PRODUCTION PROCESS

Information

  • Patent Application
  • 20110179794
  • Publication Number
    20110179794
  • Date Filed
    February 17, 2009
    15 years ago
  • Date Published
    July 28, 2011
    13 years ago
Abstract
A transition duct (94) for routing a gas flow from a combustor to the first stage of a turbine section in a combustion turbine engine is disclosed. The transition duct (94) may have an internal passage (102) extending between an inlet (98) to an outlet (100). An axis (130) of the transition duct body (96) may be generally linear such that gases expelled from the transition duct body (96) flow in a proper direction into the downstream turbine blades.
Description
FIELD OF THE INVENTION

This invention is directed generally to gas turbine engines, and more particularly to transition ducts for routing gas flow from combustors to the turbine section of gas turbine engines.


BACKGROUND OF THE INVENTION

Referring to FIG. 1, there is shown a cross-section through a portion of a combustion turbine 10. The major components of the turbine are a compressor section 12, a combustion section 14 and a turbine section 16. A rotor assembly 18 is centrally located and extends through the three sections. The compressor section 12 can include cylinders 20, 22 that enclose alternating rows of stationary vanes 24 and rotating blades 26. The stationary vanes 24 can be affixed to the cylinder 20 while the rotating blades 26 can be mounted to the rotor assembly 18 for rotation with the rotor assembly 18.


The combustion section 14 can include a shell 28 that forms a chamber 30. Multiple combustors, for example, sixteen combustors (only one combustor 32 of which is shown) can be contained within the combustion section chamber 30 and distributed around a circle in an annular pattern. Fuel 34, which may be in liquid or gaseous form—such as oil or gas—can enter each combustor 32 and be combined with compressed air introduced into the combustor 32 from the chamber 30, as indicated by the unnumbered arrows surrounding the combustor 32. The combined fuel/air mixture can be burned in the combustor 32 and the resulting hot, compressed gas flow 36 can be exhausted to a transition duct 38 attached to the combustor 32 for routing to the turbine section 16.


The turbine section 16 can include a cylindrical housing 40, including an inner cylinder 42, can enclose rows of stationary vanes and rotating blades, including vanes 44 and blades 46. The stationary vanes 44 can be affixed to the inner cylinder 42 and the rotating blades 46 can be affixed to discs that form parts of the rotor assembly 18 in the region of the turbine section 16. The first row of vanes 44 and the first row of blades 46 near the entry of the turbine section 16 are generally referred to as the first stage vanes and the first stage blades, respectively.


Encircling the rotor assembly 18 in the turbine section 16 can be a series of vane platforms 48, which together with rotor discs 50, collectively define an inner boundary for a gas flow path 52 through the first stage of the turbine section 16. Each transition duct 38 in the combustion section 14 can be mounted to the turbine section housing 40 and the vane platforms 48 to discharge the gas flow 30 towards the first stage vanes 44 and first stage blades 46.


In operation, the compressor section 12 receives air through an intake (not shown) and compresses it. The compressed air enters the chamber 30 in the combustion section 14 and is distributed to each of the combustors 32. In each combustor 32, the fuel 34 and compressed air is mixed and burned. The hot, compressed gas flow 30 is then routed through the transition duct 38 to the turbine section 16. In the turbine section 16, the hot, compressed gas flow is turned by the vanes, such as first stage vane 44 and rotates the blades, such as first stage blade 52, which in turn drive the rotor assembly 18. The gas flow is then exhausted from the turbine section 16. The turbine system 10 can include additional exhaust structure (not shown) downstream of the turbine section 16. The power thus imparted to the rotor assembly 18 can be used not only to rotate the compressor section blades 26 but also to additionally rotate other machinery, such as an external electric generator or a fan for aircraft propulsion (not shown).


For a better understanding of the invention, a coordinate system can be applied to such as turbine system to assist in the description of the relative location of components in the system and movement within the system. The axis of rotation of the rotor assembly 18 extends longitudinally through the compressor section 12, the combustion section 14 and the turbine section 16 and defines a longitudinal direction. Viewed from the perspective of the general operational flow pattern through the various sections, the turbine components can be described as being located longitudinally upstream or downstream relative to each other. For example, the compressor section 12 is longitudinally upstream of the combustion section 14 and the turbine section 16 is longitudinally downstream of the combustion section 14. The location of the various components away from the central rotor axis or other longitudinal axis can be described in a radial direction. Thus, for example, the blade 46 extends in a radial direction, or radially, from the rotor disc 50. Locations further away from a longitudinal axis, such as the central rotor axis, can be described as radially outward or outboard compared to closer locations that are radially inward or inboard.


