CN101367663A - Melt-out recombined composite aluminum oxide refractory materials - Google Patents

Melt-out recombined composite aluminum oxide refractory materials Download PDF

Info

Publication number
CN101367663A
CN101367663A CNA2008101688193A CN200810168819A CN101367663A CN 101367663 A CN101367663 A CN 101367663A CN A2008101688193 A CNA2008101688193 A CN A2008101688193A CN 200810168819 A CN200810168819 A CN 200810168819A CN 101367663 A CN101367663 A CN 101367663A
Authority
CN
China
Prior art keywords
hualv
βyang hualv
βyang
percent
alumina
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CNA2008101688193A
Other languages
Chinese (zh)
Other versions
CN101367663B (en
Inventor
王杰曾
刘锡俊
叶亚红
王俊涛
赵洪亮
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
RUITAI TECHNOLOGY Co Ltd
Original Assignee
RUITAI TECHNOLOGY Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by RUITAI TECHNOLOGY Co Ltd filed Critical RUITAI TECHNOLOGY Co Ltd
Priority to CN2008101688193A priority Critical patent/CN101367663B/en
Publication of CN101367663A publication Critical patent/CN101367663A/en
Application granted granted Critical
Publication of CN101367663B publication Critical patent/CN101367663B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Abstract

The invention relates to a melting recombined composite alumina fire proof material, which is characterized in that the formula of the fire proof material comprises: 48 to 56 percent of 5-1mm alpha beta alumina or beta alumina, 12 to 22 percent of 1-0.088mm alpha beta alumina or beta alumina, 16 to 25 percent of d90<0.088mm alpha beta alumina or beta alumina, 0 to 12 percent of d95<0.020mm beta alumina micro powder, 0 to 5 percent of alpha alumina micro powder, 2 to 7 percent of alumina hydrate, 0.5 to 5 percent of magnesium additive, 0.05 to 0.4 percent of plus super-plasticizer, 1 to 6 percent of plus polypropylene acid series latex and 1 to 6 percent of plus water. Goods made by the invention have good manufacturing performance and good high temperature proof performance, and are suitable to be used as fire proof materials of large-sized and special-shaped fire proof products, a regenerator lattice body, and the like of the upper structure of a glass kiln.

