DE102012223462B3 - Housing of fluid flow machine e.g. compressor, has seal that is arranged to seal the common contact surface in which the sealing elements are arranged, and sealing elements that are arranged axially relative to each other - Google Patents

Abstract

The housing (1) has common contact surface (6) that is screwed to the housing pot (2). The housing cover (8) is located in the common contact surface. The seal (3) is arranged to seal the common contact surface in which the sealing elements (4,5) are arranged. The sealing elements are arranged axially relative to each other.

Description

The invention relates to a housing of a turbomachine, in particular a compressor, with a housing pot and a housing arranged on a common contact surface housing cover and with a arranged in the common contact surface seal for sealing the common contact surface with a first sealing element and one to the first sealing element arranged radially offset, second sealing element.

Compressors or fluid compressing devices are used in various industries for various applications involving compression or compression of fluids, especially (process) gases.

Well-known examples of this are turbo compressors in mobile industrial applications, such as in exhaust gas turbochargers or in jet engines, or even in stationary industrial applications, such as gearbox turbo compressors for air separation.

In such - in its operation continuously working - turbo compressor, the pressure increase (compression) of the fluid is effected by an angular momentum of the fluid from entry to exit by a rotating radially extending blades having impeller of the turbo compressor is increased by the rotation of the blades , D here. H. In such a compressor stage, pressure and temperature of the fluid increase while the relative (flow) velocity of the fluid in the impeller or turbocharger wheel decreases.

In order to achieve the highest possible pressure increase or compression of the fluid, a plurality of such compressor stages can be connected in series.

As types of turbocompressors, a distinction is made between radial and axial compressors.

In the axial compressor, the fluid to be compressed, for example a process gas, flows in a direction parallel to the axis (axial direction) through the compressor. In the radial compressor, the gas flows axially into the impeller of the compressor stage and is then deflected outwards (radially, radially). With multi-stage centrifugal compressors, a flow diversion becomes necessary behind each stage.

Combined types of axial and radial compressors draw large volume flows with their axial stages, which are compressed to high pressures in the subsequent radial stages.

While usually single-shaft machines are used, in (multi-stage) Getriebeturboverdichtern (shortly below only gear compressor), the individual compressor stages are grouped around a large wheel, with several parallel (pinion) shafts, each one or two - realized as housing structures , the inflow and outflow to the compressor stages causing, pressure-bearing volute housings recorded - run wheels (arranged at free shaft ends of the pinion shafts turbochargers), are driven by a large, mounted in the housing drive gear, a large wheel.

In the pressure-bearing volute casing (in cup-shaped design also called Topfspiralgehäuse), d. H. in a cylindrical bore in the spiral housing (this part of the (cup) spiral housing often referred to only as a housing pot or pot), - in addition to the impeller - a spiral insert used such that in the cylindrical bore (the (housing) pot ) axially end face the spiral insert a space enclosed by the spiral housing and the spiral insert space, a so-called annulus remains, via which the fluid - coming from the impeller - flows radially over an expanding cross-section.

About a plant piping, such as a arranged on the volute casing or on (housing) pot pressure pipe with a Druckstutzenflansch arranged thereon, the fluid then flows from the annular space further from the compressor stage.

The inflow of the fluid into the volute casing takes place via a pot spiral suction flange which is designed as an (axially front-side) housing cover (or else only as a cover), which - via a common "radial", d. H. radially extending, axial, contact surface (in the following also just "radial" contact surface) by means of a (housing) Deckelverschraubung screwed to the pot spiral housing or the (housing) pot - the pot spiral housing or the (housing) pot axially closes ,

Such a gear compressor, a gear compressor from Siemens called STC-GC, used for the air separation, is from http://www.energy.siemens.com/hq/en/verdichtung-expansion-ventilation/turbo/engineer/getriebeturboverdichter/stc -gc.htm (available on 14.12.2012) known.

The pamphlets WO 2011/076 704 A1 . EP 0 723 143 B1 . DE 41 27300 A1 and DE 10 2009 012 038 A1 each show generic housing. For preventing / reducing pressure losses in such a cup spiral housing, for example by means of the common radial contact surface between the (housing) Lid and cup spiral housing or the (housing) pot outflowing / leaking (leakage) fluid, or for (housing) lid seal is - formed as a backup seal - (double) seal or tandem seal in the common radial contact surface intended.

