WO2016102149A1 - Feuerfeste erzeugnisse und ihre verwendung - Google Patents
Feuerfeste erzeugnisse und ihre verwendung Download PDFInfo
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- WO2016102149A1 WO2016102149A1 PCT/EP2015/078079 EP2015078079W WO2016102149A1 WO 2016102149 A1 WO2016102149 A1 WO 2016102149A1 EP 2015078079 W EP2015078079 W EP 2015078079W WO 2016102149 A1 WO2016102149 A1 WO 2016102149A1
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Definitions
- the invention relates to refractory products, in particular to DIN ISO / R 836, DIN 51060, in the form of dry, mineral offsets or mixtures based on at least one Magnesiarohstoffes as a coarse-grained main component suitable for the production of refractory products for lining of non-ferrous metal melting furnaces, and in the form of made from the offsets, unshaped or shaped refractory products, e.g.
- the invention also relates to the use of the unshaped or shaped refractory products produced from the stakes in a non-ferrous metal melting furnace, in particular in the area of an oxidized furnace zone, preferably in the slag melting zone of a non-ferrous metal melting furnace.
- refractory product is used as a general term for a refractory offset and for refractory products, for example, using a liquid binder and / or water from an offset, for example by molding and / or pressing getting produced.
- the terms "flour” or “powder” refer to grains, the usual grain distributions, eg. B. Gaussian grain distributions and their maximum grain z. B. to 95 wt .-% below 1.0, in particular less than 0.5 mm, determined z. B. as Sieb diegangswert dg. 5
- Coarse grained means that the granules usual grain distribution, z. B. Gaussian grain distribution with z. B. 95 wt .-% s 0.1, in particular £ 0.5, preferably 1, 0 mm, z. B. also determined as dgs value.
- Coarse-grained component means that the coarse graining in a product made from an offset can form a scaffold with mutually-supporting grains.
- Non-ferrous metals also called non-ferrous metals, such as copper, lead, zinc, nickel or the like are commercially available in various vessels z. B. from sulfidic ores melted (eg Pierce Smith Kon lose, QSL reactors or shaft furnaces). The melting processes are carried out in both reducing and oxidizing zones or under reducing and oxidizing melt processes in a non-ferrous metal melting furnace.
- the so-called duration of the ovens depends u. a. also on the type of refractory lining - also called lining - on the one hand protects the metal jacket of the furnace from the action of high Schmelzgut-, flame and atmospheric temperatures and on the other reduces heat loss.
- the copper ores it is mainly compounds of the metal, eg. As the copper, iron and sulfur.
- the compositions of the ores are highly dependent on the respective deposit.
- the process of refining which starts with these ores, starts with a pre-treatment and the subsequent melting of the ores. Characteristic for this process are sulfidic melts with high iron contents as well as a sulphurous atmosphere.
- this sulfidic melt is converted into a metal oxide melt, for.
- a sulphide copper melt is converted into a so-called blister copper.
- the iron content in the initially sulfidic melt eg Cu-Fe-S
- the iron is first lowered to less than 1% via a slag-forming process.
- the iron is bound in a resulting fayalite slag (Fe 2 Si0 4 ) with the addition of quartz sand (Si0 2 ) and removed from the process.
- the remaining melt based on Me-S z.
- Cu-S (usually Cu 2 S) is oxidized by blowing air into the melt, z. B. converted to blister copper.
- the oxidized Me melt to pure metal, z.
- the melt is further purified with removal of the remaining sulfur and iron.
- the process is by liquid metal z.
- copper and the resulting slag phases based on Me-Fe-O which represent the corrosion substances.
- the Ofenausmautation a non-ferrous metal melting furnace is usually exposed to high thermal cycling and high mechanical and chemical stresses.
- the thermal cycling results from the batch procedure and the injection of cold process materials.
- Mechanical stresses are z. B. caused by rotational movements of the furnace.
- Chemically, the masonry is claimed by the process slags and molten metals and by volatile compounds of the furnace atmosphere.
- the melting furnaces are divided into different zones, because the zones are differently loaded during operation. For example, in the QSL reactor a distinction is made between the reaction zone, the oxidation zone and the associated nozzle zones.
- the wear of the refractory material caused mainly by chemical corrosion and by slag attack and other process materials as well as spalling of infiltrated layers by temperature change voltages. While the state of the art usually a large proportion of the internal lining of a furnace is lined with normal MgO or MgO-Cr 2 0 3 - stones, the slag zones and especially the nozzle zones with very high-quality, so-called direct gebun- , Magnesia brooks are reinforced.
