CN100478302C - High intensity ceramic ball made from compact silicon carbide and preparation method - Google Patents
High intensity ceramic ball made from compact silicon carbide and preparation method Download PDFInfo
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- CN100478302C CN100478302C CNB031340407A CN03134040A CN100478302C CN 100478302 C CN100478302 C CN 100478302C CN B031340407 A CNB031340407 A CN B031340407A CN 03134040 A CN03134040 A CN 03134040A CN 100478302 C CN100478302 C CN 100478302C
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- 239000000919 ceramic Substances 0.000 title claims abstract description 80
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- 238000002360 preparation method Methods 0.000 title claims description 20
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- 238000000034 method Methods 0.000 claims abstract description 33
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- 239000010703 silicon Substances 0.000 claims abstract description 12
- 229910052710 silicon Inorganic materials 0.000 claims abstract description 12
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- 239000002245 particle Substances 0.000 claims abstract description 8
- 239000000843 powder Substances 0.000 claims description 32
- 238000000197 pyrolysis Methods 0.000 claims description 21
- 239000003082 abrasive agent Substances 0.000 claims description 20
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- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 claims description 14
- 239000000835 fiber Substances 0.000 claims description 13
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- KRKNYBCHXYNGOX-UHFFFAOYSA-N citric acid Chemical compound OC(=O)CC(O)(C(O)=O)CC(O)=O KRKNYBCHXYNGOX-UHFFFAOYSA-N 0.000 claims description 6
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- VNWKTOKETHGBQD-UHFFFAOYSA-N methane Chemical compound C VNWKTOKETHGBQD-UHFFFAOYSA-N 0.000 claims description 5
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- JOXIMZWYDAKGHI-UHFFFAOYSA-N toluene-4-sulfonic acid Chemical compound CC1=CC=C(S(O)(=O)=O)C=C1 JOXIMZWYDAKGHI-UHFFFAOYSA-N 0.000 claims description 3
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- XUIMIQQOPSSXEZ-UHFFFAOYSA-N Silicon Chemical compound [Si] XUIMIQQOPSSXEZ-UHFFFAOYSA-N 0.000 abstract description 11
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- BOTDANWDWHJENH-UHFFFAOYSA-N Tetraethyl orthosilicate Chemical compound CCO[Si](OCC)(OCC)OCC BOTDANWDWHJENH-UHFFFAOYSA-N 0.000 description 1
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Abstract
The invention provides a high-strength compact silicon carbide ceramics ball and the prodn, method. Counting on weight percentage, the material is composed by silicon carbide 90-98 and silicon 10-2. The prodn, process is mixing silicon carbide powder, resin with and preparing them to slurry, removing unnecessary alcohol by winding, which is treated by pugging and squeezing to be ball shape, then the ball is treated by high-temp, high-pressure solidifying in high-pressure container, the solidified ball-shaped presoma is pyrolized in protection furnace of vaccum or inert gas to obtain carbon ceramics ball idiosome which is ground to proper size by disc grinder, by silicizing process, carbon in the ball gas or liquid phase silicon are reacted to generate silicon carbide and combined with original silicon carbide particles, then is polished to obtain high-strength silicon carbide and combined with original silicon carbide particles, then is polished to obtain high-strength silicon carbide ceramics balls with high size precision.
Description
Technical field
The present invention relates to the silicon carbide ceramics ball, specifically a kind of high strength dense silicon carbide ceramics ball and preparation method thereof.
Background technology
Based on mechanical behavior under high temperature, thermal property, resistance to high temperature oxidation, antiacid caustic corrosion, the wear-resistant characteristics of thyrite excellence, the silicon carbide ceramics ball has very application prospects as the vital part of ceramic bearing, ball valve and abrading-ball in multiple environment such as high temperature, the anti-high speed impact of extensive chemical burn into, materials processing or operating mode.
High-performance compact silicon carbide ceramic ball can adopt hot pressing sintering method and HIP sintering method to make.Because HIP sintering method cost is far above hot pressing sintering method, therefore main at present employing hot-press method carries out the production of short run high-performance silicon carbide Ceramic Balls.