For this purpose, two radially to each other or radially successively arranged, circumferential (sealing) grooves in an axial end face of the (housing) cover - there on the front side of the (housing) cover on the common radial contact surface - introduced, in particular two axially in the lid screwed, radially successively arranged, concentric, circumferential sealing grooves, in which two sealing elements, for example, O-rings and / or Cupseals inserted are.

For monitoring the (tandem / backup) seal or monitoring the sealing effect of the radially inner seal / sealing element of the two seals / sealing elements usually a so-called interstitial space monitoring is provided in the lid of the cup spiral housing between the two sealing elements. D. h., The sealing effect of the radially inner sealing element is controlled by the gap monitoring.

For this purpose, a further, radially inserted between the two sealing grooves axially in the front side of the cover / screwed circumferential (monitoring) groove is provided, which is to be monitored gap in the common radial bearing surface between the lid and the pot, d. H. in the common radial contact surface there radially between the two seals / sealing grooves, forms.

About a leading through the lid channel system from an axial bore, which opens into the interstitial space, and a subsequent to the axial bore radial bore, which opens into a (terminal) area on an outer peripheral surface of the lid, a connection between the monitoring surveillance space "outwards" produced.

Where the radial bore in the lid on the outer peripheral surface of the lid occurs, or in the connection area of the outer peripheral surface of the lid, a connection flange is welded or screwed to the lid, which in turn is connected to a monitoring device, such as a sensor for detecting leakage.

This seal or the double / tandem seal of the cup spiral housing requires a large amount of space, which adversely affects the component size of the cup spiral housing and thus also on the component size of the turbomachine. In addition, the (housing) Deckelverschraubung is far away from - from the interior of the spiral housing - acting on the volute casing pressure force, whereby the screw for the application of a correspondingly necessary screwing force is correspondingly larger.

The invention has for its object to provide a pot spiral housing for a turbomachine, which allows a compact and yet pressure-safe design of the housing and thus also the turbomachine.

The object is achieved by a housing of a turbomachine with the features according to the respective independent claim.

The housing of the turbomachine has a housing pot and a arranged on a common contact surface on the housing pot, in particular screwed over the common contact surface against the housing pot by means of a Gehäusedeckelverschraubung, housing cover.

Next, the housing of the turbomachine on a arranged in the common bearing surface seal for sealing the common contact surface. The seal is configured as a double / tandem seal with a first sealing element and a second sealing element (double / tandem seal) radially offset or arranged radially next to the first sealing element.

It is further provided that the first and the second sealing element - in addition to or in addition to the radial displacement - are also axially offset from one another or axially adjacent to each other in the common contact surface.

Expressed and simplified, according to the invention it is provided that the double / tandem seal with the two (otherwise only) radially juxtaposed sealing elements offset both radially and axially, d. H. "Obliquely" or "nested" to each other, are arranged.

By the invention or by their oblique arrangement / nesting in the sealing elements so the sealing elements of the seal compact (-er) can be arranged to each other - and so a compact and yet pressure-resistant housing of the turbomachine can be realized.

This also allows the housing cover fitting closer to the sealing elements and thus also to the pressure surface sit - and may also be smaller. In addition, this also improves a residual clamping force of the Gehäusedeckelverschraubung.

This also makes it possible in the invention to reduce wall thicknesses in the housing or in the housing pot, which further leads to smaller component sizes. The housing is thus also lighter by the invention and is cheaper.

Preferred developments of the invention will become apparent from the dependent claims.

According to a preferred development, it is provided that the first sealing element is arranged in a first sealing element receptacle and the second sealing element is arranged in a second sealing element receptacle, the first and the second sealing element receptacle being formed in the housing cover and / or in the housing pot, but in particular in the housing cover are.

Particularly preferably, it can further be provided here that the first and / or the second sealing element receptacle are / is designed as a circumferential chamfer / bevels, in particular on the housing cover.

It can also be provided that the first sealing element receptacle is designed as a circumferential chamfer and the second sealing element receptacle is designed as a circumferential, rectangular groove or circumferential, rectangular recess, in particular on the housing cover.