- Such refractory linings are found in all types of non-ferrous metal furnaces regardless of design.
- the known fired refractory products have an open porosity which is approximately in the range between 13 and 20% by volume.
- materials such as slags, melts or gases can infiltrate into these open pores and, through chemical reactions, decompose the structure of the stone and / or lead to completely changed thermomechanical properties of the structure compared to the original properties of the refractory material.
- Changing chemical attacks as well as changing thermal and thermo-mechanical loads lead to accelerated wear and weakening, in particular after foreign matter infiltration and corrosion of the refractory product components or the stone components.
- Fayalitic slags arise in the production of non-ferrous metals from the sulfidic ores, z.
- copper from chalcopyrite (CuFeS 2 ).
- Copper gravel is roasted, resulting in so-called copper cinder resulting copper sulfide (Cu 2 S) and iron compounds, eg. FeS and Fe 2 0 3 .
- the chalcopyrite is further processed into crude copper, whereby molten copper stone under air supply and addition of Si0 2 , z. In the form of quartz, in a converter.
- the result is a fayalitic slag containing mainly the mineral fayalite (2FeO ⁇ Si0 2 ) and crude copper oxide (Cu 2 0).
- Magnesiachromitsteinen eg., DE 14 71 231 A1
- solid products resist but insufficient attack of sulfates, resulting from the oxidation of sulfides, eg. In the form of magnesium sulfate.
- Magnesiachromite Stones also have limited or insufficient high temperature anti-wetting properties for non-ferrous metal melts, and have insufficient penetration resistance to hot non-ferrous melts.
- Magnesiachromitsteine are also used in melting units for the production of other non-ferrous metals or non-ferrous metals such as Ni, Pb, Sn, Zn and there are equally stored problems.
- a refractory masonry of a non-ferrous metal melting furnace in which in an oxidizing zone of the furnace non-ferrous metals such as copper, lead, zinc, nickel or the like are melted at temperatures above 700 ° C, wherein the masonry of unfired stones refractory material such as MgO or refractory material in which MgO is at least partially replaced by spinel and / or corundum and / or bauxite and / or andalusite and / or mullite and / or flintelay and / or chamotte and / or zirconium oxide and / or zirconium silicate.
- MgO unfired stones refractory material
- refractory material such as MgO or refractory material in which MgO is at least partially replaced by spinel and / or corundum and / or bauxite and / or andalusite and / or mullite and / or flintelay and / or
- the stones have carbon in the form of graphite and a coking structure formed from carbonaceous binder.
- the carbon is said to reduce slag infiltration due to an in situ, thin, sealing infiltration zone, evidently upon reaction of oxygen from the structural constituents of the stone to form first reaction products in the stone which clog in situ pore channels of the stone, so that at least the further access of oxygen into the structure of the stone components is reduced and thus a further reaction of the oxygen with carbon is avoided.
- DE 10 2012 015 026 A1 discloses a refractory product according to ISO R / 836, DIN 51060 for refractory masonry in non-ferrous metals Furnaces known in the form of an unshaped or shaped offset z. In the form of shaped bricks, wherein the refractory product is highly resistant in situ to the attack of fayalitic slags (iron silicate slags) and sulphates and to be resistant to molten non-ferrous metals, in particular to molten copper.
- fayalitic slags iron silicate slags
- sulphates iron silicate slags
- a good anti-wetting property is achieved against non-ferrous metal melts, in particular molten copper, improved penetration resistance against fayalitic slags and improved resistance to sulfate attack at service temperatures through the use of an olivine raw material as the main component of the refractory product, as well as magnesium flour and silicon carbide flour.
- a refractory offset containing said substances may be mixed with a liquid binder in the form of silica sol.
- olivine raw materials containing at least 70% by weight of forsterite contents ensures high corrosion resistance and infiltration resistance to the large amounts of fayalitic slag (FeSiO 4 ). If a fayalite slag comes into contact with the refractory material of the structure of the refractory product, the liquidus temperature of the slag rises. The slag "freezes on the refractory, which does not cause further wear reactions.
- the olivine raw material or the forsterite in the olivine raw material has a poor wettability against non-ferrous metal melts, in particular molten copper, and also very good resistance to corrosion corrosion.
- Magnesia can react in the known refractory products at high corrosion rates to magnesium sulfate, which can cause Geglageschwhari12.
