(1) Field of the Invention
The present invention relates to a process for forming a turbine engine component, such as a turbine blade, having a plurality of as-cast blowing slots in a tip region using a refractory core element.
(2) Prior Art
One of the typical failure modes for high pressure turbine (HPT) rotor airfoils (blades) is tip distress via oxidation and erosion. It is particularly challenging to design a cooling configuration for a tip region for a variety of reasons. First, it is very difficult to determine the external thermal boundary conditions near the tip due to the highly-three dimensional nature of the gaspath flow. Also, the tip region of a turbine blade is typically the thinnest portion of the airfoil, which makes it more difficult to package the desired cooling features. Furthermore, the tip region of a turbine blade is typically difficult to accurately produce with investment casting processes because the internal ceramic core is thin and weak near the tip. Further, it is cantilevered relatively far from the core-locating fixture at the blade root. Considering these points, it is desirable to have methods to create intricate cooling features near the tip capable of being targeted at specific regions of high heat load, while also allowing for greater control during the investment casting process.
An existing HPT blade tip cooling design is shown in
The tip of the core in
In accordance with the present invention, there is provided a new tip cooling design that utilizes refractory metal core (RMC) technology in order to create a tip cooling scheme for a turbine engine component that is capable of more efficient use of cooling air and a more reliable casting process.
In accordance with the present invention, a process for forming an airfoil portion of a turbine engine component is provided. The process comprises the steps of placing a ceramic core having a configuration of a passageway to be formed in the airfoil portion within a mold; attaching a refractory metal core element to the ceramic core to stabilize a tip region of the ceramic core during casting; and casting the airfoil portion.
Further, in accordance with the present invention, there is in combination, a ceramic core for forming a passageway in a cast airfoil portion and means for stabilizing a tip region of the ceramic core. The stabilizing means comprises a refractory metal core element.
Still further, in accordance with the present invention, there is provided a refractory metal core element comprising a solid portion and a plurality of spaced apart legs depending from the solid portion. Each of the legs has a first portion adjacent the solid portion, a base portion, and an angled portion intermediate the first portion and the base portion so that the base portion is laterally offset from the solid portion. The base portions of the legs are preferably joined together by a lower portion.
Still further, in accordance with the present invention, there is provided a turbine engine component having an airfoil portion with a tip region, a shelf portion in said tip region, and a plurality of as-cast slots in the shelf portion through which a cooling fluid flows. The slots are located along a pressure side of the tip region.
Other details of the RMC-defined tip blowing slots for turbine blade of the present invention, as well as other objects and advantages attendant thereto, are set forth in the following detailed description and the accompanying drawings, wherein like reference numerals depict like elements.
As noted before, a new tip cooling design for a turbine blade is proposed here that utilizes refractory metal core technology in order to help create a tip cooling scheme that is capable of more efficient use of cooling air and a more reliable casting process.
Referring now to
The refractory metal core element 10 may be formed from any suitable refractory material known in the art such as molybdenum or a molybdenum alloy. The refractory metal core element 10, as shown in
As shown in
When the cooling air exits the RMC defined tip slots 30, the cooling air immediately flows into a tip gap between the blade tip 34 and the blade outer air seal (BOAS)(not shown) due to the strong pressure gradient towards the suction side 60 of the airfoil portion 42. Injecting the cooling air into the tip gap significantly reduces the gaspath temperature in the tip gap downstream of the slots 30, resulting in lower heat load to the tip region of the blade. This is a similar effect to film cooling on the body of an airfoil. Conventional tip print-out holes provide some film cooling benefit on the tip surface, but they are significantly less efficient than this new design because the conventional tip print-out holes are so large that they can only be located at one or two locations along the mid-thickness of the tip.
