The present invention relates to gas turbine engines and, more particularly, to a cooling passage disposed within a component of a gas turbine system.
A typical gas turbine engine includes a fan, compressor, combustor, and turbine disposed along a common longitudinal axis. Fuel and compressed air discharged from the compressor are mixed and burned in the combustor. The resulting hot combustion gases (e.g., comprising products of combustion and unburned air) are directed through a conduit section to a turbine section where the gases expand to turn a turbine rotor. In electric power applications, the turbine rotor is coupled to a generator. Power to drive the compressor may be extracted from the turbine rotor.
The one or more conduits forming the conduit section are liners or transition ducts through which the hot combustion gases flow from the combustion section to the turbine section. Due to the high temperature of the combustion gases, the conduits must be cooled during operation of the engine in order to preserve the integrity of the components. Commonly, the combustor and turbine components are cooled by air which is diverted from the compressor and channeled through the components.
Known solutions for cooling the conduits include supplying the cool air along an outer surface of the conduit to provide direct convection cooling to the transition duct. An impingement sleeve may be provided about the outer surface of the conduit to facilitate flow of the cooling fluid, e.g., through small holes formed in an impingement member before the air is introduced to the outer surface of the conduit. Other prior art solutions include injecting the cooling fluid along an inner surface of the conduit to provide film cooling along the inner surface.
Effective cooling of turbine components, e.g., airfoils, must deliver the relatively cool air to critical regions such as along the trailing edge of a turbine blade or a stationary vane. The associated cooling apertures may, for example, extend between an upstream, relatively high pressure cavity and one of the exterior surfaces of the turbine blade. It is a desire in the art to provide cooling designs and methods which provide more effective cooling with less air. It is also desirable to provide more cooling in order to operate machinery at higher levels of power output. Generally, cooling schemes should provide greater cooling effectiveness to create more uniform wall temperatures along the components.
Ineffective cooling can result from poor heat transfer characteristics between the cooling fluid and the material to be cooled with the fluid. In many cases, it is desirable to establish film cooling along a wall surface. A cooling air film traveling along the surface of a wall can be an effective means for increasing the uniformity of cooling and for insulating the wall from the heat of hot core gases flowing thereby. However, film cooling is difficult to maintain in the turbulent environment of a gas turbine.
Also, gaps which exist between apertures and in areas immediately downstream of the gaps, are exposed to less cooling air than are the apertures and the surface areas immediately downstream of the apertures. Consequently these regions are more susceptible to thermal degradation.
The invention will be better understood from the following description when read in conjunction with the accompanying drawings in which like reference numerals identify like elements throughout and wherein:
With reference to the perspective views of
The cooling module 10 may be formed in a casting process from, for example, a ceramic core, although other suitable materials may be used. A suitable process for fabrication is available from Mikro Inc., of Charlottesville Va. See, for example, U.S. Pat. No. 7,141,812 which is incorporated herein by reference. For the embodiment illustrated in the figures, the flow sections 18, 20, 22 and 24 may be integrally formed with one another in such a casting process. As further illustrated herein, multiple cooling modules can be integrally formed in such a casting process to create a series of cooling modules, e.g., extending in one or two dimensions along the interior of a wall. For purposes of describing features of the illustrated embodiments, the chambers in each flow section are shown as rectangular-shaped volumes formed with pairs of parallel opposing walls, but the various chambers and sections many be formed with many other geometries and the cross sectional shapes and sizes of the various sections may vary, for example, to meter the flow of cooling fluid.
With reference to
Opposing end portions 60a of the transition chamber portion 56a connect to different chambers 36a and 36b in the pair 50a of chambers 36. An opening in the transition chamber portion 56a further connects to a first end 62a of first and second opposing ends 62a, 62b of the chamber 40 of the flow section 20. Connection is effected through an opening 64a in a first wall 66 of first and second opposing walls 66, 68 of the flow section 20. The opening 64a provides a first path for the cooling fluid to enter into the chamber 40 of the flow section 20. Similarly, opposing end portions 60b of the transition chamber portion 56b connect to different chambers 36c, 36d in the pair 50b of chambers 36 while the transition chamber portion 56b further connects to the first end 62a of the chamber 40 of the flow section 20. Connection is effected through an opening 64b in a second wall 68 of first and second opposing walls 66, 68 of the chamber 40 of the flow section 20. The opening 64b provides a second path for the cooling fluid to enter into chamber 40 of the flow section 20.
