CN100473373C - Cheap machinable zirconium oxide ceramic dental repairing body and preparation thereof - Google Patents
Cheap machinable zirconium oxide ceramic dental repairing body and preparation thereof Download PDFInfo
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- CN100473373C CN100473373C CNB021375305A CN02137530A CN100473373C CN 100473373 C CN100473373 C CN 100473373C CN B021375305 A CNB021375305 A CN B021375305A CN 02137530 A CN02137530 A CN 02137530A CN 100473373 C CN100473373 C CN 100473373C
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Abstract
A machinable low-cost zirconium oxide ceramics used for repairing tooth is prepared from the nano yttrium oxide and cerium oxide stabilized squar zirconium-oxide polycrystal powder (Y-Ce)-TZP and the silicate glass powder, CaO-Al2O3-SiO2 as sinter assistant through preparing CaO-Al2O3-SiO2 powder and nano-class (Y-Ce)-TZP powder, proportional mixing and low-temp liquid-phase sintering at 1250 deg.C. Its advantages are high machinability, bending strength and break toughness, comparable thermal expansibility, and low cost.
Description
Technical field
The present invention relates to a kind of Cheap machinable zirconium oxide ceramic dental repairing body material and preparation method thereof, belong to dental prosthesis material field.
Background technology
Compare with metal and macromolecule dental prosthesis, full ceramic dental repairing body becomes the dental prosthetic material [Br.Dent.J., 1965,19:251] that a class has wide application prospects owing to have unique character.By composition and structure Design, it can have good optical property with to similar color, intensity and the wear resistence of natural teeth, the chemical stability in oral environment, excellent biological compatibility.The full ceramic dental repairing body of some novel machinables is subjected to extensive concern, aluminium oxide ceramics (In-Ceram-Alumina) [J.Prosthet.Dent. as feldspar porcelain (Vita and Celay), mica-based glass ceramics (Dicor) and glass infiltration, 1996,75 (1): 18; J.Mater.Sci., 1997,32 (13): 3621; J.Prosthet.Dent., 1999,81 (6): 662; Int.J.Prosthodont., 1994,7 (4): 329].But preceding two kinds of materials exist intensity low (only for about 200MPa) and poor toughness, thereby cause in clinical experiment mortality higher, limit its application, are preced with as the Dicor molar.Although adopt the In-Ceram-Alumina porcelain hat of the higher-strength (about 341MPa) of glass osmosis sintering acquisition, the toughness deficiency only limits to leaf-comb and labial teeth reparation.Heat pressing process, glass ceramics technology and glass osmosis process etc. are adopted in their preparation more, and too complicated, cost is higher, and the patient is difficult to bear [J.Quintessence Int., 1992,23:25; USA patent:5849068; USA patent:5916498].
Zirconia ceramics is owing to have higher bending strength and fracture toughness, become a kind of important structural ceramics [J.Am.Ceram.Soc., 2000,83 (3): 461], zoopery finds that zirconia ceramics has good biological blending [J.Prosthet.Dent., 1998,80 (5): 551], also has advantages of excellent stability, for example, wear-resistant and corrosion-resistant etc., be expected to solve the problem that exists in above-mentioned other full ceramic dental repairing body, zirconia ceramics becomes the focus of research in recent years as dental prosthesis like this, and research at present concentrates on zirconium oxide as toughness reinforcing phase material [J.Mat.Sci.:in Medicine, 1999,10 (12): 715; Biomed.Mater.Eng., 1997,7 (6): 379; Biomat.Master.Res., 2000,53 (4): 438] and alloy surface modifying material [Dent.Mater., 1998,14 (5): 339; J.Quintessence Int., 1996,27 (8): 533].As studies show that of full-porcelain dental dummy: zirconium oxide has best combination property than titanium and composite resin, and is preferably as full-porcelain dental dummy [J.Dent., 2001,29:427; J.Mat.Sci.:in Medicine, 2000,11 (12): 833]. still, zirconia ceramics intensity is too high, reach 800MPa above [J.Am.Ceram.Soc., 2000,83 (11): 2881], almost can not carry out grinding, limit its clinical practice in dental CAD/CAM (computer-aided design and manufacturing).Studies show that in the past [Materials Research Bulletin, (20001) (MS#2667)]: add a certain amount of glass sintering auxiliary agent and not only can reduce the pressureless sintering temperature, can also design its mechanical property and thermal coefficient of expansion etc.In addition, make itself and different human body dentin color basically identical, obtain splendid aesthetic effect, be that other dental prosthesis material is incomparable, thereby cause conception of the present invention by the ratio of adjusting yittrium oxide and ceria stabilized agent.
