RU2437862C1 - Fireproof concrete mix (versions) - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: fireproof concrete mix contains the following components, wt %. a fireproof filler based on a chromite calcium hexaaluminate produced by burning highly aluminous slag of metal chrome production at 1500-1750°C with its subsequent grinding to the specified grain size - 0-6 mm 65.0-70.0, finely dispersed matrix composition of fraction of less than 0.063 mm, containing corundum, baked and reactive aluminas at the ratio of 1.5:1.5:1.0, 20.0-25.0, highly aluminous cement 5.0-10.0 and deflocculant on the basis of polycarboxylate ethers 0.1-0.2 (over 100%). In another version a fireproof concrete mix contains the following components, wt %: the specified fireproof filler 55-57, a finely dispersed matrix composition of fraction of less than 0.063 mm, containing magnesium alumina spinel, baked and reactive aluminas at the ratio of 1.5:1.5:1.0, 20-25, highly aluminous cement 5.0-10.0 and deflocculant on the basis of polycarboxylate ethers 0.1-0.2 (above 100%), and magnesium alumina spinel of fraction of 0-0.5 mm 10.0-13.0. In the third version a fireproof concrete mix contains the following components, wt %: the specified fireproof filler 50.0-57.0, a finely dispersed matrix composition of fraction of less than 0.063 mm, containing corundum, baked and reactive aluminas at the ratio of 1.5:1.5:1.0, 20-25, highly aluminous cement 5.0-10.0, deflocculant on the basis of polycarboxylate ethers 0.1-0.2 (above 100%), silicon carbide of fraction of 0-2 mm 13.0-20.0.

EFFECT: higher maximum temperature of concrete application, provision of its permanent volume, reduced concrete softening, higher temperature of its deformation under load.

3 cl, 2 tbl

Description

The group of inventions relates to the refractory industry and can be used for the manufacture of refractory linings of thermal units used in various industries.

Known refractory concrete mixture, including, wt.%: Synthesized calcium hexaaluminate - bonite as a granular and finely ground aggregate - 70.0, finely dispersed matrix composition - 25.0, including, including bonite - 12.0 and reactive alumina - 13.0, high alumina cement - 5.0 and deflocculant in the form of a mixture of dispersed alumina grades ADS-3 and ADW-1 - 1.0. For the manufacture of refractory concrete from such a mixture, 6.2 wt.% Water is required [1].

Refractory concrete from a known mixture has high physical and ceramic properties in a wide temperature range, in particular, is characterized by a constant volume up to the maximum temperature of its application.

The synthesized hexaaluminate - bonite, used as the basis of the known mixture, has a number of unique properties, such as high refractoriness, low solubility in iron-containing slag, high stability in a reducing atmosphere (for example, in CO), high chemical stability in an alkaline environment, low wettability by melts both ferrous and non-ferrous metals, low thermal conductivity. Due to the combination of the listed properties, bonite-based refractory concrete is promising for use in the aluminum, cement, petrochemical industries, as well as in ferrous metallurgy.

However, at present, the domestic industry does not produce synthesized calcium hexaaluminate, and the foreign aggregate - bonite - offered on the market has a high price that exceeds the cost of domestic high-alumina aggregates and corundum. Therefore, despite the promising potential of the well-known refractory concrete mixture, it has not been used in domestic linings of thermal units.

Known refractory concrete mixture, including, wt.%: Refractory aggregate based on chromium calcium hexaaluminate, obtained by processing (crushing) of high-alumina slag aluminothermic production of metallic chromium-85 and high-alumina cement - 15 [2].

The known mixture contains cheap available slag aggregate of the following mineral composition, wt.%: Chromium calcium hexaaluminate (chromium calcium hexaaluminate contains inclusions of chromium alkaline aluminate, (Na, K) ₂ O · 12 (Al, Cr) ₂ O ₃ in a small amount), CaO · 6 (Al, Cr) ₂ O ₃ 55-70, chromium corundum, (Al, Cr) ₂ O ₃ - 15-33, spinel, Mg (Al, Cr) ₂ O ₄ - 2-4, low-basic calcium aluminates 5-9, including calcium dialuminate, CaO · 2AlO ₃ , 3-5, and mayenite, 12СаО · 7Al ₂ O ₃ , 2-4, metallic chromium, Cr, 1-2 [3].

As can be seen from the given mineral composition, the basis of the refractory aggregate of the known mixture is calcium chromium hexaaluminate, in other words, calcium hexaaluminate with an isomorphic admixture of trivalent chromium oxide, called in [3] chromium bonite, which is similar in properties to the synthesized calcium hexaaluminate.