Just by the formation of a sealing element recording as (triangular) chamfer, d. H. In simple terms, radially encircling spaces (sealing element receptacle) are placed on chamfer (short, triangular cross-sectional shape of the chamfer replaced - in the case of a rectangular groove - rectangular cross-sectional shape of the groove), even more compact sealing arrangements according to the invention - and thus more compact and pressure-resistant turbomachinery or turbomachinery will be realized. The housing cover screw connection can therefore be even closer to the sealing elements and to the pressure surface - and can be even smaller. The residual clamping force of the housing cover screw connection is further improved. Further reduced wall thicknesses in the housing or in the housing pot are possible.

In addition, such chamfers can be produced easily, for example by machining.

Together with the housing cover and a suction flange for an inflow of a fluid can be realized in the turbomachine housing. Often, the housing cover is referred to only as a suction flange or Topfspiralsaugflansch (in hat shape).

It can further be provided that the sealing elements are O-rings, Cupseals, profile seals or other similar sealing elements - or combinations thereof -, in particular of plastic, for example PTFE. O-rings, Cupseals, profile seals or similar sealing elements, in particular made of plastic, for example made of PTFE, are - in a variety of refinement - sufficiently known from the prior art, tested and available inexpensively.

Particularly preferably, it can also be provided that the first sealing element is arranged radially outside the second sealing element and the first sealing element is an O-ring and the second sealing element is a Cupseal.

Put simply, the radially outer sealing element is an O-ring and the radially inner sealing element is a Cupseal.

Particularly preferably, it can be further provided here that the Cupseal sit in a rectangular groove in the housing cover and the O-ring in a chamfer in the housing cover.

According to a further preferred development, an interspace monitoring for the seal, in particular for a in the common contact surface formed radially between the first and the second sealing element monitoring space is provided.

This, d. H. By means of this space monitoring (radially between the two sealing elements), the sealing effect of the radially inner sealing element, for example, the Cupseal, the two sealing elements can be controlled.

Particular preference may be provided that the interspace monitoring has a formed on the housing pot, the monitoring space delimiting circumferential chamfer which is formed on the housing pot that it is arranged radially and axially between the first and the second sealing element in the common contact surface.

Especially by the formation of the interstitial space via a chamfer on the housing pot, d. H. Again, the radially surrounding space (interstitial space) placed on bevel (and a groove for the interstitial space, as well as corresponding grooves in the sealing elements can be omitted), even more compact, monitored seal assemblies according to the invention - and thus more compact and pressure-resistant turbomachinery or turbomachinery will be realized.

The housing cover screw connection can here also be closer to the sealing elements and to the pressure surface - and can be even smaller. The residual clamping force of the housing cover screw connection is further improved here. Further reduced wall thicknesses in the housing or in the housing pot are possible.

Furthermore, it can also be preferred that the interstitial monitoring has a bore opening into the interstitial space in the region of the chamfer, wherein the bore is formed perpendicular to the chamfer.

In order for a tapping in production of the "monitoring bore" is simplified - and - due to a thus realizable short "monitoring bore" and at an angle to the sealing surface of the radially inner sealing member tapping surface in the "monitoring bore" - damage to the sealing surface of the radially inner sealing element largely locked out.

According to a further preferred embodiment, it is provided that the interstitial space monitoring further comprises a, in particular milled, screwed-on surface formed on an outer circumferential surface of the housing pot for screwing a connection element for interstitial monitoring to the housing pot.

Such milled screwing surfaces for components screwed there are easy and safe to produce - and thus ensure pressure-resistant component connections. In addition, unsafe, error-prone, hard-to-produce and / or more complex welded joints can be avoided.

At the connection element, a sensor can be connected, which detects leakage into the space to be monitored - and thus controls the sealing effect of the radially inner sealing element.

If, as further education provided, the gap monitoring on the housing pot realized, so is moreover a - simplified - disassembly of the housing or disassembly of the housing cover without - because without - disassembly of the gap monitoring possible.

According to a further preferred development, a spiral insert arranged in the housing pot and provided with a common radial contact surface with the housing pot and the housing cover is provided.

Expressed differently or simply and graphically, this spiral insert in the housing pot is extended axially beyond the housing pot - and thus offers - via its axially extended outer peripheral surface - a radial contact surface with both the housing pot and the housing cover. A simply realized centering of the spiral insert and the housing cover (or also a (pot spiral) suction flange realized together with the housing cover) is thereby possible.