The third coordinate direction—a circumferential direction—can describe the location of a particular component with reference to an imaginary circle around a longitudinal axis, such as the central axis of the rotor assembly 18. For example, looking longitudinally downstream at an array of turbine blades in a turbine engine, one would see each of the blades extending radially outwardly in several radial directions like hands on a clock. The “clock” position—also referred to as the angular position—of each blade describes its location in the circumferential direction. Thus, a blade in this example extending vertically from the rotor disc can be described as being located at the “12 o'clock” position in the circumferential direction while a blade extending to the right from the rotor disc can be described as being located at the “3 o'clock” position in the circumferential direction, and these two blades can be described as being spaced apart in the circumferential direction. Thus, the radial direction can describe the size of the reference circle and the circumferential direction can describe the angular location on the reference circle.


Generally, the longitudinal direction, the radial direction and the circumferential direction are orthogonal to each other. Also, direction does not connote positive or negative. For example, the longitudinal direction can be both upstream and downstream and need not coincide with the central axis of the rotor. The radial direction can be inward and outward, and is not limited to describing circular objects or arrays. The circumferential direction can be clockwise and counter-clockwise, and, like the radial direction, need not be limited to describing circular objects or arrays.


Further, depending on the context, the relevant position of two components relative to each other can be described with reference to just one of the coordinate directions. For example, the combustor 32 can be described as radially outboard of the blade 46 because the combustor 32 is located radially further away from the central axis of the rotor assembly 18 than the blade 46 is—even though the combustor 32 is not in the same longitudinal plane of the blade 44, and in fact, is longitudinally upstream of the blade 44 and may not be circumferentially aligned with a particular blade.


The coordinate system can also be referenced to describe movement. For example, gas flow 36 in the transition 38 is shown to flow in the direction of arrow 36. This gas flow 36 travels both longitudinally downstream from the combustor 32 to the turbine section 16 and radially inward from the combustor 32 to the first stage vanes 44 and blades 46.


In the context of describing movement, such as the flow of a gas, the circumferential direction can also be referred to as the tangential direction. When gas flows in the circumferential direction, a component of the flow direction is tangential to a point on the circular path. At any given point on the circle path, the circumferential flow can have a relatively larger tangential component and a relatively smaller radial component. Since the tangential component predominates, particularly for larger diameter paths, such as around vane and blade arrays in a turbine engine, a circumferential direction and tangential direction can be regarded as substantially the same.


Bearing this coordinate system in mind and referring to FIG. 2, a transition duct 54 is shown alone as it would be seen when viewed from longitudinally downstream. This particular transition duct 54 is oriented in the 12 o'clock circumferential position and it should be understood that a turbine engine would have additional transition ducts, for example, a total of sixteen, spaced in an annular array.


The transition duct 54 can include a transition duct body 56 having an inlet 58 for receiving a gas flow exhausted by an associated combustor (not shown, but see FIG. 1). The transition duct body 56 can include an internal passage 60 from the inlet 58 to an outlet 62 from which the gas flow is discharged towards the turbine section (not shown). Because the combustor is radially outboard of the first stage of the turbine section (see FIG. 1), the transition duct 54 extends radially inwardly from its inlet 58 to its outlet 62. In FIG. 2, this radial direction is depicted by the axis 64. The transition duct 54 includes a longitudinal bend 66 near the outlet 62 to discharge the gas flow predominantly longitudinally. Because the gas flow in the transition duct 54 is redirected radially inwardly and then longitudinally, the transition duct 54 experiences substantial turning in the radial direction 64. This radial thrust pushes the outlet region of the transition duct 54 radially outwardly (up in the plane of the page of the figure). To support the transition duct 54 against this bending thrust, the transition duct 54 can be radially supported by various braces (not shown) at its ends, as it well known in the art. It can be seen that the outlet 62 and the inlet 58 are aligned along the circumferential or tangential direction, which is depicted by the axis 68.