- calcium-containing silicate secondary phases such as dicallosilicate, merwinite, and monticellite in magnesia, can weaken the microstructure.
- the refractory products or products described in DE 103 94 173 A1 and DE 10 2012 015 026 A1 have proven to be superior in comparison with the magnesia bromo-stones used previously.
- the two refractory products based on MgO plus graphite (DE 103 94 173 A1) or olivine raw materials with at least 70% by weight of forsterite contents (DE 10 2012 015 026 A1) as well as on the magnesia brimstone in particular the low-viscosity metals wet.
- Oxides e.g. As the thin liquid copper oxides, but partly also the thin liquid iron oxides, especially the thin liquid Me-Fe-oxides, eg.
- the object of the invention is to provide refractory products based on Magnesiarohstoffen as coarse-grained main component, which are much more resistant during the melting process against the attack of low-viscosity Buntmetalloxiden, especially of low-viscosity copper oxides, and / or low-viscosity Buntmetalleisenoxiden, in particular low-viscosity copper iron oxides.
- the refractory products should also have the good anti-wetting properties against pure non-ferrous molten metal, in particular pure copper melt, resist well the penetration of fayalitic slags and ensure resistance to sulfate attack at operating temperatures.
- a refractory product in the form of a refractory offset based on coarse granules of at least one, in particular low iron, Magnesiarohstoff with high MgO contents of z. B. at least 90 wt .-% MgO.als main component, as well as Magnesiamehl, in particular high-quality and low-iron, sulfur-resistant Magnesiamehl, and at least one reducing during the melting process, refractory reactant, suitable for the reduction of molten low-viscosity Buntmetalloxiden and / or molten low-viscosity non-ferrous iron oxides, for. B. in the form of finely divided carbon, z. B.
- this offset with these components is also called base offset.
- High quality is intended to mean that the usual secondary phases such as Dikalziumsilikat, merwinite, monticellite, etc. with less than z. B. 2.5% by weight are present.
- Sulfur resistant means that the MgO flour should be poor in such silicic minor phases, since these are usually attacked by sulfur compounds first.
- the MgO content of magnesia should be 97% by weight.
- the iron-poor Magnesiarohstoff and the low-iron Magnesiamehl should z. B. less than 10 wt .-% iron (III) have oxide.
- the offset may additionally comprise a finely divided powdered silica.
- the offset may preferably additionally contain per se known antioxidants for refractory products.
- Finely divided should preferably mean that the silica is in the form of microsilicates and / or fumed silica and / or precipitated silica.
- the invention provides for the use of at least one finely divided refractory reaction substance reducing the thin liquid melts in the microstructure of a refractory lining product according to the invention for non-ferrous metal furnaces, the reaction substance having the property, in situ, ie in a non-ferrous metal melting furnace, during the melting process to reduce to the non-ferrous metal melts the anti-wetting properties of the other structural constituents of the refractory lining product and, in the case of the use of graphite, also the anti-wetting Properties of the graphite can act. This results in a high degree of corrosion and infiltration resistance of the lining products according to the invention.
- a reducing reactant is preferably finely divided, z. B. flour-shaped carbon, in particular in the form of graphite and / or resulting from a carbonaceous binder by the action of temperature carbon, z. B. a Koksgerüsts the product structure provided.
- z. B. a Koksgerüsts the product structure provided.
- further finely divided reducing reactants z. As carbon black and / or anthracite and / or coke can be used.
- the reducing reactants are preferably contained in amounts of between 1 and 20, especially between 5 and 15 wt .-% in the refractory base offset or in the refractory lining product based on the base offset components, for. B. with a fineness below 1000 mm.
- the reducing reaction substance is contained in an offset according to the invention in a mixture with the other constituents, in particular homogeneously distributed.
- a refractory lining product made from an offset according to the invention in particular in a solidified molded article, e.g. B. in a refractory shaped stone, the reducing reactant in the structure of the body is also present in particular homogeneously distributed.
- Unformed refractory products made from an inventive offset are e.g. B. with water and / or at least one known binder for refractory products z. B. a carbonaceous liquid binder, turned on and introduced as a refractory lining in a non-ferrous metal melting furnace, wherein z. B. a subsequent drying and / or Annealing causes a solidification of freshly prepared mass.
- the drying or the tempering can also take place during start-up or heating of the non-ferrous metal melting furnace in situ.
