EP2434163A1 - Compressor - Google Patents

Abstract

The compressor (5) has an annular flow channel which is bounded concentrically along a machine axis of compressor and radially outwardly from channel wall (20). The flow passages for influencing the flow gap between rotor blades (15) and channel wall are formed in channel wall, so that size of opening of flow passages is varied. The flow passages are extended along circumferential direction.

Description

The invention relates to a compressor having an annular flow channel which extends concentrically along a machine axis of the compressor and is bounded radially on the outside by a channel wall, wherein flow passages are provided in the channel wall for influencing the gap flow between the blades and the channel wall.

Gas turbines and their functions are well known. The sucked by a compressor of the gas turbine air is compressed in this and then mixed in a burner with fuel. Subsequently, the mixture flowing into a combustion chamber burns to a hot gas, which subsequently flows through a turbine connected downstream of the combustion chamber and, in the meantime, causes the rotor of the gas turbine to rotate due to its relaxation. Due to the rotation of the rotor, a generator coupled to the rotor is driven in addition to the compressor, which converts the mechanical energy provided into electrical energy. Gas turbines are also used as aircraft engines.

Both the compressor and the turbine each consist of several successive stages, each comprising two successive rings of blades. A turbine stage is composed of a vane ring formed by non-rotating vanes and a rotor blade arranged downstream therefrom, whereas a compressor stage is composed of a blade ring and a vane ring arranged downstream thereof; each viewed in the flow direction of the medium. In a single-shaft gas turbine, the blades of the compressor and the turbine are fixedly mounted on a common rotor.

The serially arranged, i. axially successive compressor stages, due to the blades rotating with the rotor, deliver the intake air from the compressor inlet toward the compressor outlet, with the air within each stage (or each collar) undergoing an incremental increase in pressure. The total pressure rise across the compressor is the sum of all incremental pressure rises across each stage (or all wreaths).

In a known manner, it may happen during operation of the compressor, in particular during operation of the compressor of a gas turbine, that increases when approaching the stability limit by Fehlanströmung and growing gap vortex recirculation. As a result, a stall may occur within the compressor on one or more blades, ie, the flow rate of the air in the main flow direction returns to a small amount or to zero in a part of a compression stage. At the same time, the energy transferred from the rotor to the air is not sufficient to convey it through the compressor stage and to produce the required pressure ratio of the relevant compressor stage. The pressure ratio is the pressure increase occurring over the relevant stage of the compressor, based on the inlet pressure of the respective stage. If the stall is not counteracted immediately, it may progress to a rotating stall and possibly even cause the entire airflow through the compressor to reverse direction, known as compressor-pumping. This particularly critical operating condition jeopardizes the blading and prevents sufficient supply of the combustion chamber with compressor air, so that a faulty operation of the gas turbine diagnosed and the machine must be switched off immediately. Consequently, the aforementioned flow phenomena are undesirable and must be avoided if possible during operation safely.

To combat the above problems is from the EP 0 719 907 A1 a structured, so provided with flow passages outer boundary wall, which faces the tips of the blades. This structuring of the boundary wall, the so-called "casing treatment", serves to positively influence the gap-near flow for those situations in which there is a risk of a stall on an airfoil. Due to the structuring, partial flows are taken from the main stream in the region of low flow velocities during the entire operation and are subsequently returned upstream of the removal position. The air taken from the pressure side of the compressor blade in the tip region is supplied to the suction-side main flow of the compressor blade concerned to prevent any stall occurring there. Accordingly, the channels of the casing treatment leading to the partial flows are inclined with respect to the machine axis or rotation axis in such a way that, viewed in the direction of rotation of the rotor, the removal position lies after the feed position at which the decoupled partial flow is returned to the main stream near the gap. This is necessary so that, due to the staggering angle of the tips of the blades, which are inclined to the direction of rotation, the partial flow can be conducted over the blade tip from the pressure side to the suction side. Thus, the longitudinal extent of the return flow channel is substantially transversely to the straight line of the blade tip side staggering angle, ie aligned approximately parallel to the machine axis.

A similar device is from the EP 1 286 022 A1 known.

However, the aforementioned embodiments have the disadvantage that the flow guidance of the partial flows is not optimal for each operating state of the compressor.