Particularly preferably, it can further be provided here that the radially inner sealing element is arranged on the outer peripheral surface of the spiral attachment.

D. h., The radial contact between the spiral insert and the housing (housing pot and housing cover) is used multiple times. In addition to the centering of the spiral insert and the housing cover / suction flange, the radial bearing also serves as a "support" for the radially inner sealing element.

As a result, the fit number can be reduced in the housing, which greatly simplifies its processing.

Furthermore, it can preferably be provided that the housing is used in a compressor, in particular a compressor for carbon dioxide applications.

The compressor can be a single-shaft compressor.

Also, the compressor may be a Getriebeturboverdichter. In other words, in a further preferred embodiment, the housing according to the invention - as a receptacle for an impeller of a compressor stage and as a flow guide for a fluid in the compressor stage - installed in a Getriebeturboverdichter.

It can also be provided that the housing is used in an expander or a turbine.

The previously given description of advantageous embodiments of the invention contains numerous features, which are given in the individual subclaims partially summarized in several. However, those skilled in the art will conveniently consider these features individually and summarize them to meaningful further combinations.

In figures, embodiments of the invention are shown, which are explained in more detail below. The same reference numerals in the figures designate technically identical elements. Arrows illustrate directions of movement of objects or elements.

Show it:

1 a longitudinal section through a portion of a compressor stage of a gear compressor with a pot spiral housing according to the invention with backup seal in compact design,

2 a detailed view 1 with a section of the gear compressor with a cup spiral housing according to the invention with backup seal in compact design,

3 a detailed view 1 with a section of the gear compressor with a cup spiral housing according to the invention with backup seal in compact design,

4 a plan view of a gear compressor with a pot spiral housing according to the invention with backup seal in compact design and

5 a detailed view 1 with a section of the gear compressor with a pot spiral housing according to the invention with backup seal in compact design.

Backup seal in compact design with a pot spiral housing of a compressor stage in a gearbox compressor

1 shows a longitudinal section through an illustrated part of a compressor stage 18 a gear compressor 10 with an inventive, the compressor stage 18 receiving pot spiral housing 1 ,

The pot spiral housing 1 (hereinafter only housing 1 ) has a housing pot 2 (in the following only pot 2 ) and one against the pot 2 over a common investment area 6 (between pot 2 and housing cover 8th ) by means of a screw connection 19 screwed housing cover 8th (in the following only lid 8th or even (cup spiral) suction flange 8th ) on.

The compressor stage 18 is by a about a rotation axis 22 rotating and in an axial bore 15 in the pot 2 recorded - not shown for clarity - rotor or pinion shaft formed at one end, a in the pot 2 located (also not shown) impeller is mounted.

The impeller is activated by an axial inflow 12 from one - over one in the housing cover 8th trained, axial flange 24 (Therefore, the housing cover will be described below 8th also as Topfspiralsaugflansch 8th referred to) in the pot 2 entering - fluid 11 flows (axial) and promotes the compressed fluid 11 radially outward into an annulus 23 (shown only schematically), wherein the fluid is also compressed.

The circumferentially about the axis of rotation 22 extending annulus 23 is done by means of the pot 2 and one in a recess 9 or cylindrical bore 9 of the pot 2 used spiral insert 7 educated.

The spiral insert 7 is like 1 shows, so in the pot 2 fitted that axially frontally of the spiral insert 7 an enclosed space that forms the annulus 23 forms remains.

For sealing the pressure-bearing housing 1 is in the common investment area 6 between the pot 2 and the lid 8th a backup seal 3 introduced in compact design, their tightness by means of a gap monitoring 13 is monitored or controlled.

Next 1 show the 2 and 3 this backup seal 2 (also 5 ) with their gap monitoring 13 in detail.

The backup seal 3 is how the 1 - 3 and 5 show, as a double / tandem seal with a first, radially outer sealing element 4 , an O-ring, and one to the first sealing element 4 arranged radially inside, second sealing element 5 , a cupseal, designed.

Both sealing elements / seals 4 . 5 , ie the O-ring and the Cupseal are in corresponding sealing element recordings 14 respectively. 15 in the lid 8th arranged.

The two sealing element recordings 14 and 15 are like that 1 - 3 and 5 also show that way in the lid 8th introduced that the two sealing elements 4 and 5 offset both radially and axially, ie "obliquely" or "nested" to each other, in the lid 8th or in the common contact surface 6 are arranged.

