IPC분류정보
국가/구분 |
United States(US) Patent
공개
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0680022
(2007-02-28)
|
공개번호 |
US-0179041
(2007-08-02)
|
우선권정보 |
AU-2004904959(2004-09-01) |
발명자
/ 주소 |
- Muroi,Michihito
- Trotter,Geoff, James
|
출원인 / 주소 |
- Advanced Nanotechnology Limited
|
대리인 / 주소 |
EDELL, SHAPIRO & FINNAN, LLC
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
0 |
초록
▼
A multi-component powder is described for consolidation to form a sinterable green body for a zirconia ceramic. The multi-component powder comprises at least 80% by volume of nano-sized particles of zirconia and up to 20% by volume of a stabilising agent which may form a coating around the nano-size
A multi-component powder is described for consolidation to form a sinterable green body for a zirconia ceramic. The multi-component powder comprises at least 80% by volume of nano-sized particles of zirconia and up to 20% by volume of a stabilising agent which may form a coating around the nano-sized particles of zirconia and is optionally in particulate form. A multi-component slurry formed by suspending the powder in a liquid is also described as well as a green body formed from either the slurry or the powder. A zirconia ceramic formed by sintering the green body is also described.
대표청구항
▼
What is claimed: 1. A multi-component powder for consolidation to form a sinterable green body for a zirconia ceramic, the multi-component powder comprising: at least 80% by volume of nano-sized particles of zirconia; and up to 20% by volume of a stabilising agent. 2. The multi-component powde
What is claimed: 1. A multi-component powder for consolidation to form a sinterable green body for a zirconia ceramic, the multi-component powder comprising: at least 80% by volume of nano-sized particles of zirconia; and up to 20% by volume of a stabilising agent. 2. The multi-component powder of claim 1, wherein the stabilising agent forms a coating around the nano-sized particles of zirconia. 3. The multi-component powder of claim 2, wherein the stabilising agent forming a coating around the zirconia is in particulate form. 4. The multi-component powder of claim 1, wherein the stabilising agent is in particulate form, and the particles of the stabilising agent are intimately mixed with the nano-sized particles of zirconia. 5. The multi-component powder of claim 4, wherein the particles of the stabilising agent have an average particle size not greater than 10 nm. 6. The multi-component powder of claim 1, wherein the nano-sized particles of zirconia have an average size in the range of 8 to 50 nm. 7. The multi-component powder of claim 6, wherein the nano-sized particles of zirconia have an average size in the range of 15 to 30 nm. 8. The multi-component powder of claim 1, wherein the nano-sized particles of zirconia have a non-uniform size distribution. 9. The multi-component powder of claim 8, wherein the non-uniform size distribution is bimodal, multimodal or log-normal with the average size of the largest 10 vol % of the particles being at least three times that of the smallest 10 vol % of the particles. 10. The multi-component powder of claim 1, wherein the stabilising agent comprises at least one of rare earth metal oxides, calcium oxide, magnesium oxide and precursor compounds which decompose to form at least one of rare earth metal oxides, calcium oxides and magnesium oxides at temperatures below the sintering temperature of the zirconia ceramic. 11. The multi-component powder of claim 10, wherein the stabilising agent comprises at least one of yttrium oxide, cerium oxide and precursor compounds which decompose to form at least one of yttrium oxide and cerium oxide at temperatures below the sintering temperature of the zirconia ceramic. 12. The multi-component powder of claim 1, further comprising up to 2% by volume of iron oxide or a precursor material that decomposes to form iron oxide at a temperature below the sintering temperature of the zirconia ceramic. 13. The multi-component powder of claim 1, further comprising up to 5% by volume of aluminium oxide or a precursor material that decomposes to form aluminium oxide at a temperature below the sintering temperature of the zirconia ceramic. 14. The multi-component powder of claim 1, further comprising 80-98% by volume of nano-sized particles of zirconia. 15. The multi-component powder of claim 1, further comprising 85-94% by volume of nano-sized particles of zirconia. 16. The multi-component powder of claim 1, further comprising not greater than 15% by volume of the stabilising agent. 17. The multi-component powder of claim 1, wherein the zirconia includes zirconia doped with a stabilising element. 18. A multi-component slurry for the preparation of a sinterable green body for a zirconia ceramic, the multi-component slurry comprising: at least 80% by volume of nano-sized particles of zirconia; and up to 20% by volume of a stabilising agent, suspended in a liquid. 19. The multi-component slurry of claim 18, wherein the stabilising agent forms a coating around the nano-sized particles of zirconia. 20. The multi-component slurry of claim 19, wherein the stabilising agent that forms a coating around the zirconia is in particulate form. 21. The multi-component slurry of claim 18, wherein the stabilising agent is in particulate form, and the particles of the stabilising agent are intimately mixed with the nano-sized particles of zirconia. 