Furthermore, the FR 2 325 830 a compressor housing with grooves introduced therein. Also through these grooves should a stall of the boundary flow and thus the pumping of the compressor can be prevented, wherein, however, the adjusting through the grooves current does not flow against the main flow, but with this.

The object of the invention is to provide a compressor whose structured boundary wall achieves a further increase in the operating range of the compressor and a reduction in the inclination of the compressor for flow separation. At the same time, the efficiency of the compressor should be further improved or raised to the original level of a compressor without structured boundary wall.

The object is achieved with a compressor according to claim 1. Advantageous embodiments are the subject of the dependent claims 2 to 9.

A compressor according to the invention comprises an annular flow channel which extends concentrically along a machine axis of the compressor and is bounded radially on the outside by a channel wall, wherein flow passages for influencing the gap flow between the rotor blades and the channel wall are provided in the channel wall and at least one of the dimensions of at least one Preferably, all flow passages can be changed and / or means for changing the size of the opening of at least one, preferably all flow passages are provided.

The invention recognizes that the flow passages present in the duct wall are in principle advantageous only if the compressor is operated comparatively close to the stability limit. If the distance to the stability limit is sufficiently large, the static "Casing Treatment" has a rather negative effect. This then causes Störströmungen that reduce the efficiency of the compressor in this operating condition rather.

The invention thus proposes to activate the flow passages in the channel wall only in those operating conditions in which it is required. For all other operating states of the compressor, the flow passages should not cause any aerodynamic effect. In order to achieve this, according to a first embodiment of the invention, at least one of the dimensions of at least one of the flow passages can be changed. In other words, according to the first embodiment, the volume and / or the contour of the flow passages are variable. According to a second embodiment of the invention, the flow passages are configured lockable. For this purpose, a means for changing the size of the opening of at least one of the flow passages, preferably all flow passages is provided.

This makes it possible on the whole, the contour of the channel wall in those sections in which the flow passages are provided to dynamically adapt to the operating condition of the compressor.

In the event that the compressor meets the stability limit i. approaches the surge line, so the flow passage openings can be increased, possibly even fully opened, or it will be increased their dimensions. Consequently, only then are the flow passages activated, i. fluidically connected to the flow channel of the compressor, if it is to be expected that the aforementioned undesirable phenomena occur. This improves on the one hand the operation of the compressor with casing treatment, on the other hand increases the working range of that compressor, which was not previously equipped with a casing treatment. Apart from that, it is even possible to adapt the casing treatment according to the invention always in such a way that it can individually damp or even suppress the different phenomena or flow instabilities.

At the same time, the hitherto occurring disadvantages of the casing treatment can be suppressed, which then occur when the with a conventional casing treatment equipped compressor was operated near or at the design point. Since the flow passages are now closed in such an operating state, their harmful influence on the aerodynamics in nominal operation no longer occurs. This improves the efficiency of the compressor compared to a compressor with a conventional casing treatment.

Consequently, in addition to an improvement in the efficiency of the compressor and an expansion of the operating range of the compressor can be achieved because the aerodynamic disturbing influences of the flow passages are avoided in operation near the design point and they are activated only in the required (in the stability limit) operating state. It is possible, regardless of the general fluid mechanical conditions, to set the optimum contour or the optimal dimensions of the flow passages.

Conveniently, the changing of the dimensions of the flow passages or the opening and closing of the flow passages is infinitely possible.

According to a first advantageous development of the compressor, the relevant flow passages can be distributed uniformly along the circumference of the channel wall. Preferably, the respective flow passages are arranged only in one sector or in several sectors of the circumference. The restriction to one or more sectors is possible, since to disrupt a compressor operation restricting stripping or rotating stall it may be sufficient to disturb the phenomenon locally. Thus, a structurally simple and inexpensive compressor can be specified.

According to a further advantageous embodiment of the compressor, flow passages relating to a plurality of axial sections of the flow channel are provided. As the compressor according to the invention, which is usually designed as axial compressor is having a plurality of compressor stages, corresponding interference may occur at different compressor stages, so that it is advantageous to arrange the respective flow passages on the compressor stages usually involved in order to prevent the emergence and spreading of the disturbing phenomena early and on site.

Conveniently, the flow passages concerned are at least partially opposite the blade tips of blades of a blade ring of the compressor. This allows you to most effectively influence the gap flow between the tips of the blades of the blades and the channel wall.