This is indicated by the lid 8th - in the area of the common contact area 6 - An axial and radial or an axial and radial offset forming gradation 25 on, on which two receptacles / recesses 14 . 15 , ie sealing element recordings 14 and 15 for the two sealing elements (O-ring and Cupseal) 14 and 15 are arranged or introduced.

The inclusion of the radially outer O-ring 4 takes place via a (triangular) chamfer 14 (radially outside) at the gradation 25 ; the inclusion of the radially inner cupseal 5 via a rectangular groove 15 (radially inside) at the gradation 25 ,

About the gradation 25 or their axial and radial offset in the lid 8th becomes the oblique arrangement or the nesting of the two sealing elements 4 and 5 or the O-ring 4 and the cupseal 5 realized what a compact design of the backup seal 3 and thereby the housing 1 or the compressor stage 18 / the turbomachine 10 allows.

How continue that 1 - 3 and 5 show is the - in the pot 2 introduced - spiral insert 7 extended axially (axial extension 30 ) that he so - over his by the axial extension 30 resulting axially extended outer peripheral surface 31 - A common radial contact surface 21 both with the pot 2 as well as with the lid 8th forms.

This radial outer peripheral surface 31 of the spiral insert 7 serves as the 1 - 3 and 5 also show as a support surface for the radially inner sealing element 5 or for the Cupseal 5 ,

D. h., The radial abutment on the common radial contact surface 21 between the spiral insert 7 and the housing 1 ie the pot 2 and the lid 8th , is used multiple times. In addition to the centering 33 of spiral insert 7 and lid 8th The radial system also serves as a "carrier" for the radially inner sealing element 5 ,

This allows the fit number in the case 1 be reduced, which greatly simplifies its processing.

The gap monitoring 13 looks like that 1 - 3 show a radially and axially between the first and the second sealing element 4 . 5 in the common contact area 6 arranged monitoring room 26 in front.

This - radially encircling - monitoring space 26 gets through a chamfer 27 at the pot 2 , ie there in the area of the (complementary) "counterstay" of the pot 2 to the grading 25 on the lid 8th , educated.

About two holes 28 . 29 ie, a substantially axially extending, first bore and an adjoining, substantially radially extending, second bore in the pot 2 or in the pot wall 35 becomes the gap to be monitored 27 to the outside, ie outside the housing 1 , connected.

The first hole 28 , which are in the area of (surveillance space) bevel 27 in the surveillance room 27 opens, is substantially perpendicular to the chamfer 27 aligned.

This is a drilling in making the hole 28 simplified - and - due to a short hole which can be realized thereby and at an angle to the sealing surface of the radially inner sealing element 5 standing tapping surface at the hole 28 - Damage to the sealing surface of the radially inner sealing element 5 largely excluded.

The second hole 29 runs like that 1 - 3 show, - inclined at about an angle of 45 ° - in the pot wall 35 radially outward, where they are at a milled surface 17 (see also 4 ) on the outer contour of the pot 2 outside the pot 2 occurs.

This milled surface 17 on the outer contour of the pot 2 serves for screwing 20 a connection component (not shown) for the gap monitoring 13 ,

At the connection element, a sensor may be connected, which in the space to be monitored 27 penetrating leakage detected - and thus the sealing effect of the radially inner sealing element 5 or the cupseal 5 controlled.

As 5 also shows, there is a mounting fuse 32 of the spiral insert 7 in the pot 2 by means of a stud (not shown). This is a corresponding threaded hole 32 in spiral use 7 and a corresponding hole 32 in the pot 2 intended. The fuse is done before the lid 8th or the suction flange 8th the spiral insert 7 in the pot 2 suppressed.

This backup seal 3 with its inclined two sealing elements 4 . 5 as well as laying on bevel ( 14 . 27 ) Radially circulating spaces in the backup seal 3 as well as in the gap monitoring 26 enable such a compact, easy to manufacture and pressure-resistant housing 1 , in the wall thicknesses 35 are reduced as well as the Gehäusedeckelverschraubung 19 closer to the sealing elements 4 . 5 and so on the pressure surface sit - and so can turn out smaller. In addition, this also the residual clamping force of Gehäusedeckelverschraubung 19 improved.