Hot pressing sintering method is to contain the carborundum powder and linking agent (as ethyl silicate hydrolyzed solution, the polyvinyl alcohol etc.) uniform mixing of a certain amount of sintering aid, the mould of packing into, in high temperature sintering furnace, carry out hot pressed sintering, sintering temperature is generally between 1800~2200 ℃, pressure is generally at 20~40MPa, and soaking time is generally more than 1 hour.
Because the hot pressing sintering method mould therefor can't repeatedly use, every stove energy agglomerating quantity is very limited, still has the cost height, yields poorly, and the shortcoming that is difficult to produce in enormous quantities has directly limited the extensive application of high-performance silicon carbide Ceramic Balls.Therefore, be necessary to seek the method for producing low-costly and in high volume of to realize, to realize the widespread use of high-performance silicon carbide Ceramic Balls.
Summary of the invention
The object of the present invention is to provide a kind of high strength dense silicon carbide ceramics ball and preparation method thereof, with the compact silicon carbide ceramic ball of this method preparation have density height, intensity height, size be easy to control, cost of manufacture low, can mass production etc. advantage.
Technical scheme of the present invention is:
A kind of high strength dense silicon carbide ceramics ball is characterized in that: percentage ratio meter by weight, its composition is made up of 90%~98% silicon carbide and 10%~2% silicon.
The relative density of described silicon carbide ceramics ball 〉=99%, average grain size is at 10nm~15 μ m.
A kind of preparation method of described compact silicon carbide foamed ceramics is characterized in that: with carborundum powder, high carbon output rate resin is basic raw material, makes through slip preparation, moulding, curing, pyrolysis, grinding, siliconising process, and concrete preparation process is as follows:
1) slip preparation
With carborundum powder, the high carbon output rate resin, ceramic short fiber (comprising ceramic whisker) or short carbon fiber, solidifying agent and ethanol are mixed in proportion, carborundum powder, the high carbon output rate resin, weight percent between pottery or carbon chopped fiber and the solidifying agent is 78wt%~20wt%: 20wt%~60wt%: 1wt%~10wt%: 1wt%~10wt%, 0.5~2 hour ball milling time after mechanical stirring is even, filter through 35~140 eye mesh screens, get slip, solid substance in the described slip (is solute, comprises: carborundum powder, the high carbon output rate resin, pottery or carbon chopped fiber and solidifying agent) content is 20~80% of slip total amount;
2) moulding
The wind slip, remove unnecessary alcohol, after pugging (rubbing work) is handled, get flexible material, this flexible material is extruded into the continuous bar of certain diameter with extrusion machine, and then cut into the stub material of certain-length with cutting machine, utilize the hemisphere mould then or the stub material is made spherical base substrate with the disc type bowling machine;
3) solidify
Earlier spherical base substrate is put into baking oven and carries out semicure, solidification value 50-80 ℃, set time 5~60min; Then, spherical base substrate is put into high pressure vessel, charge into nitrogen or rare gas element high temperature, high pressure curing, pressure is that 5~40MPa, temperature are at 50~300 ℃, heat-up rate is 1~5 ℃ of a per minute, is incubated 10 minutes~3 hours, obtains fine and close silicon carbide ceramics ball presoma;
4) pyrolysis
Silicon carbide ceramics ball presoma pyrolysis under the protection of nitrogen or rare gas element with densification generates spherical carbon ceramics presoma; The temperature rise rate of pyrolytic process is 1~10 ℃ of a per minute, 600~1300 ℃ of final pyrolysis temperatures, soaking time 0.5~2 hour;
5) grind
The carbon ceramics ball presoma of pyrolysis gained is ground to the spheroid of required diameter with disk grinder, this process is that abrasive material is roughly ground with 50-100 purpose carborundum powder earlier, be that abrasive material carries out fine grinding with 200-400 purpose carborundum powder again, carborundum powder with 5-10 μ m finish grindes at last, each process of lapping all is that abrasive material is dispersed in the water, and the weight ratio of abrasive material and water generally is controlled at 3/97~20/80 scope;
6) siliconising
Spherical carbon ceramics presoma after the pyrolysis is carried out siliconising, get high strength dense silicon carbide ceramics ball, siliconising is carried out under nitrogen or inert atmosphere or vacuum condition, and temperature rise rate is 5~15 ℃ of per minutes, temperature is: 1400~2000 ℃, be incubated 0.5~4 hour.
