Claims
- 1. In a turbine having arcuate inner and outer shells and a rotor within said outer and inner shells having an axis, a method for aligning the inner and outer shells relative to one another, comprising the steps of:(a) supporting an alignment fixture having a pair of mounts and a frame movable relative to said mounts from said outer shell by fixing said mounts to said outer shell; (b) supporting said inner shell within said outer shell by said alignment fixture by fixing said mounts to said outer shell; and (c) adjusting said inner shell relative to said outer shell by moving said mounts and said frame relative to one another.
- 2. A method according to claim 1 wherein the step of adjusting includes displacing the inner shell relative to the outer shell in a plane perpendicular to the axis of the rotor.
- 3. A method according to claim 1 wherein the step of adjusting includes displacing the inner shell relative to the outer shell in a direction parallel to said axis.
- 4. A method according to claim 1 wherein the step of adjusting includes displacing said inner shell relative to said outer shell about an axis perpendicular to the rotor axis.
- 5. A method according to claim 1 wherein the step of adjusting includes displacing the inner shell relative to the outer shell in planes perpendicular and parallel to the rotor axis.
- 6. A method according to claim 1 including passing support members carried by said frame through openings in said outer shell for engaging said inner shell and supporting said inner shell by said frame.
- 7. A method according to claim 1 including subsequent to step (c), transferring support of said inner shell from said alignment fixture to said outer shell.
- 8. A method of disassembling a turbine having a pair of arcuate upper and lower outer shell sections and a pair of arcuate upper and lower inner shell sections concentric about a rotor having an axis and without removing the rotor from the turbine, comprising the steps of:(a) removing the upper outer shell section; (b) removing the upper inner shell section; (c) supporting a fixture from said lower outer shell section; (d) transferring support of said lower inner shell section from said lower outer shell section to said fixture; (e) subsequent to step (c), securing roller assemblies to said lower outer shell section for engaging said lower inner shell section; (f) transferring support for said lower inner shell section from said fixture to said roller assemblies and said lower outer shell section; (g) rotating said lower inner shell section about said axis to a location above said lower outer shell section; and (h) subsequent to step (g), removing said lower inner shell section.
- 9. A method according to claim 8 wherein the inner and outer shell sections are initially secured to one another by an array of circumferentially spaced connecting elements engaging between said inner and outer shell sections including, prior to steps (a) and (b), disengaging the elements engaging between said upper outer shell section and said upper inner shell section; prior to step (c), removing certain but not all elements engaging between said lower outer shell section and said lower inner shell section, leaving access openings through said lower outer shell; and inserting support members carried by said fixture through said access openings to engage and support said lower inner shell section by said fixture.
- 10. A method according to claim 8 including subsequent to step (e), removing said support members from supporting engagement with said lower inner shell section through said access openings and securing additional roller assemblies to said lower outer shell section and in said access opening for engagement with said lower inner shell section.
- 11. A method according to claim 8 including, prior to step (g), securing a dummy inner shell section to said lower inner shell section, and rotating said lower inner shell section and said dummy section about said axis to locate said lower inner shell section about said lower outer shell section and said dummy section in said lower outer shell section.
- 12. A method according to claim 11 including reassembling the turbine, the step of reassembling the turbine including securing said lower inner shell section to said dummy section in a location above said outer shell section, rotating said dummy shell and said lower inner shell section to locate said lower inner shell section within said lower outer shell section and said dummy section above said lower outer shell section, removing said dummy section, securing said upper inner shell section to said lower inner shell section and securing said upper outer shell section to said lower outer shell section.
- 13. An alignment fixture for securement to an outer shell of a turbine having inner and outer shells secured to one another about a rotor having an axis, comprising:a pair of mounts for securement to the outer shell; a frame having support members movable thereon between (i) a support position passing through access openings of the outer shell and in engagement with the inner shell to support the inner shell from the frame and (ii) a non-support position spaced from the inner shell; and at least one adjustable element interconnecting said frame and at least one of said mounts for adjusting the position of the frame relative to the outer shell in one of an axial direction or in a plane normal to the axis of the rotor, when said support members lie in said support position, thereby adjusting the inner shell relative to the outer shell.