Another cooling benefit of the RMC-defined tip slots 30 is the substantial convective cooling of the pressure side region of the tip 34 due to the high-velocity cooling air flowing through the tip slots 30. This convective cooling is very effective at preventing oxidation and erosion along the pressure side edge 32 of the tip 34, which is a common location of tip distress. As a result of this increased convective cooling along the pressure side edge 32 of the tip 34, it is feasible to use fewer film cooling holes on the pressure side edge of the airfoil near the tip. In a prior art design, two rows of shaped cooling holes are provided along the pressure side near the tip. The purpose of these holes is to cool the tip region via film cooling and convective cooling.
The flexibility of the convective and film cooling aspects of the RMC-defined tip slots lends itself well to the challenge of designing a tip cooling configuration when the external boundary conditions are difficult to determine. Furthermore, the inherent strength of the refractory metal core element 10 during the casting process allows for increased design flexibility in the tip region. As a result, this new tip cooling configuration allows for more efficient use of cooling air and more predictable casting yields, resulting in a more cost-effective product.
Another advantage of this tip cooling configuration is that it is complimentary to tip blowing technology for aerodynamic performance benefits. Tip blowing utilizes a row of cooling air jets or holes 30 along the pressure side edge 32 of the blade tip 34, which act to improve aerodynamic efficiency by reducing endwall losses associated with gaspath leakage across the tip gap. The cooling holes 70 may be machined in the pressure side edge 32 after the blade and its airfoil portion have been cast. The cooling holes 70 may be machined using any suitable technique known in the art. The cooling holes 70 are preferably in fluid communication with the passageway 15. The RMC-defined cooling slots 30 may be situated along the recessed shelf 36 along the pressure side of the tip 34. The recessed shelf 36 will prevent the slots 30 from being unexpectedly closed during engine operation when the blade tip 34 rubs against the outer circumference of the gaspath. The recessed shelf 36 also allows for easier masking when applying abradable coating to the tip surface.
The tip portion 34 of the airfoil portion 42 of the turbine engine blade is a cast structure and is formed at the same time as the remainder of the cast portions of the turbine engine blade. For simplicity sake, only a portion of the mold 80 forming the tip region 34 of the airfoil portion 42 is illustrated in the drawings. It should be recognized that the mold 80 has a portion which is in the shape of the pressure side of the airfoil.
The tip portion 34 may be formed by placing the ceramic core 14 into a mold 80. After the ceramic core 14, as well as any other needed ceramic or silica cores, has been positioned, the refractory metal core element 10 may be attached to the ceramic core 14 using any suitable means known in the art, such as an adhesive or pins. The mold 80 is created after the ceramic core 14 and the RMC 10 are assembled. This is preferably done by first assembling the ceramic core 14 and RMC 10, then injecting wax around the cores 10 and 14 using a wax die, so that the external surface of the wax is the same geometry as the external surface of finished casting. Then, a ceramic shell is applied to the external surface of the wax pattern. Then, the wax is melted out, leaving the ceramic core 14, RMC 10 and ceramic shell (not shown). As previously mentioned, the refractory metal core element 10 serves to stabilize the tip region of the ceramic core 14. Thereafter the blade with the airfoil portion may be cast using any suitable technique known in the art. After casting has been completed, the ceramic core 14 may be removed using any suitable technique known in the art to leave the passageway 15. Similarly, the refractory metal core element 10 is removed, thus leaving the slots 30. The RMC 10 may be leached out of the casting using any suitable chemical bath known in the art, very similar to how the ceramic cores are leached. Thereafter, a plurality of cooling holes 70 may be machined into the tip region of the airfoil portion 42.
While the present invention has been described in the context of turbine blades, it should be apparent to those skilled in the art that the process of the present invention, as well as the refractory metal core element of the present invention, may be used to form tip blowing slots in other turbine engine components.
It is apparent that there has been provided in accordance with the present invention RMC-defined tip blowing slots for a turbine blade which fully satisfies the objects, means, and advantages set forth hereinbefore. While the present invention has been described in the context of specific embodiments thereof, other unforeseeable alternatives, modifications and variations may become apparent to those skilled in the art having read the foregoing description. Accordingly, it is intended to embrace those alternatives, modifications, and variations, as fall within the broad scope of the appended claims.