having a surface, characterized in that for providing the process side of the carbon stone at least on a portion of the surface of the base body, a protective coating is applied, which comprises a wear-reducing, ceramic topcoat or formed from it.

2. carbon brick according to claim 1, characterized in that the protective coating additionally comprises a disposed between the surface of the base body and the top coat intermediate coating, which has a thermal expansion in the temperature range of 20 ° C to at least 1600 ° C, between the thermal expansion of the Body and the ceramic top coat is.

3. carbon stone according to claim 1 or 2, characterized in that the intermediate coating is applied directly on the surface of the base body and the ceramic cover coating directly on the intermediate coating.

4. carbon stone according to any one of claims 1-3, characterized in that the protective coating of the intermediate coating and the top coat is formed.

5. carbon brick according to one of claims 1-4, characterized in that in the temperature range of 20 ° C to at least 1600 ° C, the thermal expansion of the intermediate coating is greater than the thermal expansion of the body and smaller than the thermal expansion of the ceramic topcoat.

6. carbon brick according to one of claims 1-5, characterized in that the ceramic topcoat one or more oxidic (s), one or more carbidic or one or more boridic (s) or one or more nitridic (s) ceramic material or ceramic materials or mixtures containing or formed from and / or that the intermediate coating one or more metallic material or one or more oxidic (s), one or more carbidic, one or more boridic or a or contains or is formed from a plurality of nitridic ceramic materials or ceramic materials or mixtures thereof.

7. carbon brick according to one of claims 1-6, characterized in that the topcoat has a thickness in the range of 50 μπι to 1500 μπι, preferably 100 μπι to 1000 μπι, more preferably 400 μπι to 700 μπι has.

8. carbon brick according to one of claims 1-7, characterized in that the intermediate coating has a thickness in the range of 10 μπι to 600 μπι, and in the case that the intermediate coating consists of several intermediate layers which individual intermediate layers each have a thickness in the range of 10 μπι to 200 μπι have.

9. carbon brick according to any one of claims 1-8, characterized in that the carbon material of the body contains amorphous carbon or graphitic or graphitized carbon or a mixture thereof.

10. carbon brick according to claim 9, characterized in that the main body in addition to the carbon material one or more ceramic component (s) which together with the carbon material form a material composition and are present in the material composition to a lesser extent than the carbon material.

1 1. carbon stone according to any one of claims 1- 10, characterized in that the carbon stone only in the

Process side providing portion of its surface has the protective coating.

12. As a shaft furnace formed melting and reduction furnace, in particular blast furnace, which has a melting zone in which molten metal, in particular pig iron, and / or slag is in operation of the furnace, as well as with an inner furnace lining, which in operation of the furnace in the area the molten zone with molten metal, in particular pig iron, and / or slag is in contact, characterized in that the inner furnace lining contains at least in the region of the melting zone at least one carbon stone according to one of claims 1 to 1 1 and with its process side into the interior of the shaft furnace has.

13. Melting or reducing furnace according to claim 12, characterized in that the furnace has at least one tap hole through which the molten metal, in particular pig iron, and / or slag can be led from the molten zone to the outside of the furnace, wherein in the area at least one further carbon brick according to one of claims 1 to 11 is provided in the at least one tap hole, which with its process side at least partially provides the outside of the furnace in the region of the tap hole.

14. Melting or reducing furnace according to claim 12, characterized in that the furnace has at least one tap hole through which the molten metal, in particular pig iron, and / or the slag can be led from the molten zone out to the outside of the furnace that at least one Carbon brick, in addition to the coating on the process side, at least partially on the process side opposite cold side of its surface has a protective coating and that the at least one carbon stone in the tap hole is arranged so that the coated process side facing the inside of the furnace and the coated cold Page provides a part of the outside of the furnace in the tap hole.

15. A method of producing a carbon brick for the interior lining of melting and reduction furnaces, the method comprising the steps of: a. Preparation of a mixture containing a plurality of constituents selected from the group of anthracites, cokes, graphites, metallic and / or ceramic additives, binders from the group of tars, pitches, bitumen, b. Shaping the mixture to obtain a green body, c. Burning and optionally subsequently graphitizing the green body to obtain a carbon body, d. Machining the carbon body to obtain a body of carbon with a surface e. Thawing the surface of the body at least in the portion intended to provide a later process side of the carbon stone, f. Applying a protective coating to at least a portion of the roughened surface

16. The method according to claim 15, characterized in that the protective coating is applied by a. first an intermediate coating on at least a portion of the roughened surface and b. subsequently applied to at least a portion of the intermediate coating of a topcoat.