Description

Melt-out recombined composite aluminum oxide refractory materials
Technical field
The present invention is that a kind of fusion is again in conjunction with compound α β or βYang Hualv refractory materials, its manufacturing processed is: electric smelting α βYang Hualv or electric smelting βYang Hualv raw material pulverizing, screening, levigate after, but with αYang Hualv micro mist ALUMINA HYDRATE, magnesia auxiliary agent, polyacrylic acid emulsion, chemical admixture and water cooperates, prefabricated component is made in stirring, shaping, the demoulding, maintenance, drying process, burn till through high temperature again and make with Na Mg-β " Ss(Na 1.51Mg 0.69Al 10.37O 17) be in conjunction with phase, with alpha-beta alumina or βYang Hualv (Na 2O11Al 2O 3Or NaAl 11O 17) be the refractory materials of principal crystalline phase.This material has good shaping, the demoulding, sintering character, and has special outstanding high temperature resistance, is suitable as refractory materialss such as large-scale, the special shape refractory product of glass kiln superstructure and regenerator lattice and uses.
Background technology
Modern glass kiln need use a large amount of founding aluminium oxide refractory materials.Wherein, founding α-βYang Hualv refractory materials contains 45% Alpha-alumina and 55% beta-alumina approximately, and about 1% impurity mutually and 2% pore.Founding beta-alumina refractory materials mainly is made up of big crystal grain beta-alumina, and impurity can be ignored void content about 4% mutually.Founding α, beta-alumina or beta-alumina material do not contain glassy phase, do not have the infusibility crystalline phase again, can not produce detrimentally affect to glass quality, also have good resistibility in the erosion to soda-lime glass or alkali steam below 1350 ℃.Therefore, α, β-alumina material are widely used in the part of glass kiln cooling end contact glass metal.β-alumina material then is widely used in the superstructure that cooling end does not have the dust position.
At present, full-oxygen combustion is the developing direction of glass kiln.After adopting pure oxygen combustion technology, can improve quality, the minimizing fuel consumption of glass, avoid getting rid of obnoxious flavour NOx, save the spending of building regenerator and handling objectionable constituent in the gas.But during comburant oxygen, the concentration of NaOH greatly increases in the products of combustion, causes Na 2O is to containing SiO 2The strong corrosion of refractory materials.Therefore, oxy-fuel glass furnace needs to use α-βYang Hualv and βYang Hualv refractory materials more.
Now, make founding α-βYang Hualv or founding βYang Hualv syphon by casting method usually, its temperature of fusion height, the production qualification rate is low and be difficult to processed shaping.Especially, the production efficiency of oversize or special shape casting product is very low.Because heat radiation is irregular, can produce very big thermal stresses in the cooling, very easily make these material damage, thereby cause very expensive production cost.
Generally, be difficult to ordinary method and make sintering α-βYang Hualv or βYang Hualv material, particularly make large size or special odd-shaped goods.On the one hand, the difficult shaping of this class refractory materials, hard-to-sinter.On the other hand, though can utilize pure calcium aluminate cement, water glass, clay to make large size or special shape βYang Hualv goods for wedding agent.But the impurity that these materials are brought into meeting and βYang Hualv reaction generate eutectic, and this will make the high thermal resistance of goods and erosion-resisting characteristics all be subjected to grievous injury.
At present, vast glassworks man presses for the technology that refractory materials scientific and technical personnel development makes new advances, and produces founding aluminium oxide refractory material more, particularly is difficult to large-scale, the special shape fire resistive material product of making.
Summary of the invention
The objective of the invention is to invent a kind of melt-out recombined composite aluminum oxide refractory materials.The contriver has proposed a new technology: but normal temperature by polyacrylic acid and ALUMINA HYDRATE, contain the reaction of magnesium oxide material, generate polyacrylic acid aluminium (magnesium) polymer and produce combination.After the thermal treatment, above-mentioned polymer decomposes, and organic constituent burns and loses, and inorganic component becomes activated alumina, activated magnesia, again sintering in addition.Like this, just greatly reduce the difficulty of making large-scale, special shape fire resistive material product.Products made thereby of the present invention has good manufacturing property and outstanding high temperature resistance very.