Reference is now made to FIG. 3, focusing on a turbine subsection 70 that includes a combustor 72, a transition duct 74 and first stage vanes 76 and blades 78. FIG. 3 shows a view from above of the combustor 72, the transition duct 74, a few first stage vanes 76 and a few first stage blades 78, illustrated schematically. It should be understood that in a turbine, there would be additional first stage vanes spaced apart circumferentially to form an annular array. Similarly, there would be additional first stage blades spaced apart circumferentially to form an annular array around the engine centerline. These additional vanes and blades are not shown in FIG. 3 to facilitate illustration. A turbine system would typically also include additional combustors and transitions, but a single combustor 72 and transition 74 are shown schematically for purposes of illustration.


From this top view, the longitudinal direction can be noted by reference to the axis 80. The circumferential or tangential direction can be noted by reference to the axis 82. The radial direction is not illustrated because the radial direction lies into and out of the page of the figure, but would be generally orthogonal to the longitudinal direction and the radial direction.


Gas flow, such as hot, compressed gas with perhaps some limited liquid content, is exhausted from the combustor 72 and routed by the transition duct 74 to the first stage vanes 76 and blades 78. The gas flow as discharged from the exit or outlet 86 of the transition duct 74 generally travels downstream in the longitudinal direction, as indicated by the arrow 84. There may be some incidental, small-scale radial and circumferential flow components to the discharged gas flow that produce a downstream wake due to edge conditions 86 at the outlet and other factors. The downstream wake can create vibrations in downstream turbine blades.


As this longitudinal gas flow 84 discharges from the outlet 86 of the transition duct 74, the flow passes the first stage vanes 76. The function of the first stage vanes 76 is to accelerate and turn the predominantly longitudinal flow in the circumferential direction 82 so that the predominant flow direction of the gas flow leaving the trailing edges of vanes 76 is angled in the circumferential or tangential direction relative to the longitudinal direction as shown, for example, by the arrow 88. This turned flow 88 thus has a longitudinal component and a circumferential component. The flow angle can be substantial, in the range of 40 degrees to 85 degrees measured from the longitudinal axis 80. By accelerating and angling the gas flow in the circumferential direction 82 relative to the longitudinal direction 80, the resulting gas flow 88 more effectively imparts its energy to the first row blades 78, which in turn rotate the associated rotor assembly (not shown).


The use of first stage vanes to accelerate and turn the longitudinal gas flow in the circumferential direction present several challenges. The vanes and the associated vane support structure (see FIG. 1) must have high strength characteristics to withstand the forces generated in changing the direction of a extremely hot, high pressure gas flow over a substantial angle in a relatively short distance. The temperature of the gas flow and the heat generated by this turning process also require a vane cooling system. The forces and heat involved diminish material properties that can crack and otherwise damage the vanes and associated support structure. To address these various requirements and operating conditions, the first stage vanes and the associated support structure and cooling systems have developed into a complex system that can be expensive to manufacture, install, and, in the event of damage, repair and replace. Thus, there is a need to accelerate and tangentially turn a gas flow for presentation to a first stage blade array without the complications and related costs and damage risks associated with first stage vanes.


SUMMARY OF THE INVENTION

This invention is directed to a transition duct for routing gas flow from a combustor to a turbine section of a turbine engine and eliminating damaging stresses created between conventional transitions and row one turbine vanes. The transition duct may have an axis that is generally linear with a generally linear flow path that combines the functions of a transition and row one turbine vanes. In such a configuration, the transition duct channels gases from a combustor basket to a downstream turbine blade assembly and accomplishes the task of redirecting the gases, thereby eliminating the need for row one vanes. The transition duct directs gases into the turbine assembly at the same incidence angle relative to the longitudinal axis of the engine as the row one vanes. However, the transition duct does not include any leading or trailing edges, and the problems inherent with each, that are found in each of the row one vanes. The transition ducts are constructed such that adjacent sides of adjacent ducts are coplanar, which causes the gases to be emitted from each of the transition ducts without an area of decreased fluid flow between adjacent flows. In at least one embodiment of the transition duct, there is no turning of the gases, in particular, no radial or circumferential turning of the gases. As a result, there is not a circumferential pressure gradient across the outlet, thereby resulting in reduced excitation and stresses on the row one blades. The nonexistence of gas turning also reduces structural loading on mounts and eliminates aerodynamic losses due to turning of the gas flow. Finally, because there is no uncovered turning, a more uniform flow angle is created over the range of operating conditions.


