A brazing method is disclosed. The brazing method includes providing a substrate, providing at least one groove in the substrate, providing a support member, positioning the support member over the at least one groove in the substrate, providing a braze material, applying the braze material over the
A brazing method is disclosed. The brazing method includes providing a substrate, providing at least one groove in the substrate, providing a support member, positioning the support member over the at least one groove in the substrate, providing a braze material, applying the braze material over the support member to form an assembly, and heating the assembly to braze the braze material to the substrate. Another brazing method includes providing a preform, providing a wire mesh, pressing the wire mesh into the preform, heating the preform to form a braze material including the wire mesh, providing a substrate, providing at least one groove in the substrate, applying the braze material over the at least one groove in the substrate, then brazing the braze material to the substrate.
대표청구항▼
1. A brazing method, comprising: providing a braze material;forming at least one groove in the braze material;securing support members within the at least one groove to form a braze assembly;providing a substrate;applying the braze assembly over the substrate; andbrazing the braze assembly to the su
1. A brazing method, comprising: providing a braze material;forming at least one groove in the braze material;securing support members within the at least one groove to form a braze assembly;providing a substrate;applying the braze assembly over the substrate; andbrazing the braze assembly to the substrate to form a brazed article such that the braze material is directly bonded to the substrate;wherein each of the at least one grooves forms a cooling microchannel in the brazed article. 2. The brazing method of claim 1, comprising maintaining the braze material above the at least one groove without the braze material entering the groove and forming a convex border. 3. The brazing method of claim 1, wherein the braze material comprises a nickel-based braze alloy. 4. The brazing method of claim 1, wherein the braze material includes a coefficient of thermal expansion compatible with the coefficient of thermal expansion of the substrate. 5. The brazing method of claim 1, comprising selecting the support members and the substrate to be made of a common material, the common material having a melting temperature above a brazing temperature of the braze material. 6. The brazing method of claim 1, comprising shaping the braze assembly to conform with a shape of the substrate prior to applying the braze assembly over the substrate. 7. The brazing method of claim 1, wherein the cooling microchannels are formed without grooves in the substrate. 8. The brazing method of claim 1, wherein applying the braze assembly over the substrate comprises positioning at least one of the grooves in the braze material to correspond with at least one groove formed in the substrate. 9. The brazing method of claim 1, wherein applying the braze assembly over the substrate comprises positioning at least one of the grooves in the braze material to not correspond with at least one groove in the substrate such that a separate microchannel is formed by the at least one groove in the braze material or the at least one groove in the substrate. 10. The brazing method of claim 1, wherein the brazing comprises vacuum brazing. 11. The brazing method of claim 1, wherein the brazing comprises atmospheric brazing. 12. The brazing method of claim 1, wherein the substrate comprises a nickel-based alloy. 13. The brazing method of claim 1, wherein the substrate comprises a cobalt-based alloy. 14. The brazing method of claim 1, wherein the support members are ceramics. 15. The brazing method of claim 1, wherein the support members are microtubes. 16. The brazing method of claim 15, wherein the microtube forms the microchannel in the brazed article. 17. A brazing method, comprising: providing a braze material;forming at least one groove in the braze material;securing support members within the at least one groove to form a braze assembly;providing a substrate;applying the braze assembly over the substrate; andbrazing the braze assembly to the substrate to form a brazed article;wherein each of the at least one grooves forms a cooling microchannel in the brazed article; andwherein the securing of the support members includes arranging and disposing the support members to reduce at least one of slumping, sagging, and drooping of the braze material into the groove during the brazing of the braze assembly to the substrate. 18. The brazing method of claim 17, comprising shaping the braze assembly to conform with a shape of the substrate prior to applying the braze assembly over the substrate. 19. A brazing method, comprising: providing a braze material;forming at least one groove in the braze material;securing support members within the at least one groove to form a braze assembly;providing a substrate having at least one groove formed therein;applying the braze assembly over the substrate;brazing the braze assembly to the substrate to form a brazed article such that the braze material is directly bonded to the substrate; andmaintaining the braze material above the at least one groove without the braze material entering the groove and forming a convex border;wherein each of the at least one grooves forms a cooling microchannel in the brazed article. 20. The brazing method of claim 19, wherein applying the braze assembly includes positioning at least one of the grooves in the braze material such that it does not correspond with the at least one groove formed in the substrate, each non-corresponding groove in the braze material and the substrate forming a separate cooling microchannel.
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