Described high carbon output rate resin is selected from one or more of Resins, epoxy, resol, furfuryl resin and furfuryl resin.
Described alcohol concn 〉=70%.
It is the carborundum powder of 10nm~15 μ m that described carborundum powder adopts mean particle size.
Described solidifying agent is that one of product, oxalic acid or citric acid are taken off in tosic acid, five Lip rivers.
Described ceramic short fiber is one of silicon carbide fiber, silicon carbide whisker etc., and diameter is that 1~20 μ m, length are 10~1000 μ m.
The present invention is mixed and made into slip with carborundum powder, high carbon output rate resin, short ceramic fiber or short carbon fiber.Remove unnecessary alcohol, pugging, extruding and mold pressing or rolling balling through wind, high temperature, high pressure solidify in high pressure vessel then, with the initial density of raising silicon carbide ceramics ball base substrate and the homogeneity of composition.Spherical presoma after solidifying is carried out the presoma pyrolysis in vacuum or inert atmosphere furnace; obtain and the spherical base substrate of carbon ceramics; with disk grinder spherical base substrate is ground to desired size; carry out the siliconising reaction; make carbon and gas phase or liquid-phase silicone reaction generation silicon carbide in the ball; and combine with original silicon-carbide particle in the carbon ball, thereby obtain the silicon carbide ceramics ball of high strength dense, after polished finish can obtain the high-strength carborundum Ceramic Balls product of high dimensional accuracy.
The present invention has following beneficial effect:
1, fine and close, high-strength.The present invention adopts the High Temperature High Pressure curing, both improved the initial density of presoma, also force the homogenizing of respectively forming phase in the presoma to distribute, the silicon carbide microstructure that forms even compact for the siliconising reaction is laid a good foundation, prepared silicon carbide ceramics ball has relative density more than 99% and the even fine and closely woven microstructure (seeing accompanying drawing 1,2) of 0.5-9 μ m, has guaranteed the high strength of Ceramic Balls.
2, the silicon carbide ceramics ball can carry out in enormous quantities, low cost production.Because each link in the technical process that the present invention proposes, no matter be batching, moulding, curing, pyrolysis, grind, or siliconising, can carry out in a large number, need not to use expensive mould, even if use compression molding, also just under 250 ℃ at the flexible material moulding, hemispherical mould only need adopt No. 45 steel and can use repeatedly on thousands of ground.Therefore, the low cost production in enormous quantities of high-strength carborundum Ceramic Balls is convenient in the technical process of the present invention's proposition.
3, silicon carbide ceramics ball size is easy to control, can realize nearly end form moulding, and this point is mainly by the decision of three aspect reasons: the first, very easily be processed into the ball of different size as the former mud of expecting of preparation silicon carbide ceramics ball; The second, the machinability excellence of resulting carbon ceramics presoma after the pyrolysis just can obtain the spherical carbon ceramics presoma of same specified dimension in a large number by simple disc type Ginding process; The 3rd, forming silicon carbide reaction-sintered by the reaction of siliconising in the carbon ceramics presoma almost is the process of a no dimensional change.The silicon carbide ceramics ball that is made by the present invention only need can obtain the high-precision ceramic ball part through polishing.
4, microstructure is inside and outside consistent, neither has " dead skin is hollow ", the inner non-homogeneous Silicon-rich phenomenon of block also do not occur.The inner non-homogeneous Silicon-rich of " dead skin is hollow " and block is two kinds of common macroscopic defectss very easy appearance, that have a strong impact on the reaction sintering silicon carbide ceramic quality when utilizing resin RESEARCH OF PYROCARBON and pasc reaction to prepare block reaction sintering silicon carbide ceramic.Form the fine and close carbon-coating of low reaction activity when the reason that causes " dead skin is hollow " is the resin pyrolysis in the prefabricated section surface, this carbon-coating stops silicon to intravital infiltration, makes the interior RESEARCH OF PYROCARBON of body can not get abundant reaction; In pyrolytic process, internal resin is decomposed to form a large amount of gases and can not in time gets rid of externally, makes and forms crackle or cavity in the presoma that forms after the pyrolysis, and when siliconising reaction subsequently, silicon is the rich long-pending inner non-homogeneous Silicon-rich that forms in crackle or cavity just.The present invention adopts the method for adding an amount of silicon carbide powder and short ceramic fiber or short carbon fiber in material resin, can not only prevent the formation of the fine and close pyrolytic carbon layer of spherome surface in the resin pyrolytic process effectively, can also make the inner gas that produces successfully be rejected to external, this has fundamentally eliminated the root that causes above two class macroscopic defectss to produce, and has guaranteed that silicon carbide ceramics spheroid microstructure is inside and outside consistent.
