The invention relates to a pane that has undergone a chemical toughening operation so as to have an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa, and a strain point at the core of at least 550° C. The pane ca
The invention relates to a pane that has undergone a chemical toughening operation so as to have an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa, and a strain point at the core of at least 550° C. The pane can be used especially in the field of domestic cooking, as a pyrolytic oven door, stove, fire guard, flue insert, and more generally for separating two gaseous atmospheres at different temperatures. The pane is particularly resistant to heat shocks.
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1. A cooker or fire screen or flue insert, comprising a door having a pane of glass positioned to be in direct contact with a hot atmosphere, wherein the glass comprises at least one type of alkali metal ion, an alkali-metal-ion concentration gradient from its surface over an exchange depth of at le
1. A cooker or fire screen or flue insert, comprising a door having a pane of glass positioned to be in direct contact with a hot atmosphere, wherein the glass comprises at least one type of alkali metal ion, an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa and a strain point in the core of at least 550° C., wherein the glass comprises an interdiffusion coefficient, at 490° C., of exchanged alkali metal ions, of less than 2×10−15 m2·s−1. 2. An oven, comprising a door having a pane of glass positioned to be in direct contact with a hot atmosphere, wherein the glass comprises at least one type of alkali metal ion, an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa and a strain point in the core of at least 550° C., wherein the glass comprises an interdiffusion coefficient, at 490° C., of exchanged alkali metal ions, of less than 2×10−15 m2·s−1. 3. The oven of claim 2, wherein the oven is a pyrolytic oven. 4. A stove, comprising a door having a pane of glass positioned to be in direct contact with a hot atmosphere, wherein the glass comprises at least one type of alkali metal ion, an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa and a strain point in the core of at least 550° C., wherein the glass comprises an interdiffusion coefficient, at 490° C., of exchanged alkali metal ions, of less than 2×10−15 m2·s−1. 5. The cooker or fire screen or flue insert of claim 1, wherein the glass comprises an interdiffusion coefficient, at 400° C., of alkali metal ions exchanged, of at most 9×10−17 m2·s−1. 6. The cooker or fire screen or flue insert of claim 1, wherein the ratio of the interdiffusion coefficient, at 490° C., of the exchanged alkali metal ions, to the interdiffusion coefficient, at 400° C., of the exchanged alkali metal ions, is at least 20:1. 7. The cooker or fire screen or flue insert of claim 1, wherein the strain point in the core is at least 570° C. 8. The cooker or fire screen or flue insert of claim 1, wherein the at least one type of alkali metal ion is selected from the group consisting of Na+, Li+, K+ and combinations thereof. 9. The cooker or fire screen or flue insert of claim 1, wherein the exchange depth is at most 300 μm. 10. The cooker or fire screen or flue insert of claim 1, wherein the thickness of the pane ranges from 2 to 7 mm. 11. The cooker or fire screen or flue insert of claim 1, wherein the thickness of the pane ranges from 2.8 to 5 mm. 12. The oven of claim 2, wherein the glass comprises an interdiffusion coefficient, at 400° C., of alkali metal ions exchanged, of at most 9×10−17 m2·s−. 13. The oven of claim 2, wherein the ratio of the interdiffusion coefficient, at 490° C., of the exchanged alkali metal ions, to the interdiffusion coefficient, at 400° C., of the exchanged alkali metal ions, is at least 20:1. 14. The oven of claim 2, wherein the strain point in the core is at least 570° C. 15. The oven of claim 2, wherein the at least one type of alkali metal ion is selected from the group consisting of Na+, Li+, K+ and combinations thereof. 16. The oven of claim 2, wherein the exchange depth is at most 300 μm. 17. The oven of claim 2, wherein the thickness of the pane ranges from 2 to 7 mm. 18. The oven of claim 2, wherein the thickness of the pane ranges from 2.8 to 5 mm. 19. The stove of claim 4, wherein the glass comprises an interdiffusion coefficient, at 400° C., of alkali metal ions exchanged, of at most 9×10−17 m2·s−1. 