Summary of the invention
The objective of the invention is to design, adopt low cost low temperature pressureless sintering method to prepare a kind of machinable zirconia ceramics that satisfies the dental prosthesis requirement by the liquid-phase sintering amount of auxiliary.This shows, the present invention includes following several respects content:
1, CaO-Al
2O
3-SiO
2The preparation of sintering aid
CaO-Al
2O
3-SiO
2(CAS) amorphous powder is as the low-temperature sintering auxiliary agent, and its chemical composition is CaO (20-30wt%)-Al
2O
3(25-50wt%)-SiO
2(surplus) after 15000C founds into glass, becomes glass gob through shrend again, after ball milling becomes particle size about 1 micron, as shown in Figure 1, dry for standby.
2, nanometer (Y, Ce)-preparation of TZP powder body
Nanometer (Y, Ce)-the TZP powder body utilizes coprecipitation preparation.By regulating Y
2O
3And CeO
2The content of stabilizing agent, make itself and Dentinal solid colour.Concrete implementation step is: with Y
2O
3(0.5-1.5mol%)-CeO
2(6-12mol%)-ZrO
2The corresponding chlorination of (surplus mol%) component is recalled, behind saline solution (concentration range 0.5-2M) mix homogeneously of cerous nitrate and zirconium oxychloride, add the excessive ammonia precipitation, use distilled water wash then 6 times, obtain nanometer 100 ℃ of oven dry and at 500-1000 ℃ of calcining 2h at last.750 ℃ of calcinings obtain (Y, Ce)-pattern of TZP powder body sees Fig. 2, crystallite dimension is about 45 nanometers, and is weakly agglomerated;
3, the introducing mode of sintering aid
The addition of sintering aid is 10-40vol%.The introducing mode by ball grinding method nanometer (Y, Ce)-introduce CaO-Al in the TZP powder body
2O
3-SiO
2The glass powder sintering aid.That is sintering aid and nanometer (Y, Ce)-the TZP powder body together, be medium with water, ball milling mixes.Nanometer (Y, Ce)-percent by volume of TZP powder body and sintering aid is 60-90:40-10.
4, nothing is forced down warm liquid-phase sintering
Adding 3wt% concentration PVA is binding agent, with different proportionings (Y, Ce)-TZP powder body and the pelletize of CAS sintering aid raw material dry-pressing formed under 30-60MPa, obtain biscuit at the inferior static pressure of 200-300MPa again.Be raised to 1250 ℃ of insulations 2 hours, furnace cooling with 2-5 ℃/minute heating rate subsequently.
The bending strength of sample is measured by three-point bending method, carries out specimen size on Instron-1195 type multifunctional material experimental machine: 3 * 4 * 36mm, and span is 30mm, load is 9.80N.Each bending strength data is the meansigma methods of 5 samples. the fracture toughness of sample is measured with indentation method, experiment condition: sample surfaces need polish, and load is 9.80N.The toughness data of per sample (p.s.) is got 6 meansigma methods (two samples, every 3 point).The linear expansion coefficient of sample is measured on TMA2940 type thermal analyzer, and heating rate is 10K/min, temperature range: 20-1000 ℃.
Machinability is at Cerec II CAD/CAM machine, and makes on the Cos5.0 software of complete crown and finish, and how much estimates by the time that the porcelain body that has ground equal area and equal height is required.With sample be processed into 8X10X15.5~the porcelain piece, three every group.After porcelain piece dehydrated alcohol cleans, with epoxy resin the bottom surface of 8X10 is being bonded at the bottom of the Cerec II CAD/CAM machine special-purpose metal on the seat, finishing the required time of master pattern that is ground to tooth by computer settings is 600seconds, writing down grinding then finishes time of Shu Suoxu. every group finish after, cutting disc that more renews and cutter pin.For ease of contrast, the sample that In-Ceram-Alumina porcelain piece is processed into same specification experimentizes under similarity condition.
