EP2846001A1 - Assembly and disassembly methods of a rotor of a gas turbine, corresponding tool and gas turbine - Google Patents

Abstract

The present invention relates to a method for dismantling a, in particular foremost, rotor (19) of a gas turbine (1) with a housing (3) and a channel (5) which diverges in a flow direction and in which the rotor is arranged, with the steps; axially displacing an outer sealing ring (27) radially opposite the rotor, the minimum inner diameter (d 27) of which is smaller than a maximum outer diameter (D 19) of the rotor, opposite to the direction of flow; and then axial displacement of the rotor against the flow direction, in particular out of the housing, a method for mounting such a rotor (19) and a tool (101-106) for this and an associated gas turbine.

Description

The present invention relates to a method for disassembling a, in particular foremost, rotor of a gas turbine, a method for mounting such a rotor and a tool for fixing at least one further rotor in such assembly or disassembly and a gas turbine particularly suitable for this purpose.

For example, from the US 7,186,078 B2 For example, a low-pressure gas turbine with a housing and a channel is known, in which several rotors are arranged in succession in order to extract energy from a gas.

The outer diameter of the channel and the successively arranged rotors increase in the direction of flow.

Accordingly, according to in-house practice for assembly, a first rotor with the smallest outer diameter is introduced against the direction of flow from the rear into the conical channel, then another rotor with a larger outer diameter, etc. to the rearmost rotor with the largest outer diameter. For disassembly of the foremost rotor, all rear rotors have to be disassembled in the reverse order, firstly consuming, before finally the foremost rotor can be pulled backwards out of the conical channel.

On the other hand, the foremost rotor is usually exposed to the highest mechanical and / or thermal stresses, so it is most often disassembled for inspection and / or maintenance purposes.

An object of an embodiment of the present invention is to improve the inspection and / or maintenance of a gas turbine.

This object is achieved by a method having the features of claims 1 and 7, respectively. Claim 13 presents a tool for use in a device according to the invention Process under protection, claim 15 a particularly suitable for such a method gas turbine. Advantageous embodiments of the invention are the subject of the dependent claims.

One aspect of the present invention relates to a method for disassembling a rotor of a gas turbine. Another aspect relates to a gas turbine particularly suitable for this purpose. Accordingly, the following explanations apply equally to a method and / or a gas turbine according to an aspect or advantageous embodiments of the present invention.

The gas turbine may in particular be a low-pressure gas turbine or turbine stage, preferably an aircraft engine, and have a housing and a channel in which the rotor is arranged and which diverges in a flow direction. For compact presentation, in the present case also a housing part of a multi-part overall housing is referred to as housing for short.

A contour, in particular a diameter, of the channel can expand in the direction of flow, in particular at least substantially monotonically and / or in steps.

In the channel of the rotor to be disassembled and in one embodiment, one or more further rotors are arranged. In the flow direction before and / or after one or more rotors, in particular between adjacent rotors, in each case a guide grid can be arranged.

In a further development, the rotor to be disassembled is a first or foremost or upstream rotor in the direction of flow, or the rotor or rotors corresponding to the latter, or rotors which are more downstream. Accordingly, in the present case, an axial upstream position in the flow direction is referred to as the front position or the front, an axial position downstream in the flow direction corresponding to the rear position and the rear, respectively.

The rotor to be disassembled has, in one embodiment, one or more circumferentially distributed blades and a rotor disc. The blades can be releasably, in particular form-fitting, preferably by means of profiled blade feet, or permanently, in particular materially secured, attached to the rotor disk, preferably integrally formed or as so-called BLISK together with the rotor disk. In one embodiment, the blades radially outwardly outer shrouds, which together form an outer ring, in another embodiment, the blades are outer dead band.

In one embodiment, an outer contour, in particular an outer diameter, of the rotor blades, in particular of an outer ring of the rotor, widens in the direction of flow.

In one embodiment, the outer ring may have one or more axially spaced radial flanges or sealing tips that extend radially outward. In one development, an outer diameter of a front radial flange is smaller than an outer diameter of a rear radial flange. In one embodiment, a maximum outside diameter of the rotor to be disassembled lies in its rear half in the direction of flow.

Between the rotor and the housing, an outer sealing ring is arranged. Accordingly, in one embodiment, the outer sealing ring of a gas turbine according to one aspect of the present invention, in the flow direction, first or foremost or upstream Außendichtring.

The outer sealing ring may be releasably secured to the channel or housing. In particular, a rear axial flow in the axial direction of the outer sealing ring may be suspended in a corresponding groove of the housing, which may be formed in a development by a fixed to the housing guide grid. In one embodiment, the outer sealing ring radially inward or facing the rotor has an inlet lining and / or a honeycomb seal.