The transition duct may also be configured to include an outlet with canted side surfaces that is configured to tilt the downstream wake thereby resulting in reduced vibration in downstream row one turbine blades. As such, the outlet reduces vibration of downstream blade that may be caused by the combustor gases exiting the transition duct.


The transition duct may be configured to route gas flow in a combustion turbine subsystem that includes a first stage blade array having a plurality of blades extending in a radial direction from a rotor assembly for rotation in a circumferential direction, said circumferential direction having a tangential direction component, the rotor assembly axis defining a longitudinal direction, and at least one combustor located longitudinally upstream of the first stage blade array and located radially outboard of the first stage blade array. The transition duct may be formed from a transition duct body having an internal passage extending between an inlet and an outlet. The outlet may be offset from the inlet in the longitudinal direction. An axis of the transition duct body may be generally linear such that a flow path for gases is generally linear.


In at least one embodiment, the inlet may be generally cylindrical and an adjacent midsection of the duct may be generally conically shaped. A throat adjacent to the midsection may have a cross-section with a generally consistent cross-sectional area. The outlet may be formed from a radially outer side generally opposite to a radially inner side, and the radially outer and inner sides may be coupled together with opposed first and second side walls. The radially inner side may be positioned radially outward a distance equivalent to the position of the ID of adjacent turbine blades, and the radially outer side may be positioned radially outward a distance equivalent to the position of the OD of adjacent turbine blades. The first side wall may be canted relative to a radial axis when viewing the outlet longitudinally upstream. The second side wall may also be canted relative to a radial axis when viewing the outlet longitudinally upstream. In one embodiment, the second side wall may be nonparallel to the first side wall of the outlet. The first or second side walls, or both, may be canted between about 20 and about 70 degrees relative to a radial axis when viewing the outlet longitudinally upstream. More particularly, the first or second side walls, or both, may be canted between about 30 and about 60 degrees relative to a radial axis when viewing the outlet longitudinally upstream.


In some embodiments, the transition duct body may be generally linear and positioned within a turbine engine such that row one vanes are unnecessary. In particular, the outlet may be offset from the inlet in the tangential direction and positioned such that gases are discharged from the outlet at an angle between the longitudinal direction and the tangential direction. The transition duct body is located between the combustor and the first stage blade array to receive the gas flow from the combustor into the internal passage through the inlet and to discharge the gas flow toward the first stage blade array.


During operation, hot combustor gases flow from a combustor into inlets of the transitions. The gases are directed through the internal passages. The position of the transition duct is such that gases are directed through the inlet, into the conical midsection where the flow is accelerated, through the adjacent throat and are expelled out of the outlet. The gases are expelled at a proper orientation relative to the turbine blades such that the gases are directed into the turbine blades in correct orientation without need of row one turbine vanes to alter the flow of the gases. Thus, energy is not lost through use of row one turbine vanes. The canted first and second sides of the outlet distribute the wake across a downstream turbine blade. In particular, the wake is distributed from a pressure side, across a leading edge of the blade, to a suction side, thereby distributing the wake across the entire blade. Such a configuration reduces vibrations and stresses in the downstream, stationary turbine blades.


An advantage of this invention is that the transition ducts have generally linear axes that enable gases to be emitted from the ducts in proper alignment relative to the row one turbine blades, thereby eliminating the necessity of row one turbine vanes and the inefficiencies associated with the row one turbine vanes.


Another advantage of this invention is that the transition duct eliminates leakages that exist between conventional transitions and turbine vanes because such connection does not exist.


Yet another advantage of this invention is that the transition duct eliminates leakage between adjacent turbine vanes at the exit frame because the transition duct eliminates the need for row one turbine vanes.


Another advantage of this invention is that the incidence angle at which the transition duct is positioned eliminates uncovered turning of gases exiting the transition, thereby making the flow angles more consistent through the range of operating power levels and enabling more power to be extracted from the first stages of the turbine.


Still another advantage of this invention is that the canted sides of the outlet of the transition reduce the trailing wake affect on the downstream turbine blades.


Another advantage of this invention is the uniform circumferential pressure gradient at the transition outlet reduces the potential vibration of downstream turbine blades caused by pressure gradients developed in the transition. The transition eliminates the abrupt pressure changes associated with radially aligned transition sides of other transition designs. Eliminating the abrupt pressure changes eliminates the vibrations created by these changes on the turbine blades as the blades rotate about the rotational axis and encounter multiple pressure changes arising from each transition upon each revolution.


