CN1686923A - Method for preparing corundum bricks composite with Nano alpha-Al2O3 - Google Patents
Method for preparing corundum bricks composite with Nano alpha-Al2O3 Download PDFInfo
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- CN1686923A CN1686923A CN 200510017457 CN200510017457A CN1686923A CN 1686923 A CN1686923 A CN 1686923A CN 200510017457 CN200510017457 CN 200510017457 CN 200510017457 A CN200510017457 A CN 200510017457A CN 1686923 A CN1686923 A CN 1686923A
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Abstract
The present invention provides a nano alpha-Al2O3 composite corundum brick and its preparation method. Said method sues fused corundum granules, fused corundum fine powder, alpha-Al2O3 nano powder and alpha-Al2O3 micropowder as raw material, and adopts special dispersion technique and forming process to prepare the invented nano alpha-Al2O3 composite corundum brick. besides, said invention also provides its extensive application range.
Description
Affiliated field:
The invention belongs to refractory oxide goods manufacturing technology field, be specifically related to a kind of with electro-corundum, α-Al
2O
3Micro mist and α-Al
2O
3Nano powder is the preparation method of the composite corundum brick of primary raw material.
Background technology:
Because Al
2O
3Be the ionic linkage compound, the low (Al of its particle spread coefficient
3+Spread coefficient only is 10 in the time of 1700 ℃
-11Cm
2.s
-1), sintering temperature is higher, and the sintering temperature of general corundum products can be up to 1800 ℃.In order to reduce the sintering temperature of corundum products, people once attempted at high temperature to produce liquid phase by sintering aid and come acceleration of sintering (liquid phase sintering mechanism) by adding sintering aid, and regrettably the adding of agglutinant will cause the material at high temperature performance to reduce.Nanometer α-Al
2O
3Powder is because size is little, surface atom accounts for sizable ratio, thereby surface energy height, has high activity, the more conventional powder of its sintering temperature is much lower, be introduced into and both can be used as sintering aids in the corundum products and also in the corundum products sintering process, serving as simultaneously effect in conjunction with phase, thereby be expected when reducing the corundum products sintering temperature, improving microstructure of products, to make goods to keep good high-temperature behavior.
Recent domestic studies show that nano heterogeneous ceramic, introduces nanodispersed phase and carry out compoundly in the micron order matrix, can make the fracture strength of material, fracture toughness improve 2~4 times, and material creep resistance and antifatigue destructive characteristics are improved.Therefore nano-powder is compound in the refractory material, obtains good high-temperature behavior by the control to its microstructure.Along with the nano powder preparation technology improves constantly, preparation cost constantly reduces, and the application and development of nano-powder is extensive day by day, and many traditional materials field is also actively introducing nano material, in the hope of further improving material property.Yet, with regard to nano-powder with regard to the applied research in the material, mainly concentrate on fine ceramics and nano heterogeneous ceramic aspect up to now, applied research in refractory materials still is in the starting stage to nano-powder, to nano-powder introduce refractory materials preparation technology and to the sintering character of material, microstructure and to mechanical behavior under high temperature produce to influence the aspect report very few.
Document " nanometer Fe
2O
3Impact to magchrome refractory sintering and mechanical property " (refractory material, 2003,37 (5): 256~258) " introduced a kind of nanometer Fe that contains
2O
3The preparation method of magchrome refractory.
Document " nanometer Al
2O
3And SiO
2Impact to corundum based refractory materials sintering and mechanical property " (refractory material, 2002,36 (2): 66~69) introduced a kind of nanometer α-Al that contains
2O
3And SiO
2Corundum brick, this technology makes the sintering temperature of corundum brick reduce by 100~200 ℃, but the high-temperature behavior of the standby material of institute system not.
Summary of the invention:
The objective of the invention is with electro-corundum material, α-Al
2O
3Micro mist and α-Al
2O
3Nano powder is raw material, adopts special dispersion technology and moulding process to prepare nanometer α-Al
2O
3Composite corundum brick had both effectively reduced the firing temperature of corundum refractory brick, improved again its performance simultaneously.