- Shaped refractory products such. As stones, made of a water and / or at least one known binder for refractory products, eg. Example, a carbonaceous liquid binder having offset, are usually dried and / or tempered and then used for lining a non-ferrous metal melting furnace. But you can also burn the products made from the offset ceramic and then use as intended.
- binder for refractory products eg. Example, a carbonaceous liquid binder having offset
- An inventive refractory offset is mainly from the basic offset of a dry mixture of coarse-grained magnesia, magnesium flour and reducing reactant, z. B. graphite formed as a reducing reagent.
- a dry inventive offset expediently additionally contain up to 4, especially up to 2.5 wt .-%, commonly used for refractory products antioxidants and / or other additives commonly used for refractory products and / or additives, but the quantitative ratio of the ingredients MgO coarse-grained, MgO flour and reducing reactant, e.g. As graphite, the base offset should be preserved.
- the reducing reactant such as graphite and optionally also carbon derived from the carbonaceous binder or the other carbons mentioned, is consumed only insignificantly by oxidation in oxidizing conditions in situ, ie during a smelting operation of a non-ferrous metal industrial smelting furnace.
- the carbon surprisingly acts in the structure on wetting and penetrating low-viscosity non-ferrous metal oxide melt.
- constituents of an inventive offset or refractory product according to the invention made from an offset according to the invention mainly act as follows:
- Mode of action like MgO coarse-grained. Furthermore formation of forsterite with the offset added Si0 2 and / or Si0 2 from slag constituents; as a result, the porosity is reduced and the effect of the Forsterite properties such as slag stiffening effect and anti-wetting effect against non-ferrous molten metal
- the Magnesiarohstoff (available in appropriate qualities on the market) is used according to the invention as - so-called in the art - coarse-grain granules and should according to the invention preferably as 100 wt%, but at least 90 wt .-% of the mineral periclase. The remainder may be other known contaminants of the raw material such as monticellite and / or merwinite and / or belite.
- the grain size of Magnesiarohstoffgranulats used is z. B. at least 95 wt .-% in the middle and coarse grain z. B. between 0.1 and 8, in particular between 1 and 8 mm, wherein the granules z. B. may have a Gaussian particle size distribution or may be formed from contractions with irregular grain distributions.
- the Magnesiarohstoff is used in particular in amounts of 30 to 74, in particular from 40 to 60 wt .-%, in the basic mixture of the invention.
- the finely divided magnesia is in the form of a flour or powder with z. B. after a certain sieving grain sizes, z. B. of 95 wt .-% ⁇ 1 mm used.
- Magnesia z As fused magnesia and / or sintered magnesia and / or synthetic deadburned or caustic magnesia used.
- fret and "powder” are understood in the context of the invention as the same terms with the same conceptual content, as they are also known in the art. This is understood to mean i.d.R. dry, loose particulate grit of 95% by weight (dgs), 1 mm particle size.
- the MgO content of the magnesia meal should preferably be> 90% by weight, in particular> 95% by weight.
- the rest are common impurities such as silicates and / or iron oxide.
- the MgO flours have z. B. on a Gaussian particle size distribution.
- the MgO flour is used in the dry basic mixture in amounts of from 25 to 50, in particular from 35 to 45 wt .-%.
- the offset may additionally contain silicon carbide (SiC).
- Silicon carbide is available on the market as a synthetic product with a high degree of purity and in various grain sizes and particle size distributions and is inventively in powder form or in flour form z. B. with grain sizes z. B. 95 wt .-% ⁇ 1 mm (d 95 ) used.
- the grain size distribution preferably corresponds to a Gaussian grain distribution.
- the SiC powder is z. B. with a purity of> 90 wt .-%, in particular> 94 wt .-% of SiC used.
- the additional amount used is up to 15, especially up to 10 wt .-%.
- the additional finely divided, dry silica is z.
- a silica which reacts with the MgO of Magnesiamehls in an aqueous medium to form Magnesiumsilikathydratphasen and z.
- magnesium silicate hydrate gel and / or magnesium silicate hydrate crystallites and / or magnesium silicate hydrates forms.
- the Si0 2 content of the finely divided dry silica is preferably above 90% by weight, in particular above 94% by weight. It has become in Surprisingly, it is found that dry, finely divided silica on admission of water to the offset according to the invention forms more rapidly with the MgO of the magnesia MSH phases and hardens faster and gives higher cold compressive strengths.