The flow passages are three-dimensionally designed and accordingly have three dimensions: length (in the axial direction of the compressor), width (in the circumferential direction) and depth (in the radial direction). In the simplest embodiment, the flow passage is cuboid or prism-shaped, both parallel to the machine axis or with respect to the machine axis inclined orientation. Instead of the rectilinear extension in each extension direction, the contour can also be designed bent. Also, steps or edges can be provided in each extension direction. Of course, different contours - straight and curved - be combined in an extension direction. Further, the flow passages may also be inclined with respect to the radial direction or may extend mainly in the circumferential direction.

According to a particularly preferred first embodiment of the flow passages, the respective flow passages are configured as holes penetrating the channel wall with, for example, a rectangular, parallelogram or ring segment-shaped cross section, in each of which a correspondingly contoured plug element is displaceably arranged to change the depth of the relevant flow passage. With the help of this first embodiment of the flow passages a particularly simple construction is given, in which the depth of the flow passages is variable as a variable measure. The depth of the flow passage can also be set to zero by means of the plug element so that the relevant flow passage is completely closed or no longer present. This operating position of the plug member is preferred for rated operation and adjacent operating conditions of the compressor. After leaving nominal operation, the plug member may be moved out of the hole to first create a low depth flow passage which then increases outwardly with increasing displacement of the plug member. This is then possible until a maximum depth of the flow passages is reached. However, the maximum depth is preferably reached only when the distance to the stability limit of the compressor has reached the minimum permissible value. Consequently, the patterning can be dynamically adjusted to the operation of the compressor to keep flow losses low overall.

According to an advantageous embodiment of the first embodiment of the flow passages, the plug element is designed as a punch with a collar, which punch is inserted from radially outside into the hole of the channel wall. By using the collar, the maximum penetration depth of the plug element is limited in the relevant hole, so that a Hininragen the plug element can be safely avoided in the flow channel. This prevents the rubbing and damaging of the compressor blades passing the holes of the flow passage on the plug member.

Preferably, the plug element is biased by means of a spring element. As a result, the plug element is in a first end position, from which it can be moved with a drive to other positions while increasing the spring preload. The provision of the plug element is then always by the spring force of the spring element, which is particularly desirable in case of failure of the drive.

According to a second embodiment of the flow passages, the relevant flow passages are not formed as holes with a variable plug element, but as blind hole-like grooves, the groove opening by means of a displaceable in the circumferential direction cover, which also has openings, are exposable or closable. The contour of the openings of the cover and the distance between them correspond to the Nutöffnungskontur and the distance between the grooves. By moving the cover whose openings with the groove openings can not, partially or completely be brought into coverage. With this embodiment, a comparatively simple construction is specified in order to influence the aerodynamic effect of always provided in the channel wall casing treatments and optionally almost completely off. Of course, this embodiment can also be used in addition to the plug element solution. In the channel wall then the grooves are replaced by holes.

Preferably, a stationary gas turbine provided for generating energy is equipped with a compressor of the aforementioned embodiment. Of course, an aircraft engine can be configured with such a compressor.

FIG 1

eine Gasturbine in einem Längsteilschnitt,

FIG 2

einen Querschnitt durch den Verdichter der Gasturbine mit einer in der Kanalwand angeordneten dynamischen Strukturierung gemäß einer ersten Ausgestaltung,

FIG 3

gemäß einer ersten Ausgestaltung die Kanalwand mit einer einstellbaren Strömungspassage durch ein in einer ersten Endlage befindliches Stopfenelement,

FIG 4

die Kanalwand nach FIG 3 mit dem in einer zweiten Endlage befindlichen Stopfenelement,

FIG 5

das aus den FIG 3 und FIG 4 bekannte Stopfenelement in einer perspektivischen Darstellung,

FIG 6

zwei Ausschnitte aus einem Längsschnitt durch den Verdichter mit einer in der Kanalwand angeordneten Strömungspassage gemäß einer zweiten Ausgestaltung,

FIG 7

eine perspektivische Darstellung einer mit Öffnungen versehenen Abdeckung für die Strömungspassagen gemäß der zweiten Ausgestaltung,

FIG 8

eine Darstellung von möglichen Konturen der Öffnungen der Strömungspassagen,

FIG 9

in schematischer perspektivischer Darstellung eine Kanalwand mit in Umfangsrichtung verlaufenden Nuten zur Bildung von Strömungspassagen,

FIG 10, 11

jeweils einen Schnitt durch FIG 9, mit in der Umfangsnut angeordnetem Segment in zwei unterschiedlichen Betriebspositionen,

FIG 12

Segmente zur Bildung eines Rings zum Verschluss der Umfangsnuten aus FIG 9,

FIG 13

eine alternative Ausgestaltung einer Kanalwand mit segmentierten Umfangsschlitzen zur Bildung von Strömungspassagen und

FIG 14, 15

in perspektivischer schematischer Darstellung eine Kanalwand mit durch Abdeckungen verschließbare Umfangsnuten.