A disadvantage of the known refractory concrete mixture is that it does not provide lining based on it for stable operation in the temperature range above 800 ° C. At a temperature of 800 ° C, as a result of dehydration of high-alumina cement, concrete softening occurs, while the loss of strength is 50%

from the original value. When the temperature rises to 1400 ° С and higher, the process of transition of low-basic calcium aluminates - calcium dialuminate and mayenite, which are present in the slag aggregate, to chromium calcium hexaaluminate begins. The process is accompanied by an increase in the volume of concrete due to loosening of the aggregate, while the strength indicators of concrete are insufficient for the successful operation of the linings, and the deformation temperature under load is 1400 ° C.

Due to the lack of high temperature stability, the well-known refractory concrete mixture has not been widely used at temperatures above 1400 ° C, despite the high application temperatures indicated in [2].

Closest to the proposed group of inventions is a refractory concrete mixture, including, wt.%: Refractory aggregate based on chromium calcium hexaaluminate, obtained by processing (crushing) of high alumina slag of aluminothermic metal chromium production - 70.0, finely ground corundum - 7.5 and sintered alumina - 7.5, reactive alumina - 5.0, forming a finely dispersed matrix composition of a fraction of less than 0.063 mm with a ratio of the above components, respectively, 1.5: 1.5: 1.0 in total e - 20.0, high-alumina cement - 10.0, deflocculant based polycarboxylate - 0.15 (over 100%) [4].

The decrease in the content of high-alumina cement in the mixture and the introduction of a finely dispersed matrix composition in combination with a deflocculant prevented concrete softening at 800 ° C. However, due to the processes occurring in the aggregate at 1400 ° С and higher, associated with the crystallization of chromium calcium hexaaluminate, the concrete structure loosens, as evidenced by a decrease in its volume constancy (an increase in volume in the temperature range of 1400-1650 ° С exceeds 2%), concrete softening and low deformation temperature under load - 1400 ° С. All of the above factors indicate that the maximum temperature of the use of concrete from a known mixture does not exceed 1400 ° C.

The objective of the group of inventions is the creation of refractory concrete mixtures based on cheap slag aggregate, ensuring the stable operation of concrete linings at a higher operating temperature.

The technical result that can be achieved using the group of inventions is to increase the maximum temperature of application to 1650 ° C by ensuring the volume stability of concrete in the temperature range of 1400-1650 ° C, reducing softening in this temperature range and increasing the temperature of deformation under load.

The specified technical result is achieved by the fact that the refractory concrete mixture, including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high alumina slag of aluminothermic metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing corundum, sintered and reactive alumina : 1.5: 1.0, high alumina cement and a polycarboxylate ester deflocculant, according to the first embodiment of the group of inventions INH refractory filler based on calcium chromite hexaaluminate obtained by calcination of said slag at a temperature of 1500-1750 ° C, followed by grinding to a predetermined grain composition, with the following ratio of the mixture components, wt.%:

specified placeholder 65.0-70.0 specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2

(over 100%).

The specified technical result is also achieved by the fact that the refractory concrete mixture, including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high-alumina slag of aluminum-thermal metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing an oxide component including aluminum oxide, sintered alumina in a ratio of 1.5: 1.5: 1.0, high alumina cement and a deflocculant based on polycarboxylate esters, according It is clear to the second variant of the group of inventions that it contains a refractory aggregate based on chromium calcium hexaaluminate obtained by calcining the specified slag at a temperature of 1500-1750 ° C, followed by grinding it to a predetermined grain composition, additionally contains 0.5-0 mm aluminum-magnesian spinel, and a finely dispersed matrix the composition, as the oxide component comprising aluminum oxide, contains alumina-magnesian spinel, fractions of less than 0.063 mm, in the following ratio of components of the mixture, wt.%:

specified placeholder 55.0-57.0 aluminum-magnesia spinel fractions of 0.5-0 mm 10.0-13.0 specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2

(over 100%).

The specified technical result is also achieved by the fact that the refractory concrete mixture, including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high-alumina slag of aluminum-thermal metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing corundum, sintered and reactive alumina 5: 1.5: 1.0, high alumina cement and a polycarboxylate ester deflocculant according to a third embodiment of the group The second contains a refractory aggregate based on chromium calcium hexaaluminate obtained by calcining the specified slag at a temperature of 1500-1750 ° C and then grinding it to a predetermined grain composition and additionally contains silicon carbide fractions of 2-0 mm, in the following ratio of mixture components, wt.% :

specified placeholder 50.0-57.0 silicon carbide fraction 2-0 mm 13.0-20.0 specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2

(over 100%).