Yet another advantage of this invention is that the transition eliminates the need for row one turbine vanes and thus eliminates the leading and trailing edges, and the associated problems, including the difficulties of cooling the leading and trailing edges, and the gas blockage caused by the existence of the row one turbine vanes.


Another advantage of this invention is that in an assembly of transition ducts in which the transition ducts are positioned adjacent one another and extend radially outward around a centerline of a turbine engine, the flow paths of the transition ducts are parallel downstream of throats within each duct and offset such that the flow from each transition duct is tangential to a circular configuration of transitions.


These and other embodiments are described in more detail below.





BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of the specification, illustrate embodiments of the presently disclosed invention and, together with the description, disclose the principles of the invention.



FIG. 1 is a cross-sectional view of a portion of a prior turbine engine.



FIG. 2 is an upstream longitudinal view of a prior transition duct.



FIG. 3 is a schematic radial view of a combustor, transition duct and first stage vanes and blades of a prior turbine engine.



FIG. 4 is a longitudinal upstream view of a circular array of transition ducts embodying aspects of the invention.



FIG. 5 is a upstream longitudinal view of a circular array of transition ducts embodying aspects of the invention.



FIG. 6 is a side view of a transition duct.



FIG. 7 is a top view of a circular array of transition ducts.



FIG. 8 is an end view of the transition duct of FIG. 6.



FIG. 9 is a partial perspective view of two transition ducts.





DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

As shown in FIG. 4-9, this invention is directed to a transition duct 94 for routing gas flow from a combustor to a turbine section of a turbine engine. The transition duct 94 may have an axis 130 that is generally linear. In such a configuration, the transition duct 94 channels gases from a combustor basket to a downstream turbine blade assembly and accomplishes the task of redirecting the gases, which has been accomplished in conventional systems with row one vanes. Thus, the transition duct 94 eliminates the need for row one vanes. The transition duct 94 may also be configured to include an outlet 100 with canted side surfaces 112, 114 that is configured to reduce the effect of the transition wake thereby resulting in reduced vibration in downstream turbine blades. As such, the outlet 100 reduces inefficiencies caused by the combustor gases exiting the transition duct 94.


As shown in FIGS. 4, 5 and 7, the transition ducts 94 may be positioned in an annular array 90, as shown without surrounding turbine components in an elevation as viewed from longitudinally downstream in a turbine. Each transition duct 94 can include a transition body 96 having an inlet 98 and an outlet 100 and an internal passage 102 between the inlet 98 and the outlet 100 for routing a gas flow through the transition duct 92 from the inlet 98 to the outlet 100. The array 90 is shown illustrating an arrangement for use in a combustion turbine engine having 16 combustors (not shown). However, the number of transition ducts 92 and their annular arrangement can be varied for use with more or less combustors.


As shown in FIG. 4-6, the transition duct 94 may include an outlet 100 formed from a radially outer side 108 generally opposite to a radially inner side 110 and configured to match the row one blade annulus. The radially outer side 108 may be positioned radially outward a distance equal to the OD of an adjacent row one turbine blade. The radially inner side 110 may be positioned radially outward a distance equal to the ID of an adjacent row one turbine blade. The radially outer and inner sides 108, 110 may be coupled together with opposed first and second side walls 112, 114. The outlet 100 may be offset from the inlet 98 in the longitudinal direction. The term “offset” as used herein and in the claims means that the outlet is spaced from the inlet as measured along the coordinate direction(s) identified. The outlet 100 may also be offset from the inlet 98 in a tangential direction 106, as shown in FIG. 4. The outlet 100 may also be configured such that the outlet 100 is generally orthogonal to a longitudinal axis 136 of the turbine engine such that the transition duct 94 does not interfere with the row one turbine blades, as shown in FIG. 7.