The CAS sintering aid of the 10-40vol% that the mode of mechanical ball milling is introduced sees Table 1 in the performance of 1250 ℃ of sintering sintered bodies, the machinability of material suitable with In-Ceram-Alumina; Mechanical property is than In-Ceram-Alumina excellence, and bending strength is at 340-360MPa, and fracture toughness is at 2.7-3.5MPam
1/2Have the thermal coefficient of expansion suitable in 7.19-8.15 * 10 with repairing the body piercing porcelain
-6/ ℃ [J.Biomedical Mater.1994,28 (2): 189; China's stomatology magazine, 1991,26 (6): 329; Dtsch Zanhnarztl Z, 1990,45:505; Dental materials and devices, 1994,13:170]; Technology is simple, and cost is low, can large-scale industrial production.
Fig. 3 is the SEM photo of fracture, shows that microstructure is even substantially.
The performance of table 1 zirconium oxide ceramic dental repairing body
In-Ceram -Alumina | |
Embodiment 2 | Embodiment 3 | Embodiment 4 | |
Cutting time (second) | 451.7±0.6 | >600 | 567.5±1.6 | 533.3±3.8 | 523.3±3.3 |
Bending strength MPa | 200 | 416±17 | 366±16 | 340±21 | 226±16 |
Fracture toughness MPam 1/2 | 1.3~~1.7 | 4.2±0.2 | 3.5±0.1 | 2.7±0.1 | 1.9±0.2 |
Thermal coefficient of expansion 10 -6/℃ | 9.02 | 8.15 | 7.19 | 6.43 |
The characteristics of zirconium oxide ceramic dental repairing body material provided by the invention are:
1, the machinability of zirconium oxide dentistry dummy greatly improves, and is suitable with In-Ceram-Alumina;
2, mechanical property is than In-Ceram-Alumina excellence, and bending strength is at 340-360MPa, and weak point splits toughness at 2.7-3.5MPam
1/2
3, the thermal coefficient of expansion with the decorations porcelain has good coupling, has the thermal coefficient of expansion suitable with repairing the body piercing porcelain in 7.19-8.15 * 10
-6/ ℃,
4, low temperature pressureless sintering, sintering temperature need not special equipment about 1250 ℃, technology is simple, and cost is low, can large-scale industrial production.
Description of drawings
Fig. 1 is CaO-Al
2O
3-SiO
2The SEM figure of glass powder, particle size is about 1 micron.
Fig. 2 is that (Y, Ce)-TEM of TZP powder body figure, behind 750 ℃ of calcining 2h, crystallite dimension is about 45nm.
Fig. 3 shows that sample adds the CAS sintering aid of 30vol%, (Y, Ce)-the TZP fracture on the big crystal grain of spottiness shape exist.
Fig. 4 be the heterogeneous co-precipitation CAS's that introduces 30vol% (Y, Ce)-TZP is at the burnishing surface of 1250 ℃ of agglomerating sintered bodies and the X diffraction pattern of fracture.The X diffraction pattern of burnishing surface shows has the monocline phase zircite to exist.The X diffraction pattern surface of fracture has a large amount of monocline to exist mutually, illustrates that the transformation toughening effect is that this material has higher-strength and flexible main cause.
Fig. 5 wears photo on master pattern for the corona that processes on the Cerec II CAD/CAM machine.
The specific embodiment
With the CAS sintering aid of 10vol% with (Y, Ce)-the back oven dry about 12 hours of TZP powder machinery ball milling, it is dry-pressing formed under 60MPa after the coupler pelletize adding 3wt%PVA again, and obtains biscuit at the inferior static pressure of 200MPa.Subsequently biscuit is placed the Si-Mo rod stove to be raised to 1250 ℃ of insulations 2 hours, furnace cooling with 2 ℃/second heating rate.Sintered body is processed into the sample of 3 * 3 * 35mm, adopts three-point bending method to survey bending strength (σ
f) (instrument: Instron-1195 type multifunctional material experimental machine; Loading speed: 0.5mm/min; Span: 30mm; A kind of data of sample are by the evaluation of estimate that is no less than 5 strips.)。σ
fCalculate by following formula:
σ
f=3PL/2bh
2
σ
f: bending strength; P: the critical load during fracture; L: span (30mm); B: sample width (4mm); H: sample thickness (3mm).