The foregoing and other features as well as other advantages of the present invention will become more apparent from the following description of embodiments. They show schematically:

FIG. 1

a gas turbine in a longitudinal section,

FIG. 2

a cross section through the compressor of the gas turbine with a arranged in the channel wall dynamic structuring according to a first embodiment,

FIG. 3

According to a first embodiment, the duct wall with an adjustable flow passage through a plug element located in a first end position,

FIG. 4

the canal wall after FIG. 3 with the plug element located in a second end position,

FIG. 5

that from the 3 and FIG. 4 known plug element in a perspective view,

FIG. 6

two sections from a longitudinal section through the compressor with a flow passage arranged in the channel wall according to a second embodiment,

FIG. 7

a perspective view of an apertured cover for the flow passages according to the second embodiment,

FIG. 8

a representation of possible contours of the openings of the flow passages,

FIG. 9

a schematic perspective view of a channel wall with circumferentially extending grooves for the formation of flow passages,

FIG. 10, 11

each cut through FIG. 9 with segment arranged in the circumferential groove in two different operating positions,

FIG. 12

Segments for forming a ring for closing the circumferential grooves FIG. 9 .

FIG. 13

an alternative embodiment of a channel wall with segmented circumferential slots for the formation of flow passages and

FIG. 14, 15

in a perspective schematic representation of a channel wall with closable by covers circumferential grooves.

In all figures, identical components are provided with identical reference numerals.

FIG. 1 shows a construction variant of a gas turbine 1 in a longitudinal partial section. It has inside a rotatably mounted about a machine axis 2 rotor 3, which is also referred to as a turbine runner. Along the rotor 3 successive an intake 4, a compressor 5, a toroidal annular combustion chamber 6 with a plurality of rotationally symmetrical to each other arranged burners 7, a turbine unit 8 and an exhaust housing 9. The annular combustion chamber 6 surrounds a combustion chamber 17 which is connected to an annular hot gas duct 16 , There four successively connected blade stages 10 form the turbine unit 8. Each blade stage 10 is formed of two blade rings. Viewed in the flow direction of a hot gas 11 produced in the annular combustion chamber 6, follows in the hot gas duct 16 each of a row of vanes 13 formed by a blade 15 row 14. The vanes 12 are attached to the stator, whereas the blades 15 a row 14 each by means of a disc 19 on the rotor 3 are attached. On the rotor 3, a generator or a working machine (not shown) is coupled.

Also in the compressor 5 a plurality of blade stages 10 are arranged in a cascading, wherein each blade stage 10 is formed from a blade row 14 and one of them downstream arranged guide blade row 13. As in the turbine unit 8, the rotor blades 15 are attached to a disc 19 of the rotor 3 in the compressor 5. The tips of the blades 15 are gap-forming a channel wall 20 opposite, which is arranged concentrically to the machine axis 2 of the gas turbine 1. The inwardly facing surface of the channel wall 20th limits the axially extending flow channel 22 of the compressor 5 radially outward. The channel wall 20 may be formed either as a guide blade carrier or as a housing.

In the inwardly facing surface of the channel wall 20 are in FIG. 1 structures not shown further introduced, which are at least partially opposite the tips of the blades 15 and are known in principle as casing treatment. The inventive design of these structures and their mode of action are described in detail in the following figures.

FIG. 2 - FIG. 5 show a first embodiment for changing the dimension of a flow passage.

