This application relates to a method of forming a turbine blade with triangular/trapezoidal serpentine cooling passages with a unique tooling die construction.
Turbine blades are utilized in gas turbine engines. As known, a turbine blade typically includes a platform, with an airfoil shape extending above the platform to the tip. The airfoil is curved, extending from a leading edge to a trailing edge, and between a pressure wall and a suction wall.
Cooling circuits are formed within the airfoil body to circulate cooling fluid, typically air. One type of cooling circuit is a serpentine channel. In a serpentine channel, air flows serially through a plurality of paths, and in opposed directions. Thus, air may initially flow in a first path from a platform of a turbine blade outwardly through the airfoil and reach a position adjacent an end of the airfoil. The flow is then returned in a second path, back in an opposed direction toward the platform. Typically, the flow is again reversed back away from the platform in a third path.
The location and shape of the paths in a serpentine channel has been the subject of much design consideration.
During operation of the gas turbine engine, the cooling air flowing inside the paths is subjected to a rotational force. The interaction of the flow through the paths and this rotational force results in what is known as a Coriolis force which creates internal flow circulation in the paths. Basically, the Coriolis force is proportional to the vector cross product of the velocity vector of the coolant flowing through the passage and the angular velocity vector of the rotating blade. Thus, the Coriolis effect is opposite in adjacent ones of the serpentine channel paths, dependent on whether the air flows away from, or towards, the platform.
To best utilize the currents created by the Coriolis effect, designers of airfoils have determined that the flow channels, and in particular the paths that are part of the serpentine flow path, should have a triangular/trapezoidal shape. Essentially, the Coriolis effect results in there being a primary flow direction within each of the flow channels, and then a return flow on each side of this primary flow. Since the cooling air is flowing in a particular direction, designers in the airfoil art have recognized the heat transfer of a side that will be impacted by this primary direction will be greater than on the opposed side. Thus, trapezoidal shapes have been designed to ensure that a larger side of the cooling channel will be impacted by the primary flow direction.
To form cooling channels, a so-called lost wax molding process is used. Essentially, a ceramic core is initially formed in a tooling die. Wax is placed around that core to form the external contour of the turbine blade. An outer mold, or shell is built up around the wax using a ceramic slurry. The wax is then melted, leaving a space into which liquid metal is injected. The metal is then allowed to solidify and the outer shell is removed. The ceramic core is captured within the metal, forming the blade. A chemical leeching process is utilized to remove the ceramic core, leaving hollows within the metal blade. In this way, the cooling passages in the blade are formed.
There are challenges in forming triangular/trapezoidal cooling channels using existing methods. As shown in
As mentioned, due to the Coriolis effect, as the blade rotates, the heat transfer characteristics will differ dependent on whether the air is moving outwardly or inwardly relative to the platform.
Thus, as shown in
As shown schematically in
The prior art core to make the blade of
As shown in
As shown in
At the end of formation, the process proceeds in the reverse direction with the inserts 58-59 and 60-61 being moved away from each other, and the die halves 50 and 52 then being moved away from each other, leaving the ceramic core. As can be appreciated, it would be impossible to withdraw the extensions 54 and 56 if they were at an angle that was non-parallel to a direction of movement of the die halves. As such, this prior art molding process cannot be utilized to make the
In the disclosed embodiment of this invention, a die is utilized to form a ceramic core, wherein the ribs are within a serpentine passage are non-parallel to each other. In one method, at least one of a plurality of moving members, which together form a space for forming the ceramic core, have rib extensions that are non-parallel to other of the moving parts. At least one moving part contacts at least two other moving parts. Also, at least one of the moving parts entirely forms a rib extension on its own, without abutting an extension from another of the moving parts.
In the disclosed embodiment, the insert for forming one of the leading or trailing edges is provided with rib extensions which not only form the ribs adjacent one of the leading or trailing edges, but also forms some of the ribs between the serpentine cooling passages. Thus, there is at least one rib formed between serpentine passages that is parallel to ribs formed adjacent the one of the leading and trailing edges, and other ribs intermediate the two parallel ribs which are non-parallel.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
As can be appreciated from the above, triangular/trapezoidal shaped passages 122, 124, 126, 128 are desirable. However, the die such as shown in prior art
The die shown in
As shown in
As with the prior art, once the core has been formed, the steps are reversed to release the core.
The present invention thus provides a simple method for forming a very complex internal flow passage.
Although a preferred embodiment of this invention has been disclosed, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.