Relevant chemical reaction is as follows:
At first, room temperature is carried out ρ Al 2O 3With the aquation of MgO, and Al (OH) 3, Mg (OH) 2With polyacrylic chemical reaction.By reaction, 1)-4) high volence metal ion Al, Mg replace the H on the emulsion carboxyl, and glue connects a plurality of polyacrylic acid molecules and forms the bigger polyacrylic acid aluminium (magnesium) of molecular weight.ρ aluminum oxide or magnesium oxide also may direct and polyacrylic acid reactions.This is the principle that produces physical strength after condensation of materials, sclerosis and the oven dry, sees following various:
ρAl 2O 3+3H 2O=2Al(OH) 3 1)
MgO+H 2O=Mg(OH) 2 2)
Al(OH) 3+3R-COOH=(R-COO) 3Al+1.5H 2O 3)
Mg(OH) 2+2R-COOH=(R-COO) 2Mg+H 2O 4)
Hot, the decomposition of polyacrylic acid aluminium (magnesium) before this, organic burning is lost, and is MgO and Al then 2O 3Reaction forms magnesium-aluminium spinel, and forms Na, Mg-β " ss (Na 1.51Mg 0.69Al 10.37O 17).Na, Mg-β " ss can be by Na-β " (NaAl 6O 10) molten admittedly MA and Na 2O forms; Na, Mg-β " ss also can be by βYang Hualv (NaAl 11O 17) form with MgO or MA reaction.The relevant formula as follows of reacting:
0.69MgO+0.755Na 2O11Al 2O 3=Na 1.51Mg 0.69Al 10.37O 17+3.12Al 2O 3 5.1)
MgO+AL 2O 3=MgOAL 2O 3 5.2.1)
0.69MgOAL 2O 3+0.755Na 2O11Al 2O 3=Na 1.51Mg 0.69Al 10.37O 17+3.81Al 2O 3 5.2.2)
β-Al 2O 3-α-Al 2O 3-Na, Mg-β " ss (Na 1.51Mg 0.69Al 10.37O 17) initial melting temperature of phase region is greater than 1680 ℃, belongs to the extremely fireproof system.So, material of the present invention through batching, companion and, shaping, maintenance, the demoulding, drying and burn till after can obtain the high thermal resistance of excellence.
Because of the purity extra-high-speed, the α βYang Hualv is corresponding with the βYang Hualv material to have very high sintering temperature.If temperature is low, material can not sintering.If the temperature height, Na 2The O volatile material can not sintering.Help burning if mix the silicon ash, the silicon ash will form eutectic material-nepheline with the βYang Hualv reaction.Help burning if admixture contains the material of CaO, these materials also will form eutectic material-C 3N 2A 5If admixture MgO does not form eutectic, but middle temperature burning back intensity is extremely low.When being heat-treated to 1000 ℃ of left and right sides, low temperature bond is decomposed mutually already, and pottery is not in conjunction with producing as yet, and the bonding force in the matrix is very weak.At this moment, MgO and Al 2O 3Solid state reaction takes place, form magnesium-aluminium spinel, producing expands will influence the medium temperature intensity of sample, even the qualification rate of product.
So the present invention creatively proposes and replace magnesia as being shaped and sintering aid with the activated carbon aluminate.On the one hand, the activated carbon aluminate can part aquation, form polyacrylic acid aluminium (magnesium) polymer of some amount, guarantee to condense, sclerosis and demolding performace.On the other hand, add pre-synthetic MgAl spinal and just can avoid forming the volumetric expansion that magnesium-aluminium spinel is followed, thereby temperature is burnt back intensity in significantly improving, and significantly reduce sintering temperature.Like this, with regard to the ingenious problem that has solved α βYang Hualv or βYang Hualv material hard-to-sinter.
In view of the above, prescription of the present invention is:
5-1mm α βYang Hualv or βYang Hualv 48-56%
1-0.088mm α βYang Hualv or βYang Hualv 12-22%
d 90<0.088mm α βYang Hualv or βYang Hualv 16-25%
d 95<0.020mm βYang Hualv micro mist 0-12%
αYang Hualv micro mist 0-5%
But ALUMINA HYDRATE 2-7%
Magnesia auxiliary agent 0.5-5%
Add high efficiency water reducing agent (poly carboxylic acid+sulfonated naphthalene yuban+sulfonated melamine polymkeric substance) 0.05-0.4%
Add polyacrylic emulsion 1-6%
Add water 1-6%
The feature of above-mentioned raw materials:
Described α βYang Hualv is that electric smelting α βYang Hualv material (as the waste product of founding α βYang Hualv) makes.