The present invention proposes a kind of new, cheap, preparation compact high-strength degree silicon carbide ceramics ball method in a word.
Description of drawings
Fig. 1 is the silicon carbide carbon Ceramic Balls fracture microscopic appearance (scale is 100 μ m) after the pyrolysis.
Fig. 2 is compact silicon carbide ceramic ball fracture microscopic appearance (scale is 50 μ m).
Embodiment
Below by embodiment in detail the present invention is described in detail.
Embodiment 1
Weight ratio was respectively 40%: 50%: 5%: 5% mean particle size 2 μ m carborundum powders, Resins, epoxy (trade mark is EP0141-310), (diameter is 10 μ m to carbon fiber, length is 200 μ m), tosic acid adds in the dehydrated alcohol, make slip, the 1 hour ball milling time after mechanical stirring is even, filter through 55 eye mesh screens, get slip, solid content is 30% of a slip total amount in the described slip; Become material mud after the wind, pugging is squeezed into Φ 4mm bar with extrusion machine after handling, and is pressed into silicon carbide ceramics ball base substrate with Φ 4 hemisphere moulds then.Earlier spherical base substrate is put into baking oven and carries out semicure, 60 ℃ of solidification values, set time 40min; Then, spherical base substrate is put into high pressure vessel, charge into nitrogen and make air pressure reach 10MPa, be warming up to 200 ℃, 1 ℃/minute of heat-up rate is incubated curing in 1 hour, obtains fine and close silicon carbide ceramics ball presoma; Pyrolysis under argon shield generates carbon ceramics ball presoma; Wherein the temperature rise rate per minute is 2 ℃, is warming up to 900 ℃, is incubated 0.5 hour.Grind to form the carbon ceramics ball of Φ 3mm, process of lapping adopts disk grinder, be that abrasive material is roughly ground with 50 purpose carborundum powders earlier, be that abrasive material carries out fine grinding with 200 purpose carborundum powders again, carborundum powder with 5 μ m finish grindes at last, each process of lapping all is that abrasive material is dispersed in the water, and the weight ratio of abrasive material and water is controlled at 3/97 scope.Carry out the reaction sintering siliconising again, 1600 ℃ of temperature of reaction, temperature rise rate is 10 ℃/minute, be incubated 0.5 hour, get high strength dense silicon carbide ceramics ball, its density is 99%, silicon carbide average crystal grain granularity is 1.7 μ m, and its composition is a silicon carbide: 95%, and silicon: 5%.
Embodiment 2
Difference from Example 1 is:
Weight ratio was respectively 55%: 35%: 5%: (diameter is 20 μ m for 5% mean particle size 1.5 μ m carborundum powders, boron bakelite resin, silicon carbide whisker, length is 150 μ m), five Lip rivers take off product and add in the dehydrated alcohol, the 0.5 hour ball milling time after mechanical stirring is even, filter through 95 eye mesh screens, get slip, solid content is 50% of a slip total amount in the described slip; Become material mud after the wind, pugging is squeezed into Φ 10mm bar with extrusion machine after handling, and is pressed into silicon carbide ceramics ball base substrate with Φ 10mm hemisphere mould then.Earlier spherical base substrate is put into baking oven and carries out semicure, 75 ℃ of solidification values, set time 20min; Then, spherical base substrate is put into high pressure vessel, charge into argon gas and make air pressure reach 18MPa, be warming up to 240 ℃, 4 ℃/minute of heat-up rates are incubated curing in 1 hour, obtain fine and close silicon carbide ceramics ball presoma; Pyrolysis under argon shield generates the carbon ball; Wherein the temperature rise rate per minute is 2 ℃, is warming up to 1000 ℃, is incubated 0.5 hour.Grind to form the carbon ceramics ball of Φ 9mm, process of lapping adopts disk grinder, be that abrasive material is roughly ground with 70 purpose carborundum powders earlier, be that abrasive material carries out fine grinding with 320 purpose carborundum powders again, carborundum powder with 7 μ m finish grindes at last, each process of lapping all is that abrasive material is dispersed in the water, and the weight ratio of abrasive material and water is controlled at 10/90 scope.Carry out the reaction sintering siliconising again, 1700 ℃ of temperature of reaction, temperature rise rate is 15 ℃/minute, be incubated 1 hour, get high strength dense silicon carbide ceramics ball, its density is 100%, silicon carbide average crystal grain granularity is 1.1 μ m, and its composition is a silicon carbide: 96%, and silicon: 4%.