- the silicic acid is to be selected so finely that in a fresh fresh mass containing water, which is formed by adding water to a dry offset and mixing according to the invention, a reaction takes place between the MgO of the particles of magnesia and particles of the silica and magnesium silicate hydrate phases - hereinafter also MSH- Called phases - z. B. as gel and / or crystallites and / or crystals, which cause a solidification of the water-containing mass in the manner of a hydraulic setting.
- the offset is preferably composed in such a way that a pH of more than 7, in particular more than 10, is established in the aqueous medium, ie after the addition of water to the offset according to the invention. Accordingly, suitable for the reaction to MSH phases z. B. crystalline quartz flour fineness of quartz particles below 500, in particular below 200 [im.
- silicas particularly suitable for the invention as dry, finely divided silicas are: Silica fume
- Silica fume is a very fine, non-crystalline amorphous Si0 2 powder that is produced in an electric arc furnace as a by-product in the production of elemental silicon or silicon alloys. It is z. B. under the trade name silica dust or microstica offered on the market and usually has about 85 wt .-% Si0 2 on. The particle size of silica fume - also called silica fume - is usually less than 1 mm. The English name is "silica fume".
- Pyrogenic silica Pyrogenic silicas are very pure amorphous Si0 2 powder with SiCV contents z. B. to 99 wt .-% and usually with particle sizes z. B. between 5 and 50 nm and high specific surface z. B. between 50 and 600 m 2 / g. These silicas are produced by flame hydrolysis. Pyrogenic silica is on the market for. B. offered under the trade name Aerosil. The English name is "fumed silica".
- silicic acids are used.
- the silicas are expediently selected with respect to their reactivity with the MgO of the magnesia flour and it is ensured that the silica reacts as completely as possible with MgO on hardening.
- the finely divided dry silica is added to the dry offset mixture to 10, in particular from 0.5 to 6 wt .-%.
- dry basic offsets described above preferably only water added to the production of refractory products according to the invention.
- dry basis offsets are thus preferably compiled in% by weight:
- Coarse-grained magnesia 30 to 74, in particular 40 to 60 magnesia flour: 25 to 50, in particular 35 to 45 reducing reactant, in particular
- Fine-particle silica 0 to 10, in particular 0.5 to 6 finely divided SiC: 0 to 15, in particular 0 to 10
- the silica is at least one of the abovementioned amorphous silicic acids.
- the amounts of the reactants MgO flour and Si0 2 in inventive offsets are selected so that at water addition of 1 to 10, in particular from 2.5 to 6 wt .-%, based on the dry matter of the offset, in a period between 6 and 120, in particular between 8 and 12 hours, in the temperature range from 50 to 200, in particular from 100 to 150 ° C, cold compressive strengths of 40 to 160, in particular from 60 to 150 MPa can be ensured.
- the reactive MgO of the magnesia flour is present quantitatively predominantly to the reactive finely divided silica. This should result in the formation of MgO-rich MSH phases after addition of water, which on exposure to high temperatures up to z.
- 1350X may form forsterite (2MgO.SiO 2 ), which increases the proportion of forsterite.
- prevailing mass ratios MgO to Si0 2 to 500: 1 are expedient.
- the ratio is between 1.2: 1 and 100: 1, preferably between 1, 34: 1 and 50: 1, most preferably between 1, 34: 1 and 35: 1.
- Refractory products according to the invention are produced from dry stratoms according to the invention after addition of water, a mixture with amounts of water, based on the mass of the dry offset, being 1 to 10% by weight, preferably 2.5 to 6.0% by weight.
- Hydrous so-called fresh masses z. B. for monolithic linings z. B. between 1 and 5, in particular between 1, 5 and 3 wt .-% pressed by conventional pressing method to shaped stone blanks.
- the shaped stones are allowed to harden and dry in the temperature range between 15 and 200, preferably between 50 and 200, in particular between 100 and 150 ° C., MSH phases being formed. After curing, the stones have relatively high strengths and can be handled so that a refractory lining can be built from them. According to the stones have cold compressive strengths z. B. between 40 and 100, in particular between 60 and 80 MPa, on.
- the molded and optionally tempered and optionally hardened or solidified by formation of MSH phases and dried ceramic stones to burn so that z. B. from MSH phases sintered products, for. B. arise from forsterite and sintered bridges from z. B. forsterite between the olives grains or olivine and / or MgO flour particles and / or possibly Si0 2 particles.