Described βYang Hualv is that electric smelting βYang Hualv material (as the waste product of founding βYang Hualv) makes.
Described particle diameter d 90Or d 95Be respectively and account for total amount 90% small-particle and account for total amount 10% oarse-grained boundary size in the powder, or account for total amount 95% small-particle and account for total amount 5% oarse-grained boundary size.
Described αYang Hualv micro mist is commercially available prod d 50=8-2 μ m.
But described ALUMINA HYDRATE is the commercially available prod, and its principal constituent is ρ-Al 2O 3The mixture of the steady alpha-alumina crystals of Jie.
Described magnesia auxiliary agent can be magnesia powder (<0.088mm content〉90% or magnesia micro mist (<0.020mm content〉95%), any mixture of activated carbon aluminate (<0.020mm content〉95%).Preferably main component is the activated carbon aluminate.This auxiliary agent plays and improves curing speed and improve the agglomerating effect." very low temperature prepares the technology of active synthetic refractory raw material " (Chinese invention patent CN 01118014.5) that this spinel can adopt the author to propose makes.
Described high efficiency water reducing agent is commercially available cement water reducing agent, comprises sulfonated naphthalene yuban high efficiency water reducing agent and sulfonated melamine polymer high efficiency water reducer, and any cooperation of polycarboxylic acid series high efficiency water reducing agent.
Described polyacrylic emulsion is commercially available building polyacrylic acid emulsion, comprises building polyacrylic acid emulsion, building vinylformic acid and acrylate copolymer emulsion and vinylformic acid-acrylate-styrene terpolymer non-ionic water-soluble emulsion.The solids content 40-60% of emulsion, typical particle diameter 0.1-0.3 μ m, pH value 6-9.
Melt-out recombined composite aluminum oxide brick main component: Al 2O 391-96%, Na 2O 3-7%, MgO 0.2-3.5%, SiO 20.1-0.5%.
Each raw material makes base substrate through mixing, shaping, maintenance by above proportioning weighing, drying again through 1430-1650 ℃ burn till, operation such as check makes large-scale or special odd-shaped fire resistive material product.
Embodiment
Embodiment 1
Adopt 5-1mm electric smelting α βYang Hualv 53%, 1-0.088mm electric smelting α βYang Hualv 17%, d 90<0.088mm electric smelting α βYang Hualv 17%, d 95<0.020mm electric smelting βYang Hualv micro mist 4%, d 95<0.020mm alumina powder 2%, activated carbon aluminate micro mist 3%, but ALUMINA HYDRATE 4%,, add polycarboxylate water-reducer 0.1%, polyacrylic acid emulsion 3%, water 3% back companion and, obtain the slurry of good fluidity.After the shaping, slurry condensed in 0.5 hour, solidified in 2 hours, can the demoulding after 12-16 hours.Through 110 ℃ * 24H drying, sample obtains the folding strength of 8MPa, the compressive strength of 35MPa; Obtain the folding strength of 12MPa again through thermal treatment in 1500 ℃ * 3 hours, the compressive strength of 71MPa is burnt till line and is changed to 0.6%, refractoriness under load T 0.61700 ℃.
Products made thereby has good manufacturing property and outstanding high temperature resistance very, and experiment has obtained success.
Embodiment 2
Adopt 5-1mm electric smelting βYang Hualv 50%, 1-0.088mm electric smelting βYang Hualv 20%, d 90<0.088mm electric smelting βYang Hualv 17%, d 95<0.020mm electric smelting βYang Hualv micro mist 4%, activated carbon aluminate micro mist 4%, but ALUMINA HYDRATE 5%,, add polycarboxylate water-reducer 0.1%, polyacrylic acid emulsion 3%, water 3% back companion and, obtain the slurry of good fluidity.After the shaping, slurry condensed in 2 hours, solidified in 8 hours, can the demoulding after 24 hours.Through 110 ℃ * 24H drying, sample obtains the folding strength of 10MPa, the compressive strength of 45MPa; Can obtain through thermal treatment in 1100 ℃ * 3 hours the compressive strength of 12MPa, the light sample of mixing magnesia improves nearly 200%; Obtain the folding strength of 16MPa again through thermal treatment in 1500 ℃ * 3 hours, the compressive strength of 80MPa is burnt till line and is changed to 0.5%, refractoriness under load T 0.61700 ℃.
Products made thereby of the present invention has good manufacturing property and outstanding high temperature resistance very, is suitable as refractory materialss such as large-scale, the special shape refractory product of glass kiln superstructure and regenerator lattice and uses.