FIG. 2 shows the cross section through the compressor 5 of the gas turbine 1 in the axial section of blades 15, which are arranged on the rotor 3 in a ring. The tips 24 of the blades 15 is the annular channel wall 20 at a distance opposite. In a sector of the annular channel wall 20, a plurality of holes 26 is shown along the circumference, in each of which a radially displaceable plug element 28 is seated. Instead of the sector-shaped arrangement of the holes 26 with the plug members 28 seated therein, it is also possible to arrange them distributed uniformly along the circumference. In this case, the number of holes 26 then corresponds to the number of blades 15 in the blade ring or a multiple thereof. It is also possible for the holes 26 together with the plug elements 28 to be provided in two or more sectors of the circumference. Not shown in FIG. 2 is a the channel wall 20 encompassing housing.

3 and FIG. 4 show the cross section of a portion of the channel wall 20 with only one of the holes 26 and the plug member 28 disposed therein in detail. The hole 26 has a rectangular contour in the embodiment shown. Accordingly, the in FIG. 5 shown in perspective Plug element 28 in addition to a collar 29, a filling member 31 for closing the hole 26th

FIG. 3 shows the plug member 28 in a first position. In this first position, the plug member 28 completely closes the hole 26. As a result, the inner surface of the channel wall 20 has a stepless and edge-free course along the circumference in the region of the hole 26. Thus, there is no structuring at this point that affects the flow between the tips 24 of the blades 15 below the channel wall 20.

By the displacement of the plug member 28 to the outside, which is in FIG. 4 is shown, a portion of the hole 26 is exposed. The depth of the hole 26 is dependent on the length of the displacement path of the plug element 28. The space thus created in the hole 26 is then a flow passage 32 which influences the gap flow between the blade tip 24 and channel wall 20 as a casing treatment.

The displacement of the plug element 28 to the outside was carried out by a drive not shown. The drive can be designed, for example, electrically, pneumatically or hydraulically. Other types of drive, such as piezoelectric actuators are also possible. For return adjustment of the plug element 28, a helical spring 30 is provided, which is supported on a housing wall 33 of the compressor 5 which likewise surrounds the channel wall 20 in a ring-like manner. Also conceivable are spiral or disc springs as well as a return adjustment, which takes place only by means of one of the drive types described.

In the 2, FIG. 3 and FIG. 4 shown holes 26 extend along the radial direction 27. This is not mandatory. The holes 26 can also be compared to the radial direction 27 by a fixed, arbitrary angle α ( FIG. 3 ), which is indicated by a hole center line 29. Accordingly, the plug elements 28 also designed displaceable along the hole center line 29.

In one embodiment, not shown, the flow passages 32 distributed over the circumference or in segments may also be divided into groups of flow passages 32. Within a group, the holes 26 are aligned parallel to each other, the orientation of the holes of two different groups are inclined to each other. If the different orientation is required, the group arrangement simplifies the production of the holes. This lowers the manufacturing costs.

In FIG. 5 is that from the 3 and FIG. 4 known plug element 28 shown in perspective. Shown is a massive embodiment of the plug member 28, whereby this reacts rather sluggish due to its mass to dynamic Strömungseinflusse. The dimensions C and D are identical according to the plug member 28 shown. Alternatively, it is also possible that the dimensions C and D are different in size.

In the FIG. 2 - FIG. 5 Thus, the construction shown is suitable for adjusting at least one dimension of the flow passage 32. By plug elements 28 modified in their contour, it is possible to change not only the depth of the flow passages 32 but also the width of the flow passages or their length. A displacement of the plug elements in the axial and / or circumferential direction is conceivable.

A second embodiment of a variable flow passage 32 is in the 6 and FIG. 7 shown.

In detail shows FIG. 6 two identical sections through the longitudinal section of the compressor 5 in the axial section of blades 15. The channel wall 20 is the tips 24 of the blades 15 with respect to radial gap forming. In the inwardly facing surface of the channel wall 20, as flow passages 32, a plurality of grooves 34 are uniform along the circumference distributed, of which only one is shown. The number of grooves 34 preferably corresponds to the number of blades 15 in the blade ring. All grooves 34 have a substantially rectangular contour and thus a correspondingly contoured slot opening. Other contours, such as those in FIG. 8 are shown are of course also possible. The axial length of the grooves 34 corresponds approximately to the length of the axial projection of the tips 24. In addition, in the longitudinal section shown on the left FIG. 6 the grooves 34 and the tips 24 of the blades axially aligned with each other, which corresponds to a coverage of 100%. Deviations from this are possible, as in FIG. 6 shown on the right. Here, a rotor blade 15 is shown in full line, the tip 24 is only minimally covered by the groove 34. In dashed line style are right in FIG. 6 also schematically shows three further axial positions of blades 15, in which the groove 34 covers about 30%, 60% and 95% of the axial projection of the blade tip 24.