Technical scheme of the present invention is:
With Al
2O
3Content is greater than 99% electro-corundum particle and fine powder, α-Al
2O
3Nano powder and α-Al
2O
3Micro mist is raw material, adopts dispersion technology and moulding process, the steps include:
A. be α-Al of 0.25-3.5% with parts by weight
2O
3Nano powder adds water and is mixed with suspension, and ultrasonic dispersion adds the dispersant of parts by weight 0.05-2.0% and α-Al of 2-15%
2O
3Micro mist is mixed and made into mud;
B. be that the corundum in granules of 84-96% and fine powder and mud mix with parts by weight, add the wedding agent of raw material gross weight 3-6%, be mixed into pug, under the room temperature ageing mixture 22-25 hour, machine was pressed into green compact, 100-120 ℃, 20-24h drying treatment;
C. dried green compact are placed stove, are warming up to 950-1100 ℃, continue to be warming up to 1250-1600 ℃ with 30-100 ℃/hour speed again and burn till, be incubated 3-10 hour with 60-300 ℃/hour speed, be cooled to room temperature after, promptly get product.
Wherein:
α-Al
2O
3The particle diameter of nano powder is 50-120nm.
α-Al
2O
3The D of micro mist
50=1-10 μ m.
In fused corundom particle and the fine powder, coarse grained particle diameter is 5-1mm, and parts by weight are 45-65%; Middle particle grain size is 1-0.088mm, parts by weight 10-20%; The particle diameter of fine powder is less than 0.088mm, parts by weight 15-35%.
Dispersion agent is an ammonium polyacrylate, sodium polyacrylate, polycarboxylate ether, tripoly phosphate sodium STPP, one or both in the Sodium hexametaphosphate 99.
Wedding agent is a kind of in dextrin, polyvinyl alcohol, xylogen, the carboxymethyl cellulose.
The invention has the advantages that:
1, the present invention has added a small amount of α-Al in corundum brick
2O
3Nano powder makes the sintering temperature of corundum brick reduce by 200~400 ℃, is conducive to save energy and reduce the cost, and is easier to make.
2, at nanometer α-Al
2O
3In the preparation process of composite corundum brick, the dispersion technology of employing and mud moulding process can guarantee α-Al
2O
3Nano powder is Uniform Dispersion in matrix.
3, the nanometer α for preparing with the present invention-Al
2O
3Composite corundum brick improves 30-80% than present commodity corundum brick high temperature break resistant intensity, and thermal shock resistance improves 20-50%.
Embodiment:
Below in conjunction with embodiment the present invention is further described, but is not limited to the following example.
Embodiment 1
Raw material:
Select Al
2O
3Content is greater than 99% electro-corundum coarse granule, middle particle, fine powder, α-Al
2O
3Micro mist and α-Al
2O
3Nano powder is raw material, wherein α-Al
2O
3The nano powder average grain diameter is 50-120nm, corundum in granules, fine powder, α-Al
2O
3Granularmetric composition such as the table 1 of micro mist,
Table 1 corundum in granules, fine powder and α-Al
2O
3The granularmetric composition of micro mist
| Component | Al 2O 3 | |||
| Coarse granule | Middle particle | Fine powder | α-Al 2O 3Micro mist | |
| Mm | 5-1 | 1-0.088 | <0.088 | 0.005 (D 50) |
Various raw materials by weight are: α-Al
2O
3Nano powder 1%, α-Al
2O
3Micro mist 6%, corundum coarse granule 45%, corundum fine grained 15%, corundum fine powder 33%.
Dispersion agent is an ammonium polyacrylate, and consumption is 0.2% of a raw material weight.