Claims (2)

1. melt-out recombined composite aluminum oxide refractory materials, it is characterized in that: described refractory materials prescription is:
5-1mm α βYang Hualv or βYang Hualv 48-56%
1-0.088mm α βYang Hualv or βYang Hualv 12-22%
d 90<0.088mm α βYang Hualv or βYang Hualv 16-25%
d 95<0.020mm βYang Hualv micro mist 0-12%
αYang Hualv micro mist 0-5%
But ALUMINA HYDRATE 2-7%
Magnesia auxiliary agent 0.5-5%
Add high efficiency water reducing agent 0.05-0.4%
Add polyacrylic emulsion 1-6%
Add water 1-6%
Described α βYang Hualv is that electric smelting α βYang Hualv material (as the waste product of founding α βYang Hualv) makes;
Described βYang Hualv is that electric smelting βYang Hualv material (as the waste product of founding βYang Hualv) makes;
Described particle diameter d 90Or d 95Be respectively and account for total amount 90% small-particle and account for total amount 10% oarse-grained boundary size in the powder, or account for total amount 95% small-particle and account for total amount 5% oarse-grained boundary size;
Described αYang Hualv micro mist is commercially available prod d 50=8-2 μ m.
But described ALUMINA HYDRATE is the commercially available prod, and its principal constituent is ρ-Al 2O 3The mixture of the steady alpha-alumina crystals of Jie;
Described magnesia auxiliary agent can be magnesia powder (<0.088mm content〉90% or magnesia micro mist (<0.020mm content〉95%), any mixture of activated carbon aluminate (<0.020mm content〉95%), preferably main component is the activated carbon aluminate;
Described high efficiency water reducing agent is commercially available cement water reducing agent, comprises sulfonated naphthalene yuban high efficiency water reducing agent and sulfonated melamine polymer high efficiency water reducer, and any cooperation of polycarboxylic acid series high efficiency water reducing agent;
Described polyacrylic emulsion is commercially available building polyacrylic acid emulsion, comprise building polyacrylic acid emulsion, building vinylformic acid and acrylate copolymer emulsion and vinylformic acid-acrylate-styrene terpolymer non-ionic water-soluble emulsion, the solids content 40-60% of emulsion, typical particle diameter 0.1-0.3 μ m, pH value 6-9;
The main component of described melt-out recombined composite aluminum oxide brick is: Al 2O 391-96%, Na 2O 3-7%, MgO 0.2-3.5%, SiO 20.1-0.5%.
2. production technique of making the described refractory materials of claim 1, above-mentioned each raw material makes base substrate by proportioning weighing, mixing, shaping, maintenance, drying, burn till, operation such as check makes, it is characterized in that: firing temperature is: 1430-1650 ℃.
CN2008101688193A 2008-09-28 2008-09-28 Melt-out recombined composite aluminum oxide refractory materials Active CN101367663B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN2008101688193A CN101367663B (en) 2008-09-28 2008-09-28 Melt-out recombined composite aluminum oxide refractory materials

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN2008101688193A CN101367663B (en) 2008-09-28 2008-09-28 Melt-out recombined composite aluminum oxide refractory materials

Publications (2)

Publication Number Publication Date
CN101367663A true CN101367663A (en) 2009-02-18
CN101367663B CN101367663B (en) 2011-08-31

Family

ID=40411694

Family Applications (1)

Application Number Title Priority Date Filing Date
CN2008101688193A Active CN101367663B (en) 2008-09-28 2008-09-28 Melt-out recombined composite aluminum oxide refractory materials

Country Status (1)

