Patent Grant
7927073
The present invention is directed generally to cooling turbine components of gas turbine systems, and more particularly to cooling a fillet between an end wall and an airfoil in a gas turbine blade or vane.
Typically, gas turbine engines include a compressor for compressing air, a combustor for mixing the compressed air with fuel and igniting the mixture, and a turbine blade assembly for producing power. Combustors often operate at high temperatures that may exceed 2,500 degrees Fahrenheit. Typical turbine combustor configurations expose turbine blade and vane assemblies to these high temperatures. As a result, turbine rotating blades and turbine stationary vanes (hereafter “turbine airfoils”) must be made of materials capable of withstanding such high temperatures. In addition, turbine airfoils often contain cooling systems for prolonging the life of the turbine airfoils and reducing the likelihood of failure as a result of excessive temperatures.
Typically, turbine blades are formed from a root portion and a platform, or end wall, at one end and a generally elongated airfoil forming a blade that extends radially outward from the end wall. The blade is ordinarily composed of a tip opposite the root section, a leading edge, a trailing edge, a pressure side wall and a suction side wall. A turbine blade typically includes a fillet on the outer surface of the blade along the intersection of the generally elongated airfoil and the end walls. The inner aspects of most turbine blades contain an intricate maze of cooling channels forming a cooling system. The cooling channels in the blades may receive air from the compressor of the turbine engine and pass the air through the airfoil.
Turbine vanes are formed from a generally elongated airfoil, having a first end wall on one end and a second end wall on the opposite end of the airfoil. The airfoil itself generally has a leading edge, a trailing edge, a pressure side wall and a suction side wall. The elongated portion of the vane extends radially between the first end wall and the second end wall. A turbine vane may include a first fillet along the intersection of the generally elongated airfoil and the first end wall, and a second fillet along the intersection of the generally elongated airfoil and the second end wall. Much like blades, the inner aspects of most turbine vanes contain cooling channels forming a cooling system.
The cooling channels often include multiple flow paths that are designed to maintain the turbine airfoil at a relatively uniform temperature. However, localized hot spots may form where parts of the turbine airfoil are not adequately cooled. These localized hot spots may damage the turbine airfoil and may eventually necessitate replacement of the turbine airfoil.
One area of a turbine airfoil that is particularly difficult to cool is the fillet at the intersection between the generally elongated airfoil and the end wall. Such difficulty cooling fillets is a result of several factors. First, in order to handle high localized stress, the fillet is generally thicker than adjacent turbine airfoil components. Thus, conventional impingement cooling and convection cooling of the inner surface of the generally elongated airfoil or end plate is less effective for cooling the fillet region. Second, due to the high local Stresses, convection cooling holes that penetrate the outer surface of the fillet are not desirable because such holes may concentrate the local stresses thereby significantly reducing the useful life of the turbine airfoil. Finally, film cooling along the outer surface of the fillet generally provides only limited cooling to the fillet because the horseshoe vortex may sweep the film away from the fillet or the film has mixed with hot gases prior to reaching the fillet thereby substantially reducing the film's effectiveness. Thus, a need exists for providing effective direct cooling of blade fillets and vane fillets without reducing the useful life of the blades or vanes.
The present invention is directed to a cooling system that provides direct cooling to a fillet portion of a turbine airfoil at an intersection between the generally elongated airfoil and an end wall. The fillet cooling system effectively cools the large body mass typically found at the intersection between the generally elongated airfoil and the end wall by passing cooling fluid through fillet cooling channels positioned within close proximity to the outer surfaces of the airfoil. The fillet cooling system may also include one or more impingement plates positioned proximate to an inner surface of the side wall outer surface for increasing the cooling ability of the cooling system. The fillet cooling system may also include one or more vortex chambers for increasing the effectiveness of the cooling system. The fillet cooling system may also include one or more end wall film cooling channels.
The turbine airfoil may include a generally elongated airfoil having a leading edge, a trailing edge, a pressure side wall and a suction side wall, and an end wall extending generally orthogonal to the generally elongated airfoil and proximate an end of the generally elongated airfoil. The turbine airfoil may have an internal cooling system formed from at least one cooling cavity in the turbine airfoil.
The turbine airfoil may include at least one fillet cooling channel, passing proximate to the intersection between a side wall and the end wall. The fillet cooling channel may be positioned such that a first opening of the at least one fillet cooling channel is situated on an inner surface of the side wall, and a second opening of the at least one fillet cooling channel may be situated on the inner surface of the end wall. A portion of the fillet cooling channel may be positioned proximate to the intersection between the generally elongated airfoil and the end wall without breaching an outer surface of the turbine airfoil. The airfoil may include a fillet on the outer surface of the turbine airfoil that extends along the intersection between the generally elongated airfoil and the end wall.
The turbine airfoil may include a first impingement plate that may be positioned within the internal cooling system proximate to an inner surface of the end wall. This arrangement may form a first impingement plate cavity between the inner surface of the end wall and the first impingement plate.
The airfoil cooling system may include a second impingement plate. The second impingement plate may be positioned generally along the inner surface of the side wall. The airfoil cooling system may also include a closure plug attached to the inner surface of the side wall and located proximate to the end of the second impingement plate closest to the end wall. This arrangement may form a second impingement cavity between the inner surface of the side wall, the second impingement plate and the closure plug. The closure plug may be positioned on the side wall such that the end of the side wall proximate the end wall and the closure plug are on opposite sides of the first opening of a fillet cooling channel on the inner surface of the side wall.
The turbine airfoil may include a vortex plate positioned proximate to an end of the end wall proximate the side wall, whereby a vortex chamber may be formed proximate to the inner surface of the end wall and the vortex plate. The second opening of the at least one fillet cooling channel may be in fluid communication with the vortex chamber. The vortex plate may include at least one vortex orifice in fluid communication with the first impingement plate cavity.
The turbine airfoil may also include one or more end wall film cooling channels that extend obliquely relative to the end wall. An end wall film cooling channel may be positioned such that a first opening of the end wall film cooling channel may be situated on an inner surface of the end wall, and a second opening of the end wall film cooling channel may be situated on an outer surface of the end wall. The first opening of the end wall film cooling channel may be in fluid communication with the vortex chamber. The end wall film cooling channels may be offset from the fillet cooling channels such that none of the end wall film cooling channels intersect with any of the at least one fillet cooling channels.
In addition to the vortex plate, the cooling system may include a second impingement plate. The second impingement plate may be positioned generally along the inner surface of the side wall. A closure plug may be attached to the inner surface of the side wall and proximate to the end of the second impingement plate closest to the end wall, thereby forming a second impingement cavity between the inner surface of the side wall, the second impingement plate and the closure plug. Finally, the closure plug may be positioned on the side wall such that the end of the side wall proximate the end wall and the closure plug are on opposite sides of the first opening of the at least one fillet cooling channel on the inner surface of the side wall.
An advantage of this invention is that it provides direct convection cooling to the airfoil fillet region without creating areas of concentrated local stress and reducing the useful life of the airfoil. Another advantage of the invention is that it provides a cooling method that delivers impingement cooling, vortex cooling, or both, to the fillet region. Yet another advantage of the invention is that it provides an integrated fillet cooling system that provides both direct convection cooling of the fillet region without reducing the useful life of the airfoil combined with impingement cooling, vortex cooling, or both, to the fillet region.
These and other embodiments are described in more detail below.
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.
This invention is directed to a turbine airfoil 12 that includes a fillet cooling system 17 designed to provide direct cooling to the fillet 24. Although the fillet 24 of a turbine vane 12 is used to illustrate the present invention, it should be understood that the invention applies equally to fillets 24 of turbine blades 12. In order to make application of the present invention to blades more apparent, where possible the detailed description uses terminology that may be applied to turbine airfoils 12, whether a blade 12 or a vane 12.
Each side wall 26, 28 may have a side wall inner surface 43 and a side wall outer surface 44. Similarly, each end wall 18 may have an end wall inner surface 30 and an end wall outer surface 42. The fillet 24 may have a fillet outer surface 46.