Preparation:
With α-Al
2O
3Nano-powder adds water (amount of water be total amount of water about 50%) and is mixed with suspension, and ultrasonic dispersion adds ammonium polyacrylate and α-Al
2O
3Micro mist is mixed and made into mud; Successively corundum coarse granule, middle particle, fine powder and mud are added mixer, take the dextrin of batch mixing weight 3% as bond, adding mixes, and ageing mixture is 24 hours under the room temperature, and machine is pressed into green compact under the pressure of 150MPa, green compact through 120 ℃, 24h is dry processes.
Above-mentioned green compact are placed stove, be warming up to 1000 ℃ with 120 ℃/hour speed; Continue to be warming up to 1350 ℃ with 60 ℃/hour speed again, be incubated 9 hours; Treat that furnace temperature reduces to room temperature and take out, promptly make nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.21g/cm
3, apparent porosity is 17.9%, strength at normal temperature is 18MPa, cold crushing strength is 93MPa, the high temperature break resistant intensity under 1400 ℃ is 9Mpa, 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 38%.
Embodiment 2
Raw materials used and granularity is with embodiment 1.
Various raw materials by weight are: α-Al
2O
3Nano powder 1%, α-Al
2O
3Micro mist 4%, corundum coarse granule 50%, corundum fine grained 10%, corundum fine powder 35%.
Dispersion agent is that polycarboxylate ether and ammonium polyacrylate are composite, and consumption is 0.78% and 0.1% of a raw material weight.
Preparation α-Al
2O
3Nano-powder suspension and ultrasonic dispersion add polycarboxylate ether and α-Al
2O
3Micro mist is mixed and made into mud; Successively corundum coarse granule, middle particle, fine powder and mud are added mixer, take the dextrin of batch mixing weight 3% as bond, ageing mixture is 22 hours under the room temperature, and machine is pressed into green compact under the pressure of 150MPa, the dry 24h that processes about 110 ℃.
Above-mentioned green compact are warming up to 1000 ℃ with 160 ℃/hour speed; Continue to be warming up to 1500 ℃ with 65 ℃/hour speed again, be incubated 5 hours; Treat that furnace temperature reduces to room temperature and take out, promptly make nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.25g/cm
3, apparent porosity is 17.5%, and strength at normal temperature is 20MPa, and cold crushing strength is 102MPa, and the high temperature break resistant intensity under 1400 ℃ is 10MPa; 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 37%.
Embodiment 3
Raw materials used and granularity is with embodiment 1.
Various raw materials by weight are: α-Al
2O
3Nano powder 0.5%, α-Al
2O
3Micro mist 12%, corundum coarse granule 45%, corundum fine grained 15%, corundum fine powder 27.5%.
Dispersion agent is a Sodium hexametaphosphate 99, and consumption is 0.08% of a raw material weight.
Preparation α-Al
2O
3Nano-powder suspension and ultrasonic dispersion add calgon and α-Al
2O
3Micro mist is mixed and made into mud; Successively corundum coarse granule, middle particle, fine powder and mud are added mixer, take the carboxymethyl cellulose of batch mixing weight 2.5% as bond, adding mixes, and ageing mixture is about 23 hours under the room temperature, machine is pressed into green compact under the pressure of 120MPa, 110 ℃ of dry 24h that process.
Above-mentioned green compact are placed stove, be warming up to 1000 ℃ with 180 ℃/hour speed; Continue to be warming up to 1250 ℃ with 80 ℃/hour speed again, be incubated 4 hours; Treat that furnace temperature reduces to room temperature and take out, promptly make nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.31g/cm
3, apparent porosity is 16.3%, and strength at normal temperature is 21MPa, and cold crushing strength is 121MPa, and the high temperature break resistant intensity under 1400 ℃ is 14MPa; 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 28%.
Embodiment 4
Select for use raw material with embodiment 1.
α-Al wherein
2O
3The nano powder average grain diameter is 50-120nm, corundum in granules, fine powder, α-Al
2O
3The granularmetric composition of micro mist is as shown in table 2.