Country Link
CN (1) CN101367663B (en)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101948300A (en) * 2010-08-26 2011-01-19 武汉科技大学 Corundum-spinel lightweight heat-insulating material and preparation method thereof
CN101708997B (en) * 2009-11-10 2012-05-23 武汉科技大学 Alumina light-weight brick and preparation method thereof
CN107162611A (en) * 2017-05-26 2017-09-15 长兴华悦耐火材料厂 The resource recycle method of carbon containing waste and old refractory brick
CN110062749A (en) * 2016-12-08 2019-07-26 西门子股份公司 Corrosion resistant ceramic material, powder, mud and component

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1067359C (en) * 1994-12-22 2001-06-20 沈阳耐火材料厂 Method for increasing finished product rate of fusion-cast alpha-beta aluminum oxide bricks
FR2767130B1 (en) * 1997-08-08 1999-10-22 Produits Refractaires REFRACTORY MATERIAL CONSISTING OF ALUMINUM BETA
CN100402470C (en) * 2006-09-07 2008-07-16 浙江大学 Thermal-knock resisting diamond spar-spinele refractory materials and its production

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101708997B (en) * 2009-11-10 2012-05-23 武汉科技大学 Alumina light-weight brick and preparation method thereof
CN101948300A (en) * 2010-08-26 2011-01-19 武汉科技大学 Corundum-spinel lightweight heat-insulating material and preparation method thereof
CN110062749A (en) * 2016-12-08 2019-07-26 西门子股份公司 Corrosion resistant ceramic material, powder, mud and component
CN107162611A (en) * 2017-05-26 2017-09-15 长兴华悦耐火材料厂 The resource recycle method of carbon containing waste and old refractory brick

Also Published As

Publication number Publication date
CN101367663B (en) 2011-08-31

Similar Documents

Publication Publication Date Title
CN101367666B (en) Large-scale, specially shaped mullite-corundum system sintered refractory material product and preparing technique thereof
CN100378029C (en) Ceramic material of porous spinel, and preparation method
US9840628B2 (en) Methods of use of calcium hexa aluminate refractory linings and/or chemical barriers in high alkali or alkaline environments
US5106797A (en) Refractory material produced from red mud
CN103601507B (en) A kind of complex sintered refractory material of low porosity magnesium aluminate spinel-zirconia corundum zirconia and production technology thereof
CN102219535A (en) Recombined magnesia-alumina spinel brick with properties of nodulation and blockage prevention and high corrosion resistance, and production technology thereof
CN101066878A (en) Alumina-silica refractory brick containing light porous aggegate and its making process
CN1704384A (en) Periclase-olivine light thermal-insulated fireproof materials and method for preparing same
CN100393656C (en) High-intensity corrosion-proof chimney lining brick made by mullite and method for manufacturing the same
Wang et al. Fabrication and characterization of porous cordierite ceramics prepared from fly ash and natural minerals
CN101367663B (en) Melt-out recombined composite aluminum oxide refractory materials
CN1303036C (en) Process for preparing high strength corundum refractory material by low temperature sintering
WO1995015932A1 (en) Chromium-free brick
CN103819212A (en) Refractory lining pouring material for incineration rotary kiln
JPH072536A (en) Fire brick as bed of tin bath
Choo et al. Modified cenospheres as non-sacrificial pore-forming agent for porous mullite ceramics
CN101671046B (en) Method for manufacturing high-purity magnesium-aluminum spinel
Ramezani et al. Effect of waste serpentine on the properties of basic insulating refractories
CN1704383A (en) Mg-Al light thermal-insulated fireproof materials and method for preparing same
CN101434492B (en) Large-sized special-shaped composite magnesium aluminate spinel product and technique for producing the same
US3008842A (en) Basic refractory insulating shapes
CN108439961A (en) A kind of preparation method of the high-purity calcium hexaluminate of densification-corundum composite diphase material
CN108395262A (en) A kind of olivine combination magnesium aluminate spinel hollow ball castable and preparation method
JP2756934B2 (en) Sinter from coal ash as raw material and method for producing the same
JP2002519302A (en) Molding material for producing refractory lining and fired molded member, lining, and method for producing molded member

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant