This invention relates generally to turbine rotor assemblies and, more particularly, to seal systems for sealing radial leakage in turbine bucket covers.
Known steam turbines are classified as action turbines, or “constant-pressure” turbines and reaction turbines, or “excess-pressure” turbines. Each turbine includes a turbine shaft that includes moving blades, or buckets positioned circumferentially around the shaft, and includes an inner casing with guide blades, or diaphragms positioned between axially spaced buckets.
In the case of a constant-pressure turbine, the entire energy gradient is converted essentially into kinetic flow energy in the ducts that are narrowed by the guide blades. During the process, the velocity rises and the pressure falls. In the moving blades, the pressure and relative velocity remain essentially constant, being achieved through ducts having a uniform clear width. Because the direction of the relative velocity changes, action forces occur that drive the moving blades and, thus, cause rotation of the turbine shaft. The magnitude of the absolute velocity decreases considerably when the flow passes around the moving blades, resulting in a flow that transfers a large part of its kinetic energy to the moving blades and, therefore, to the turbine shaft.
In the case of an excess-pressure turbine, only part of the energy gradient is converted into kinetic energy when the flow passes through the guide blades. The rest of the energy gradient brings about an increase in relative velocity within the moving-blade ducts formed between the moving blades. Where the blade forces are almost exclusively action forces in the constant-pressure turbine, in an excess-pressure turbine, a greater or lesser fraction resulting from the change in the velocity magnitude is added. The term “excess-pressure” turbine is derived from the pressure difference between the downstream and the upstream side of the moving blade. In an excess-pressure turbine, therefore, a change in the velocity magnitude takes place when the pressure varies.
A turbine typically includes at least one rotor including a plurality of rotor buckets or blades that extend radially outwardly from a plurality of wheels attached to a common annular shaft. Specifically, the rotor buckets are attached to the wheels with dovetail joints. A radial extrema of the bucket, or tip may support a cover that joins the tips of a plurality of buckets circumferentially around the periphery of the turbine. In some known bucket designs the cover is individual to each bucket and integrally cast with the bucket during manufacture.
A gap between adjacent bucket covers may define a radial leakage path that may allow the working fluid to escape the bucket surfaces and adversely affect an operational efficiency of the turbine.
To facilitate reducing radial leakage, rotor assemblies may include sealing covers. At least some known rotor assemblies include additional loose fitting seals that are separate from the bucket covers. The seals block the leakage path to reduce radial leakage.
During operation, forces induced within the bucket may cause the adjacent bucket covers to flex and to separate from each other increasing the width of the leakage gap. Over time, continued leakage between the adjacent bucket covers may erode the covers where adjacent covers adjoin and increase leakage flow, adversely affecting the turbine operational efficiency.
In one aspect, a method of fabricating a rotor assembly for a turbine is provided. The method facilitates minimizing radial leakage of a working fluid, the rotor assembly is rotatable about a longitudinal axis, and includes a radially outer rim and a plurality of buckets that extend radially outward from the radially outer rim, each of the buckets includes a blade including a pair of opposing sidewalls. The method includes forming a cover on each bucket radial tip wherein the cover includes a leading edge side in a direction of rotation, and a trailing edge side in the direction of rotation wherein the leading edge and trailing edges are parallel with respect to each other, and wherein the leading edge and trailing edges are skewed with respect to the axis of rotation. The method includes forming an extension in the cover leading edge side, forming a groove in the cover trailing edge side, and attaching each bucket to the radially outer rim, such that the extension in the cover leading edge side of one cover is in mating engagement with the groove in the cover trailing edge side of an adjoining cover.
In another aspect, a rotor assembly for a turbine is provided. The rotor assembly is rotatable about a longitudinal axis of the rotor assembly, and includes a radially outer rim and a plurality of buckets that extend radially outward from the radially outer rim wherein each of the buckets includes a blade that includes a pair of opposing sidewalls. The rotor assembly includes a cover formed on each bucket radial tip wherein the cover includes a leading edge side in a direction of rotor assembly rotation, and a trailing edge in the direction of rotor assembly rotation wherein the leading edge and trailing edges are parallel with respect to each other, and wherein the leading edge and trailing edges are skewed with respect to the axis of rotation. The rotor assembly also includes an extension formed in the cover leading edge side, and a groove formed in the cover trailing edge side, and wherein each bucket is attached to the radially outer rim, such that the extension in the cover leading edge side of one cover is in mating engagement with the groove in the cover trailing edge side of an adjoining cover.
A steam turbine is provided that includes a rotor assembly rotatable about a longitudinal axis of the rotor assembly, that includes a radially outer rim and a plurality of buckets that extend radially outward from the radially outer rim wherein each of the buckets includes a blade that includes a pair of opposing sidewalls, a cover that is formed on each bucket radial tip, wherein the cover includes a leading edge side in a direction of rotor assembly rotation, and a trailing edge in the direction of rotor assembly rotation wherein the leading edge and the trailing edge are parallel with respect to each other, and wherein the leading edge and the trailing edge are skewed with respect to the axis of rotation, and the cover is formed integrally with the blade. The steam turbine also includes a semi-circular extension formed in the cover leading edge side, and a semi-circular groove formed in the cover trailing edge side, and wherein each bucket is attached to the radially outer rim, such that the extension in the cover leading edge side of one cover is in mating engagement with the groove in the cover trailing edge side of an adjoining cover such that adjoining sides of the covers are slidingly engaged and in substantially metal-to-metal contact.