Further, this also allows the number of fits in the housing 1 reduced and centerings 33 at pot 2 , Lid 8th and spiral insert 7 simple and efficient - because they can be used multiple times.

The disassembly of the housing 1 is also easier because the gap monitoring 26 when disassembling the lid 8th / suction flange 8th does not have to be dismantled.

While the invention has been further illustrated and described in detail by the preferred embodiments, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (12)

Casing ( 1 ) of a turbomachine ( 10 ) with a housing pot ( 2 ) and one over a common contact surface ( 6 ) on the housing pot ( 2 ), in particular via the common contact surface ( 6 ) screwed against the housing pot, housing cover ( 8th ) and with one in the common contact surface ( 6 ) arranged seal ( 3 ) for sealing the common contact surface ( 6 ) with a first sealing element ( 4 ) and one to the first sealing element ( 4 ) arranged radially offset, second sealing element ( 5 ), characterized in that the first and the second sealing element ( 4 . 5 ) are also arranged axially offset from one another. Casing ( 1 ) according to at least one of the preceding claims, characterized in that the first sealing element ( 4 ) in a first sealing element receptacle ( 14 ) and the second sealing element ( 5 ) in a second sealing element receptacle ( 15 ) are arranged, wherein the first and the second sealing element receiving ( 14 . 15 ) in the housing cover ( 8th ) are formed. Casing ( 1 ) according to claim 2, characterized in that the first and / or the second sealing element receptacle ( 14 . 15 ) as a circumferential chamfer / bevels on the housing cover ( 8th ) are formed, or that the first sealing element receptacle ( 14 ) as a circumferential chamfer and the second sealing element receptacle ( 15 ) as a circumferential, rectangular groove or circumferential, rectangular recess on the housing cover ( 8th ) are / is formed. Casing ( 1 ) according to at least one of the preceding claims, characterized in that the sealing elements ( 4 . 5 ) O-rings and / or Cupseals are. Casing ( 1 ) according to at least one of the preceding claims, characterized in that the first sealing element ( 4 ) radially outside the second sealing element ( 5 ) is arranged and the first sealing element ( 4 ) an O-ring and the second sealing element ( 5 ) are a cupseal or a profile seal. Casing ( 1 ) according to at least one of the preceding claims, characterized by a gap monitoring ( 13 ) for the seal ( 3 ), in particular for one in the common contact surface ( 6 ) radially between the first and the second sealing element ( 4 . 5 ) trained surveillance room ( 26 ). Casing ( 1 ) according to claim 6, characterized in that the gap monitoring ( 13 ) one on the housing pot ( 2 ), the surveillance space ( 26 ) limiting circumferential chamfer ( 27 ), which in such a way on the housing pot ( 2 ) is formed so that it is radially and axially between the first and the second sealing element ( 4 . 5 ) in the common contact surface ( 6 ) is arranged. Casing ( 1 ) according to claim 7, characterized in that the gap monitoring ( 13 ) one in the area of the chamfer ( 27 ) into the surveillance room ( 26 ) opening bore ( 28 ), wherein the bore ( 28 ) perpendicular to the chamfer ( 27 ) is trained. Casing ( 1 ) according to at least one of the three preceding claims, characterized in that the gap monitoring ( 13 ) one on an outer peripheral surface ( 17 ) of the housing pot ( 2 ) formed, in particular milled, screwing surface ( 17 ) for screwing a connection element for the gap monitoring ( 13 ) on the housing pot ( 2 ) having. Casing ( 1 ) according to at least one of the preceding claims characterized by a in the housing pot ( 2 ), a common radial contact surface ( 31 ) with the housing pot ( 2 ) and the housing cover ( 8th ) having spiral insert ( 7 ). Casing ( 1 ) according to claim 10, characterized in that one ( 5 ) of the two sealing elements ( 4 . 5 ), in particular the radially inner sealing element ( 5 ) of the two sealing elements ( 4 . 5 ), on an outer peripheral surface ( 21 ) of the spiral attachment ( 7 ) is arranged Casing ( 1 ) according to at least one of the preceding claims, used in a compressor ( 10 ), in particular a single-shaft or a gear turbo compressor ( 10 ), hereinafter in particular for a carbon dioxide application, an expander or a turbine.

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