JP5638696B2 - Compressor and related gas turbine - Google Patents

Description

  The present invention includes a housing having a radially outer limit of an annular flow duct, and a compressor in which guide vanes of a vane ring extending radially through the flow duct are rotatably assembled inside the housing. The guide vane relates to a compressor having a first rotating part extending through the housing on the housing side and a second rotating part extending into the inner ring on the rotor side.

Known compressors of modern gas turbines include one or more compressor stages whose guide vanes are adjustable. Here, the guide vanes assigned to the corresponding rings can be adjusted with respect to the longitudinal axis in order to limit the mass flow. The capacity to limit the mass flow gives the compressor a larger operating range. In order to rotatably mount the guide vanes of such a compressor stage, a rotating part is provided at each end of the two blades of the guide vane. Here, the outer rotating part is supported in an annular housing, and the inner rotating part is supported in a so-called inner ring. In this case, the inner ring is held by all guide vanes. The inner ring is centered with respect to the rotor shaft through the radial position of the outer rotating part in the housing. Here, however, the radial adjustment of the vanes not only contributes to the positioning of the inner ring with respect to the rotor, but at the same time also sets the gap between the adjustable guide vane, the outer housing and the inner ring, in the blade adjustment process. This does not contact the boundary wall of the flow duct.

  Known designs for holding the inner ring provide a clear radial interlock between the guide vane and the inner ring, so greater mechanical stress is generated inside the individual inner ring bearings, It can cause significant wear of the bearing bush used there. Here, the mechanical stress during operation may also be exacerbated by thermal stress.

  U.S. Pat. No. 6,089,077 discloses an alternative variation of adjustable guide vane bearings. The device shown there comprises an inner ring divided into two equal segments. The ends of the segments are placed loosely relative to each other at the tongue and groove connection, and the inner rotating part of the adjustable guide vane is supported directly in the radial bore of the inner ring. This allows each segment to be supported by the associated guide vane bore, leading to increased wear.

US Pat. No. 2,671,634

  Accordingly, the object of the present invention comprises a fastening device for a guide vane that is rotatable about a longitudinal axis and an inner ring that is wear free and at the same time allows easy positioning of the inner ring associated with the rotor. Is to provide a compressor.

The object of the invention is achieved by a compressor according to the preceding stage of claim 1, in which the inner ring is formed as a split ring with two opposite ends and a spring element for widening the ring gap. Is provided. For this purpose, it has been proposed to attach a suitably encapsulated spring element in the region of the ring gap. Together with the upper and lower housing parts in the assembled state, this provides a radial preload on the inner ring. The radial preload contributes to pressing the inner ring against the second rotating part of the guide vane. This makes it possible to dispense with the radial fixing of the inner ring to all guide vanes. This means that the second rotating part extending into the inner ring is simply inserted into the individual bore or recess from the outside, and the positive radial interlock provided so far is It can be omitted . As a result, the guide vane can be provided with a second rotating part arranged radially inward and simply having a cylindrical design. The same applies to the bore in the inner ring, which receives the rotating part, and the inner ring according to the invention no longer comprises a continuous circumferential flange for positive interlocking. The potential distortion of the inner ring is avoided here by the absence of radial latches, which is a particular advantage. In addition, the simplification of the guide vane inner bearing design reduces assembly time.

  In thermal transient operation, the thermal expansion of the inner ring and all guide vanes is further compensated by the spring element, the stress between the inner ring and the inner point of the guide vane support is reduced, and the bearing Wear is also reduced.

  As a result, the introduction of spring elements allows the inner ring to be designed as a self-supporting and self-centering system, with only adjustable guide vanes located in the lower half of the vane ring, supporting the so-called floating inner ring. ing.

  A further advantage of the present invention is that thanks to the self-centering support of the inner ring, an adjustable device for the radial positioning of the guide vanes in the housing can be simplified. This simplification of the compressor reduces the likelihood of compressor failure thanks to the smaller number of parts used.

  Advantageous refinements are specified by the dependent claims.

  According to a first advantageous refinement of the invention, the two ends of the split ring comprise first sockets facing each other, which are essentially in the category of blind holes, on which spring elements rest. Has been. This identifies a relatively simple design for separating the split rings, and the spring element is implemented, for example, as a coil spring. Since the coil spring is placed in the socket, it prevents slipping.

  In order to protect the spring element from contamination, the spring element is advantageously enclosed in a capsule.

  Relative movement of the two ends of the inner ring in the axial direction can be prevented if these ends are locked in the axial direction. For example, this is done with a parallel key and predetermines the axial position of the two opposite ends of the split ring. For this purpose, parallel keys, for example, are likewise arranged in the socket, which sockets are provided for this purpose at both ends of the gap of the inner ring.

  According to a further advantageous refinement, the inner ring comprises at least two segments. Here the segments preferably extend to an arc length of 180 °. This allows a relatively easy assembly of the guide vanes in the compressor.

  A collar-like bush may be provided as wear lubrication between the second rotating part and each bore of the inner ring that receives the rotating part. In order to prevent contamination of the friction bearings of the rotating parts in the individual bores of the inner ring, a continuous circumferential groove is provided in the second rotating part, inside which a groove seal ring such as an O-ring is arranged. It is proposed that This reduces the radial wear of the inner bearing.

  Inner rings or segments that are relatively easy to produce can be designated if they are axially splittable. The segments or parts of the inner ring can be integrated by means of screws, for example by welding. However, the segment or inner ring is preferably not axially splittable.

  According to the invention, a stationary gas turbine with a housing that can be divided into equal parts and intended to generate electric power is provided with an inventive compressor according to the above-mentioned improvement.

  The invention is further described with reference to the exemplary embodiments represented in the figures.