Table 2 corundum in granules, fine powder and α-Al
2O
3The granularmetric composition of micro mist
| Component | Al 2O 3 | |||
| Coarse granule | Middle particle | Fine powder | α-Al 2O 3Micro mist | |
| Mm | 4-1 | 1-0.088 | <0.044 | 0.01 (D 50) |
Various raw materials by weight are: α-Al
2O
3Nano powder 1%, α-Al
2O
3Micro mist 8%, corundum coarse granule 50%, corundum fine grained 10%, corundum fine powder 31%.
Dispersion agent is that polycarboxylate ether and Sodium hexametaphosphate 99 are composite, and consumption is respectively 0.2% and 0.05% of raw material weight.
Preparation α-Al
2O
3Nano-powder suspension and ultrasonic dispersion add polycarboxylate ether and calgon and α-Al
2O
3Micro mist is mixed and made into mud; Successively corundum coarse granule, middle particle, fine powder and mud are added mixer, take the carboxymethyl cellulose of batch mixing weight 2% as bond, adding mixes, and ageing mixture is 24 hours under the room temperature, and machine is pressed into green compact under the pressure of 180MPa, 120 ℃ of dry 24h that process.
Above-mentioned green compact are placed stove, be warming up to 950 ℃ with 100 ℃/hour speed; Continue to be warming up to 1450 ℃ with 60 ℃/hour speed again, be incubated 6 hours; Treat that furnace temperature reduces to room temperature and take out, promptly make nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.29g/cm
3, apparent porosity is 16.0%, and strength at normal temperature is 18MPa, and cold crushing strength is 141MPa, and the high temperature break resistant intensity under 1400 ℃ is 16MPa; 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 32%.
Embodiment 5
Raw materials used and granularity is with embodiment 4.
Various raw materials by weight are: α-Al
2O
3Nano powder 3%, α-Al
2O
3Micro mist 10%, corundum coarse granule 60%, corundum fine grained 10%, corundum fine powder 17%.
Dispersion agent is a sodium polyacrylate, and consumption is 0.3% of a raw material weight.
Preparation α-Al
2O
3Nano-powder suspension and ultrasonic dispersion add Sodium Polyacrylate and α-Al
2O
3Micro mist is mixed and made into mud; Successively corundum coarse granule, middle particle, fine powder and mud are added mixer, take the polyvinyl alcohol of batch mixing weight 3% as bond, adding mixes, and ageing mixture is 22 hours under the room temperature, and machine is pressed into green compact under the pressure of 150MPa, 120 ℃ of dry 22h that process.
Above-mentioned green compact are placed stove, be warming up to 1100 ℃ with 120 ℃/hour speed; Continue to be warming up to 1600 ℃ with 90 ℃/hour speed again, be incubated 3 hours; Treat that furnace temperature reduces to room temperature and take out, obtain nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.24g/cm
3, apparent porosity is 17.0%, and strength at normal temperature is 16MPa, and cold crushing strength is 132MPa, and high temperature break resistant intensity is 12MPa in the time of 1400 ℃; 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 33%.
Embodiment 6
Institute's raw material is with embodiment 1.
α-Al wherein
2O
3The nano powder average grain diameter is 50-120nm, corundum in granules, fine powder, α-Al
2O
3The granularmetric composition of micro mist is as shown in table 3.
Table 3 corundum in granules, fine powder, α-Al
2O
3The granularmetric composition of micro mist
| Component | Al 2O 3 | |||
| Coarse granule | Middle particle | Fine powder | α-Al 2O 3Micro mist | |
| Mm | 5-1 | 1-0.088 | <0.088 | 0.008 (D 50) |
Various raw materials by weight are: α-Al
2O
3Nano powder 2%, α-Al
2O
3Micro mist 5%, corundum coarse granule 47%, corundum fine grained 18%, corundum fine powder 28%.
Dispersion agent is a tripoly phosphate sodium STPP, and consumption is 0.08% of a raw material weight.