Adopt indentation method to survey fracture toughness (K
PC) (instrument: the microhardness instrument (AVK-A, AKASHI, Jpn), load: 98N; Load time: 20min; Sample surfaces characteristic: be polished to minute surface; A kind of data of sample are by the evaluation of estimate that is no less than at 5).K
ICComputing formula as follows:
P: load, 98N; β: 68 °; A=(2a
1+ 2a
2)/4; C=(2c
1+ 2c
2)/4.
This embodiment obtain (Y, Ce)-bending strength and the fracture toughness of TZP pottery be respectively 416 ± 17MPa and 4.2 ± 0.2MPam
1/2
The linear expansion coefficient of sample is measured on TMA2940 type thermal analyzer, and heating rate is 10K/min, temperature range: 20-1000 ℃. and the linear expansion coefficient that this embodiment obtains is 9.02 * 10
-6/ ℃.
Machinability is at Cerec II CAD/CAM machine, and finish on the Cos5.0 software of making complete crown, how much estimate by the time that the porcelain body that has ground equal area and equal height is required. sample is processed into the porcelain piece of 8 * 10 * 15.5mm, every group three. after porcelain piece dehydrated alcohol cleans, with epoxy resin 8 * 10 bottom surface is being bonded at the bottom of the Cerec II CAD/CAM machine special-purpose metal on the seat, finishing the required time of master pattern that is ground to tooth by computer settings is 600seconds, writing down grinding then finishes time of Shu Suoxu. every group finish after, cutting disc that more renews and cutter pin.For ease of contrast, the sample that In-Ceram-Alumina porcelain piece is processed into same specification experimentizes under similarity condition.The required time 451.7 ± 0.6 of sample that the cutting time that this embodiment obtains and In-Ceram-Alumina porcelain piece are processed into same specification is compared, and cannot finish in the 600 second time of setting, and is difficult to cut.
Embodiment 2
Add the CAS sintering aid of 20vol%, other condition is with embodiment 1.This embodiment obtain (Y, Ce)-bending strength and the fracture toughness of TZP pottery be respectively 366 ± 16MPa and 3.5 ± 0.1MPam
1/2The linear expansion coefficient that this embodiment obtains is 7.19 * 10
-6/ ℃.The required time 451.7 ± 0.6 of sample that the cutting time that this embodiment obtains and In-Ceram-Alumina porcelain piece are processed into same specification is compared, and finishes in 567.5 ± 1.6 seconds, and machinability is improved.
Embodiment 3
Add the CAS sintering aid of 30vol%, other condition is with embodiment 1.This embodiment obtain (Y, Ce)-bending strength and the fracture toughness of TZP pottery be respectively 340 ± 21MPa and 2.7 ± 0.1MPam
1/2The linear expansion coefficient that this embodiment obtains is 7.19 * 10
-6/ ℃.The required time 451.7 ± 0.6 of sample that the cutting time that this embodiment obtains and In-Ceram-Alumina porcelain piece are processed into same specification is compared, and finishes in 533.3 ± 3.8 seconds, and machinability is suitable with In-Ceram-Alumina porcelain piece.
Embodiment 4
Add the CAS sintering aid of 40vol%, other condition is with embodiment 1.This embodiment obtain (Y, Ce)-bending strength and the fracture toughness of TZP pottery be respectively 226 ± 16MPa and 1.9 ± 0.2MPam
1/2, suitable with In-Ceram-Alumina porcelain piece.The linear expansion coefficient that this embodiment obtains is 6.43 * 10
-6/ ℃.The required time 451.7 ± 0.6 of sample that the cutting time that this embodiment obtains and In-Ceram-Alumina porcelain piece are processed into same specification is compared, and finishes in 523.3 ± 3.3 seconds, and machinability is suitable with In-Ceram-Alumina porcelain piece.