The use of refractory aggregates based on chromium calcium hexaaluminate obtained in the composition of the mixtures obtained by processing high alumina slag of aluminothermic metal chromium production at a temperature of 1500-1750 ° C with its subsequent grinding to a predetermined grain composition allows to increase the temperature of concrete application to 1650 ° C.

The higher temperature of the use of concrete from the proposed mixes is due to the stability of the concrete structure in the temperature range 1400-1650 ° C, which is associated with the mineral composition of the aggregate formed during the firing of the specified slag at 1500-1750 ° C.

The refractory aggregate has the following mineral composition, wt.%: Chromium calcium hexaaluminate, CaO · 6 (Al, Cr) ₂ O ₃ , 86.0-94.0, chromium corundum, (Al, Cr) ₂ O ₃ - 1.5 -10.0, spinel, Mg (Al, Cr) ₂ O ₄ - 2.0-4.0, calcium dialuminate, CaO · 2Al ₂ O ₃ , 0.1-0.5. During the firing process, the low-basic calcium aluminates present in the unfired slag almost completely recrystallized into a volume-constant chromium calcium hexaaluminate, the content of which in the aggregate increased to 86.0-94.0 wt.%, Impurities of metallic chromium during firing were oxidized to Cr ₂ O ₃ , which in the form of an isomorphic impurity became part of the mineral phases of the aggregate.

Thus, the aggregate reacted, loosened, and sintered during firing includes volume-constant mineral phases of chromium calcium hexaaluminate, corundum, and spinel, thereby reducing the volume growth of the aggregate upon repeated heating, thereby increasing the volume constancy of concrete in the temperature range 1400-1650 ° C, a decrease in softening in this temperature range and an increase in the deformation temperature under load.

At the same time, low-basic calcium aluminates of high-alumina cement at a temperature of 1400 ° C and above react with aluminum oxide of the matrix composition with the formation of calcium hexaaluminate. Due to the fact that the process proceeds in the concrete matrix, its accompanying increase in volume is carried out by reducing the pore volume and densification of the concrete structure, while there is no significant change in the volume of concrete itself and loosening of its structure.

The total amount of injected refractory aggregate of a certain grain composition in all three versions of the mixtures is associated with the creation of the most dense concrete frame.

In the second embodiment, a part of the aggregate based on chromium calcium hexaaluminate is replaced by fine-grained aluminum-magnesium spinel, and corundum in the finely divided matrix composition is replaced by fine-dispersed aluminum-magnesium spinel. The introduction of spinel in the mixture, both in the aggregate and in its binder, creates conditions for increasing slag resistance and heat resistance of concrete due to the difference in the CTE of the spinel and chromium calcium hexaaluminate, while the stability of the concrete at temperatures up to 1650 ° C is preserved, since alumino-magnesian spinel does not react with the components of the mixture associated with softening or changing the volume of concrete, and does not impair its deformation properties.

The amount of spinel introduced into the mixture according to the second variant of the spinel provides the best results in volume stability, strength, slag resistance and heat resistance.

The third option involves replacing a part of the aggregate based on chromium calcium hexaaluminate with silicon carbide fraction 2-0 mm. The introduction of silicon carbide does not affect the volume constancy and strength of concrete. At the same time, refractory concrete with the addition of SiC is not wetted by metal and slag melts and acquires a more heat-resistant structure due to the difference in the CTE of silicon carbide and chromium calcium hexaaluminate.

The content of silicon carbide in the inventive mixture of less than 13 wt.% Does not give positive results in increasing the metal and slag resistance and heat resistance of concrete. An increase in the specified component of more than 20 wt.% Reduces the strength of concrete.

Thus, all three variants of the mixture ensure the stability of concrete to a temperature of 1650 ° C, are characterized by the constancy of volume, are not softened, and have a high deformation temperature under load.

The first variant of the mixture is expediently used for the manufacture of linings for thermal units operating in reducing and alkaline environments.

The second version of the mixture gives positive results in the lining of steel casting ladles, exposed to molten metal and slag.

The third version of the mixture is intended for linings of thermal units with a sharp temperature fluctuation, working in a reducing environment.

Execution example

The following raw materials were used for the manufacture of refractory concrete mixtures.

1. High alumina slag of aluminothermic metal chromium production, manufactured by Klyuchevsky Ferroalloy Plant OJSC according to TU 14-141-41-99 of PG-75 grade lump (50-150 mm).

