The disclosure relates to first stage vane arrangement for receiving a combustor transition piece which guides hot gases from the combustor to the turbine at the interface from a combustor to a turbine.
Gas turbines with can combustors are known from various applications in power plants. Typically a plurality of combustors is disposed in an annular array about the axis of the turbine. Hot combustion gases flow from each combustor through a respective transition piece into the first stage vane. In addition to relative movement, e.g. due to dynamic pulsing between these components, the transition pieces and first stage vane are made of different materials and are subjected to different temperatures during operation, thereby experiencing different degrees of thermal growth. Support frames which support and guide the transition piece at the turbine inlet have been proposed to allow such a “mismatch” at the interface of the transition pieces and the first stage vane. To allow movement between the transition piece and the support frames the US 2009/0115141 A1 suggests the use of sealed slots. The described arrangement is intended to allow radial, circumferential and axial relative movements. However, radial, circumferential and axial relative movements of hot gas path sections relative to each other are difficult to seal and can lead to steps at the interface between the side walls of such an arrangement. These steps are detrimental to the aerodynamics of the turbine, they can cause local high heat loads due to turbulences they might induce in the boundary layer.
An improved first stage turbine vane arrangement is suggested in order to assure good aerodynamics in the hot gas flow path and reliable cooling. Lifetime is increased and power and efficiency losses due to steps in a hot gas flow path and large cooling gas consumption, as well as increased emissions due to uncontrolled cooling gas flows, are avoided.
The present disclosure relates to a first stage vane arrangement for receiving a combustor transition piece from a can combustor to the turbine inlet adapted to guide combustion gases in a hot gas flow path extending between a gas turbine can combustor and a first stage of turbine. The combustor transition piece comprises a duct having an inlet at an upstream end adapted for connection to the can combustor and an outlet at a downstream end adapted for connection to a first stage of a turbine. Typically each outlet is inserted into a picture frame receptacle formed by a frame segment. The downstream end of the combustor transition piece comprises combustor transition walls. Typically these are an outer wall, an inner wall, as well as two combustor transition side walls.
The inlet of a combustor transition typically has the same cross section as the can combustor to which the transition piece is attached. These can for example be a circular, an oval or a rectangular cross section. The outlet typically has the form of a segment of an annulus. A plurality of combustor transitions installed in the gas turbine form an annulus for guiding the hot gas flow into the turbine.
According to a first embodiment the first stage vane arrangement comprises a vane carrier, an array of first stage vanes, and an array of frame segments for axially receiving aft ends of a combustor transition pieces.
The vanes comprise an outer platform, an inner platform, an airfoil, extending between said outer and inner platforms, an outer suspension for pivotable connection of the vane to the vane carrier. The vanes further comprise an inner rim segment which extends radially inwards from the inner platform.
The frame segments comprise an I-beam with an upper horizontal element, a lower horizontal element, and a vertical web, and a fixation to the vane carrier. From the lower horizontal element at least one arm extends in axial direction below the inner rim segment for supporting the inner platform of the vane and for sealing a gap between the inner platform and the lower horizontal element.
The pivotable connection is arranged such that the vane can rock around an axis which is normal to the longitudinal direction of the airfoil, i.e. the direction from inner platform to outer platform, and normal to the axial direction of the gas turbine when the vane is installed in a turbine. Such a pivotable vane is also called rocking vane.
The pivotable connection can for example be a projection extending against the axial direction from a vertical wall of the vane carrier into a notch in a vertical side wall of the outer platform, or a projection extending in axial direction from a vertical side wall of the outer platform into a notch in a vertical side wall of the vane carrier. The vertical direction is the direction from the inner platform to the outer platform of the vane. A side wall is a wall terminating in axial direction, i.e. a wall in a plane normal to the axis of the gas turbine.
The arm which is extending from the lower horizontal element below the inner rim segment for supporting the inner platform of the vane facilitates the alignment of inner platform of the rocking vane with exit of a combustor transition piece which can be axially inserted into the frame segments.
According to a further embodiment of the first stage vane arrangement an outer rim segment extends radially outwards from the arm. The outer rim limits the axial movement of the vane relative to the lower horizontal element. In addition the combination of outer rim and inner rim improves the sealing in a labyrinth like manner.