With the flow section 20 having a second end 62b of first and second opposing ends 62a, 62b, and the pair of openings 64a and 64b positioned at the first end 62a thereof, second openings 68a and 68b are positioned at the second end 62b to connect the chamber 40 to chambers 46 in the section 22.
The flow section 22 comprises four chambers 46a, 46b, 46c and 46d, first and second spaced-apart transition chambers 76a and 76b and third and fourth spaced-apart transition chambers 78a and 78b. A first end 80 of each of the chambers 46a and 46d merges into the transition chamber 76a. The combination of the chambers 46a and 46d and the transition chamber 76a connecting the chambers 46a and 46d is illustrated in the figures as a “U” shape configuration. The chambers 46a and 46d each connect to the transition chamber 76a at a different opposing end of the transition chamber 76a while the second opening 68a of the flow section 20 transitions into the transition chamber 76a.
Similarly, with respect to the chambers 46b and 46c, a first end 80 of each of the chambers 46b and 46c merges into transition chamber 76b. The combination of the chambers 46b and 46c and the transition chamber 76b connecting the chambers 46b and 46c is also illustrated in the figures as a “U” shape configuration. The chambers 46b and 46c each connect to the transition chamber 76b at a different opposing end of the transition chamber 76b while the second opening 68b of the flow section 20 transitions into the transition chamber 76b.
The transition chambers 78a and 78b are each connected to the chamber 48 along first and second opposing walls 82 and 84 of the flow section 24. Second ends 86 of each of the chambers 46c and 46d merge into the transition chamber 78a. The combination of the chambers 46c and 46d and the transition chamber 78a connecting the pair of chambers 46c and 46d is illustrated in the figures as a “U” shape configuration. The chambers 46c and 46d each connect to the transition chamber 78a at a different opposing end of the transition chamber 78a.
An opening 79a in the transition chamber 78a connects to an opening 82a in the first wall 82 of the chamber 48 to provide a path for cooling fluid to pass into the flow section 24.
Second ends 86 of each of the chambers 46a and 46b merge into the transition chamber 78b. The combination of the chambers 46a and 46b and the transition chamber 78b connecting the pair of chambers 46a and 46b is also illustrated in the figures as a “U” shape configuration. The chambers 46a and 46b each connect at a different opposing end of the transition chamber 78b. An opening 79b in the transition chamber 78b, connects to an opening 84b through the second wall 84 of the chamber 48 to provide another path for cooling fluid to pass into the flow section 24.
Having described one embodiment of a cooling module it will be apparent that the flow of cooling fluid, such as indicated in
The combustion chamber 126, and other components (e.g., vanes and blades) along which the hot exhaust gases flow, are cooled to counter the high temperature effects which the hot exhaust gases would otherwise have on component materials. Commonly, at least the initial blade stages within the turbine 128 are cooled using air bled from various stages of the compressor 124 at a suitable pressure and temperature to effect flow of cooling fluid along exterior surfaces of materials which are in the path of the hot exhaust gases. For example, a plurality of cooling apertures may be formed through pressure and suction sidewalls of the blade. Conventionally, cooling fluid which flows through the base of the blade to the airfoil portion may follow a serpentine path within the airfoil to reach the apertures. Once the fluid exits the blade interior through the apertures it flows along exterior surface regions on both the pressure side and the suction side of the blade. For further details see U.S. Pat. No. 5,370,499 which is incorporated herein by reference.
According to numerous embodiments of the invention, a variety of cooling module arrays are disposed within the walls of different components positioned along the path of the hot exhaust gases. Thermal energy is transferred from the walls to cooling fluid which passes through modules in the arrays. One or more arrays of the modules can be disposed in any wall that requires cooling, e.g., walls for which temperature must be limited to preserve the integrity of the associated component.
In one example application of the invention, the modules 10 network units in an array formed within walls of multiple modular conduit sections 100 which are assembled to provide the transition exhaust ducts 136 for the system 120 shown in
With further reference to
The views of
The sides 14 of the cooling modules 10 are formed along the wall surface 14′ with openings corresponding to the output ports 34 of the modules 10. With this array configuration the net flow of cooling fluid is predominantly in the radial direction relative to axial flow of hot exhaust gases through the conduit section 100.
