The present invention relates to a housing-side structure of a turbomachine. In addition, the present invention relates to a turbomachine.
DE 10 2004 037 955 A1 describes a turbomachine having a stator and a rotor, the rotor having moving blades and the stator having a housing and guide blades. The rotor-side moving blades form at least one moving blade ring, which is adjacent to a radially inner housing wall of the housing on a radially outer end, is surrounded by same, and restrains a radial clearance with same. The radially inside housing wall of the housing is also referred to as the inner ring or the jacket ring and functions in particular as a carrier for an abradable lining. The inner ring or jacket ring of a compressor or a turbine may be segmented and may thus be composed of multiple jacket ring segments; a jacket ring segment may also be referred to as a shroud. It is also known from DE 10 2004 037 955 A1 that the clearance between the jacket ring of the housing and the radially outer end of the/each moving blade ring may be adjusted or adapted to provide a so-called active clearance control via control elements in its clearance, to thereby automatically influence the clearance and ensure an optimum clearance control and thus an optimum surge margin and optimum efficiency across all operating conditions. According to this prior art, a control element, preferably designed as electromechanical actuators, is assigned to each jacket ring segment of the jacket ring. An active clearance control principle may thus be provided in this way.
The clearance control of the clearance between the radially outer ends of the moving blades of a moving blade ring and the inner ring or jacket ring of the housing via active clearance control is structurally complex. It is therefore desirable to implement the clearance control with little complexity.
It is an object of the present invention to provide a housing-side structure of a turbomachine, which allows a novel and simple clearance control principle. The present invention provides a housing-side structure of a turbomachine so that a jacket ring carrying the abradable lining is connected via at least one constriction to a stator-side housing part, which is radially adjacent to the jacket ring on the outside and is thermally decoupled from same.
With the housing-side structure of a turbomachine according to the present invention, thermal overshooting is reduced as a result of thermal decoupling of the jacket ring or inner ring from the radially adjacent outside housing, in particular in transient operating ranges of the turbomachine during acceleration or deceleration of same, making it possible to improve clearance control between the moving blade ring and the jacket ring radially adjacent to the moving blade ring on the outside. The thermal decoupling is achieved via at least one constriction between the jacket ring and the housing part radially adjacent to same on the outside. An inexpensive, weight-optimized, reliable and simple compact design may be achieved through the design principle of a housing-side structure of a turbomachine according to the present invention, which is used in high-pressure compressors in particular. With this design, it is possible to achieve clearance control between the radially outer ends of the moving blades of a moving blade ring and a radially adjacent jacket ring on the outside, and thus an optimal surge margin and optimal efficiency may be provided without complex active clearance control.
According to one advantageous refinement of the present invention, a flange is formed on the stator-side housing part radially adjacent to the jacket ring on the outside, so that a supporting element which is attached to the flange is preferably in contact with a downstream end of the jacket ring for stabilization of same in at least one section. The supporting element secures the jacket ring against tilting and thereby stabilizes it. In addition, the supporting element which comes to rest on a downstream end of the jacket ring also assumes a sealing function.
A heat shield preferably prevents a hot gas inflow into a housing-side recess. The heat shield may further improve the clearance control.
Preferred refinements of the present invention are derived from the subclaims and the following description. Exemplary embodiments of the present invention are described in greater detail with reference to the drawings although without being limited thereto.
The present invention here relates to a housing-side structure of a turbomachine, in particular a gas turbine. The present invention is used in compressors in particular, preferably in high-pressure compressors.
A jacket ring 16, which functions as the carrier for an abradable lining for the radially outer ends of rotor-side moving blades 11 of moving blade ring 10 and which together with same defines a clearance 17, is radially adjacent to moving blade ring 10 and the moving blades 11 of same on the outside.
To ensure clearance control of clearance 17 between the radially outer ends of moving blades 11 of moving blade ring 10 and jacket ring 16 using simple structural means, jacket ring 16 of the housing-side structure is connected to a stator-side housing part 19 which is radially adjacent to jacket ring 16 on the outside, forming at least one constriction 18 and is thermally decoupled from same as well as from the rest of the housing. In
A flange 20 to which a supporting element 21 is attached is formed on this stator-side housing part 19 which is radially connected to jacket ring 16 on the outside and is connected to same via constriction 18 in the exemplary embodiment in
In the exemplary embodiment shown in
According to
Supporting element 21 is preferably designed as a segmented ring.
To prevent an inflow of hot gas from the flow channel of the turbomachine into a housing-side recess 23, the housing-side structure of the turbomachine also has a heat shield 24, heat shield 24 engaging at a first end 25 in a recess 26 of a stator-side component, which is connected downstream to jacket ring 16, namely engaging in recess 26 of a guide blade 15 according to
Two constrictions 18A and 18B are present in the exemplary embodiment of
It is also possible to have only one eccentric constriction. It is thus possible for upstream constriction 18A to be present in the exemplary embodiment in
As shown by a dashed line in the illustration of the exemplary embodiment in
In the exemplary embodiment in
In the exemplary embodiment in
In thermal expansion of component 31 during operation, the latter comes to rest against section 30 of supporting element 21′, therefore preventing hot gas from the flow channel from flowing into a housing-side recess through a clearance 32 formed between supporting element 21 and component 31. This component 31 may be a section of a stator-side guide blade ring or a stator-side flow channel section.
A radially inner contour 35 of section 29 of supporting element 21′ which restrains a flow channel radially on the outside in some sections, namely in the transitional zone to component 31, is designed and contoured in such a way that this contour deflects a gas stream radially toward the inside and thus prevents or greatly reduces the inflow of hot gas through clearance 32 into housing-side recess 23.
A heat shield 33 is also present in the exemplary embodiment in
An effective and reliable clearance control between the radially outer ends of the moving blades of a moving blade ring and a jacket ring 16 radially connected on the outside may be ensured in a structurally simple manner using the present invention. Jacket ring 16 is thermally decoupled from the housing via at least one constriction 18, 18A, 18B.
Tilting of jacket ring 16 is preferably prevented by a supporting element 21 or 21′ which mechanically stabilizes jacket ring 16 and seals it in particular against a hot gas inflow.
Clearance control may be further improved by an additional heat shield 24 or 33.
Number | Date | Country | Kind |
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102010036071.6 | Sep 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE11/01667 | 8/29/2011 | WO | 00 | 2/27/2013 |