- the ceramic firing is preferably carried out in the temperature range from 400 to 1400, in particular from 600 to 1200 ° C and for a period of 1 to 24, in particular from 4 to 12 hours, wherein it is advantageous to burn in a reducing atmosphere.
- displacement agents known per se or to add them to the water-containing mixture in order to increase the plasticity of the mixture.
- Such flow agents are known in the art. You will be i.d.R. in amounts of 0.01 to 2, in particular from 0.1 to 1, 5 wt .-% added.
- a product according to the invention is advantageously prepared by coarse-grained magnesia, magnesia flour and reducing reactant, e.g. Carbon and / or graphite and / or anthracite and / or coke, and optionally silica and / or SiC and / or antioxidants and / or dry, in particular powdered synthetic resin binder and / or flow agent, and water and / or a liquid binder for refractory products with suitable mixers, a homogeneous mixture with predetermined plastic or flowable processability is produced.
- This viscous or flowable mass of the batch can be used on site for lining melt converters. From the mixture - as already described - but also monolithic shaped prefabricated parts or pressed stones can be produced; The latter can be unburned or ceramic fired to the lining of z. B. melt converters are used.
- the invention thus also relates to a dry offset exclusively from or z. B. mainly, d. H. z. B. over 80 wt .-%, preferably over 90 wt .-%, in particular more than 95 wt .-% of Magnesiarohstoffgranulat, MgO flour, finely divided carbon, in particular graphite, optionally a finely divided, dry silica, in particular in the form of microsilica, and / or optionally a dry, z. B. powdery, z. B. carbonaceous, binder z.
- B at least one other refractory coarse-grained material granules and / or refractory finely divided material, eg. B.
- Magnesiachromit, magnesium spinels, spinels, chromium oxide, zirconium oxide, silicon nitride, zirconium and / or at least one refractory, finely divided or flour-shaped additive such Magnesiachromit, magnesium spinels, spinels, chromium oxide, zirconium oxide, silicon nitride, zircon strig.
- a constructive may conveniently at least one itself known additive for refractory offsets, such as liquefier and / or Abbinderegulator be present.
- aqueous and / or binder-containing batch offset pressed or unpressed moldings are prepared and the moldings except for residual moisture preferably between 0.1 and 2 wt .-% z. B. brought by drying and / or tempering or moldings are additionally ceramic in accordance with another embodiment of the invention a ceramic kiln fired at temperatures between preferably 400 and 1400, in particular between 600 and 1200 ° C, preferably in a reducing atmosphere for a period of time preferably between 1 and 24, in particular between 4 and 12 hours.
- the firing conditions are inventively chosen so that the ingredients Magnesiarohstoff, MgO flour and reducing reactant, z.
- Linings of non-ferrous metal melt converters which are superior to the previous linings in terms of infiltration and corrosion resistance to non-ferrous metal melts and liquid slags of non-ferrous metal smelting can be created with the unfired and fired shaped bodies according to the invention.
- the unbaked pressed dried shaped bodies have z. For example, you can set the following properties:
- Cold pressure resistance 40 to 100, in particular 60 to 85 MPa.
- the fired shaped bodies according to the invention have z.
- the finished parts according to the invention which are molded parts, in particular molded and pressed stones, have z. For example, you can set the following properties:
- Cold pressure resistance 30 to 180, in particular 50 to 150 MPa.
- the products according to the invention are particularly suitable for use in PS converters for copper production, they are also advantageous over the conventional refractory products in other applications in which fayalitic slags and low-viscosity non-ferrous metal oxides occur, as is the case in virtually the entire non-ferrous metal industry , usable with the described advantages.
- the inventive concept is based on the fact that based on Magnesiagrobkorn as a supporting grain and a relatively high proportion of MgO fine grain or flour grain balance in the stone between the reactants from the stone and the slag only at Schmelz processes about 1000 ° C, z. B. between 1200 and 1350 ° C sets. At these temperatures graphite is still effective in spite of oxidizing melting process conditions with respect to anti-wetting effect against the already described molten media. MgO reacts with Si0 2 to further forsterite, reducing the pore volume of the microstructure.
- MgO is selected in the stoichiometric excess to be Si0 2 available for a reaction in order to avoid the formation of enstatite which is not refractory.
- This reaction in situ during the melting process largely seals the stone directly on the firing side and hampers the penetration through the very thin liquid molten metal, eg. B. molten copper.
