This invention relates generally to a blade outer air seal for a gas turbine engine. More particularly, this invention relates to a blade outer air seal with improved cooling features.
A gas turbine engine includes a compressor, a combustor and a turbine. Compressed air is mixed with fuel in the combustor to generate an axial flow of hot gases. The hot gases flow through the turbine and against a plurality of turbine blades. The turbine blades transform the flow of hot gases into mechanical energy to rotate a rotor shaft that drives the compressor. A clearance between a tip of each turbine blade and an outer air seal is preferably controlled to minimize flow of hot gas therebetween. Hot gas flow between the turbine tip and outer air seal is not transformed into mechanical energy and therefore negatively affects overall engine performance. Accordingly, the clearance between the tip of the turbine blade and the outer air seal is closely controlled.
The outer air seal is exposed to the hot gases and therefore requires cooling. The outer air seal typically includes an internal chamber through which cooling air flows to control a temperature of the outer air seal. Cooling air is typically bleed off from other systems that in turn reduces the amount of energy that can be utilized for the primary purpose of providing thrust. Accordingly it is desirable to minimize the amount of air bleed off from other systems to perform cooling. Various methods of cooling the outer air seal are currently in use and include impingement cooling where cooling air is directed to strike a back side of an outer surface exposed to hot gases. Further, cooling holes are utilized to feed cooling air along an outer surface to generate a cooling film that protects the exposed surface. Each of these methods provides good results. However, improvements in gas turbine engines have resulted in increased temperatures and more extreme operating conditions for those parts exposed to the hot gas flow.
Accordingly, there is a need to design and develop a blade outer air seal that utilizes cooling air to the maximum efficiency to both increase cooling effectiveness and reduce the amount of cooling air required for cooling.
This invention is an outer air seal assembly for a turbine engine that includes a plurality of pedestals within two main cavities that produce a turbulent airflow and increase surface area resulting in an increase in cooling capacity for maintaining a hot side surface at a desired temperature.
The outer seal assembly includes a plurality of seal segments joined together to form .a shroud about a plurality of turbine blades. Each of the outer air seal segments includes the hot side exposed to the gas flow, and a back side that is exposed to a supply of cooling air. The outer air seal segment includes a leading edge, a trailing edge and two axial edges that are transverse to the leading and trailing edges. A trailing edge cavity and a leading edge cavity are separated within the seal segment. Cooling air introduced on the back side of the seal segment and enters each of the cavities to cool the hot side.
The cavities are feed cooling air through a plurality of inlet openings. The inlet openings are disposed transverse to the gas flow. Cooling air enters the cavities and flows toward a plurality of outlets at the leading edge and a plurality of outlets along the trailing edge. Cooling air also enters the cavities through a plurality of re-supply openings that introduce additional cooling air to local areas of the cavities for maximizing cooling and heat transfer functions.
The seal segment includes axial cavities disposed adjacent axial edges that provide cooling air flow to the axial edges for preventing hot gas from seeping between adjacent seal segments. The axial cavities include dividers to isolate cooling air flow from the other cavities.
The leading edge, trailing edge and axial cavities include a plurality of pedestals that disrupt and cooling air flow to increase heat absorption capacity and to increase the surface area capable of transferring heat from the hot side. Disruption of the cooling air flow creates desirable turbulent flow from the inlets to the outlets. Turbulent air flow provides an increased heat absorption capacity. Further, the increased surface area provided by the plurality of pedestals provides an increase in heat absorption capacity. The combination of increased turbulent flow and increased surface area increases the efficiency of the cooling features allowing less cooling air flow to be utilized to provide the desired cooling of the seal segment.
Accordingly, the blade outer air seal of this invention increase cooling air effectiveness providing for the decrease in cooling air required to maintain a desired temperature of an outer air seal.
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.
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Cooling air flow 44 entering the cavities 40,42 flows toward a plurality of outlets 50 at the leading edge 30 and a plurality of outlets 52 along the trailing edge 32. Cooling air flow 44 also enters the cavities through a plurality of re-supply openings 48. The re-supply openings 48 introduce additional cooling air 44 to local areas of the cavities 40,42 to optimize cooling and heat transfer functions.
The seal segment 22 also includes axial cavities 54 and 55 disposed adjacent axial edges 34. The axial cavities 54, 55 provide cooling air flow 44 to the axial edges 34 to prevent hot gas 12 from seeping between adjacent seal segments 22. The axial cavities 54, 55 include dividers 57 to isolate cooling air flow 44 from the other cavities. The axial cavities 54,55 receive cooling air flow from a re-supply opening 48 in communication with only that cavity.
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The pedestals 62 extend between the top surface 58 and the bottom surface 60 to form a honeycomb structure that creates a tortuous path for the cooling air flow 44. The pedestals 62 are cylindrical structures that disrupt the laminar flow of the cooling air flow 44. Disruption of the cooling air flow 44 creates desirable turbulent flow from the inlets 46 to the outlets 50,52. Turbulent air flow provides an increased heat absorption capacity. Further, the increased surface area provided by the plurality of pedestals 62 also provides an increase in heat absorption capacity. The combination of increased turbulent flow and increased surface area increases the efficiency of the cooling features allowing less cooling air flow to be utilized to provide the desired cooling of the seal segment 22.
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The seal segment 22 is constructed utilizing a lost core molding operation were a core is provided having a desired configuration that would provide the desired cavity structure. The core is over-molded with a material forming the segment. The material may include metal, composite structures or a worker versed in the art knows ceramic structures. The core is then removed from the seal segment 22 to provide the desired internal configuration of the cavities 40,42 and 54. As should be appreciated, many different construction and molding techniques for forming the seal segment 22 are within the contemplation of this invention.
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Further, a small peak indicated at 78 represents a location of the re-supply openings 48. The re-supply openings 48 provide additional cooling air flow 44 required to maintain and balance a relationship between cooling capacity and heat input into the seal segment 22. The leading edge cavity 42 and the trailing edge cavity 40 provide a cooling potential that matches the external heat loads on the seal segment 22. The pedestal geometries in each of the cavities 40,42 are adjusted to substantially match the external heat loads on the hot side 24 for any axial location. The specific location is determined according to application specific requirements to provide the desired cooling capacity in local areas of the seal segment.
The seal segment 22 of this invention provides improved heat removal properties by directing incoming cooling air flow 44 to the region of greatest heating and by generating turbulent flow over increased cavity surface area provided by the plurality of pedestals 62. The resulting seal segment 22 provides improved cooling without a corresponding increase in cooling air flow requirements.
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.
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4573866 | Sandy et al. | Mar 1986 | A |
5375973 | Sloop et al. | Dec 1994 | A |
5486090 | Thompson et al. | Jan 1996 | A |
5584651 | Pietraszkiewicz et al. | Dec 1996 | A |
6139257 | Proctor et al. | Oct 2000 | A |
6368054 | Lucas | Apr 2002 | B1 |
Number | Date | Country | |
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20060140753 A1 | Jun 2006 | US |