Coated seal housing

The invention claimed is: 1. A seal housing disposed to support an axially facing seal segment, the seal housing comprising: a substrate having an inner annular surface, an axially facing substrate surface, and a corner feature at an intersection of the inner annular surface and the axially facing substrate surface, the corner feature including an annular notch in the inner annular surface, and a chamfer extending from the annular notch to the axially facing substrate surface; and a coating formed on the axially facing substrate surface and into the corner feature of the substrate, and having a coating surface, parallel to the axially facing substrate surface, that terminates at the inner annular surface and abuts the seal segment; wherein the annular notch comprises: an axially facing notch surface extending radially outward from the inner annular surface; and an annular notch surface extending axially towards the chamfer from the axially facing notch surface. 2. The seal housing of claim 1 , wherein the chamfer is a frustoconical surface extending from the annular notch surface to the axially facing substrate surface, and angled radially outward and axially away from the axially facing notch surface. 3. The seal housing of claim 2 , wherein the frustoconical surface is angled at 45° with respect to the annular notch surface and the axially facing substrate surface. 4. The seal housing of claim 1 , wherein the coating surface is separated from the axially facing substrate surface by a coating thickness, and wherein the axially facing notch surface has a radial extent greater than or equal to the coating thickness. 5. The seal housing of claim 1 , wherein the coating surface is separated from the axially facing substrate surface by a coating thickness, and wherein the annular notch surface has an axial extent greater than or equal to the coating thickness. 6. A method of forming an edge of an annular workpiece, the method comprising: fabricating a substrate having an annular surface, an axially facing substrate surface, and a corner feature at the intersection of the annular surface and the axially facing substrate surface, the corner feature including an annular notch in the annular surface, and a chamfer extending from the annular notch to the axially facing substrate surface; depositing coating material into the corner feature and on the axially facing substrate surface, axially out to at least a target plane parallel to the axially facing substrate surface, via spray deposition at a spray orientation obtuse to the axially facing substrate surface and at least an axial surface of the annular notch; and removing excess coating material beyond the target plane, such that the coating material has a uniform first axial thickness along the axially facing substrate surface, and greater thickness within the corner feature; wherein the annular notch comprises: an axially facing notch surface extending at a right angle from the annular surface; and an annular notch surface extending at a right angle from the axially facing notch surface to the chamfer. 7. The method of claim 6 , wherein the chamfer extends frustoconically from the annular notch surface to the axially facing substrate surface. 8. The method of claim 6 , wherein the spray orientation is angled at more than 60° with respect to the axially facing substrate surface. 9. The method of claim 6 , wherein the chamfer forms a 45° angle with respect to the annular notch surface and the axially facing substrate surface. 10. The method of claim 9 , wherein the spray orientation is angled at less than 45° with respect to the chamfer. 11. A seal assembly comprising: a rotating shaft; a seal segment situated on and reciprocatable with the rotating shaft, the seal segment having an axially facing seal surface terminating at a first inner radial extent; a seal housing situated adjacent the seal segment and around the rotating shaft, the seal housing comprising: a substrate terminating at a second inner radial extent inboard of the first inner radial extent, the substrate having an annular notch at a corner adjacent the seal segment, the annular notch extending radially outward from the second inner radial extent, inboard and axially forward of a corner chamfer; and a coated surface deposited atop the substrate, covering the annular notch and the corner chamfer, abutting the axially facing seal surface and terminating at the second inner radial extent. 12. The seal assembly of claim 11 , wherein the seal segment is a gas turbine engine bearing seal. 13. The seal assembly of claim 11 , wherein coating is a high velocity oxygen fuel coating. 14. The seal assembly of claim 11 , wherein the seal segment is formed at least partially of carbon. 15. The seal assembly of claim 11 , wherein the annular notch has a rectangular cross-section. 16. The seal assembly of claim 15 , wherein the substrate comprises: a primary coated axial surface parallel to the axial seal face; an inner annular surface situated at the second inner radial extent; an axially facing notch surface parallel to and inboard of the coated axial surface; an annular notch surface situated parallel to and outboard of the inner annular surface, and extending axially from the axially facing notch surface to the corner chamfer, such that the axially facing notch surface and the annular notch surface together define the rectangular cross-section of the notch. 17. The seal assembly of claim 11 , wherein the seal segment is permitted to displace radially up to a deflection distance with respect to the seal housing. 18. The seal assembly of claim 17 , wherein the deflection distance is less than a radial separation between the first inner radial extent and the second inner radial extent.