The transition duct 94 may be configured to direct gases along a generally linear flow path along the transition axis 130. In one embodiment, the transition duct 94 may have a generally cylindrical inlet 98 adjacent to a conical midsection 132. The conical midsection 132 may be positioned between the inlet 98 and the throat 134. The conical midsection 132 may include an ever decreasing cross-sectional area until the conical midsection 132 joins an adjacent throat 134. The conical midsection 132 accelerates the flow of gases before the gases are directed into the row one turbine blades 140, as shown in FIG. 6. Accelerating the flow of gases before the gases strike the row one turbine blades increases the efficiency of the turbine engine. The throat 134 may have any appropriate cross-section. In at least one embodiment, the throat 134, as shown in FIG. 8, may have a cross-section with two opposing, generally linear sides and two opposing, non-linear sides. The cross-sectional area of the throat 134 may be less than a cross-sectional area of the conical midsection 132.


As shown in FIG. 9, the transition ducts 94 may be formed from first and second opposing side walls 112, 114. A first side wall 112 of a first transition duct 94 may be positioned such that an inner surface of the first side wall is coplanar with an inner surface of the second side wall 114 of an adjacent transition duct 94. As such, the gas flows through each transition duct 94 are generally parallel to each other and immediately adjacent to each other without an area of decreased fluid flow between adjacent flows. Instead, the gas flows emitted from each of the transition ducts 94 are parallel and touching each other.


As shown in FIG. 4, the first side wall 112 may be canted relative to a radial axis 104 when viewing the outlet longitudinally upstream. The second side wall 114 may be canted relative to the radial axis 104 when viewing the outlet longitudinally upstream. In one embodiment, the first and second side walls 112, 114 may be canted between about 20 and about 70 degrees relative to the radial axis 104 when viewing the outlet longitudinally upstream. More particularly, the first and second side walls 112, 114 may be canted between about 30 and about 60 degrees relative to the radial axis 104 when viewing the outlet longitudinally upstream. In one embodiment, as shown in FIG. 4, the second side wall 114 may be nonparallel to the first side wall 112 of the outlet 100.


The first and second side walls 112, 114 may be canted as shown in FIGS. 4 and 5 to reduce the affects of the pressure differential between high pressure regions, denoted by the plus sign 116, and the low pressure regions, denoted by the minus sign 118. The high and low pressure regions 116, 118 exist within the same transition but in different portions of the cross-section. Such is the case because as the hot combustor gases flow quickly and accelerate through the transition 94.


Inclusion of the canted first and second sides 112, 114 in the outlet 100 facilitates an increased incidence angle 142, which is the angle shown in FIG. 7 between an axis orthogonal to the longitudinal axis 136 and the linear flow path at the outlet 100 of the transition 94. A higher incidence angle, which is an angle at which the discharge gas flow path is moving further way from alignment with the longitudinal axis 136, facilitates positioning the transition duct 94 at improved angles of discharge of the combustor gases to downstream turbine blades.


During operation, hot combustor gases flow from a combustor into inlets 98 of the transitions 94. The gases are directed through the internal passages 102. The position of the transition duct 94 is such that gases are directed through the inlet 98, the conical midsection 132, and the adjacent throat 134 and are expelled out of the outlet 100. The gases are expelled at a proper orientation relative to the turbine blades such that the gases are directed into the turbine blades in correct orientation without need of row one turbine vanes to alter the flow of the gases. Thus, energy is not lost through use of row one turbine vanes. In transition ducts 94 with linear flow paths, the gases are exhausted through the outlets 100. The canted first and second sides 112, 114 of the outlet 100 distribute the wake across a downstream turbine blade. In particular, the wake is distributed from a pressure side, across a leading edge of the blade, to a suction side, thereby distributing the wake across the entire blade. Such a configuration reduces vibrations and stresses in the downstream, stationary turbine blades.


The foregoing is provided for purposes of illustrating, explaining, and describing embodiments of this invention. Modifications and adaptations to these embodiments will be apparent to those skilled in the art and may be made without departing from the scope or spirit of this invention.

