The present invention relates to tip shrouded turbine blades and, more particularly, to such blades having a sealing rail with a thickness that varies along a length of the rail in a circumferential direction.
U.S. Pat. No. 6,805,530 discloses an airfoil having a tip shroud and a seal extending radially from the shroud. A cutter tooth is located along the seal, between opposing ends of the shroud and in substantial radial alignment with a center of mass of the airfoil.
U.S. Pat. No. 6,241,471 discloses an airfoil having a tip shroud and a seal rail. Reinforcing bars are provided, each of which extends from the shroud to the seal rail, so as to stiffen the shroud.
In accordance with a first aspect of the present invention, a turbine blade is provided comprising: an airfoil including upper and lower ends; a root coupled to the airfoil lower end, the root adapted to couple the blade to a rotatable disk; a shroud coupled to the airfoil upper end; and at least one sealing rail extending radially outwardly from an upper surface of the shroud and extending generally along a circumferential length of the shroud. The sealing rail may comprise a mid-section, opposing end sections and at least one intermediate section located between the mid-section and one of the opposing end sections. An axial thickness of the rail may vary such that the mid-section has a first thickness, the intermediate section has a second thickness and the one end section has a third thickness. The first thickness may be greater than the second thickness and the second thickness may be greater than the third thickness.
The sealing rail mid-section may be radially positioned in-line with the airfoil.
The sealing rail mid-section may comprise first and second generally planar surfaces spaced apart from one another in the axial direction.
The sealing rail may have first and second outer surfaces. The first outer surface may have first and second sections each having a generally parabolic shape in a plane extending in the axial and circumferential directions.
The first and second generally parabolic sections may meet at a first point located at the mid-section.
The second outer surface may have third and fourth sections each having a generally parabolic shape in the plane extending in the axial and circumferential directions.
The third and fourth generally parabolic sections may meet at a second point located at the mid-section.
The first and second points may be spaced apart from one another in the circumferential direction.
The at least one sealing rail may comprise first and second sealing rails. Each of the rails may have an axial thickness varying such that a mid-section has a first thickness, an intermediate section has a second thickness and one of opposing end sections has a third thickness. The first thickness may be greater than the second thickness and the second thickness may be greater than the third thickness.
The intermediate section may be spaced circumferentially from the airfoil.
In accordance with a second aspect of the present invention, a turbine is provided comprising at least one row of circumferentially engaging tip shrouded blades. Each blade may comprise: an airfoil including upper and lower ends; a root coupled to the airfoil lower end, the root adapted to couple the blade to a rotatable disk; a shroud coupled to the airfoil upper end; and at least one sealing rail extending radially outwardly from an upper surface of the shroud and extending generally along a circumferential length of the shroud. The sealing rail may comprise a mid-section, opposing end sections and at least one intermediate section located between the mid-section and one of the opposing end sections. An axial thickness of the rail may vary such that the mid-section has a first thickness, the intermediate section has a second thickness and the one end section has a third thickness. The first thickness may be greater than the second thickness and the second thickness may be greater than the third thickness.
Referring now to
The blades are coupled to a shaft and disc assembly (not shown). Hot working gases from a combustor (not shown) in the gas turbine engine travel to the rows of blades. As the working gases expand through the turbine, the working gases cause the blades, and therefore the shaft and disc assembly, to rotate.
The turbine blade 10 comprises an airfoil 11 including an upper end 12 and a lower end 13. A root 14 is coupled to the airfoil lower end 13. The root 14 couples the blade 10 to the rotatable disk (not shown) of the shaft and disc assembly. The blade 10 further comprises a tip shroud 14 coupled to the airfoil upper end 12. The tip shroud 14 functions to keep hot working gases away from an engine casing and further functions to prevent the hot gases from passing over the airfoil upper end. In the embodiment illustrated in
In
In the embodiment illustrated in
The first outer surface 20A is defined by a first intermediate planar surface 22A, which forms part of the mid-section 22, and first and second generally curvilinear sections 40 and 42. The second outer surface 20B is defined by a second intermediate planar surface 22B, which also forms part of the mid-section 22, and third and fourth curvilinear sections 44 and 46. It is contemplated that the curvilinear sections 40, 42, 44 and 46 could alternatively be linear in shape or comprise a combination of linear and curvilinear portions.