Between the tips 24 of the blades 15 and the grooves 34, a cover 36 is provided. The cover 36 is in FIG. 7 shown in perspective and formed as a ring plate. In the cover 36 34 openings 38 are provided in the same number to the grooves. The openings 38 have an identical contour as the slot openings. In the illustrated embodiment, therefore, the contours of the openings 38 are also rectangular. The cover 36 is as indicated by the arrow 39 in FIG FIG. 7 indicated, rotatable about a not-shown drive in the circumferential direction, so that the openings 38 can be superimposed with the groove openings aligned. In FIG. 7 this is shown for the groove 34a. By slight twisting of the cover 36, it is possible to push the webs 40 present between the openings 38 of the cover 36 partially or completely over the openings of the grooves 34, whereby they are partially or completely closed. Such positioning of openings 38 and groove opening is by the in FIG. 7 shown groove 34b shown.

By means of the circumferentially adjustable cover 36, the flow passages 32 formed by the grooves 34 are variable. In this case, the size of the opening of the flow passages 32, so the groove opening, adjusted by the positioning of the cover 36 in this second embodiment.

Of course, the cover 36 could also at one of the edges of each opening 38 radially outwardly projecting tabs 41 which protrude into the grooves 34. Depending on the arrangement of these tabs on the cover 36 and the direction of displacement of the cover 36, it is then possible to change the length or width of the flow passage 32: By a arranged on the longitudinal edge of the openings 38 tab 41, the width of the flow passage 32 upon rotation the cover 36 are changed in the circumferential direction. With arranged on the transverse edge of the openings 38 tab 42 can be changed in displacement of the cover 36 in the axial direction, the length of the flow passage 32. In order to ensure the displaceability of the cover 36, however, this has only one of the two types of tabs, either the tab 41 or the tab 42, on.

In FIG. 8 Alternative contours 38a-38d for the holes 26 and plug members 28 and / or for the grooves 34 and openings 38 are shown. Instead of a rectangular contour 38a, a contour 38b which is basically rectangular but provided with a kink is also possible, as is an arcuate contour 38c or a contour 38d which is inclined relative to the machine axis 2 and thus parallelogram-shaped. Further, modified contours are also conceivable.

As an alternative to the embodiments described above, circumferential grooves 44 running in the circumferential direction can also be provided in the channel wall 20 as a casing treatment. Such circumferential grooves 44 and modifications thereof are in the FIGS. 9 to 15 and are described in more detail below.

In the FIG. 9 shown embodiment shows in the axial section of a blade ring three axially successive circumferential grooves 44 which are endlessly circulating. Each of these circumferential grooves 44 is closed by a ring formed from segments. FIG. 12 shows rings of two segments 46a, three segments 46b or four segments 46c, which may be arranged in the circumferential grooves 44. Each segment 46 is movable in the radial direction, which is in FIG. 12 is illustrated with the help of the arrows shown there. By the displacement of the segments 46, 46a, 46b, 46c in the radial direction, the inwardly facing opening of the corresponding circumferential groove 44, in which the corresponding ring is seated, can be at least partially exposed ( FIG. 11 ), resulting in a circumferentially endless flow passage 32. If the segments 46, 46a, 46b, 46c are in their radially inner position, the circumferential grooves 44 are completely closed, so that the channel wall 20 has no structuring and thus no casing treatment.

Not shown, but also possible is a configuration with circumferentially extending groove portions that can be opened and closed in a similar manner by segments 46.

Instead of circumferential grooves 44, be they endless or groove sections, they may instead also, as in FIG FIG. 13 shown, slots 47 may be provided in the channel wall 20 to form flow passages 32. The slots 47 completely penetrate the channel wall 20. By inserted from the outside into the channel wall 20 arc segments 48, the individual slots 47 can be completely or partially closed ie filled. If a plurality of slots 47 are arranged one behind the other in the axial direction A, there is the possibility that an arc segment 48 can close only one slot 47, several slots 47 or all slots 47. The arc segments 48 are thus formed analogously to the plug elements 28 and can therefore be positioned in a similar manner or be driven and reset, without being discussed here in more detail.