20. The stove of claim 4, wherein the ratio of the interdiffusion coefficient, at 490° C., of the exchanged alkali metal ions, to the interdiffusion coefficient, at 400° C., of the exchanged alkali metal ions, is at least 20:1. 21. The stove of claim 4, wherein the strain point in the core is at least 570° C. 22. The stove of claim 4, wherein the at least one type of alkali metal ion is selected from the group consisting of Na+, Li+, K+ and combinations thereof. 23. The stove of claim 4, wherein the exchange depth is at most 300 μm. 24. The stove of claim 4, wherein the thickness of the pane ranges from 2 to 7 mm. 25. The stove of claim 4, wherein the thickness of the pane ranges from 2.8 to 5 mm. 26. The cooker or fire screen or flue insert of claim 1, further comprising a second pane of glass and wherein the glass that comprises at least one type of alkali metal ion is positioned to be in direct contact with the hot atmosphere. 27. The oven of claim 2, further comprising a second pane of glass and wherein the glass that comprises at least one type of alkali metal ion is positioned to be in direct contact with the hot atmosphere. 28. The stove of claim 4, further comprising a second pane of glass and wherein the glass that comprises at least one type of alkali metal ion is positioned to be in direct contact with the hot atmosphere. 29. The cooker or fire screen or flue insert of claim 1, wherein the glass separates two gaseous atmospheres at different temperatures, wherein the first gaseous atmosphere is at a temperature from 300 to 530° C. and the second gaseous atmosphere is at a temperature of at least 50° C. below the first gaseous atmosphere. 30. The oven of claim 2, wherein the glass separates two gaseous atmospheres at different temperatures, wherein the first gaseous atmosphere is at a temperature from 300 to 530° C. and the second gaseous atmosphere is at a temperature of at least 50° C. below the first gaseous atmosphere. 31. The stove of claim 4, wherein the glass separates two gaseous atmospheres at different temperatures, wherein the first gaseous atmosphere is at a temperature from 300 to 530° C. and the second gaseous atmosphere is at a temperature of at least 50° C. below the first gaseous atmosphere. 32. The cooker or fire screen or flue insert of claim 1, wherein the pane of glass is positioned inside of the cooker or fire screen or flue. 33. The oven of claim 2, wherein the pane of glass is positioned inside of the oven. 34. The stove of claim 4, wherein the pane of glass is positioned inside of the stove. 35. A glass comprising at least one type of alkali metal ion, an alkali-metal-ion concentration gradient from its surface over an exchange depth of at least 100 μm, a surface stress of at least 200 MPa and a strain point in the core of at least 550° C., wherein the glass has an interdiffusion coefficient, at 490° C., of exchanged alkali metal ions, of less than 2×10−15 m2·s−1. 36. The glass of claim 35, wherein the glass comprises an interdiffusion coefficient, at 400° C., of alkali metal ions exchanged, of at most 9×10−17 m2·s−1. 37. The glass of claim 36, wherein the ratio of the interdiffusion coefficient, at 490° C., of the exchanged alkali metal ions, to the interdiffusion coefficient, at 400° C., of the exchanged alkali metal ions, is at least 20:1. 38. The glass of claim 35, wherein the strain point in the core is at least 570° C. 39. The glass of claim 35, wherein the at least one type of alkali metal ion is selected from the group consisting oft Na'0, Li+, K+ and combinations thereof. 40. The glass of claim 35, wherein the exchange depth is at most 300 μm. 41. The glass of claim 35 in the form of a pane. 42. The pane of claim 41, wherein the thickness of the pane ranges from 2 to 7 mm. 43. A door comprising the pane of claim 41.
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이 특허에 인용된 특허 (11)
Forker ; Jr. Ray B. (Beaver Dams NY) Panzarino Joseph N. (Corning NY), Chemical strengthening method.
Aratani Shinichi (Mie JPX) Katano Masaaki (Mie JPX) Mizoguchi Takeshi (Mie JPX), Method of strengthening glass article formed of float glass by ion exchange.
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