The present invention generally relates to gas turbine engines, and more particularly relates to inter-turbine ducts between the turbines of gas turbine engines.
A gas turbine engine may be used to power various types of vehicles and systems. A gas turbine engine may include, for example, five major sections: a fan section, a compressor section, a combustor section, a turbine section, and an exhaust nozzle section. The fan section induces air from the surrounding environment into the engine and accelerates a fraction of this air toward the compressor section. The remaining fraction of air induced into the fan section is accelerated through a bypass plenum and exhausted. The compressor section raises the pressure of the air it receives from the fan section and directs the compressed air into the combustor section where it is mixed with fuel and ignited. The high-energy combustion products then flow into and through the turbine section, thereby causing rotationally mounted turbine blades to rotate and generate energy. The air exiting the turbine section is exhausted from the engine through the exhaust section.
In some engines, the turbine section is implemented with one or more annular turbines, such as a high pressure turbine and a low pressure turbine. The high pressure turbine may be positioned upstream of the low pressure turbine and configured to drive a high pressure compressor, while the low pressure turbine is configured to drive a low pressure compressor and a fan. The high pressure and low pressure turbines have optimal operating speeds, and thus, optimal radial diameters that are different from one another. Because of this difference in radial size, an inter-turbine duct is arranged to fluidly couple the outlet of the high pressure turbine to inlet of the low pressure turbine and to transition between the changes in radius. It is advantageous from a weight and efficiency perspective to have a relatively short inter-turbine duct. However, decreasing the length of the inter-turbine duct increases the radial angle at which the air must flow between the turbines. Increasing the angle of the duct over a relatively short distance may result in boundary layer separation of the flow within the duct, which may adversely affect the performance of the low pressure turbine. Accordingly, the inter-turbine ducts are designed with a compromise between the overall size and issues with boundary separation. As a result, some conventional gas turbine engines may be designed with elongated inter-turbine ducts or inter-turbine ducts that do not achieve the optimal size ratio between the high pressure turbine and the low pressure turbine.
Accordingly, it is desirable to provide gas turbine engines with improved inter-turbine ducts. Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention.
In accordance with an exemplary embodiment, a turbine section is provided for a gas turbine engine. The turbine section is annular about a longitudinal axis. The turbine section includes a first turbine with a first inlet and a first outlet; a second turbine with a second inlet and a second outlet; an inter-turbine duct extending from the first outlet to the second inlet and configured to direct an air flow from the first turbine to the second turbine, the inter-turbine duct being defined by a hub and a shroud; and at least a first splitter blade disposed within the inter-turbine duct. The first splitter blade includes a pressure side facing the shroud, a suction side facing the hub, and at least one vortex generating structure positioned on the suction side.
In accordance with another exemplary embodiment, an inter-turbine duct is provided and extends between a first turbine having a first radial diameter and a second turbine having a second radial diameter. The first radial diameter is less than the second radial diameter. The inter-turbine duct includes a hub; a shroud circumscribing the hub to form a flow path fluidly coupled to the first turbine and the second turbine; and at least a first splitter blade disposed within the inter-turbine duct. The first splitter blade includes a pressure side facing the shroud, a suction side facing the hub, and at least one vortex generating structure positioned on the suction side.
The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and
The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. As used herein, the word “exemplary” means “serving as an example, instance, or illustration.” Thus, any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. All of the embodiments described herein are exemplary embodiments provided to enable persons skilled in the art to make or use the invention and not to limit the scope of the invention which is defined by the claims. Furthermore, there is no intention to be bound by any expressed or implied theory presented in the preceding technical field, background, brief summary, or the following detailed description.
Broadly, exemplary embodiments discussed herein provide gas turbine engines with improved inter-turbine ducts. In one exemplary embodiment, the inter-turbine duct is positioned between a high pressure turbine with a relatively small radial diameter and a low pressure turbine with a relatively large radial diameter. The inter-turbine duct may be defined by a shroud forming an outer boundary and a hub forming an inner boundary. The inter-turbine duct may further include one or more splitter blades positioned at particular radial distances that prevent and/or mitigate boundary separation of the air flow from the shroud and other surfaces as the air flow transitions in a radial direction. Each splitter blade may include one or more vortex generating structures on the suction side to prevent and/or mitigate boundary separation of the air flow from the splitter blade. Improvements in boundary separation along the shroud and along the splitter blade enable shorter inter-turbine ducts, and as such, improvements in weight and efficiency.