A feature of embodiments of the invention so far described is that each of the cooling modules in a conduit section 100 provides a set of paths wherein cooling fluid may flow in a radial direction (e.g., through module sections 18 and 20), a longitudinal direction i.e., along the direction of flow of the exhaust gas (e.g., traveling through the transition ducts 136 from transition chambers 56a, 56b of module sections 18, through openings 64a or 64b and into the chamber 40; and travelling from transition chambers 78a and 78b of module sections 22, through openings 82a or 84b and into chambers 48 of sections 24), a circumferential direction (e.g., travelling from chambers 46a-46d and through transition chambers 78a and 78b of module sections 22) and in a radial direction again (e.g., travelling through chambers 48 of module sections 24 to the output ports 34). Thus with the conduit section 100 formed with an array of the modules 10, there can be a sequence of flow directions comprising radial, longitudinal, radial, longitudinal, radial, longitudinal and radial directions, each corresponding to flow through a different chamber or between chambers.
In a second example application of the invention, the modules 10 are formed as an array of network units within walls of an airfoil to provide interior flow paths for cooling fluid. In embodiments according to the second example, the modules of different designs are formed in combination to provide module sections.
The module 210 is now briefly described. It is to be understood that, like the module 10, the module 210 includes a series of sections that each comprise one or more chambers for serial or parallel flow of cooling fluid therethrough. Also, like the module 10 and numerous other embodiments of modules according to the invention, alternate sections of the module 210 include a transition chamber connected to a pair of chambers. The transition chamber and the pair of chambers are in a “U” shape configuration to effect parallel flow of cooling fluid through the pair of chambers. To the extent that details of connections (e.g., via openings in walls of chambers) between chambers in the module 210 are not described, it will be understood that such connections can be effected in a manner similar to the connections described for the module 10.
The module 210 has a first, second, third and fourth module sections 218, 220, 222 and 224. The first section 218 comprises one transition chamber 230 coupled to receive cooling fluid from the chamber 48 of the section 24 of the first module 10. The first section 218 further includes two parallel chambers 232a and 232b each connected at a different end of the transition chamber 230 to receive cooling fluid from the transition chamber 230 for parallel flow of cooling fluid through the chambers 232a and 232b. The second section 220 comprises a single chamber 236 coupled at a first of two opposing ends thereof to receive cooling fluid from the two parallel chambers 232a and 232b. A second end of the second chamber 236 is coupled to send the received cooling fluid into a transition chamber 240 of the third section 222. The third section 222 further includes two parallel chambers 242a and 242b, each connected at a different end of the transition chamber 240 to receive cooling fluid from the transition chamber 240 for parallel flow of cooling fluid therethrough and into the chamber 246 of the fourth section 224. The fourth section 224 comprises a single chamber 246 coupled to receive the cooling fluid from both of the chambers 242a and 242b of the third section 222. Fluid passing through the chamber 246 exits the module 210.
The rotatable turbine blade 250 shown in the view of
The array 216, formed between the pressure and suction side walls 274, 276, extends as a vertical stack of the modules from above the platform 254 to near the upper end 268 at the top of the blade.
While the rotatable turbine blade 250 shown in the view of
Numerous concepts and designs have been illustrated which provide cooling along a hot surface. The invention is particularly useful in applications where hot gases flow through channels, including the flow of exhaust gases through liners or transition ducts that convey hot exhaust gases from a combustion section of an engine toward a turbine section. Such a liner or transition duct is disclosed in U.S. Pat. No. 5,415,000, issued May 16, 1995, entitled “Low Nox Combustor Retro-Fit System For Gas Turbines,” the entire disclosure of which is incorporated herein by reference. The conduit section 100 may also be the duct structure disclosed in U.S. application Ser. No. 11/498,479, filed Aug. 3, 2006, entitled “At Least One Combustion Apparatus and Duct Structure For a Gas Turbine Engine,” by Robert J. Bland, the entire disclosure of which is incorporated herein by reference.
Numerous variations, changes and substitutions may be made without departing from the invention. Accordingly, it is intended that the invention be limited only by the scope of the claims which follow.
This application relates to co-pending application Ser. No. 12/832,124 filed on 8 Jul. 2010 titled “Meshed Cooled Conduit for Conveying Combustion Gases” and co-pending application 12/908,029 filed on 20 Oct. 2010 titled “Airfoil Incorporating Tapered Cooling Structures Defining Cooling Passageways” and co-pending application 12/765,004 filed 22 Apr. 2010 titled “Discreetly Defined Porous Wall Structure for Transpirational Cooling.”
Number | Date | Country | |
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Parent | 13023716 | Feb 2011 | US |
Child | 14551211 | US |