- the MgO In contact with the ubiquitous fayalite slag melt (melting temperature 1210 ° C), the MgO also reacts with the forsterite (melting temperature 1890 ° C) to olivine mixed crystals.
- the liquidus temperature of the mixed-crystal melt thereby increases, ie the reaction product slag-product structure freezes, ie leads to a stiffening of the reaction product melt and the corrosion. rosion reaction or infiltration is stopped accordingly or at least greatly reduced.
- At least Magnesiarohstoff, MgO and optionally finely divided silica and reducing reactant, eg. B. graphite-containing molded body z. B. have a water content between 1 and 5, in particular between 1, 5 and 3 wt .-%, harden, possibly forming MSH phases, which cause the hardening.
- the hardening time is temperature-dependent.
- the pressed moldings are expediently hardened for 6 to 120, in particular 24 to 96 hours, and dried in the temperature range between 50 and 200, in particular between 100 and 150 ° C, to residual moisture contents between 0.1 and 4.5, in particular between 0.1 and 2.5 wt .-% water content in a suitable drying unit.
- the inventively produced non-pressed, poured into molds and possibly vibrated fresh masses for monolithic prefabricated components from the above-mentioned components have water contents between 4 and 10, in particular between 4 and 6 wt .-%. They are introduced into molds and possibly vibrated. You let them z. In the air, for example, harden between 15 and 35 ° C and dry in the temperature range given above for the pressed moldings, with the exception of residual moisture as in the case of the pressed moldings. This gives cold compressive strengths of between 30 and 180, in particular between 50 and 150 MPa.
- At least one known per se water-containing binder for refractory products from the following group lignosulfonate, magnesium sulfate, ethyl silicate and molasses or other sugars used in an amount calculated on the dry matter of an offset of z. B. 2 to 5 wt .-% for pressed products and z. B. 4 to 10 wt .-% for prefabricated components and castables.
- the water content of these binders contributes to the MSH phase formation described above.
- a per se known binder for refractory products from the group pitch and / or tar and in particular the known synthetic resins such as phenol-formaldehyde resins are used in amounts of z. B. 2 to 5 wt .-% calculated on the dry matter.
- the products according to the invention are particularly suitable for use in PS converters for copper production, but are also with equal advantages compared to the usual refractory products in other applications in which fayalitic slags and low-viscosity non-ferrous metal melts occur, as in the non-ferrous metal melting processes is usable with the described advantages.
- Stones produced from the stakes do not necessarily have to be fired, but it is generally sufficient that they are dried, possibly and / or tempered, so that they can be handled and used for lining masonry.
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Abstract
Description
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PL15805133.4T PL3237356T3 (pl) | 2014-12-22 | 2015-11-30 | Zastosowanie wyrobów ogniotrwałych |
JP2017533558A JP6694887B2 (ja) | 2014-12-22 | 2015-11-30 | 耐火物およびその使用 |
CN201580070089.1A CN107108368B (zh) | 2014-12-22 | 2015-11-30 | 耐火制品及其应用 |
AU2015371612A AU2015371612B2 (en) | 2014-12-22 | 2015-11-30 | Refractories and use thereof |
MX2017008169A MX2017008169A (es) | 2014-12-22 | 2015-11-30 | Productos refractarios y su uso. |
RS20230349A RS64186B1 (sr) | 2014-12-22 | 2015-11-30 | Upotreba vatrostalnih proizvoda |
US15/538,429 US10227260B2 (en) | 2014-12-22 | 2015-11-30 | Refractories and use thereof |
