A process for repairing combined heavy erosion and thermal fatigue cracks and/or other defects, such as large cracks, in a high temperature superalloy component, such as a vane in a turbine section of a gas turbine engine, that does not require mechanical grinding to prepare the defect site. The pro
A process for repairing combined heavy erosion and thermal fatigue cracks and/or other defects, such as large cracks, in a high temperature superalloy component, such as a vane in a turbine section of a gas turbine engine, that does not require mechanical grinding to prepare the defect site. The process includes depositing a loose finely granulated superalloy powder or a low viscosity superalloy slurry in the crack up to a suitable level and then depositing a superalloy putty layer on the superalloy powder or slurry at the top of the crack A braze putty layer is then deposited over the superalloy putty layer and the component is sintered in a vacuum furnace to harden the superalloy putty and powder or slurry to repair the defect.
대표청구항▼
1. A method for repairing a defect in a component, said defect including a crack having a top portion that is wide enough to accept a superalloy putty and a bottom portion that is not wide enough to accept the superalloy putty, said method comprising: depositing a granulated loose superalloy powder
1. A method for repairing a defect in a component, said defect including a crack having a top portion that is wide enough to accept a superalloy putty and a bottom portion that is not wide enough to accept the superalloy putty, said method comprising: depositing a granulated loose superalloy powder with a maximum powder size that is smaller than the crack, including the bottom portion of the crack, or a superalloy slurry that is a combination of the granulated loose superalloy powder and an organic binder in the crack;depositing a superalloy putty layer on top of the superalloy loose powder or the superalloy slurry so that the superalloy putty layer extends above a top surface of the component;depositing a braze putty layer on top of the superalloy putty layer; andsintering the superalloy powder or the superalloy slurry and the superalloy putty to harden. 2. The method according to claim 1 further comprising providing mechanical vibration to cause the superalloy powder to further fill the crack. 3. The method according to claim 1 wherein depositing the granulated loose superalloy powder or the superalloy slurry includes depositing the granulated loose superalloy powder or the superalloy slurry to a level within the crack that fills the bottom portion that is not wide enough to accept the superalloy putty, but does not fill the top portion of the crack that is wide enough to accept the superalloy putty. 4. The method according to claim 1 wherein depositing the granulated loose superalloy powder or the superalloy slurry includes depositing the granulated loose superalloy powder or the superalloy slurry so that it completely fills the crack. 5. The method according to claim 1 wherein depositing the granulated loose superalloy powder or the superalloy slurry includes depositing the granulated loose superalloy powder if the crack does not extend completely through the component and depositing the superalloy slurry if the crack does extend completely through the component. 6. The method according to claim 1 wherein the superalloy putty is a mixture of a superalloy powder and an organic binder with higher viscosity than the granulated loose superalloy powder or the superalloy slurry, and wherein depositing the loose granulated superalloy powder or the superalloy slurry includes depositing a superalloy powder or a superalloy slurry including a different superalloy than the superalloy in the superalloy putty. 7. The method according to claim 1 wherein the superalloy putty is a mixture of a superalloy powder and an organic binder, and wherein depositing the granulated loose superalloy powder or the superalloy slurry includes depositing a superalloy powder or a superalloy slurry including the same superalloy as the superalloy in the superalloy putty. 8. The method according to claim 1 wherein the defect includes a combined erosion cavity with thermal fatigue cracking where the crack extends from a bottom of the erosion cavity. 9. The method according to claim 1 wherein depositing a superalloy putty layer includes depositing the superalloy putty layer within an erosion cavity or on an opening site of the crack of the defect. 10. The method according to claim 1 wherein the defect includes large deep thermal fatigue cracks with a crack opening gap larger than 0.2 mm. 11. The method according to claim 1 wherein the superalloy in the superalloy powder, the superalloy slurry and the superalloy putty are selected from the group consisting of a cast grade nickel, cobalt superalloys, IN738, MM247, Rene 80, Rene 142, IN100, IN939, X40, Alloy 713, Alloy 731, Rene 125, Rene 41 and MM509. 12. The method according to claim 1 wherein the braze putty includes a pure braze putty or a braze-superalloy mixture putty with a braze/superalloy mixing ratio range equal or higher than 70/30. 13. The method according to claim 1 wherein the component is a vane in a gas turbine engine. 14. A method for repairing damage to a vane in a gas turbine engine, said damage including a cavity having a top portion that is wide enough to accept a superalloy putty and a bottom portion that is not wide enough to accept a superalloy putty, said method comprising: depositing a granulated superalloy powder in the damage so that it at least partially fills the bottom portion of the damage;depositing a superalloy putty layer on top of the superalloy powder to fill the top portion of the damage; anddepositing a braze putty layer on top of the superalloy putty layer. 15. The method according to claim 14 further comprising providing mechanical vibration to cause the superalloy powder to further fill the damage. 16. The method according to claim 14 wherein depositing the granulated superalloy powder includes depositing a superalloy powder to a level within the damage that fills the bottom portion, but does not fill the top portion of the damage. 17. The method according to claim 14 wherein depositing the granulated superalloy powder includes depositing the granulated superalloy powder so that it completely fills the damage. 18. The method according to claim 14 wherein the superalloy putty is a mixture of a superalloy powder and an organic binder, and wherein depositing the granulated superalloy powder includes depositing a superalloy powder including a different superalloy than the superalloy in the superalloy putty. 19. The method according to claim 14 wherein the superalloy putty is a mixture of a superalloy powder and an organic binder, and wherein depositing the granulated superalloy powder includes depositing a superalloy powder including the same superalloy as the superalloy in the superalloy putty. 20. The method according to claim 14 wherein the damage includes an erosion cavity and a crack that extends from a bottom of the erosion cavity. 21. The method according to claim 20 wherein depositing a superalloy putty layer includes depositing the superalloy putty layer within the erosion cavity. 22. A method for repairing a crack in a vane in a gas turbine engine, said crack including a cavity having a wide top portion that is wide enough to accept a superalloy putty and a narrow bottom portion that is not wide enough to accept the superalloy putty, said method comprising: depositing a superalloy powder slurry in the crack so that the superalloy powder slurry at least partially fills the narrow bottom portion of the crack;depositing a superalloy putty layer on top of the superalloy powder slurry to fill the wide top portion of the crack where the superalloy putty has a higher viscosity than the superalloy powder slurry; anddepositing a braze putty layer on top of the superalloy putty layer.
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