Preparation α-Al
2O
3Nano-powder suspension and ultrasonic dispersion add ammonium polyacrylate and α-Al
2O
3Micro mist is mixed and made into mud, successively corundum coarse granule, middle particle, fine powder and mud is added mixer, take the lignin of batch mixing weight 6% as bond, adding mixes, ageing mixture is 24 hours under the room temperature, and machine is pressed into green compact under the pressure of 250MPa, 120 ℃ of dry 24h that process.
Above-mentioned green compact are placed stove, under oxidizing atmosphere, be warming up to 1000 ℃ with 200 ℃/hour speed; Continue to be warming up to 1550 ℃ with 60 ℃/hour speed again, be incubated 5 hours; Treat that furnace temperature reduces to room temperature and take out, obtain nanometer α-Al
2O
3Composite corundum brick.
After testing, prepared nanometer α-Al
2O
3The bulk density of composite corundum brick is 3.26g/cm
3, apparent porosity is 16.8%, and strength at normal temperature is 21MPa, and cold crushing strength is 126MPa, and the high temperature break resistant intensity under 1400 ℃ is 15MPa; 1100 ℃ of water-cooleds once after thermal shock residual strength conservation rate be 34%.
Claims (7)
1, nanometer α-Al
2O
3The preparation method of composite corundum brick is with Al
2O
3Content is greater than 99% electro-corundum particle and fine powder, α-Al
2O
3Nano powder and α-Al
2O
3Micro mist is raw material, adopts dispersion technology and moulding process, it is characterized in that:
A. be α-Al of 0.25-3.5% with parts by weight
2O
3Nano powder adds water and is mixed with suspension, and ultrasonic dispersion adds the dispersant of parts by weight 0.05-2.0% and α-Al of 2-15%
2O
3Micro mist is mixed and made into mud;
B. be that the corundum in granules of 84-96% and fine powder and mud mix with parts by weight, add the wedding agent of raw material gross weight 3-6%, be mixed into pug, under the room temperature ageing mixture 22-24 hour, machine was pressed into green compact, 100-120 ℃, 20-24h drying treatment;
C. dried green compact are placed stove, are warming up to 950-1100 ℃, continue to be warming up to 1250-1600 ℃ with 30-100 ℃/hour speed again and burn till, be incubated 3-10 hour with 60-300 ℃/hour speed, be cooled to room temperature after, promptly get product.
The 2 nanometer α that states according to claim 1-Al
2O
3The preparation method of composite corundum brick is characterized in that α-Al
2O
3The particle diameter of nano powder is 50-120nm.
3, according to the nanometer α-Al of claim 1
2O
3The preparation method of composite corundum brick is characterized in that α-Al
2O
3The D of micro mist
50=1-10 μ m.
4 according to the described nanometer α of claim 1-Al
2O
3The preparation method of composite corundum brick is characterized in that in said electro-corundum particle and the fine powder, coarse grained particle diameter is 5-1mm, and parts by weight are 45-65%; The particle diameter of middle particle is 1-0.088mm, parts by weight 10-20%; The particle diameter of fine powder is less than 0.088mm, parts by weight 15-35%.
5, according to the described arbitrary nanometer α of claim 1-4-Al
2O
3The preparation method of composite corundum brick is characterized in that dispersant is ammonium polyacrylate, Sodium Polyacrylate, polycarboxylate ether, sodium phosphate trimer, one or both in the calgon.
6, according to the described arbitrary nanometer α of claim 1-5-Al
2O
3The preparation method of composite corundum brick is characterized in that bond is a kind of in dextrin, polyvinyl alcohol, lignin, the carboxymethyl cellulose.
7, according to the described nanometer α of claim 1-Al
2O
3The preparation method of composite corundum brick is characterized in that: the pressure of mechanical pressing is 100-250MPa.