Embodiment 3
Difference from Example 1 is:
Carborundum powder, resin (heat-reactive phenolic resin 40%, furfuryl resin 60%), (diameter is 15 μ m to silicon carbide fiber, length is 500 μ m) and to take off the product weight ratio be 50wt%: 30wt%: 10wt%: 10wt% in five Lip rivers, product are taken off in heat-reactive phenolic resin and furfuryl resin and five Lip rivers to be dissolved in the dehydrated alcohol altogether, make slurry solution, the carborundum powder and the silicon carbide fiber that with mean particle size are 5 μ m again evenly add in the above-mentioned solution, the 1 hour ball milling time after mechanical stirring is even, filter through 120 eye mesh screens, get slip, solid content is 60% of a slip total amount in the described slip; Become material mud after the wind, after pugging is handled, be pressed into silicon carbide ceramics ball base substrate with the hemisphere mould of Φ 20mm.Earlier spherical base substrate is put into baking oven and carries out semicure, 80 ℃ of solidification values, set time 5min; Then, spherical base substrate is put into high pressure vessel, charge into argon gas and make air pressure reach 25MPa, be warming up to 220 ℃, 5 ℃/minute of heat-up rates are incubated curing in 0.5 hour, obtain fine and close silicon carbide ceramics ball presoma; Pyrolysis under argon shield generates the ceramic carbon ball; Wherein the temperature rise rate per minute is 2 ℃, is warming up to 1200 ℃, is incubated 0.5 hour.Grind to form the carbon ceramics ball of Φ 18mm, process of lapping adopts disk grinder, be that abrasive material is roughly ground with 80 purpose carborundum powders earlier, be that abrasive material carries out fine grinding with 360 purpose carborundum powders again, carborundum powder with 8 μ m finish grindes at last, each process of lapping all is that abrasive material is dispersed in the water, and the weight ratio of abrasive material and water is controlled at 20/80 scope.Carry out the reaction sintering siliconising again, 1850 ℃ of temperature of reaction, temperature rise rate is 15 ℃/minute, be incubated 3 hours, get high strength dense silicon carbide ceramics ball, its density is 99%, silicon carbide average crystal grain granularity is 4.8 μ m, and its composition is a silicon carbide: 90%, and silicon: 10%.
Claims (7)
1. high strength dense silicon carbide ceramics ball is characterized in that: percentage ratio meter by weight, and its composition is made up of 90%~98% silicon carbide and 10%~2% silicon; The relative density of silicon carbide ceramics ball 〉=99%, average grain size is at 10nm~15 μ m.