- 14. A fixture according to claim 13 including a pair of said elements connected to said mounts, respectively, and said frame, whereby adjustment of one of said elements causes movement of said frame to adjust the inner shell relative to the outer shell in said plane normal to the rotor axis.
- 15. A fixture according to claim 13 wherein said one element is connected between one of said mounts and said frame on one side of a vertical plane through the rotor axis, another element connected between another of said mounts and said frame on an opposite side of said frame from said one element, whereby adjustment of one of said elements causes movement of said frame to adjust the inner shell relative to the outer shell in said plane normal to the rotor axis.
- 16. A fixture according to claim 13 wherein said one element adjusts the position of the frame relative to the outer shell in said axial direction, another element interconnecting said frame and one of said mounts for adjusting the position of the frame relative to the outer shell in said plane normal to the axis of the rotor.
- 17. A method according to claim 1 wherein step (b) includes displacing a pair of support members along said frame into engagement with said inner shell.
- 18. A method according to claim 17 wherein the step of adjusting includes displacing the inner shell relative to the outer shell in a plane perpendicular to the axis of the rotor, in a direction parallel to said axis and about an axis perpendicular to the rotor axis.
- 19. A method according to claim 1 wherein step (c) includes moving said mounts and said frame relative to one another externally of said outer shell.
- 20. An alignment fixture for securement to an outer shell of a turbine having inner and outer shells secured to one another about a rotor having an axis, comprising:a pair of mounts for securement to the outer shell; a frame having support members movable thereon between (i) a support position passing through access openings of the outer shell and in engagement with the inner shell to support the inner shell from the frame and (ii) a non-support position spaced from the inner shell; and a first pair of axially spaced forward and aft elements connected between one of said mounts and said frame on one side of a vertical plane through said rotor axis, a second pair of axially spaced forward and aft elements connected between another of said mounts on an opposite side of said vertical axis, whereby differential adjustment of said forward and aft elements, respectively, causes movement of said frame to incline the inner shell relative to the outer shell in said vertical plane.
- 21. A fixture according to claim 20 including a further element connected between one of said mounts and said frame for adjusting the position of the frame relative to the outer shell in an axial direction.
- 22. An alignment fixture for securement to an outer shell of a turbine having inner and outer shells secured to one another about a rotor having an axis, comprising:a pair of mounts for securement to the outer shell; a frame having support members movable thereon between (i) a support position passing through access openings of the outer shell and in engagement with the inner shell to support the inner shell from the frame and (ii) a non-support position spaced from the inner shell; and a first pair of axially spaced forward and aft elements connected between one of said mounts and said frame on one side of a vertical plane through said rotor axis, a second pair of axially spaced forward and aft elements connected between one of said mounts and said frame on an opposite side of said vertical plane for adjusting the position of the frame relative to the outer shell thereby adjusting the inner shell relative to the outer shell, a fifth element connected between one of said mounts and said frame for adjusting the position of the frame relative to the outer shell in one of axial and lateral directions thereby adjusting the inner shell relative to the outer shell in one of said axial and lateral directions.
- 23. A fixture according to claim 21 wherein said fifth element adjusts the position of the frame relative to the outer shell to adjust the position of the inner shell relative to the outer shell in an axial direction and a sixth element connected between one of said mounts and said frame for adjusting the position of the frame relative to the outer shell to adjust the position of the inner shell relative to the outer shell in a direction normal to said axial direction.
Government Interests
The Government of the United States of America has rights in this invention pursuant to COOPERATIVE AGREEMENT NO. DE-FC21-95MC31176 awarded by the U.S. Department of Energy.
US Referenced Citations (5)