The engine 100 generally includes, in serial flow communication, a fan section 110, a low pressure compressor 120, a high pressure compressor 130, a combustor 140, and a turbine section 150, which may include a high pressure turbine 160 and a low pressure turbine 170. During operation, ambient air enters the engine 100 at the fan section 110, which directs the air into the compressors 120 and 130. The compressors 120 and 130 provide compressed air to the combustor 140 in which the compressed air is mixed with fuel and ignited to generate hot combustion gases. The combustion gases pass through the high pressure turbine 160 and the low pressure turbine 170. As described in greater detail below, an inter-turbine duct 180 couples the high pressure turbine 160 to the low pressure turbine 170.
The high pressure turbine 160 and low pressure turbine 170 are used to provide thrust via the expulsion of the exhaust gases, to provide mechanical power by rotating a shaft connected to one of the turbines, or to provide a combination of thrust and mechanical power. As one example, the engine 100 is a multi-spool engine in which the high pressure turbine 160 drives the high pressure compressor 130 and the low pressure turbine 170 drives the low pressure compressor 120 and fan section 110.
As shown, the turbine section 150 includes the high pressure turbine 160, the low pressure turbine 170, and the inter-turbine duct 180 fluidly coupling the high pressure turbine 160 to the low pressure turbine 170. Particularly, the inter-turbine duct 180 includes an inlet 202 coupled to the outlet 162 of the high pressure turbine 160 and an outlet 204 coupled to the inlet 172 of the low pressure turbine 170. In the depicted embodiment, the boundaries between the high pressure turbine 160 and the inter-turbine duct 180 and between the inter-turbine duct 180 and the low pressure turbine 170 are indicated by dashed lines 164, 174, respectively. The annular structure of the inter-turbine duct 180 is defined by a hub 210 and a shroud 220 to create a flow path 230 for air flow between the high pressure turbine 160 and low pressure turbine 170.
As noted above, the inter-turbine duct 180 transitions from a first radial diameter 250 at the inlet 202 (e.g., corresponding to the radial diameter at the outlet 162 of the high pressure turbine 160) to a larger, second radial diameter 252 (e.g., corresponding to the radial diameter at the inlet 172 of the low pressure turbine 170). In one exemplary embodiment, as shown in
In general, it is advantageous to minimize the axial length 254 of the inter-turbine duct 180 for weight and efficiency. For example, a shorter axial length 254 may reduce the overall axial length of the engine 100 (
During operation, the inter-turbine duct 180 functions to direct the air flow along the radial transition between turbines 160, 170. It is generally advantageous for the air flow to flow smoothly through the inter-turbine duct 180. Particularly, it is advantageous if the air flow adjacent to the shroud 220 maintains a path along the shroud 220 instead of undergoing a boundary layer separation. However, as the axial length 254 decreases and the angle 256 increases, the air flow along the shroud 220 tends to maintain an axial momentum through the inlet 202 and, if not addressed, attempts to separate from the shroud 220, particularly near or downstream the inflection point 222. Such separations may result in unwanted vortices or other turbulence that result in undesirable pressure losses through the inter-turbine duct 180 as well as inefficiencies in the low pressure turbine 170.
In one exemplary embodiment, one or more splitter blades 260 are provided within the inter-turbine duct 180 to prevent or mitigate the air flow separation. In some instances, the splitter blade 260 may be referred to as a splitters or guide vane. As described in greater detail below, one splitter blade 260 is illustrated in
The splitter blade 260 generally extends in an axial-circumferential plane, axi-symmetric about the axis 102 and has an upstream end 262 and a downstream end 264. In the depicted exemplary embodiment, the upstream end 262 of the splitter blade 260 is positioned at, or immediately proximate to, the inlet 202 of the inter-turbine duct 180, and the downstream end 264 of the splitter blade 260 are positioned at, or immediately proximate to, the outlet 204 of the inter-turbine duct 180. As such, in one exemplary embodiment, the splitter blade 260 extends along approximately the entire axial length 254 of the inter-turbine duct 180. Other embodiments may have different arrangements, including different lengths and/or different axial positions. For example, in some embodiments, the splitter blade may be relatively shorter than that depicted in
The splitter blade 260 may be considered to have a pressure side 266 and a suction side 268. The pressure side 266 faces the shroud 220, and the suction side 268 faces the hub 210. Additional details about the suction side 268 of the splitter blade 260 are provided below. As also discussed below, the splitter blade 260 may have characteristics to prevent flow separation.