2. High alumina cement brand Secar-71 company Kerneos.

3. White aluminum oxide produced by Boksitogorsk Alumina OJSC according to TU 3988-012-00658716-2002.

4. Sintered alumina produced by OAO Boksitogorsk alumina grade GN.

5. Reactive alumina grade STS-40 company Almatis (Germany).

6. Aluminum magnesia spinel of the AMSH-T brand produced by Pervouralsky Dinas Plant OJSC according to TU 1527-031-00187085-2004.

7. Silicon carbide according to GOST 3647-80.

8. Deflocculant based on polycarboxylate esters FS-40 from BASF (Germany).

9. Drinking water.

The slag was calcined at 1650 ° C, after which it was crushed to obtain a fraction of 6-0 mm.

The components included in the matrix composition (except reactive alumina) were subjected to vibratory grinding until a fraction of less than 0,063 mm was obtained.

The initial components of the mixtures, the compositions of which are shown in table 1, were mixed dry for 2 minutes, after which they were shut with water in an amount of 5.00% (in excess of 100%) and mixed again.

For the manufacture of products, the resulting masses were placed in molds, subjected to vibration compaction, curing and heat treatment according to a certain regime at a temperature of 350 ° C to remove physical and chemically bound moisture from the microporous concrete structure.

The properties of refractory concrete, shown in table 2, were determined on the samples in accordance with existing GOSTs.

As can be seen from table 2, the proposed compositions of refractory concrete mixtures (examples 1-3) maintain the constancy of the volume of concrete based on them up to a temperature of 1650 ° C, residual dimensional changes are within acceptable limits, that is, do not exceed 2%, while concrete of the known mixture (example 4) already at 1500 ° C has a growth of 2.8%, and at 1650 ° C the increase in volume reaches 3.4%, which indicates the loosening of the concrete structure. The latter is also confirmed by a decrease in the strength of concrete from a known mixture in the temperature range of 1200-1500 ° C by almost 2 times, while the proposed compositions provide a more stable concrete strength to 1650 ° C. The deformation temperature under load of concrete from the proposed mixtures is 250 ° C higher than that of concrete from a mixture of known composition.

Thus, refractory concretes from the proposed mixtures using calcined slag aggregate based on chromium calcium hexaaluminate can ensure stable operation of linings up to a temperature of 1650 ° C, which is the maximum temperature for their use.

Comparison of concrete indicators from the proposed mixtures with concrete indicators from a mixture of a similar composition with corundum aggregate (Example 5) allows us to conclude that concrete from mixtures with cheap slag aggregate can successfully replace, in some cases, concrete from mixtures with more expensive corundum aggregate.

Table 1 Compositions of refractory concrete mixtures Mixture Components The content of components, wt.% Execution Examples ² one 2 3 four 5 Aggregate based on chromium calcium hexaaluminate, obtained from unfired slag, fraction 6-0 mm - - - 70.0 A filler based on chromium calcium hexaaluminate, obtained from slag calcined at 1650 ° C, fractions of 6-0 mm 70.0 57.0 55.0 - - Aggregate corundum fraction 6-0 mm - - - - 70.0 Aluminum magnesia spinel fractions of 0.5-0 mm - 13.0 - - - Silicon carbide fraction 2-0 mm - 15.0 - - Fine matrix composition of a fraction of less than 0.063 mm, 20,0 20,0 20,0 20,0 20,0 including: corundum 7.5 - 7.5 7.5 7.5 magnesia spinel - 7.5 - - - sintered alumina 7.5 7.5 7.5 7.5 7.5 reactive alumina 5,0 5,0 5,0 5,0 5,0 High Alumina Cement 10.0 10.0 10.0 10.0 10.0 Deflocculant based on dolicarboxylate esters FS-40 (over 100%) 0.15 0.15 0.15 0.15 0.15 Water (over 100%) 5,0 5.0 5,0 5,0 5,0 ² Examples 1, 2 and 3 correspond to variants of the mixture 1, 2 and 3; 4 is a known composition, example 5 is a mixture with corundum aggregate, shown for comparison.

