Low deflection bi-metal rotor seals

We claim: 1. A seal assembly, comprising: an annular division wall having an outside surface, an inside surface, a first axial end surface disposed adjacent a high-pressure side of the seal assembly, and a second axial end surface disposed adjacent a low-pressure side of the seal assembly; a carrier ring disposed adjacent the inside surface of the annular division wall; and a sealing substrate metallurgically-bonded to an inner-most surface of the carrier ring, the sealing substrate forming a seal surface, wherein the first axial end surface of the annular division wall defines a first opening in direct fluid communication with the high-pressure side, the carrier ring defines a second opening in direct fluid communication with the high-pressure side of the seal assembly and radially offset from the first opening, the first opening and the second opening are in fluid communication via at least one gas conduit that extends through the annular division wall and the carrier ring, and the at least one gas conduit is configured to inject a high-pressure process gas from the high-pressure side of the seal assembly adjacent the carrier ring. 2. The seal assembly of claim 1 , further comprising a gap defined between the inside surface of the annular division wall and the carrier ring, wherein the carrier ring is configured to translate axially in response to a pressure buildup on the high-pressure side of the seal assembly. 3. The seal assembly of claim 1 , wherein the annular division wall and the carrier ring are made of a material exhibiting a high modulus of elasticity. 4. The seal assembly of claim 3 , wherein the material is a ferrous alloy, a nickel alloy, or a titanium alloy. 5. The seal assembly of claim 1 , wherein the sealing substrate is made of an abradable material. 6. The seal assembly of claim 5 , wherein the abradable material is an aluminum alloy, a copper alloy, a powder metal alloy, a graphite-containing ferrous alloy, or a polymer. 7. The seal assembly of claim 1 , wherein the sealing substrate is metallurgically-bonded to the carrier ring via hot isostatic pressing techniques. 8. The seal assembly of claim 1 , wherein the sealing substrate is metallurgically-bonded to the carrier ring via explosive cladding or laser cladding. 9. The seal assembly of claim 1 , wherein the sealing substrate is metallurgically-bonded to the carrier ring via centrifugal casting. 10. The seal assembly of claim 1 , wherein the sealing substrate is metallurgically-bonded to the carrier ring by welding or brazing. 11. The seal assembly of claim 1 , further comprising a balance piston seal. 12. A seal assembly, comprising: an annular division wall having an outside surface, coupled to a casing of a turbomachine, an inside surface, a first axial end surface disposed adjacent a high-pressure side of the seal assembly, and a second axial end surface disposed adjacent a low-pressure side of the seal assembly; a carrier ring disposed adjacent the inside surface of the annular division wall; an abradable sealing substrate metallurgically-bonded to the carrier ring; and a seal surface formed into the abradable sealing substrate, the seal surface being disposed proximate a rotor and maintained substantially parallel thereto during operation of the turbomachine, wherein the first axial end surface of the annular division wall defines a first opening in direct fluid communication with the high-pressure side, the carrier ring defines a second opening in direct fluid communication with the high-pressure side of the seal assembly, the second opening being axially aligned and radially offset from the first opening, the first opening and the second opening are in fluid communication via at least one gas conduit that extends through the annular division wall and the carrier ring, and the at least one gas conduit is configured to inject a high-pressure process gas from the high-pressure side of the seal assembly adjacent the carrier ring. 13. The seal assembly of claim 12 , further comprising a gap defined between the inside surface of the annular division wall and the carrier ring, wherein the carrier ring is configured to translate axially with respect to the rotor in response to a pressure buildup on the high-pressure side of the seal assembly. 14. The seal assembly of claim 12 , wherein the seal surface has teeth for a labyrinth seal or perforations for a hole-pattern seal. 15. The seal assembly of claim 12 , wherein the annular division wall and the carrier ring are made of a ferrous alloy, a nickel alloy, or a titanium alloy. 16. The seal assembly of claim 12 , wherein the abradable sealing substrate is made of an aluminum alloy, a copper alloy, a powder metal alloy, a graphite-containing ferrous alloy, or a polymer. 17. The seal assembly of claim 12 , wherein the abradable sealing substrate is metallurgically-bonded to the carrier ring via hot isostatic pressing, explosive cladding, laser cladding, centrifugal casting, welding, or brazing.