22. The multi-component slurry of claim 21, wherein the particles of the stabilising agent have an average particle size not greater than 10 nm. 23. The multi-component slurry of claim 18, wherein the nano-sized particles of zirconia have an average size in the range of 8 to 50 nm. 24. The multi-component slurry of claim 23, wherein the nano-sized particles of zirconia have an average size in the range of 15 to 30 nm. 25. The multi-component slurry of claim 18, wherein the nano-sized particles of zirconia have a non-uniform size distribution. 26. The multi-component slurry of claim 25, wherein the non-uniform size distribution is bimodal, multimodal or log-normal with the average size of the largest 10 vol % of the particles being at least three times that of the smallest 10 vol % of the particles. 27. The multi-component slurry of claim 18, wherein the stabilising agent comprises at least one of rare earth metal oxides, calcium oxides, magnesium oxides and precursor compounds which decompose to form at least one of rare earth metal oxides, calcium oxides and magnesium oxides at temperatures below the sintering temperature of the zirconia ceramic. 28. The multi-component slurry of claim 27, wherein the stabilising agent comprises at least one of yttrium oxide, cerium oxide and precursor compounds which decompose to form at least one of yttrium oxide and cerium oxide at temperatures below the sintering temperature of the zirconia ceramic. 29. The multi-component slurry of claim 18, further comprising up to 2% by volume of iron oxide or a precursor material that decomposes to form iron oxide at a temperature below the sintering temperature of the zirconia ceramic. 30. The multi-component slurry of claim 18, further comprising up to 5% by volume of aluminium oxide or a precursor material that decomposes to form aluminium oxide at a temperature below the sintering temperature of the zirconia ceramic. 31. The multi-component slurry of claim 18, further comprising 80-98% by volume of nano-sized particles of zirconia. 32. The multi-component slurry of claim 18, further comprising 85-94% by volume of nano-sized particles of zirconia. 33. The multi-component slurry of claim 18, further comprising not greater than 15% by volume of the stabilising agent. 34. The multi-component slurry of claim 19, wherein the zirconia includes zirconia doped with a stabilising element. 35. The multi-component slurry of claim 18, wherein the liquid is water. 36. A green body for sintering to produce a zirconia ceramic formed by consolidation of the multi-component powder of claim 1. 37. The green body of claim 36 formed by dry compaction of the multi-component powder. 38. The green body of claim 37, wherein the dry compaction is uniaxial pressing, cold-isostatic pressing or the combination of both. 39. The green body of claim 37, wherein the dry compaction is carried out without a binder. 40. The green body of claim 37, wherein the step of consolidation is conducted at a pressure less than 200 MPa. 41. The green body of claim 36, wherein the green body is formed by plastic forming. 42. The green body of claim 41, wherein the plastic forming is extrusion or injection moulding. 43. The green body of claim 36, wherein the green body is pre-fired at a temperature below the sintering temperature prior to sintering to form a zirconia ceramic. 44. The green body of claim 43, wherein the green body is pre-fired at a temperature in the range of 500-800째 C. 45. A green body for sintering to produce a zirconia ceramic formed by consolidation of the particles contained in the multi-component slurry of claim 18. 46. The green body of claim 45, wherein the green body is formed by slip casting, pressure filtration, centrifuge casting, tape casting and doctor blading. 47. The green body of claim 45, wherein the green body is pre-fired at a temperature below the sintering temperature prior to sintering of the green body to form a zirconia ceramic. 48. The green body of claim 47, wherein the green body is pre-fired at a temperature in the range of 500-800째 C. 49. A zirconia ceramic produced by heating the green body of claim 36 to a sintering temperature not greater than 1250째 C. 50. The zirconia ceramic of claim 49, wherein the sintering temperature not greater than 1200째 C. 51. The zirconia ceramic of claim 50, wherein the sintering temperature is not greater than 1150째 C. 52. A zirconia ceramic produced by heating the green body of claim 36 to a sintering temperature in the range of 1100 to 1200째 C. 53. The zirconia ceramic of claim 49, wherein sintering is conducted under pressure. 54. The zirconia ceramic of claim 53, wherein sintering is conducted using hot pressing, hot isostatic pressing or sinter-forging. 55. The zirconia ceramic of claim 49, wherein the zirconia ceramic has a density after sintering of at least 90% theoretical density. 56. The zirconia ceramic of claim 55, wherein the zirconia ceramic has a density after sintering of at least 95% theoretical density. 57. The zirconia ceramic of claim 55, wherein the zirconia ceramic has a density after sintering of at least 98% theoretical density. 58. A zirconia ceramic comprising at least 80% tetragonal phase of zirconia and having a Vickers hardness greater than 9 GPa or a fracture toughness greater than 10 MPa.m1/2 . 59. A zirconia ceramic having a bending strength greater than 700 MPa, a Vickers hardness greater than 9 GPa and a fracture toughness greater than 7 MPa.m1/2.
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