table 2 Properties of refractory concrete mixtures The name of indicators Property metrics Execution examples one 2 3 four 5 one 2 3 four 5 6 7 one. The compressive strength, N / mm ² after 3 days of hardening 35 22 51.3 14.5 twenty after heat treatment at ° C 150 - - - - 60 350 130 98.5 58.7 112 - 800 - - 68.8 - - 1000 103 124 88.4 160 (1150 ° C) 60 1200 121 124 - 131 - 1500 109 161 66.8 (1400 ° C) 68 - 1650 111 132 - - one hundred 2. Residual dimensional changes,%, after heat treatment, ° C 150 -0.2 0,03 -0.06 - - 350 -0.08 0.05 -0.03 -0.06 -0.8 1000 -0.03 -0.05 0.02 0,07 -0.02 1200 -0.16 0,045 - 0.31 - 1400 0.84 0.75 0.86 1.51 - 1500 1,59 0.45 - 2.80 - 1650 1,64 0.05 not def. 3.40 -0.8 3. The apparent density, g / cm ³ after heat treatment at temperature, ° C 150 2.86 3.13 - - - 350 2.82 3.16 - 2.86 3.0 800 - - 2.86 - - 1000 2.86 2.77 - 2.84 2.90 1200 2.84 2.74 - 2.90 - 1400 2.78 - 2.80 2.82 - 1500 2.75 2.77 - 2.77 - 1650 3.03 2.79 - 2.82 3.10 four. Deformation temperature under load t _{0.6, P,} ° С 1650 1650 1650 ³ 1400 1650 5. Maximum temperature of application, ° С 1650 1650 1650 ³ 1400 1650 ³ In a reducing environment

Information sources

1. Buchel G., Bur A., Girish D., Recher R.P. Bonit is a new raw material that offers new opportunities in the production of refractories // New Refractories, 2006, No. 7, p.66-73, table 2, 3.

2. Abyzov A.N., Perepelitsyn V.A., Rytvin V.M. et al. Heat-resistant concrete based on aluminothermic slags of Kluchevsky Ferroalloy Plant OJSC // New Refractories, 2007, No. 12, p.15-18.

3. Perepelitsyn V. A., Rytvin V. M., Ignatenko V. G. The technogenic treasury of the Urals // Mineral raw materials of the Urals, 2007, No. 4 (12), pp. 24-26.

4. Technological regulations for the production of bonite concrete low-cement products TP69-2009 // Collection of technological instructions and regulations of the CJSC Experimental Refractory Plant. Verkhnyaya Pyshma, 2009.

Claims (3)

1. Refractory concrete mixture (option 1), including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high-alumina slag of aluminothermic metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing corundum, sintered and reactive alumina in the ratio: 1.5: 1.0, high alumina cement and a polycarboxylate ester deflocculant, characterized in that it contains a refractory aggregate based on chromium hexaalumin calcium atlas obtained by calcining the specified slag at a temperature of 1500-1750 ° C, followed by grinding it to a predetermined grain composition - 0-6 mm, in the following ratio of mixture components, wt.%:
specified placeholder 65.0-70.0 specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2 (over 100%). 2. Refractory concrete mixture (option 2), including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high-alumina slag of aluminothermic metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing an oxide component including aluminum oxide, sintered and reactive clay 1.5: 1.5: 1.0 ratio, high alumina cement and a polycarboxylate ester deflocculant, characterized in that it contains a refractory filling It is based on chromium calcium hexaaluminate, obtained by calcining the specified slag at a temperature of 1500-1750 ° C, followed by grinding it to a predetermined grain composition of 0-6 mm, and additionally contains 0-0.5 mm aluminum-magnesian spinel, a finely dispersed matrix composition in as the oxide component, including aluminum oxide, contains alumina-magnesian spinel fractions of less than 0.063 mm, in the following ratio of the components of the mixture, wt.%:
specified placeholder 55.0-57.0 aluminum-magnesian spinel fractions 0-0.5 mm 10.0-13.0 the specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2 (in excess of 100%). 3. Refractory concrete mixture (option 3), including a refractory aggregate based on chromium calcium hexaaluminate, obtained by processing high-alumina slag of aluminum-thermal metal chromium production, a finely dispersed matrix composition of a fraction of less than 0.063 mm, containing corundum, sintered and reactive alumina in the ratio: 1.5: 1.0, high alumina cement and a polycarboxylate ester deflocculant, characterized in that it contains a refractory aggregate based on chromium hexaalumin calcium acetate obtained by calcining the specified slag at a temperature of 1500-1750 ° C, followed by grinding it to a predetermined grain composition of 0-6 mm, and additionally contains silicon carbide fractions of 0-2 mm, in the following ratio of mixture components, wt.%:
specified placeholder 50.0-57.0 silicon carbide fraction 0-2 mm 13.0-20.0 specified fine matrix composition 20.0-25.0 high alumina cement 5.0-10.0 polycarboxylate ester deflocculant 0.1-0.2 (over 100%).