More specifically the outer rim segment and the arm form an L-shaped hock for supporting the rocking vane wherein the inner rim engages in the hock.
In another embodiment of the first stage vane arrangement an inner seal is attached to an outer face of the arm for sealing a gap between the inner rim segment and the arm. Alternatively or in combination an inner seal can be attached to an inner face of the inner platform for sealing a gap between the outer rim segment and the inner platform. An outer face is a surface facing radially away from the axis of the gas turbine when the arrangement is installed in a gas turbine and an inner face is a surface facing radially inwards.
According to a further embodiment of the first stage vane arrangement an inner seal is arranged between the sides of the inner rim segment and the outer rim segment which are facing each other. Alternatively or in combination an inner seal is arranged between the sides of the inner rim segment and the lower horizontal element which are facing each other.
The inner seal can be configured as a honeycomb seal. According to one embodiment the webs of the honeycombs of the inner seal are orientated parallel to the outer face of the arm. Thus the webs can deflect easily if a force is imposed on them by the inner rim segment. The honeycomb can act as a spring closing the gap. The inner rim, respectively the honeycomb with the inner rim segment can hold the rocking vane into a preferred position.
In a further embodiment the fixation for mounting the frame segment to vane carrier comprises at least one ear. The ear can be attached radially outwards of the upper horizontal element for bolting the frame segment to the vane carrier.
According to yet another embodiment of the first stage vane arrangement the outer horizontal element has a mounting face and the vane carrier has matching mounting face for mounting the frame segment to the vane carrier in a substantially gas tight manner. For gas tight mounting the mounting faces can have substantially flat smooth facing each other and which are pressed onto each other during assembly.
In a more specific embodiment a seal is arranged between the mounting face of the outer horizontal element and the matching mounting face of the vane carrier. The seal can for example be a rope seal. A notch in circumferential direction around the axis of the gas turbine can be provided in the mounting face of the outer horizontal element or in the mounting face of the vane carrier for receiving the rope seal.
In another embodiment the first stage vane arrangement comprises a combustor transition piece with a duct having an inlet at an upstream end adapted for connection to a combustor, and an outlet at an aft end wherein the aft end is adapted for axial insertion into a frame formed by two neighboring frame segments. To reduce cooling air leakages a seal is arranged between the outer surface of the combustor transition wall of the combustor transition piece's aft end and the surface of the frame segment facing the combustor transition wall of the combustor transition piece.
The seal can for example be arranged in a plane normal to the axis of the gas turbine and spanning around the outside of the combustor transition piece.
According to a further embodiment the seal between combustor transition wall and the frame segment is an E-seal. The E seal can be inserted between two strips which span around the combustor transition wall and which are axially displaced to define a slot. Alternatively two strips can also extend from the frame segment towards the combustor transition wall. These can also be axially displaced to define a slot for receiving the E-seal. The strips can be an integral part of the combustor transition wall, respectively of the frame segment, or attached to it.
Further, a gas turbine comprising such a first stage vane arrangement is an object of the disclosure. The proposed gas turbine has at least one compressor, at least one turbine, and at least one can combustor with a transition piece and a first stage vane arrangement according to the disclosure.
In addition to the first stage vane arrangement and a gas turbine comprising such a first stage vane arrangement a Method for assembly of a first stage vane arrangement is a subject of the disclosure.
The method for assembly of a first stage vane arrangement comprises the steps of
In such a first stage vane arrangement the vanes comprise an outer platform, an inner platform, an airfoil, extending between said outer and inner platforms. The vanes have an outer suspension for pivotable connection of the vane to the vane carrier, and an inner rim segment which is extending radially inwards from the inner platform.
In such a first stage vane arrangement the frame segments comprise an I-beam with an upper horizontal element, a lower horizontal element, a vertical web, and an outer fixation to the vane carrier. For supporting the inner platform of the vane and for sealing a gap between the inner platform and the lower horizontal element an arm is extending from the lower horizontal element in axial direction below the inner rim segment.
