초록 ▼

A multi-axial pivoting liner within the combustion system of a turbine engine allows the system to work with minimum thermal interference, especially during system operation at transient conditions, by allowing the liner to pivot and slide about its centerline and relative to the turbine scroll. The

A multi-axial pivoting liner within the combustion system of a turbine engine allows the system to work with minimum thermal interference, especially during system operation at transient conditions, by allowing the liner to pivot and slide about its centerline and relative to the turbine scroll. The pivoting liner has the ability to control and minimize air leakage from part to part, for example, from the liner to the turbine scroll and liner to the surrounding structures, during various operating conditions. Additionally, the liner provides for easy assembly with no flow path steps. Finally, the pivoting liner tolerates thermal and mechanical stresses and minimizes thermal wear.

대표청구항 ▼

We claim: 1. A liner for a turbine engine, comprising: a lower joint that movably connects said liner with a combustion gas output receiving device; an upper joint that movably attaches a housing to said liner, said upper joint formed by contacting two substantially spherical surfaces; and said l

We claim: 1. A liner for a turbine engine, comprising: a lower joint that movably connects said liner with a combustion gas output receiving device; an upper joint that movably attaches a housing to said liner, said upper joint formed by contacting two substantially spherical surfaces; and said lower joint providing angular and axial axes of movement for said liner with respect to said combustion gas output receiving device, and said upper joint providing angular axes of movement for said liner with respect to said housing. 2. The liner according to claim 1, wherein said combustion gas output receiving device is a turbine scroll. 3. A liner for a turbine engine, comprising: a lower joint that movably connects said liner with a turbine scroll; an upper joint that movably attaches a housing to said liner, said upper joint formed by contacting two substantially spherical surfaces; said lower joint and said upper joint providing multiple axes of movement for said liner; a vibration damper/thermal and mechanical spring providing a preload to said upper joint in a first direction along a liner centerline, thereby maintaining said upper and lower joint in a connected state; and said upper joint minimizing movement of said liner in a second direction orthogonal to said first direction, so as to minimize leakage, provide wear surface area, and allow angular pivoting motion while constraining motion along a liner axial axis. 4. The liner according to claim 3, further comprising: a forging ring, said forging ring having a first surface for movably contacting said turbine scroll and a second, opposite surface attached to said liner; said first surface forming a substantially spherical point of contact between said liner and said turbine scroll; and said second surface having a diameter smaller than a diameter of said first surface. 5. The liner according to claim 4, further comprising a louver formed from said liner extending toward said turbine scroll past the point of attachment of said second surface and said liner, said louver deflecting hot gases from said lower joint during operation of said turbine engine. 6. The liner according to claim 5, further comprising fine holes in said forging ring. 7. The liner according to claim 3, further comprising an upper joint louver for deflecting air from said upper joint. 8. The liner according to claim 7, further comprising sweep holes in said upper joint, said sweep holes providing cooling for said upper joint and preventing carbon formation at said upper joint. 9. The liner according to claim 3, further comprising a carbon deflector extending into a combustion zone around said upper joint. 10. The liner according to claim 3, wherein a contact angle formed between said liner centerline and said upper joint is optimized to minimize friction force between said two substantially spherical surfaces. 11. A combustor liner for a gas turbine engine comprising: a lower joint that movably connects said liner with a turbine scroll; an upper joint formed by contacting two substantially spherical surfaces that movably attach a housing to said liner; said lower joint and said upper joint providing multiple axes of movement for said liner; a vibration damper/thermal and mechanical spring; said vibration damper/thermal and mechanical spring providing a preload to said upper joint in a first direction along a liner centerline, thereby maintaining said upper joint in a connected state; said upper joint minimizing movement of said liner in a second direction orthogonal to said first direction; a hole in said liner for inserting an igniter; and a grommet for movably holding said igniter in said hole. 12. The liner according to claim 11, further comprising: a forging ring, said forging ring having a first surface for movably contacting said turbine scroll and a second, opposite surface attached to said liner; said first surface forming a substantially spherical circumferential line of contact between said liner and said turbine scroll; and said second surface having a cylindrical diameter smaller than a spherical diameter of said first surface. 13. The liner according to claim 12, further comprising: fine holes in said forging ring; an upper joint louver for deflecting air from said upper joint; and sweep holes in said upper joint, said sweep holes providing cooling for said upper joint and preventing carbon formation on said two substantially spherical surfaces. 14. The liner according to claim 13, further comprising a carbon deflector extending into a combustion zone around said upper joint. 15. A combustor liner for a gas turbine engine of a high performance aircraft comprising: a lower joint that movably connects said liner with a turbine scroll; an upper joint formed by contacting two substantially spherical surfaces that movably attach a housing to said liner; said lower joint and said upper joint providing multiple axes of movement for said liner; a vibration damper/thermal and mechanical spring; said vibration damper/thermal and mechanical spring providing a preload to said upper joint in a first direction along a liner centerline, thereby maintaining said upper joint in a connected state; said upper joint minimizing movement of said liner in a second direction-orthogonal to said first direction; a hole in said liner for inserting an igniter; a grommet for movably holding said igniter in said hole; a forging ring, said forging ring having a first surface for movably contacting said turbine scroll and a second, opposite surface attached to said liner; said first surface forming a substantially circumferential line of contact between said liner and said turbine scroll; said second surface having a spherical diameter smaller than a cylindrical diameter of said first surface; fine holes in said forging ring; an upper joint louver for deflecting air from said upper joint; sweep holes in said upper joint, said sweep holes providing cooling for said upper joint; a contact angle formed between a said liner centerline and said upper joint is optimized to minimize friction force between said first surface and said second surface; and a carbon deflector extending into said combustion zone around said upper joint. 