Claims
  • 1. A transition duct (94) for routing gas flow in a combustion turbine subsystem that includes a first stage blade array having a plurality of blades extending in a radial direction from a rotor assembly for rotation in a circumferential direction, said circumferential direction having a tangential direction component, an axis of the rotor assembly defining a longitudinal direction, and at least one combustor located longitudinally upstream of the first stage blade array and located radially outboard of the first stage blade array, said transition duct (94), characterized in that: a transition duct body (96) having an internal passage (102) extending between an inlet (98) and an outlet (100);wherein the outlet (100) is offset from the inlet (98) in the longitudinal direction and the tangential direction;wherein the outlet (100) is formed from a radially outer side (108) generally opposite to a radially inner side (110), and the radially outer and inner sides (108, 110) are coupled together with opposed first and second side walls (112, 114); andwherein a first side (112) of the transition duct body (96) is configured to be coplanar with a second side (114) of an adjacent transition duct (94) when assembled beside the second transition duct (94).
  • 2. The transition duct (94) of claim 1, further characterized in that a throat (134) positioned in the transition duct body (96) and having a cross-sectional area that is less than other aspects of the transition duct body (96) and wherein an axis (130) of the transition duct body (96) downstream of the throat (134) is generally linear, thereby eliminating unguided turning.
  • 3. The transition duct (94) of claim 2, characterized in that the inlet (98) is generally cylindrical and an adjacent midsection (132) of the duct between the inlet (98) and the throat (134) is generally conically shaped.
  • 4. The transition duct (94) of claim 1, characterized in that the second side wall (114) is canted relative to a radial axis (104) when viewing the outlet (100) longitudinally upstream.
  • 5. The transition duct (94) of claim 1, characterized in that the second side wall (114) is nonparallel to the first side wall (112) of the outlet (100).
  • 6. The transition duct (94) of claim 1, characterized in that the first side wall (112) is canted between about 20 and about 70 degrees relative to a radial axis (104) when viewing the outlet (100) longitudinally upstream.
  • 7. The transition duct (94) of claim 6, characterized in that the first side wall (112) is canted between about 30 and about 60 degrees relative to the radial axis (104) when viewing the outlet (100) longitudinally upstream.
  • 8. The transition duct (94) of claim 6, characterized in that the second side wall (114) is canted relative to the radial axis (104).
  • 9. The transition duct (94) of claim 8, characterized in that the second side wall (114) is nonparallel to the first side wall (112) of the outlet (100).
  • 10. The transition duct (94) of claim 8, characterized in that the second side wall (114) is canted between about 20 and about 70 degrees relative to a radial axis (104) when viewing the outlet (100) longitudinally upstream.
  • 11. The transition duct (94) of claim 10, characterized in that the second side wall (112) is canted between about 30 and about 60 degrees relative to the radial axis (104) when viewing the outlet (100) longitudinally upstream.
  • 12. A transition duct (94) for routing gas flow in a combustion turbine subsystem that includes a first stage blade array having a plurality of blades extending in a radial direction from a rotor assembly for rotation in a circumferential direction, said circumferential direction having a tangential direction component, an axis of the rotor assembly defining a longitudinal direction, and at least one combustor located longitudinally upstream of the first stage blade array and located radially outboard of the first stage blade array, said transition duct (94), characterized in that: a transition duct body (96) having an internal passage (102) extending between an inlet (98) and an outlet (100);wherein the outlet (100) is offset from the inlet (98) in the longitudinal direction and the tangential direction;a throat (134) positioned in the transition duct body (96) and having a cross-sectional area that is less than other aspects of the transition duct body (96); andwherein an axis (130) of the transition duct body (96) downstream of the throat (134) is generally linear;wherein the outlet (100) is formed from a radially outer side (108) generally opposite to a radially inner side (110), and the radially outer and inner sides (108, 110) are coupled together with opposed first and second side walls (112, 114).
  • 13. The transition duct (94) of claim 12, characterized in that the outlet (100) is configured such that a first side (112) of the outlet (100) of a first transition duct (94) is coplanar with a second side (114) of a second transition duct (94) when assembled beside the second transition duct (94).
  • 14. The transition duct (94) of claim 13, characterized in that the inlet (98) is generally cylindrical and an adjacent midsection (132) of the duct is generally conically shaped.
  • 15. The transition duct (94) of claim 13, characterized in that the second side wall (114) is nonparallel to the first side wall (112) of the outlet (100).
  • 16. The transition duct (94) of claim 13, characterized in that the first side wall (112) is canted between about 20 and about 70 degrees relative to a radial axis (104) when viewing the outlet (100) longitudinally upstream, and wherein the second side wall (114) is canted relative to the radial axis (104) between about 20 and about 70 degrees relative to the radial axis (104) when viewing the outlet (100) longitudinally upstream.
Priority Claims (2)
Number Date Country Kind
2008903933 Jul 2008 AU national
12190074 Aug 2008 US national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/US09/00980 2/17/2009 WO 00 4/6/2011