The above described combustor transition, can combustor and gas turbine can be a single combustion gas turbine or a sequential combustion gas turbine as known for example from EP 0 620 363 B1 or EP 0 718 470 A2. It can also be a combustor transition of a gas turbine with one of the combustor arrangements described in the WO 2012/136787.
The invention, its nature as well as its advantages, shall be described in more detail below with the aid of the accompanying drawings. Referring to the drawings:
The same or functionally identical elements are provided with the same designations below. The examples do not constitute any restriction of the invention to such arrangements.
An exemplary arrangement is shown in
Cooling gas 5, 6 is branched off from the compressor 1 to cool the turbine 3, the combustor 2 (not shown) and a frame segment (not shown in
Exhaust gas 8 leaves the turbine 3. The exhaust gas 8 is typically used in a heat recovery steam generator to generate steam for cogeneration or for a water steam cycle in a combined cycle (not shown).
The combustor transition pieces 24 of the gas turbine 9 of the cross section B-B are shown in
An example for the interface between combustor transition piece 24 and the first stage vane 10 of a turbine 3 is shown in more detail in
A front seal 28 can be installed between the frame segment 12 and the vane carrier 16.
The sealing and supporting interface between the lower horizontal element 21 and the inner platform 14 is indicated by the dotted circle III and shown in more detail in
Two strips 34 extend from the combustor transition wall 11 into the gap between the combustor transition wall 11 and the frame segment 12 (here only shown at the section between the wall and the lower horizontal element 21) and span around the combustor transition wall 11. They are axially displaced to define a slot in which an E-seal 33 is inserted. The seal allow axial movement of the combustor transition wall 11 relative to the frame segment 12 and seals the gap between the two pieces.
In this example an arm 26 extends from the lower horizontal element 21 in axial direction towards the inner platform 14 (of the gas turbine when the segment is installed). At the axial end of the arm 26 an outer rim segment 27 extends radially outwards in the direction of an inner face 31 of the inner platform 14. The arm 26 with the outer rim segment 27 form an L-shaped hook. This L-shaped hocks behind the inner rim segment 23 which extends radially inwards at an upstream end from the inner face 31 of the inner platform 14.
The inner platforms 14 of all vanes of the first turbine stage form a ring. The inner faces 31 of the inner platforms 14 from a cylindrical inner face. The outer rim segments 27 of all frame segments form a ring which fits into the cylinder formed by the inner platforms 14. It is sealing a space below the inner platform 14 and the hot gas flow path above the inner platform 14. In addition the outer rim segments 27 support the inner platform 14 and can keep it in the correct position aligned with the aft end of the combustor transition wall 11.
As shown in the close-up view in
Alternatively an inner seal 29 can be attached to inner face 31 of the inner platform 14 next to the inner rim segment 23 for better sealing. During assembly the outer rim segment 27 is pressed against the inner seal 29. In this arrangement radial forces are transferred via the inner rim segment 23 to the outer face 30 of the arm 26. An example for such a configuration is shown in the close-up view in
In
Number | Date | Country | Kind |
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14195265 | Nov 2014 | EP | regional |
Number | Name | Date | Kind |
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5402631 | Wolf | Apr 1995 | A |
5634327 | Kamber et al. | Jun 1997 | A |
6450762 | Munshi | Sep 2002 | B1 |
8105019 | McCaffrey | Jan 2012 | B2 |
8356981 | Cooke | Jan 2013 | B2 |
8491259 | Sutcu | Jul 2013 | B2 |
20060288707 | Weaver et al. | Dec 2006 | A1 |
20070017225 | Bancalari | Jan 2007 | A1 |
20090115141 | Simmons | May 2009 | A1 |
20140033728 | Marmilic et al. | Feb 2014 | A1 |
Number | Date | Country |
---|---|---|
0 620 363 | Oct 1994 | EP |
0 718 470 | Jun 1996 | EP |
2061396 | May 1981 | GB |
WO 2012136787 | Oct 2012 | WO |
Entry |
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The Extended European Search Report dated May 20, 2015, issued in corresponding European Patent Application No. 14195265.5-1610. (4 pages). |
Number | Date | Country | |
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20160153294 A1 | Jun 2016 | US |