Balance piston seal centering

We claim: 1. A balance piston seal assembly for a balance piston of a compressor, comprising: a balance piston seal configured to be disposed about the balance piston such that an inner radial surface of the balance piston seal and an outer radial surface of the balance piston define a radial clearance therebetween; a stationary support configured to be coupled or integral with a casing of the compressor; and a gripping assembly disposed between the balance piston seal and the stationary support, the gripping assembly configured to secure the balance piston seal with the stationary support and to maintain concentricity between the balance piston seal and the balance piston during thermal radial expansion of the balance piston seal relative to the balance piston. 2. The balance piston seal assembly of claim 1 , wherein the gripping assembly comprises a Hirth coupling disposed between the balance piston seal and the stationary support and configured to maintain concentricity between the balance piston seal and the balance piston during thermal radial expansion of the balance piston seal relative to the balance piston. 3. The balance piston seal assembly of claim 1 , wherein the gripping assembly comprises: a first annular ring coupled with the balance piston seal; and a second annular ring coupled with the stationary support and configured to engage with the first annular ring to secure the first annular ring with the stationary support and maintain concentricity between the balance piston and the balance piston seal. 4. The balance piston seal assembly of claim 3 , wherein the first annular ring is coupled with the balance piston seal via a first mechanical fastener, and the second annular ring is coupled with the stationary support via a second mechanical fastener. 5. The balance piston seal assembly of claim 3 , wherein the balance piston seal and the first annular ring coupled therewith are configured to expand radially outward relative to the second annular ring. 6. The balance piston seal assembly of claim 3 , wherein the second annular body defines a plurality of grooves, and the first annular body defines a plurality of axial splines configured to engage with the plurality of grooves. 7. The balance piston seal assembly of claim 6 , wherein the plurality of axial splines are selected from the group consisting of involute splines, prismatic splines, axially straight splines, and combinations thereof. 8. A compressor, comprising: a casing; a rotary shaft disposed in the casing and configured to be driven by a driver; an impeller coupled with and configured to be driven by the rotary shaft; a balance piston integral with the impeller and configured to balance an axial thrust generated by the impeller; a balance piston seal disposed about the balance piston such that an inner radial surface of the balance piston seal and an outer radial surface of the balance piston define a radial clearance therebetween; and a gripping assembly disposed between the balance piston seal and the casing, the gripping assembly configured to secure the balance piston seal with the casing and maintain concentricity between the balance piston seal and the balance piston during thermal expansion of the balance piston seal relative to the balance piston. 9. The compressor of claim 8 , further comprising an axial inlet coupled or integral with the casing. 10. The compressor of claim 9 , wherein the axial inlet and the casing at least partially define a fluid pathway of the compressor, the fluid pathway comprising: an inlet passageway configured to receive a process fluid comprising carbon dioxide; an impeller cavity fluidly coupled with the inlet passageway; a diffuser fluidly coupled with the impeller cavity; and a volute fluidly coupled with the diffuser. 11. The compressor of claim 10 , wherein the impeller is configured to receive the process fluid from the inlet passageway and discharge the process fluid to the diffuser at an absolute Mach number of about 1.0 or greater. 12. The compressor of claim 11 , wherein the compressor is configured to provide a compression ratio of at least about 8.1. 13. The compressor of claim 12 , wherein the gripping assembly comprises a Hirth coupling disposed between the balance piston seal and the casing and configured to maintain concentricity between the balance piston seal and the balance piston during thermal radial expansion of the balance piston seal relative to the balance piston. 14. The compressor of claim 12 , wherein the gripping assembly comprises: a first annular ring coupled with the balance piston seal; and a second annular ring coupled with the casing and configured to engage with the first annular ring to secure the first annular ring with the casing and maintain concentricity between the balance piston and the balance piston seal. 15. The compressor of claim 14 , wherein the balance piston seal and the first annular ring coupled therewith are configured to expand radially outward relative to the second annular ring. 16. The compressor of claim 14 , wherein the second annular body defines a plurality of grooves, and the first annular body defines a plurality of teeth configured to engage with the plurality of grooves. 17. The compressor of claim 16 , wherein the plurality of teeth are selected from the group consisting of involute splines, prismatic splines, axially straight splines, and combinations thereof. 18. The compressor of claim 16 , wherein respective side walls of each of the plurality of teeth are radially aligned with a central axis of the first annular ring. 19. A compression system, comprising: a driver; and a compressor coupled with and configured to be driven by the driver, the compressor comprising: a casing; an inlet coupled or integral with the casing, the inlet and the casing at least partially defining a fluid pathway of the compressor, the fluid pathway configured to receive a process fluid; a rotary shaft disposed in the casing and configured to couple the compressor with the driver; an impeller coupled with and configured to be rotated by the driver via the rotary shaft; a balance piston integral with the impeller and configured to balance an axial thrust generated by the rotation of the impeller; a balance piston seal disposed radially outward of the balance piston such that the balance piston seal and the balance piston define a radial clearance therebetween; and a gripping assembly disposed between the balance piston seal and the casing, the gripping assembly configured to secure the balance piston seal with the casing and maintain concentricity between the balance piston seal and the balance piston during thermal expansion of the balance piston seal. 20. The compression system of claim 19 , wherein the impeller is configured to discharge the process fluid to a diffuser at an absolute Mach number of about 1.0 or greater, and wherein the compressor is configured to provide a compression ratio of at least about 8:1.