FIG. 2 shows a detailed cross section of a compressor with compressor guide vanes rotatably supported at both ends and rotatable about their longitudinal axes. It is the figure which showed schematically the inner ring implemented as a split ring. FIG. 6 shows an example of a spring element arranged in a gap between two opposite ends of a split ring.

  FIG. 1 shows a cross section of an axial flow type compressor 10 in the shaft of a guide vane 14 that is rotatable about a longitudinal axis 12. The guide vane 14 is an inflow guide vane of the compressor 10, for example. However, they may form part of the vane ring of the subordinate compressor stage installed downstream thereof. The guide vane 14 comprises an aerodynamically curved blade 16 (only part of which is shown), on which a circular platform 20 is arranged at the radially inner end 18. The platform 20 is fused in the first cylindrical portion 22, and a circumferential groove 24 is formed therein to receive a sealing O-ring. Next to the first cylindrical portion 22 is a concentric second cylindrical portion having a smaller diameter. Both parts 22 and 23 are a part of the rotation part 26, and each is cylindrical. The collar-shaped bush 28 is disposed around the second cylindrical portion 23. The first cylindrical portion 22 and the collar-like bush 28 are placed in a socket 30 that matches their contours, and the socket is materialized as a stepped bore. Here, the bores are arranged in a so-called inner ring 32. An outer peripheral surface 34 of the inner ring 32 forms a radially inner limit of the annular flow duct 36 of the compressor 10. At the same time, the inner ring 32 surrounds the rotor 35 of the compressor 10. At the radially outer end (not shown) of the guide vane 14, the rotating part is provided in the housing forming the outer limit of the flow duct 36 according to a rule similar to the inner end 18.

  The selected design means in principle that the guide vanes 14 are simply inserted into the socket 30 radially from the outside. The radial direction here is related to the machine shaft 38 of the compressor 10, which extends along the compressor.

The inner ring 32 assembled from two segments 40 is shown schematically in FIG. Each of the two segments 40 has an arc length of 180 °. In the first connection area 42, the two segments 40 are screwed together with no gaps at the end surfaces. The other two end portions 44 of the segment 40 are arranged to face each other in the second connection area 46 forming the ring gap. The term ring gap is hereinafter abbreviated as gap 48. The second connection area 46 is shown in detail in FIG. A first socket 50 formed by a blind hole in each case is provided at each of the two end portions 44. The two first sockets 50 are arranged facing each other, and the encapsulated spring element 52 is placed in these sockets. In the exemplary embodiment, the spring element 52 is designed as a coil spring with a capsule 53. The spring element 52 is placed in the gap 48 under preload and the two ends 44 are about to be spaced apart. Therefore, the inner ring 32 is pressed against the rotating portion 26 of the guide vane 14 in the attached state. Self centering of the inner ring 32 is thereby achieved.

  According to the same rules as the first socket 50, sockets 54 are also provided at the two end portions 44, which are also arranged facing each other. For example, a centering element 56, which can be designed as a parallel key, is mounted in the second socket 54. This arrangement prevents relative movement of the two ends 44 in the axial direction, thereby allowing the two ends 44 to be locked. This prevents a load caused by a shearing force acting on the spring element 52.

Accordingly, the present invention generally relates to an axial compressor 10 with an annular flow duct 36 in which a vane ring adjustable guide vane 14 extending through the flow duct 36 is rotatably assembled. Each guide vane 14 on the rotor side includes a rotating portion 26 to be assembled to the inner ring 32 on the blade 16. In order to provide wear-free of the self-centering inner ring 32, the inner ring is realized as a split ring with two opposed ends 44, and a spring element 52 is provided for spreading the split ring.

DESCRIPTION OF SYMBOLS 10 ... Compressor 12 ... Longitudinal axis 14 ... Guide vane 16 ... Blade 18 ... Radial inner side edge part 20 ... Circular platform 22 ... First cylindrical part 23 ... First 2 Cylindrical part 24 ... Circumferential groove 26 ... Turning part 28 ... Bush 30 ... Socket 32 ... Inner ring 34 ... Outer peripheral surface 36 ... Annular flow duct 38 ... Machine Axis 40 ... Segment 42 ... First connection area 44 ... End 46 ... Second connection area 48 ... Gap 50, 54 ... First socket 52 ... Spring element 56 ..Centering elements

Claims (8)

A guide vane (14) of a guide vane rig having a housing forming a radially outer limit of the annular flow duct (36) and extending radially through the flow duct (36) is rotatably assembled in the housing. Each of the guide vanes (14) includes a first rotating part (26) extending through the housing on the housing side, and a second extending in the inner ring (32) on the rotor side. In the compressor (10) provided with the rotating part (26),
The inner ring (32) is formed as a split ring with two opposite ends (44), provided with a spring element (52) for spreading the split ring , the spring element ( 52) A compressor (10) characterized in that it is enclosed in a capsule .   The two ends (44) of the split ring comprise first sockets (50) facing each other, wherein the spring element (52) is placed in the socket. Compressor (10). The compressor (10) according to claim 1 or 2 , characterized in that the two ends (44) are axially locked to prevent relative movement of each other . It said inner ring (32) according to any one of claims 1 to 3, characterized in that it comprises at least two segments (40) compressor (10). The compressor (10) according to any one of claims 1 to 4 , characterized in that a colored bush (28) is arranged in each of the second rotating parts (26). The said 2nd rotation part (26) comprises the continuous circumferential groove (24), This circumferential groove is equipped with the seal ring mounted inside, The 1st Claim 5 characterized by the above-mentioned. A compressor (10) according to claim 1. It said inner ring (32) is a compressor according to any one of claims 1 to 6, characterized in that it is dividable in the axial direction (10). A gas turbine comprising the compressor (10) according to any one of claims 1 to 7 .

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