2. preparation method by the described high strength dense silicon carbide ceramics of claim 1 ball, it is characterized in that: with carborundum powder, high carbon output rate resin is basic raw material, make through slip preparation, moulding, curing, pyrolysis, grinding, siliconising process, concrete preparation process is as follows:
1) slip preparation
Carborundum powder, high carbon output rate resin, ceramic short fiber or short carbon fiber, solidifying agent and ethanol are mixed in proportion, weight percent between carborundum powder, high carbon output rate resin, pottery or carbon chopped fiber and the solidifying agent is 78wt%~20wt%: 20wt%~60wt%: 1wt%~10wt%: 1wt%~10wt%, 0.5~2 hour ball milling time after mechanical stirring is even, filter through 35~140 eye mesh screens, get slip, solid content is 20~80% of a slip total amount in the described slip;
(2) moulding
The wind slip is removed unnecessary alcohol, after pugging is handled, get flexible material, with extrusion machine this flexible material is extruded into the continuous bar of required diameter, and then cut into the stub material of desired length, utilize the hemisphere mould then or the stub material is made spherical base substrate with the disc type bowling machine with cutting machine;
(3) solidify
Earlier spherical base substrate is put into baking oven and carries out semicure, solidification value 50-80 ℃, set time 5~60min; Then, spherical base substrate is put into high pressure vessel, charge into nitrogen or rare gas element high temperature, high pressure curing, pressure is that 5~40MPa, temperature are at 50~300 ℃, heat-up rate is 1~5 ℃ of a per minute, is incubated 10 minutes~3 hours, obtains fine and close silicon carbide ceramics ball presoma;
(4) pyrolysis
Silicon carbide ceramics ball presoma pyrolysis under the protection of nitrogen or rare gas element with densification generates spherical carbon ceramics presoma; The temperature rise rate of pyrolytic process is 1~10 ℃ of a per minute, 600~1300 ℃ of final pyrolysis temperatures, soaking time 0.5~2 hour;
(5) grind
The carbon ceramics ball presoma of pyrolysis gained is ground to the spheroid of required diameter; Described step 5) process of lapping adopts disk grinder, be that abrasive material is roughly ground with 50-100 purpose carborundum powder earlier, be that abrasive material carries out fine grinding with 200-400 purpose carborundum powder again, carborundum powder with 5-10 μ m finish grindes at last, each process of lapping all is that abrasive material is dispersed in the water, and the weight ratio of abrasive material and water is controlled at 3/97~20/80 scope;
(6) siliconising
Spherical carbon ceramics presoma after the pyrolysis is carried out siliconising, get high strength dense silicon carbide ceramics ball, siliconising is carried out under nitrogen or inert atmosphere or vacuum condition, and temperature rise rate is 5~15 ℃ of per minutes, temperature is: 1400~2000 ℃, be incubated 0.5~4 hour.
3. according to the preparation method of the described high strength dense silicon carbide ceramics of claim 2 ball, it is characterized in that: described high carbon output rate resin is selected from one or more of Resins, epoxy, resol, furfuryl resin and phenol-furfural resin.
4. according to the preparation method of the described high strength dense silicon carbide ceramics of claim 2 ball, it is characterized in that: described alcohol concn 〉=70%.
5. according to the preparation method of the described high strength dense silicon carbide ceramics of claim 2 ball, it is characterized in that: it is the carborundum powder of 10nm~15 μ m that described carborundum powder adopts mean particle size.
6. according to the preparation method of the described high strength dense silicon carbide ceramics of claim 2 ball, it is characterized in that: described solidifying agent is that one of product, oxalic acid or citric acid are taken off in tosic acid, five Lip rivers.
7. according to the preparation method of the described high strength dense silicon carbide ceramics of claim 2 ball, it is characterized in that: described ceramic short fiber is one of silicon carbide fiber, silicon carbide whisker, and diameter is that 1~20 μ m, length are 10~1000 μ m.
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CN102531606B (en) * | 2011-12-23 | 2014-12-03 | 台州学院 | Low-temperature manufacturing method of high-strength and toughness silicon carbide ceramics |
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CN104402448B (en) * | 2014-11-19 | 2017-01-25 | 山东宝纳新材料有限公司 | Preparation method of non-pressure silicon carbide bearing balls |
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CN105924207B (en) * | 2016-04-22 | 2019-07-05 | 中国科学院光电技术研究所 | Preparation method of silicon carbide foam ceramic |
CN106673661A (en) * | 2016-12-26 | 2017-05-17 | 上海工程技术大学 | Thick-plate silicon carbide ceramic material and preparation method and application thereof |
CN109279899A (en) * | 2018-10-23 | 2019-01-29 | 山东宝纳新材料有限公司 | Carbon/carbide composite ceramic preparation method, its carbon/carbide composite ceramic, application and brake disc obtained |
CN113698215B (en) * | 2020-05-20 | 2022-10-11 | 中国科学院金属研究所 | Compact layered silicon carbide ceramic and preparation method thereof |
CN113149683A (en) * | 2021-04-29 | 2021-07-23 | 上海骐杰碳素材料有限公司 | Carbon or carbon ceramic composite material short fiber preform, product and preparation method thereof |
CN113979765B (en) * | 2021-09-27 | 2022-10-04 | 武汉拓普准晶新材料有限公司 | Silicon carbide porous ceramic and preparation method thereof |
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