In accordance with exemplary embodiments, the splitter blade 260 may be radially positioned to advantageously prevent or mitigate flow separation. In one embodiment, the radial positions may be a function of the radial distance or span of the inter-turbine duct 180 between hub 210 and shroud 220. For example, if the overall span is considered 100% with the shroud 220 being 0% and the hub 210 being 100%, the splitter blade 260 may be positioned at approximately 33% (e.g., approximately a third of the distance between the shroud 220 and the hub 210), 50%, or other radial positions.
The splitter blade 260 may be supported in the inter-turbine duct 180 in various ways. In accordance with one embodiment, the splitter blade 260 may be supported by one or more struts 290 that extend generally in the radial direction to secure the splitter blades 260 to the shroud 220 and/or hub 210. In the depicted embodiment, one or more struts 290 extend from the shroud 220 to support the splitter blade 260. In one exemplary embodiment, the splitter blade 260 may be annular and continuous about the axis 102, although in other embodiments, the splitter blade 260 may be in sections or panels. Reference is briefly made to
Returning to
During operation, the splitter blade 260 prevents or mitigates flow separation by guiding the air flow towards the shroud 220 or otherwise confining the flow along the shroud 220. However, unless otherwise addressed, flow separation may occur on the splitter blade 260. As such, the splitter blade 260 may include one or more flow control mechanisms to prevent and/or mitigate flow separation as the air flows around the splitter blade 260, particularly flow separation on the suction side (or underside) 268 of the splitter blade 260.
Reference is made to
As shown in
In one embodiment, the vortex generating structures 400 may be considered micro vortex generators. The vortex generating structures 400 may have various types of individual and collective characteristics. In the embodiment of
The vortex generating structures 400 may have any suitable shape, and each structure 400 may further be considered to have a leading end 410, a trailing end 412, a length 414 along the surface of the splitter blade 260, and a height 416 from the surface of the splitter blade 260. In the embodiment of
In the embodiment of
In the embodiment of
As noted above, the vortex generating structures 400 are paired and angled to produce counter-rotating vortices 408. In one embodiment, the counter-rotating vortices provide the desired energy characteristics to mix the air flowing along the suction side 268 with the core flow flowing through the duct. As angled, the vortex generating structures 400 may be considered to have a forward surface that at least partially faces the oncoming flow and an opposite aft surface. As shown, the vortices 408 may be most pronounced from the trailing ends 412 of the structures 400. In particular, the vortices 408 tend to result from air flow striking the forward surface, flowing along the forward surface, and curling around the trailing end 412 towards the aft surfaces. Since the paired vortex generating structures 400 have different orientations and are generally non-parallel, the resulting adjacent vortices 408 may be counter-rotating relative to one another.
Similarly, the structures 400 within a pair and relative to adjacent pairs may have any suitable spacing. In one embodiment, the structures 404, 406 may be spaced such that the leading ends 410 are separated by a gap distance 426. The gap distances 426 may be sized such that the vortices generated by the structures 404, 406 are appropriately positioned and have the desired characteristics. For example, the structures 404, 406 may have a length 414 and gap distances 426 such that vortices 408 at the trailing ends 412 of the array of vortex generating structures 400 are appropriately placed and sized. In one embodiment, the gap distances 426 may be approximately 2 mm to approximately 10 mm.
The length 414 and height 416 of the vortex generating structures 400 may also influence the vortex characteristics. In one embodiment, the length 414 may be approximately 10 mm to approximately 50 mm. In one embodiment, the height 416 may be approximately 1 mm to approximately 20 mm. In particular, the height 416 may be approximately 2 mm to approximately 5 mm.
As shown in
The vortex generating structures 500 may have any suitable shape, and each structure 500 may further be considered to have a leading end 510, a trailing end 512, a length 514 along the surface of the splitter blade 560, and a height 516 from the surface of the splitter blade 560. In the embodiment of
The vortex generating structures 500 are angled relative to air flow with an angle of attack 522 of approximately 2° to approximately 30°, although the angle may vary. In the embodiment of
The separated or gap distance 524 between vortex generating structures 500 may also be sized to result in the desired vortex characteristics. In one embodiment, the gap distance 524 is approximately 5 mm to approximately 25 mm.
As above, the inter-turbine duct 600 extends between a high pressure turbine 700 and a low pressure turbine 710 and is defined by an inlet 602, an outlet 604, a hub 610, and a shroud 620. In this exemplary embodiment, at least one splitter blade 660 is provided within the inter-turbine duct 600 to prevent or mitigate the air flow separation and are positioned similar to the arrangement of
In this embodiment, the splitter blade 660 extends proximate to or beyond the outlet 604 and are supported by a vane 712 of the low pressure turbine 710 that at least partially extends into the inter-turbine duct 600. As such, the splitter blade 660 may be considered to be integrated with the low pressure turbine vane 712. In such an embodiment, struts (e.g., struts 290 of
Accordingly, the splitter blades 260, 560, 660 provide a combination of passive devices that maintain a smooth flow through the inter-turbine duct 180. In general, active devices, such as flow injectors, are not necessary.