The turbine airfoil 12 may also include a fillet cooling channel 36, having a first fillet cooling channel opening 38 situated in a side wall inner surface 43 and a second fillet cooling channel opening 40 situated in an end wall inner surface 30. The fillet cooling channel 36 may pass proximate to the fillet 24 yet not breach an outer surface 42, 44, 46 of the turbine airfoil 12.
As shown in
A cooling fluid may flow from a first fillet cooling channel opening 38 to a second fillet cooling channel opening 40 and may provide convection cooling directly to the fillet 24. As shown in
There are many possible configurations and orientations for the at least one fillet cooling channels 36. For instance, the number of fillet cooling channels 36, the spacing of the fillet cooling channels 36, the diameter of the fillet cooling channels 36, and the angle, hereafter angle theta (θ), between the fillet cooling channel 36 with respect to an axis 60 defined by the end plate outer surface 42, are all variables that may be adjusted to deliver the desired level of cooling to the fillet 24. As shown in
Another variable for the fillet cooling channels 36 is the pressure difference between the first fillet cooling channel opening 38 and the second fillet cooling channel opening 40. Depending on the relative pressure difference, cooling fluid may flow from the first fillet cooling channel opening 38 to the second fillet cooling channel opening 40 or vice versa. The pressure difference at each opening 38, 40 of a fillet cooling channel 36 may be controlled by a number of means including, but not limited to, use of an impingement plate 32, 48, use of a vortex plate 54, perforation density in an impingement plate 32, 48 or vortex plate 54, the fluid supply pressure in a cavity 14, 34, 52, 56 adjacent to each fillet cooling opening 38, 40, the number and size of fillet cooling holes 36, and the number and size of end wall film cooling channels 62.
Referring now to
The vortex chamber 56 may utilize cooling fluid traveling between a second fillet cooling channel opening 40 and a vortex orifice 58 or an end wall film cooling channel 62 to create a high velocity vortex proximate to the end wall inner surface 30 nearest the fillet 24. This high velocity, vortex of cooling fluids may have a higher heat transfer coefficient than cooling fluid used in convection cooling or impingement cooling. Thus, the vortex chamber 56 may provide better cooling of the airfoil 12, such as the end wall inner surface 30 and the fillet 24, than conventional cooling methods.
As shown in
The turbine airfoil 12 may also include at least one end wall film cooling channel 62, that extends obliquely relative to the end wall 18, as shown in
The end wall film cooling channels 62 may be used to exhaust cooling fluid from the vortex chamber 56. The end wall film cooling channels 62 may also provide convection cooling to the fillet 24 by cooling adjacent portions of the end wall 18 and film cooling to the end wall outer surface 42.
The characteristics of a vortex formed within the vortex chamber 56 may be dependent on a number of factors. For instance the size, spacing, and location of the one or more vortex orifices 58 may have a significant impact on the pressure within the vortex chamber 56 and the flow of cooling fluid within the vortex chamber 56. Other variables include the size, spacing, location and angle theta (θ) of the fillet cooling channels 36 in fluid communication with the vortex chamber 56. Yet other variables include the size, spacing, location and angle of the end wall film cooling channels 62 in fluid communication with the vortex chamber 56.
The efficiency of the vortex cooling may also be improved by creating additional turbulence within the vortex chamber 56 by adding texture to the end wall inner surface 30, the vortex plate 54, or other surfaces in thermal communication with the fillet 24. Additional cooling of the fillet 24 may also be achieved by increasing the surface area of the end wall inner surface 30, the vortex plate 54, or other surfaces in thermal communication with the fillet 24. Texture and additional surface area may be created by including surface features including, but not limited to, surface roughness, ribs, or pedestals on a surface of a portion of a surface 30, 54 defining the vortex chamber 56 that is in thermal communication with the fillet 24.
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.
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| Number | Date | Country | |
|---|---|---|---|
| 20080166240 A1 | Jul 2008 | US |
