This application relates generally to a turbine seal and damper assembly and specifically to a nested seal and damper assembly.
Conventional gas turbine engines include a turbine assembly that has a plurality of turbine blades attached about a circumference of a turbine rotor. Each of the turbine blades is spaced a distance apart from adjacent turbine blades to accommodate movement and expansion during operation. The blades typically include a root that attaches to the rotor, a platform and a blade that extends radially outwardly from the platform.
Problems arise when hot gases penetrate below the platform of the turbine blades. Hot gases flowing over the platform are prevented from leaking between adjacent turbine blades by a seal. This is done because components below the platform are generally not designed to operate for extended durations at the elevated temperatures of the hot gases. The seal is typically a metal sheet nested between adjacent turbine blades on an inner surface of the platform. The seal is typically flexible so as to conform to the inner surface of the platform and prevent the intrusion of hot gases below the platform of the turbine blade. Typically, the seal is disposed against a radially outboard inner surface of the platform of the turbine blade.
In addition to the seal it is common practice to include a damper between adjacent turbine blades to dissipate potentially damaging vibrations. A damper is typically sized to provide sufficient mass and rigidity to dissipate vibration from the turbine blade. Vibrations from the turbine blade are transmitted through frictional contact between the damper and an inner surface of the turbine blade platform. Dampers provide the maximum benefit and dampening when positioned at a radial outermost part of an inner surface of the platform.
Disadvantageously, both the damper and the seal perform to the maximum benefit when positioned against the inner surface of the platform. As appreciated, it is only possible to position either the seal or the damper immediately adjacent the inner surface.
A currently proposed solution provides a single part that performs as both the seal and as the damper. Such a device provides for the desired location of both the damper and the seal. However, the material properties of the seal and the damper are compromised to accommodate the separate functions. That is the seal material is not as flexible as desired in order to provide the dampening properties required and the damper material does not provide the most beneficial dampening properties in order to provide some flexibility for the seal. The compromise between favorable dampening properties and favorable seal properties yields less than desirable performance for both functions.
Accordingly, it is desirable to develop a seal and damper assembly utilizing the most beneficial material for each function while providing the most beneficial placement of the damper and seal.
This invention is a damper-seal assembly for a turbine blade that includes a seal nested within a damper such that both the seal and damper are disposed at an interior outer most surface of the turbine blade.
The damper-seal assembly includes the seal that prevents hot gases from penetrating a gap between adjacent turbine blades. The seal abuts the inner surface of the platform and bridges the gap to block the flow of hot gases. The damper includes a recess within which the seal nests. On each side of the recess the damper includes a surface that contacts the inner most surfaces of the turbine blade. The surface of the damper provides frictional contact that absorbs vibrational energy from the turbine blade generated during operation.
The damper-seal assembly is assembled within a cavity of the turbine blade such that both the damper and the seal are adjacent the inner surface. Both the damper and the seal provide the most benefit by being located at the radially outermost point within the cavity.
The damper-seal assembly of this invention provides for the use of separate material for the seal and the damper while providing for optimal placement of both the seal and the damper. The seal includes a plastically deformable material that provides the desired seal to prevent the intrusion of hot gases and the damper provides the dense rigid structure necessary for absorbing vibrational energy generated during operation.
Accordingly, the damper-seal assembly of this invention provides for the most beneficial material for each function and the most beneficial placement of the damper and 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.
Referring to
Hot gas 24 flows around the airfoil 22 and over the outer surface 18. A gap 26 extends axially between adjacent turbine blades 12. The gap 26 prevents contact between the turbine blades 12. A damper-seal assembly 28 includes a seal 30 that prevents hot gases 24 from penetrating the gap 26 and penetrating the underside of the platform 16. The seal 30 is positioned within a cavity 32 formed between adjacent turbine blades 12. The seal 30 abuts the inner surface 20 of the platform 16 and bridges the gap 26 to block the flow of hot gases. The cavity 32 of the turbine blade 12 includes a nub 36 for aligning and positioning the damper-seal assembly 28.
Referring to
Referring to
The damper 34 includes a body portion 50 and seal retention arms 52 that extend forward of the body portion 50 for supporting a forward portion of the seal 30. The damper 34 includes rub surfaces 46 disposed on either side of the recess 38. The rub surfaces 46 are in frictional contact with the inner surface 20 along a plane common with the seal 30. The damper 34 includes retention features 54 that correspond to the cavity 32 to position and secure the damper-seal assembly 28 relative to the inner surface 20. An alignment feature 56 is also included and juts from the body 50 on each side of the damper 34. Stiffening portions 58 extend the rub surfaces 46 on each side of the damper 34. The stiffening portions 58 strengthen and reinforce the rub surfaces 46.
The damper 34 is fabricated from a material that does not plastically deform under the thermal and centrifugal loads produced during operation. Further the material utilized for the damper 34 is selected to provide desired vibration dampening properties in addition to the thermal capacity. The damper 34 is placed under centrifugal loading against the inner surface 20 of the platform 16. Although a preferred configuration of the damper 34 is shown, a worker with the benefit of this disclosure would understand that different configurations and features of the damper 34 are within the contemplation of this invention and dependent on application specific requirements.
The seal 30 is preferably a thin sheet of metal that includes a forward portion 60 that fits onto the retention arms 52 of the damper 34. The fingers 44 interfit the damper 34 and hold the seal 30 nested within the recess 38. The seal 30 is preferably flexible to conform to the inner surface 20 to provide a desired seal against the intrusion of hot gases 24 under the turbine blade 12. A rearward portion 62 extends axially rearward and extends inboard to conform and seal with the configuration of the axially extending gap 26. The material utilized for the seal 30 is selected to withstand the pressures and temperatures associated with a specific application and to allow for some plastic deformation. The seal 30 plastically deforms responsive to the thermal and centrifugal loads to conform and fit the contours of the inner surface 20. The plastic deformation provides a desired seal against the intrusion of hot gases 24.
Referring to
The damper-seal assembly 28 of this invention provides for the use of separate material for the seal 30 and the damper 34 while providing for optimal placement of both the seal 30 and the damper 34. The seal 30 includes a plastically deformable material that provides the desired seal to prevent the intrusion of hot gases 24 and the damper 34 provides the dense rigid structure necessary for absorbing vibrational energy generated during operation.
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.
The US Government may have certain rights in this invention in accordance with Contract Number N00019-02-C-3003 awarded by the United States Navy.