FIG. 14 If partially or completely opened inwardly, the circumferential grooves 44 represent the flow passages 32 of the casing treatment. Due to the cylindrical channel wall 20 can be by means of axial direction in the axial direction A sliding covers 52, 54, the circumferential grooves 44 are closed. By the use of the cover 52, the circumferential grooves 44 are closed successively upon displacement of the cover 52. If 54 openings 58 with a corresponding axial distance are present in the insert, this can close all circumferential grooves 44 at the same time. Depending on the relative position of the insert 54 relative to the channel wall 20, the circumferential grooves 44 can be completely or partially closed. The cover 54 has over the cover 52 has the advantage that a comparatively short axial displacement is required to cover all three circumferential grooves 44.

FIG. 15 shows a schematic perspective partial view of a conical channel wall 20 to the machine axis with segmented circumferential grooves 44 to form flow passages 32. Due to the conical channel wall 20, the cover 56 is displaceable only in the circumferential direction and not in the axial direction to change the size of the openings of the groove portions 47.

The in the FIG. 9 to FIG. 15 The embodiments shown have the particular advantage that the flow passages 32, which extend mainly in the circumferential direction, can now for the first time be considered as casing treatment. As a static casing treatment, the circumferential grooves 44, slots 47 or groove sections cause such large losses at rated load that their use in avoiding flow phenomena at partial load was unjustifiable. Since the elimination of this defect by deactivating the Casing treatments at nominal load and by activating the casing treatment when approaching the surge line now possible, the use of circumferential grooves 44 or slots 47 and sections thereof as Casing Treatment is economically feasible for the first time.

The embodiments shown are not intended to be limiting. Regardless of the illustrated embodiments, any features can be further combined with each other, provided that no structural obstacles make the combination impossible.

By in the Figures 2-15 shown embodiments and variations thereof, it is possible to activate the function of influencing the gap flow flow passages 32 depending on the operation, to deactivate and to adjust their size. This makes it possible, for operating states that do not require influencing the main flow - because harmful phenomena then tend not occur - to turn off the structuring present in the channel wall 20 and for operating conditions in which to expect the occurrence of the phenomena mentioned above, first partially and later fully activated if necessary. This has the advantage that the casing treatment can actually be avoided for those operating states in which influencing the flow through the casing treatment is undesirable. This leads to the restoration of efficiency despite the possibility of suppressing damage-causing phenomena by means of the casing treatment during endangered operating conditions.

Claims (9)

Compressor (5),
with an annular flow channel (22) which extends concentrically along a machine axis (2) of the compressor (5) and is bounded radially on the outside by a channel wall (20),
wherein in the channel wall (20) flow passages (32) for influencing the gap flow between blades (15) and the channel wall (20) are provided,
characterized,
in that at least one of the dimensions of at least one of the flow passages (32) is variable and / or means for changing the size of the opening of at least one of the flow passages (32) are provided. Compressor (5) according to claim 1,
wherein the respective flow passages (32) extend mainly along the axial direction, are evenly distributed along the circumference of the channel wall (20), or arranged in one or more sectors of the circumference
and or
wherein the respective flow passages (32) extend mainly along the circumferential direction. Compressor (5) according to claim 1 or 2,
wherein flow passages (32) relating to a plurality of axial sections of the flow channel (22) are provided. A compressor (5) according to any one of claims 1, 2 or 3, wherein the respective flow passages (32) are at least partially opposite the blade tips (24) of rotor blades (15) of the compressor (5). Compressor (5) according to one of the preceding claims, in which the respective flow passages (32) are designed as holes (26) or slots (47) penetrating the channel wall (20), in which a plug element (28) or an arc segment (48) for changing the depth of the flow passage (32) is slidably disposed. Compressor (5) according to claim 5,
in which the plug element (28) is designed as a punch with a collar (29), which punch is inserted from radially outward into the holes (26) of the channel wall (20). Compressor (5) according to claim 5 or 6,
in which the plug element (28) or the arc segment (48) is pretensioned by means of a spring element (30). A compressor (5) according to any one of claims 1, 2 or 3, wherein the respective flow passages (32) are formed as grooves (34, 44) by means of a sliding cover (36, 52, 54, 56) corresponding to the grooves (34) formed openings (38, 58) are exposable. Gas turbine (1) with a compressor (5) according to one of the preceding claims.

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