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|---|---|---|---|
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|---|---|---|---|
| CNB2005100174574A CN100436369C (en) | 2005-03-29 | 2005-03-29 | Method for preparing corundum bricks composite with Nano alpha-Al2O3 |
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Cited By (9)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101955361A (en) * | 2010-09-29 | 2011-01-26 | 河南省伯马股份有限公司 | Method for producing high-chrome bricks containing nano composite particles |
| CN103183516A (en) * | 2013-04-10 | 2013-07-03 | 济南钢铁集团耐火材料有限责任公司 | Machine pressing carbon-free lining brick for steel ladles |
| CN105237003A (en) * | 2015-10-20 | 2016-01-13 | 长兴宏泰耐火器材有限公司 | Method for producing environmentally friendly high-temperature fold-resistant high-strength high purity corundum bricks |
| CN106468086A (en) * | 2016-08-31 | 2017-03-01 | 长兴科特碳化硅有限公司 | Combined type disperse air brick and preparation method thereof |
| CN108610027A (en) * | 2018-07-16 | 2018-10-02 | 武汉科技大学 | A kind of high-performance cement combination castable and preparation method thereof |
| CN108658621A (en) * | 2018-05-18 | 2018-10-16 | 宜兴市东山新型材料有限公司 | A kind of high purity aluminium oxide lightweight load bearing board and preparation method thereof |
| CN108947500A (en) * | 2018-08-16 | 2018-12-07 | 中钢集团洛阳耐火材料研究院有限公司 | A kind of low sodium abrasion-resistant corundum product and preparation method |
| CN111099883A (en) * | 2019-12-27 | 2020-05-05 | 江苏国窑科技有限公司 | Corundum brick for hazardous waste rotary kiln and preparation method thereof |
| CN113880563A (en) * | 2021-09-16 | 2022-01-04 | 山东工业陶瓷研究设计院有限公司 | High-temperature creep-resistant ceramic material and preparation method thereof |
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| Publication number | Priority date | Publication date | Assignee | Title |
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| CN1303036C (en) * | 2004-09-15 | 2007-03-07 | 郑州大学 | Process for preparing high strength corundum refractory material by low temperature sintering |
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2005
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101955361A (en) * | 2010-09-29 | 2011-01-26 | 河南省伯马股份有限公司 | Method for producing high-chrome bricks containing nano composite particles |
| CN103183516A (en) * | 2013-04-10 | 2013-07-03 | 济南钢铁集团耐火材料有限责任公司 | Machine pressing carbon-free lining brick for steel ladles |
| CN103183516B (en) * | 2013-04-10 | 2015-01-14 | 济南钢铁集团耐火材料有限责任公司 | Machine pressing carbon-free lining brick for steel ladles |
| CN105237003A (en) * | 2015-10-20 | 2016-01-13 | 长兴宏泰耐火器材有限公司 | Method for producing environmentally friendly high-temperature fold-resistant high-strength high purity corundum bricks |
| CN106468086A (en) * | 2016-08-31 | 2017-03-01 | 长兴科特碳化硅有限公司 | Combined type disperse air brick and preparation method thereof |
| CN108658621A (en) * | 2018-05-18 | 2018-10-16 | 宜兴市东山新型材料有限公司 | A kind of high purity aluminium oxide lightweight load bearing board and preparation method thereof |
| CN108610027A (en) * | 2018-07-16 | 2018-10-02 | 武汉科技大学 | A kind of high-performance cement combination castable and preparation method thereof |
| CN108947500A (en) * | 2018-08-16 | 2018-12-07 | 中钢集团洛阳耐火材料研究院有限公司 | A kind of low sodium abrasion-resistant corundum product and preparation method |
| CN111099883A (en) * | 2019-12-27 | 2020-05-05 | 江苏国窑科技有限公司 | Corundum brick for hazardous waste rotary kiln and preparation method thereof |
| CN113880563A (en) * | 2021-09-16 | 2022-01-04 | 山东工业陶瓷研究设计院有限公司 | High-temperature creep-resistant ceramic material and preparation method thereof |
| CN113880563B (en) * | 2021-09-16 | 2023-02-17 | 山东工业陶瓷研究设计院有限公司 | High-temperature creep-resistant ceramic material and preparation method thereof |
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|---|---|
| CN100436369C (en) | 2008-11-26 |
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