16. A turbine engine comprising a combustor liner having a lower joint that movably connects said liner with a forging ring of a combustion gas output receiving device, said liner able to revolve with a circular line contact along a spherical surface of said forging ring and an upper joint having two substantially spherical surfaces that movably attach a housing to said liner, said lower joint providing angular and axial axes of movement for said liner, and said upper joint providing angular axes of movement for said liner. 17. A turbine engine comprising: a combustor liner having a lower joint that movably connects said liner with a combustion gas output receiving device and an upper joint having two substantially spherical surfaces that movably attach a housing to said liner, said lower joint and said upper joint providing multiple axes of movement for said liner; an atomizer for injecting fuel into a combustor; an igniter for igniting said fuel, said igniter movably attached to said liner; a combustor housing and a combustor cap for encasing at least an upper portion of said combustor liner, said combustor housing and said combustor cap having said atomizer and said igniter mounted therein; and a turbine scroll for receiving combustion gases, said turbine scroll movably attached to said liner. 18. The turbine engine according to claim 17, further comprising: a vibration damper/thermal and mechanical spring; said vibration damper/thermal and mechanical spring providing a preload to said upper joint in a first direction from said atomizer to said turbine scroll, thereby maintaining said upper joint in a connected state; and said upper joint minimizing movement of said liner in a second direction orthogonal to said first direction, so as to minimize air leakage from said liner, provide wear surface area, and allow angular pivoting motion of said liner with respect to said housing while constraining the translational motion of said liner with respect to said upper joint along a liner longitudinal axis. 19. The turbine engine according to claim 18, further comprising: a forging ring, said forging ring having a first surface for movably contacting said turbine scroll and a second, opposite surface attached to said combustor liner; said first surface forming a substantially spherical circumferential line of contact between said liner and said turbine scroll; and said second surface having a cylindrical diameter smaller than a spherical diameter of said first surface. 20. The turbine engine according to claim 19, further comprising: a louver formed from said combustor liner extending past the point of attachment of said second surface and said liner, said louver deflecting hot gases from said lower joint during operation of said turbine engine; and fine holes in said forging ring. 21. The turbine engine according to claim 20, further comprising an upper joint louver for deflecting air from said upper joint. 22. The turbine engine according to claim 21, further comprising sweep holes in said upper joint, said sweep holes providing cooling for said upper joint and preventing carbon formation at said upper joint. 23. The turbine engine according to claim 22, further comprising a carbon deflector extending into a combustion zone around said upper joint. 24. A method for operating a turbine engine, comprising: encasing a combustor zone with a combustor liner; providing a fuel source via an atomizer to said combustor zone; providing an ignition source to said combustor zone; and passing combustion gases through a turbine scroll to drive a turbine; wherein: said combustor liner is a multi-axial pivoting liner having a lower joint that movably connects said liner with said turbine scroll and an upper joint formed by contacting two substantially spherical surfaces that movably attach a housing to said liner, said lower joint providing for angular and axial directions of movement for said liner, and said upper joint providing for angular directions of movement for said liner, wherein inspection or removal of said atomizer is performed without requiring complete disassembly of said combustor liner. 25. A method for operating a turbine engine, comprising: encasing a combustor zone with a combustor liner; providing a fuel source via an atomizer to said combustor zone; providing an ignition source to said combustor zone; and passing combustion gases through a turbine scroll to drive a turbine; wherein said combustor liner is a multi-axial pivoting liner having a lower joint that movably connects said liner with said turbine scroll and an upper joint formed by contacting two substantially spherical surfaces that movably attach a housing to said liner, said lower joint and said upper joint providing multiple axes of movement for said liner, wherein inspection or removal of said atomizer is performed without requiring complete disassembly of said combustor liner; providing a vibration damper/thermal and mechanical spring at said upper joint; said vibration damper/thermal and mechanical spring providing a preload to said upper joint in a first direction from said housing, thereby maintaining said upper joint in a connected state; said upper joint minimizing movement of said liner in said second direction orthogonal to said first direction, so as to minimize leakage, provide wear surface area, and allow angular pivoting motion while constraining motion along a liner axial axis; movably mounting said igniter to said liner through a grommet; providing a forging ring, said forging ring having a first surface for movably contacting said turbine scroll and a second, opposite surface attached to said liner; said first surface forming a substantially spherical point of contact between said liner and said turbine scroll; and said second surface having a diameter smaller than a diameter of said first surface. 26. The method according to claim 25, further comprising: forming a louver from said liner extending past the point of attachment of said second surface and said liner, said louver deflecting hot gases from said lower joint during operation of said turbine engine; disposing fine holes through said forging ring; deflecting air from said upper joint with an upper joint louver; and providing cooling for said upper joint by inserting sweep holes in said upper joint.