Claims (5)
1, a kind of Cheap machinable zirconium oxide ceramic dental repairing body material is characterized in that tetragonal zirconia polycrystal Y-Ce-TZP powder body and the sintering aid CaO-Al of this repair materials by nano yttrium oxide and ceria stabilized
2O
3-SiO
2The silicate glass powder body is formed; Both percents by volume are 60-90:40-10; It is 0.5~1.5Y that described Y-Ce-TZP powder body mol percentage is formed
2O
3-6~12CeO
2-surplus ZrO
2Described CaO-Al
2O
3-SiO
2The silicate glass powder body consists of 20~30CaO
2-25-50Al
2O
3-surplus SiO
2
2, by the described Cheap machinable zirconium oxide ceramic dental repairing body material of claim 1, the specific surface area that it is characterized in that described nanometer Y-Ce-TZP powder body is 5-75m
2/ g, crystallite dimension is the 14-260 nanometer; Described CaO-Al
2O
3-SiO
2The silicate glass powder body is of a size of 1 micron.
3, by the wrong ceramic dental repairing body preparation methods of the machinable oxidation of the described low cost of claim 1, it is characterized in that comprising sintering aid CaO-Al
2O
3-SiO
2The preparation of silicate glass powder body, nanometer Y-Ce-TZP powder preparing, and the two is mixed in proportion and nothing is forced down warm liquid-phase sintering process, concrete steps are:
(1) CaO-Al
2O
3-SiO
2The preparation of sintering aid, by the chemical composition proportioning 1500 ℃ found into glass after, become glass gob through shrend again, it is 1 micron fine powder that last ball milling becomes particle size;
(2) nanometer Y-Ce-TZP powder preparing by behind the hydrochloric acid solution mix homogeneously of component with Yttrium chloride(Y2Cl6), cerous nitrate and the zirconium oxychloride of concentration 0.5-2M, adds the excessive ammonia precipitation, unexpectedly after the washing and drying, 500-1000 ℃ of calcining 2 hours;
(3) in nanometer Mg-Y-TZP powder body, introduce CaO-Al by ball milling method
2O
3-SiO
2The glass powder sintering aid adds the PVA binding agent, and pelletize is also dry-pressing formed, makes biscuit at the inferior static pressure of 200-300MPa again; Do not have in 2 hours 1250 ℃ of insulations at last and force down warm liquid-phase sintering process, furnace cooling.
4, by the described Cheap machinable zirconium oxide ceramic dental repairing body preparation methods of claim 3, when it is characterized in that described nanometer Y-Ce-TZP powder preparing, add the excessive ammonia precipitation, use distilled water wash then 6 times, and 100 ℃ of oven dry.
5, by the described Cheap machinable zirconium oxide ceramic dental repairing body preparation methods of claim 3, the addition that it is characterized in that described PVA binding agent is 3wt%; Dry-pressing formed pressure is 30-60MPa; Heating rate at 1250 ℃ of heat preservation sinterings is 2-5 ℃/minute at last.
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DE102004045752B3 (en) * | 2004-09-21 | 2006-05-04 | Forschungszentrum Karlsruhe Gmbh | Use of a ceramic as a dental ceramic |
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CN101811874B (en) * | 2010-04-14 | 2013-03-06 | 邓旭亮 | Method for synthesizing nanometer zirconia composite ceramics |
CN104446512A (en) * | 2013-09-24 | 2015-03-25 | 宝山钢铁股份有限公司 | Composite sintering aids for BN-ZrO2-SiC composite material |
FR3039540B1 (en) * | 2015-07-30 | 2019-12-06 | Saint-Gobain Centre De Recherches Et D'etudes Europeen | ALUMINA AND ZIRCONIA-BASED FRITTED PRODUCT |
CN105832563A (en) * | 2016-05-05 | 2016-08-10 | 东莞市爱嘉义齿有限公司 | 3D printing false tooth material |
CN111908892B (en) * | 2020-08-05 | 2022-05-06 | 苏州知会智能科技有限公司 | Preparation method, product and application of artificial tooth model material |
CN114538923A (en) * | 2022-03-31 | 2022-05-27 | 无锡宜雅科技合伙企业(有限合伙) | Machinable zirconia ceramic block for dentistry and preparation method thereof |
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