In addition to the splitter blades, turbine sections, and inter-turbine ducts described above, exemplary embodiments may also be implanted as a method for controlling air flow through the inter-turbine duct of a turbine section. For example, the inter-turbine duct may be provided with radial characteristics (as well as other physical and operational characteristics) for overall engine design that should be accommodated. In response to the identification or potential of flow separation through the inter-turbine duct, a splitter blade may be provided. If testing or CFD analysis indicates that some flow separation still occurs, vortex generating structures may be provided on the suction side of the splitter blade. The characteristics and arrangements of the vortex generating structures may be modified, as described above, for the desired vortex characteristics and resulting impact on flow separation. In some embodiments, one or more additional splitter blade may be provided, each of which may or may not include vortex generating structures on the suction sides.
Accordingly, inter-turbine ducts are provided with splitter blades that prevent or mitigate boundary separation. The splitter blades are shaped and positioned to prevent or mitigate boundary separation along the shroud. The vortex generating structures function to prevent or mitigate boundary separation along the suction side of the splitter blade. In combination, the shape and position of the splitter blade and the vortex generating structures enable smooth flow through the overall inter-turbine duct, even for aggressive ducts. This is particularly applicable when the duct is too aggressive for a single splitter blade without vortex generating structures, but an additional splitter blade would be undesirable because of additional weight, complexity, cost, and surface area pressure losses. This enables an inter-turbine duct with only a single splitter blade.
By maintaining the energy of the boundary layer flowing through the duct, a more aggressively diverging duct can be used, allowing for the design of more compact, and also more efficient, turbines for engines. In particular, the radial angle of the inter-turbine duct may be increased and the axial length may be decreased to reduce the overall length and weight of the engine and to reduce friction and pressure losses in the turbine section. In one exemplary embodiment, the guide vanes may reduce pressure losses by more than 15%. Additionally, the splitter blades enable the use of a desired ratio between the radial sizes of the high pressure turbine and the low pressure turbine.
In general, the techniques described above can be applied either during the design of a new engine to take advantage of the shorter duct length and optimized area-ratio made possible by the boundary layer control, or to retrofit an existing engine or engine design in order to improve the efficiency of the engine while changing the design as little as possible. Although reference is made to the exemplary gas turbine engine depicted in
While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
3578264 | Kuethe | May 1971 | A |
4023350 | Hovan | May 1977 | A |
4822249 | Eckardt et al. | Apr 1989 | A |
6851264 | Kirtley et al. | Feb 2005 | B2 |
7137245 | Graziosi et al. | Nov 2006 | B2 |
7549282 | Widenhoefer et al. | Jun 2009 | B2 |
7931720 | Stucki | Apr 2011 | B2 |
8061980 | Praisner | Nov 2011 | B2 |
8257036 | Norris | Sep 2012 | B2 |
8517686 | Allen-Bradley et al. | Aug 2013 | B2 |
8845286 | Ramachandran et al. | Sep 2014 | B2 |
20030192339 | Macbain | Oct 2003 | A1 |
20070012046 | Larsson et al. | Jan 2007 | A1 |
20130034433 | Ramachandran et al. | Feb 2013 | A1 |
20130192200 | Kupratis et al. | Aug 2013 | A1 |
20150030439 | Pesteil et al. | Jan 2015 | A1 |
20150300253 | Lord | Oct 2015 | A1 |
20160052621 | Ireland et al. | Feb 2016 | A1 |
Number | Date | Country |
---|---|---|
2554793 | Feb 2013 | EP |
3354848 | Aug 2018 | EP |
113273 | Jan 1919 | GB |
Entry |
---|
Haskew, J.T. and M.A.R. Sharif, “Performance Evaluation of Vaned Pipe Bends in Turbulent Flow of Liquid Propellants,” Appl. Math. Modelling, vol. 21, Jan. 1997, p. 48-62. |
Cuming, H.G., “The Secondary Flow in Curved Pipes,” Aeronautical Research Council Reports and Memoranda No. 2880, Feb. 1952. |
Number | Date | Country | |
---|---|---|---|
20190136702 A1 | May 2019 | US |