In operation, steam 24 enters an inlet 26 of turbine 10 and is channeled through nozzles 22. Nozzles 22 direct steam 24 downstream against buckets 20. Steam 24 passes through the remaining stages imparting a force on buckets 20 causing rotor 12 to rotate. At least one end of turbine 10 may extend axially away from rotor 12 and may be attached to a load or machinery (not shown), such as, but not limited to, a generator, and/or another turbine. Accordingly, a large steam turbine unit may actually include several turbines that are all co-axially coupled to the same shaft 14. Such a unit may, for example, include a high-pressure turbine coupled to an intermediate-pressure turbine, which is coupled to a low-pressure turbine. In one embodiment, steam turbine 10 is commercially available from General Electric Power Systems, Schenectady, N.Y.
Blades 108 are configured for cooperating with a motive or working fluid, such as steam. In the exemplary embodiment illustrated in
Blades 108 rotate about the axial centerline axis up to a specific maximum design rotational speed, and generate centrifugal loads in rotating components. Centrifugal forces generated by rotating blades 108 are carried by dovetails 104 and portions of shaft 106 directly below each blade 108. Rotation of rotor assembly 100 and blades 108 from steam passing past blades 108 removes energy from the steam.
Blades 108 each include a leading edge 114, a trailing edge 116, and an airfoil 118 extending therebetween.
Cover 110 includes a leading edge side 134 in a direction 136 of rotation, and a trailing edge side 138 in direction 136 of rotation. Cover 110 also includes an inlet edge side 140 and an outlet edge side 142 wherein inlet and outlet are referenced to a direction 144 of steam flow past airfoil 118. Leading edge side 134 is parallel with trailing edge side 138, and inlet edge side 140 and outlet edge side 142 are parallel. Leading edge side includes an extension 146 that extends circumferentially from leading edge side 134 toward trailing edge side 138 of adjacent cover 110. Trailing edge side 138 of cover 110 each includes a groove 148 that extends inwardly from trailing edge side 138 into cover 110. Groove 148 is sized and positioned to receive extension 146 in a sliding engagement.
In the exemplary embodiment, joint 149 includes metal-to-metal contact between corresponding surfaces of adjacent covers 110. Specifically, inner radial portion 150 of leading edge side 134 and inner radial portion 162 of trailing edge side 138 are butted together such that no intended gap exists between their respective surfaces. Likewise, outer radial portions 152 and 164 are similarly butted together such that substantially no gap exists between their respective mated surfaces. Additionally, extension 146 is received in groove 148 such that no intended gap exists between their respective surfaces. Further, leading edge side 134 and trailing edge side 138 are able to slide approximately axially, with respect to each other. Leading edge side 134 and trailing edge side 138 are restrained from sliding radially with respect to each other due to the engagement in the radial direction of extension 146 in groove 148.
In operation, during a startup of turbine 10, steam 24 is admitted into inlet 26. Steam 24 is directed past airfoil 118 between shoulder 112 and covers 110. Initially, steam 24 is hotter than airfoil 118, shoulder 112, and covers 110, and transfers heat to airfoil 118, shoulder 112, and covers 110. The heat causes expansion of airfoil 118, shoulder 112, and covers 110 which may be uneven and may tend to cause warpage of airfoil 118, shoulder 112, and covers 110. Additionally, steam 24 may tend to leak past joint 149 due to a pressure gradient that may exist across covers 110. To relieve compressive forces which may build up in airfoil 118 due to a thermal expansion of airfoil 118, covers 110 of adjacent buckets 102 may slide axially, allowing the compressive forces to dissipate. Because of the metal-to-metal engagement of sides 134 and 138 including extension 146 and groove 148, respectively, steam 24 is facilitated being blocked during expansion of the components within turbine 10.
The above-described rotor assembly is cost-effective and highly reliable. The rotor assembly includes an integral cover for each bucket that interlocks with each adjacent bucket to facilitate sealing radial leakage of working fluid. More specifically, seals include an extension and a groove formed in the cover that cooperate during various operational modes to maintain contact between the covers of adjacent covers. The covers are skewed with respect to a longitudinal axis and are slidably engaged to facilitate maintaining a seal between adjacent covers while facilitating stress relief between adjacent covers. During operation, the differential expansion of turbine bucket airfoils and covers may tend to open the cover seals. Additionally, a force generated by the differential expansion turbine bucket airfoils and covers may induce compressive stress in the turbine bucket airfoils and covers. The groove and extension seal, and skewed cover facilitate relieving the stress while maintaining the seal between adjacent covers. As a result, the bucket covers facilitate sealing a radial leakage area in the rotor assembly.
Exemplary embodiments of rotor assembly components are described above in detail. The components are not limited to the specific embodiments described herein, but rather, components of each assembly may be utilized independently and separately from other components described herein. Each rotor assembly component can also be used in combination with other rotor assembly components.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
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Number | Date | Country | |
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20040120819 A1 | Jun 2004 | US |