Aspirating face seal assembly for a rotary machine

What is claimed is: 1. A seal assembly for a rotary machine, the seal assembly configured to be positioned between a rotating component and a stationary component of the rotary machine, the seal assembly comprising: a seal bearing having a face that opposes the rotating component of the rotary machine; and a slide device coupled with the seal bearing, the slide device configured to be positioned between a first fluid pressure volume in the rotary machine and a different, second fluid pressure volume in the rotary machine, the slide device configured to axially move parallel to a rotation axis of the rotary machine and toward the rotating component of the rotary machine responsive to pressurization of the rotary machine, wherein the slide device includes one or more cross-over ports and the seal bearing includes one or more feed ports, wherein the one or more feed ports extend through the face of the seal bearing to direct a fluid toward the face of the seal bearing to form one or more aerostatic portions of a film bearing between the face of the seal bearing and the rotating component of the rotary machine using the fluid and a pressure differential in the fluid between a higher fluid pressure side of the seal assembly and a lower fluid pressure side of the seal assembly, and wherein the face of the seal bearing or the rotating component is a non-planar surface that, during rotating motion of the rotating component relative to the face of the seal bearing, forms one or more aerodynamic portions of the film bearing between the face of the seal bearing and the rotating component of the rotary machine, wherein the one or more feed ports extend through the face of the seal bearing within one or more recessed grooves extending into the face of the seal bearing. 2. The seal assembly of claim 1 , wherein the face of the seal bearing or the rotating component includes one or more recessed grooves that extend into the seal bearing or the rotating component in directions oriented away from the rotating component of the rotary machine or the face of the seal bearing in axial directions that are parallel to the rotation axis of the rotary machine. 3. The seal assembly of claim 1 , wherein the seal bearing or the rotating component includes one or more recessed grooves having edges axially extending into the face of the seal bearing or the rotating component away from the rotating component of the rotary machine or the rotating component, the edges of the one or more recessed grooves adjacent to each other and intersecting each other to form a corner. 4. The seal assembly of claim 3 , wherein the corner formed by the edges in the one or more recessed grooves is configured to compress a fluid that moves through the slide device and the seal bearing from the first fluid pressure volume to the second fluid pressure volume via the one or more feed ports, the fluid compressed at the corner in the one or more recessed grooves between the face of the seal bearing and the rotary component of the rotary machine. 5. The seal assembly of claim 1 , wherein the face of the seal bearing or the rotating component includes elongated segments of spiral grooves recessed into the face of the seal bearing or the rotating component away from the rotating component of the rotary machine or away from the face of the seal bearing. 6. The seal assembly of claim 1 , wherein the face of the seal bearing includes polygon-shaped grooves recessed into the face of the seal bearing or the rotating component away from the rotating component of the rotary machine or away from the face of the seal bearing. 7. The seal assembly of claim 6 , wherein the polygon-shaped grooves include two or more triangle-shaped recessed portions of the face. 8. The seal assembly of claim 7 , wherein at least two of the triangle-shaped recessed portions of the face overlap each other. 9. The seal assembly of claim 8 , wherein the polygon-shaped grooves include Rayleigh steps recessed into the face of the seal bearing or the rotating component. 10. The seal assembly of claim 1 , wherein the face of the seal bearing or the rotating component is an undulating surface. 11. The seal assembly of claim 10 , wherein the undulating surface is on the face of the seal bearing and includes crests that axially extend toward the rotating component of the rotary machine along axial directions that are parallel to the rotation axis of the rotary machine, the undulating surface of the face also including troughs that axially extend away from the rotating component of the rotary machine along opposite axial directions that are parallel to the rotation axis of the rotary machine. 12. The seal assembly of claim 10 , wherein the undulating surface is on the rotating component and includes troughs that axially extend away from the slide device along axial directions that are parallel to the rotation axis of the rotary machine, the undulating surface also including crests that axially extend toward from the slide device along opposite axial directions that are parallel to the rotation axis of the rotary machine. 13. A seal assembly for a rotary machine, the seal assembly configured to be positioned between a rotating component and a stationary component of the rotary machine, the seal assembly comprising: a seal bearing having a face that opposes the rotating component of the rotary machine; and a slide device coupled with the seal bearing, the slide device configured to be positioned between a first fluid pressure volume in the rotary machine and a different, second fluid pressure volume in the rotary machine, the slide device configured to axially move parallel to a rotation axis of the rotary machine and toward the rotating component of the rotary machine responsive to pressurization of the rotary machine, wherein the slide device includes cross-over ports and one or more of the seal bearing or the rotating component includes feed ports, wherein the feed ports are positioned to direct a fluid through the one or more of the seal bearing or the rotating component and form an aerostatic film bearing between the face of the seal bearing and the rotating component of the rotary machine using the fluid and a pressure differential in the fluid between a higher fluid pressure side of the seal assembly and a lower fluid pressure side of the seal assembly, and wherein the feed ports form differently-sized openings through one or more of the rotating component or the face of the seal bearing, wherein the openings formed by the feed ports on the face of the seal bearing have different internal dimensions at the face of the seal bearing. 14. The seal assembly of claim 13 , wherein the feed ports extend through the seal bearing. 15. The seal assembly of claim 13 , wherein the openings formed by the feed ports on the face of the seal bearing form a repeating alternating pattern of larger openings and smaller openings. 16. The seal assembly of claim 13 , wherein the differently-sized openings include larger openings and smaller openings, the larger openings are effective to direct fluid through the face of the seal bearing for thicker aerostatic films between the face of the seal bearing and the rotating component of the rotary machine, the smaller openings are effective to direct fluid through the face of the seal bearing for thinner aerostatic films between the face of the seal bearing and the rotating component of the rotary machine. 17. A seal assembly for a rotary machine, the seal assembly configured to be positioned between a rotating component and a stationary component of th