The first curvilinear section 40 is generally parabolic in shape in a plane extending in the axial and circumferential directions A and C and extends from the first planar surface 22A to a first end face 224 of the sealing rail 20. The second curvilinear section 42 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the first planar surface 22A to a second end face 226 of the sealing rail 20. The third curvilinear section 44 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the second planar surface 22B to the first end face 224 of the sealing rail 20. The fourth curvilinear section 46 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the second planar surface 22B to the second end face 226 of the sealing rail 20.
A thickness of the sealing rail 20 in an axial direction, see arrow A in
It is noted that the mid-section 22, the widest portion of the sealing rail 20, is radially positioned in-line with the airfoil 11, see
During operation of the turbine, the shaft and disc assembly, including the row R of the blades 10, see
Referring now to
The sealing rail 120 comprises first and second outer surfaces 120A and 120B. The sealing rail 120 further comprises a mid-section 122, first and second opposing end sections 124 and 126, respectively, and first and second intermediate sections 128 and 130, respectively, located between the mid-section 122 and a corresponding one of the opposing end sections 124 and 126, see
The first outer surface 120A is defined by a first point 122A, which forms part of the mid-section 122, and first and second curvilinear sections 140 and 142. The second outer surface 120B is defined by a point 122B, which also forms part of the mid-section 122, and third and fourth curvilinear sections 144 and 146. It is contemplated that the curvilinear sections 140, 142, 144 and 146 could alternatively be linear in shape or comprise a combination of linear and curvilinear portions.
The first curvilinear section 140 is generally parabolic in shape in a plane extending in the axial and circumferential directions A and C and extends from the first point 122A to a first end face 324 of the sealing rail 120. The second curvilinear section 142 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the first point 122A to a second end face 326 of the sealing rail 120. The third curvilinear section 144 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the second point 122B to the first end face 324 of the sealing rail 120. The fourth curvilinear section 146 is generally parabolic in shape in the plane extending in the axial and circumferential directions A and C and extends from the second point 122B to the second end face 326 of the sealing rail 120.
A thickness of the sealing rail 120 in an axial direction varies such that the axial thickness decreases when moving along the rail 120 in the circumferential direction C from the mid-section 122 to one or both of the first and second opposing end sections 124 and 126. For example, the mid-section 122 has a first axial thickness T1, the first intermediate section 128 has a second axial thickness T2 and the first end section 124 has a third axial thickness T3. The first axial thickness T1 is greater than the second axial thickness T2 and the second axial thickness T2 is greater than the third axial thickness T3. Further, the second intermediate section 130 has a fourth axial thickness T4 and the second end section 126 has a fifth axial thickness T5. The first axial thickness T1 is greater than the fourth axial thickness T4 and the fourth axial thickness T4 is greater than the fifth axial thickness T5. It is contemplated that the first axial thickness T1 may be between about 20% to about 100% greater in size than the second and fourth axial thicknesses T2 and T4 and the second and fourth axial thicknesses T2 and T4 may be about 1% to about 30% greater in size than the third and fifth axial thicknesses T3 and T5.
Referring now to
Each of the first and second sealing rails 420 and 520 has a shape very similar to the shape of the sealing rail 120 illustrated in
In the
The second sealing rail 520 has an axial thickness that varies such that a mid-section 522 has a first thickness T1, intermediate sections 528 and 530 have second and fourth thicknesses T2 and T4 and opposing end sections 524 and 526 have third and fifth thicknesses T3 and T5. The first thickness T1 is greater than the second and fourth thicknesses T2 and T4 and the second and fourth thicknesses T2 and T4 are greater than the third and fifth thicknesses T3 and T5.
Both sealing rails 420 and 520 are adapted to be received in and move along corresponding grooves in a stationary honeycomb sealing structure.
Having described the invention in detail and by reference to preferred embodiments thereof, it will be apparent that modifications and variations are possible without departing from the scope of the invention defined in the appended claims.
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Number | Date | Country | |
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