EP15805133.4A EP3237356B1 (de) | 2014-12-22 | 2015-11-30 | Verwendung feuerfester erzeugnisse |
BR112017013141-2A BR112017013141B1 (pt) | 2014-12-22 | 2015-11-30 | Uso de um produto na forma de um tijolo moldado refratário para a construção de uma alvenaria refratária ao lado do fogo de um forno industrial de fundição de metais não ferrosos, e uso de um produto refratário como um revestimento monolítico refratário ao lado do fogo |
ES15805133T ES2942486T3 (es) | 2014-12-22 | 2015-11-30 | Utilización de productos refractarios |
CA2971765A CA2971765C (en) | 2014-12-22 | 2015-11-30 | Refractory products and their use |
RU2017126131A RU2712870C2 (ru) | 2014-12-22 | 2015-11-30 | Огнеупоры и их применение |
FIEP15805133.4T FI3237356T5 (fi) | 2014-12-22 | 2015-11-30 | Tulenkestävien tuotteiden käyttö |
ZA2017/04105A ZA201704105B (en) | 2014-12-22 | 2017-06-15 | Refractories and use thereof |
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DE202013011886U1 (de) * | 2013-06-28 | 2014-09-03 | Refratechnik Holding Gmbh | Feuerfestes Erzeugnis |
CN111099902B (zh) * | 2019-12-23 | 2022-03-15 | 北京联合荣大工程材料股份有限公司 | 一种转炉遥控湿式自流喷注料 |
CN111187088B (zh) * | 2020-02-14 | 2022-06-07 | 海城市中昊镁业有限公司 | 一种中档镁砂电熔镁砂复配制备高热震镁砂原料的方法 |
EP4139406A1 (de) * | 2020-04-22 | 2023-03-01 | Danieli & C. Officine Meccaniche S.p.A. | Beschichtungszusammensetzung für metallische produkte und entsprechendes verfahren |
CN114477800B (zh) * | 2022-03-03 | 2022-11-11 | 苏州华光信息科技有限公司 | 一步法生产大结晶电熔镁砂联产电熔镁砂、轻烧氧化镁的制备方法 |
CN115626838B (zh) * | 2022-12-20 | 2023-04-07 | 河北炫坤耐火材料科技发展有限公司 | 一种高抗热震耐侵蚀零膨胀再生硅砖及其制备工艺 |
JP7368648B1 (ja) | 2023-03-13 | 2023-10-24 | 黒崎播磨株式会社 | 不焼成塩基性れんがの製造方法 |
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2014
- 2014-12-22 DE DE102014019347.0A patent/DE102014019347A1/de active Pending
-
2015
- 2015-11-30 FI FIEP15805133.4T patent/FI3237356T5/fi active
- 2015-11-30 WO PCT/EP2015/078079 patent/WO2016102149A1/de active Application Filing
- 2015-11-30 AU AU2015371612A patent/AU2015371612B2/en active Active
- 2015-11-30 PL PL15805133.4T patent/PL3237356T3/pl unknown
- 2015-11-30 US US15/538,429 patent/US10227260B2/en active Active
- 2015-11-30 JP JP2017533558A patent/JP6694887B2/ja active Active
- 2015-11-30 CN CN201580070089.1A patent/CN107108368B/zh active Active
- 2015-11-30 ES ES15805133T patent/ES2942486T3/es active Active
- 2015-11-30 EP EP15805133.4A patent/EP3237356B1/de active Active
- 2015-11-30 RS RS20230349A patent/RS64186B1/sr unknown
- 2015-11-30 CA CA2971765A patent/CA2971765C/en active Active
- 2015-11-30 MX MX2017008169A patent/MX2017008169A/es unknown
- 2015-11-30 RU RU2017126131A patent/RU2712870C2/ru active
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2017
- 2017-06-15 ZA ZA2017/04105A patent/ZA201704105B/en unknown
- 2017-06-19 CL CL2017001597A patent/CL2017001597A1/es unknown
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Also Published As
Publication number | Publication date |
---|---|
RS64186B1 (sr) | 2023-06-30 |
ES2942486T3 (es) | 2023-06-01 |
MX2017008169A (es) | 2017-09-18 |
JP6694887B2 (ja) | 2020-05-20 |
EP3237356A1 (de) | 2017-11-01 |
CA2971765A1 (en) | 2016-06-30 |
AU2015371612B2 (en) | 2018-06-14 |
BR112017013141A2 (pt) | 2018-01-02 |
CA2971765C (en) | 2019-12-31 |
FI3237356T5 (fi) | 2023-06-08 |
CL2017001597A1 (es) | 2018-04-02 |
CN107108368B (zh) | 2021-06-22 |
RU2712870C2 (ru) | 2020-01-31 |
FI3237356T3 (en) | 2023-04-24 |
US10227260B2 (en) | 2019-03-12 |
US20180016191A1 (en) | 2018-01-18 |
RU2017126131A3 (de) | 2019-01-24 |
RU2017126131A (ru) | 2019-01-24 |
EP3237356B1 (de) | 2023-03-01 |
PL3237356T3 (pl) | 2023-07-31 |
DE102014019347A1 (de) | 2016-06-23 |
JP2018505835A (ja) | 2018-03-01 |
ZA201704105B (en) | 2018-08-29 |
AU2015371612A1 (en) | 2017-07-27 |
CN107108368A (zh) | 2017-08-29 |
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