In one embodiment, an inner contour, in particular an inner diameter, of the outer sealing ring in the flow-through direction expands, in particular monotonously, preferably in one or more shoulders. In a further development, a shoulder of the inner surface of the assembled outer sealing ring is opposite to a radial flange of an outer ring of the rotor to be dismantled, a further shoulder being another radial flange of the outer ring.

In one embodiment, a minimum, in particular foremost, inner diameter of the outer sealing ring is smaller than a maximum outer diameter of the rotor, in particular as a rearmost outer diameter of an outer ring, preferably as an outer diameter of a (rearmost) radial flange of the outer ring.

According to one aspect of the present invention, the rotor to be disassembled is disassembled or axially displaced, in particular forward toward the direction of flow, out of the housing.

For this purpose, in one embodiment, the outer sealing ring, whose - smaller - minimum inner diameter would come into conflict with its - larger - maximum outer diameter upon displacement of the rotor, moves axially counter to the throughflow direction, in particular out of the housing. Subsequently, the rotor itself can then be moved axially against the flow direction, in particular forward out of the housing.

As a result, according to one aspect of the present invention, a, in particular foremost, rotor directly, in particular without dismantling rear rotors, be disassembled. In this way, the inspection and / or maintenance, in particular an exchange, of the rotor can be simplified.

If the maximum outer diameter of the outer sealing ring is smaller than the minimum (inner) diameter of the section of the channel in front of it in the direction of displacement, the outer sealing ring can easily be displaced axially out of the channel against the direction of flow. If, however, the minimum (Inside) diameter of the direction of displacement in front of him section of the channel is smaller, this is not. Therefore, according to one aspect of the present invention for disassembly, the outer seal whose maximum outer diameter is greater than a minimum (inner) diameter of the channel is circumferentially divided into two or more, preferably at least 16, more preferably at least 32 parts. Subsequently, the outer sealing ring parts can be displaced radially inwards or to a rotational axis of the gas turbine and in this way also past the smaller inner diameter of the channel.

This radial displacement inwards and the axial displacement against the direction of flow can be superimposed, at least in sections or partially. In one embodiment, this can minimize the effort and / or movement space required to be carried out counter to the direction of flow. Additionally or alternatively, outer sealing ring parts can also be displaced, at least in sections or partially, purely radially and / or purely axially. For example, the entire outer sealing ring or outer sealing ring parts can first be displaced by an axial path length in the direction opposite to the throughflow direction, for example until they block up through the channel. Subsequently, the outer sealing ring parts can be moved purely radially or radially inwards with superimposition of a further axial displacement, so that they can pass through the channel.

In one embodiment, the outer sealing ring parts are also tilted in addition to an axial and / or radial displacement, in particular in order to release them from axial displacement from a circumferential groove of the housing. In a preferred embodiment, however, the outer sealing ring parts can, on the other hand, be displaced axially and, if necessary, radially, at least essentially, without tilting, or do not have to be tilted in advance for axial displacement. In particular, it can be provided that the outer sealing ring or the outer sealing ring parts are initially initially displaced axially without tilting.

In particular, according to one aspect of the present invention, the outer sealing ring on the housing is frictionally engaged, detachable and counter to the direction of flow attached form-fitting. This is understood in the present case in particular that the outer sealing ring on the housing is releasably and frictionally mounted so that it can be displaced axially against the flow direction, in particular macroscopically or by at least 5 mm after loosening the frictional engagement, without that a radial shoulder of a Friction contact surface of the housing for frictional connection with the outer sealing ring opposite, in particular a wall of a circumferential groove. The outer sealing ring can be attached to the housing in one embodiment by a one-part or multi-part strained so-called C-ring ("C-clip") releasably and frictionally mounted or be.

In a flow direction, the outer sealing ring on the housing, however, be positively secured or fixed in a development, in particular by a one-sided paragraph, in the present case a circumferential groove in contrast to such a one-sided paragraph is referred to as two- or two-sided paragraph.

In a circumferential direction, the outer sealing ring is secured or fixed in a form-fitting manner to the housing. For this purpose, in one development, the outer sealing ring may have one or more radial projections which extend radially outwardly from an outer peripheral surface of the outer sealing ring for frictional engagement with a radially opposite inner peripheral surface of the housing and engage in corresponding axial grooves of the housing, which in particular at an in front in the flow direction End face of the housing can be arranged. Additionally or alternatively, the housing may have one or more radial projections which extend radially inwardly from an inner peripheral surface of the housing for frictional engagement with a radially opposed outer peripheral surface of the outer sealing ring and engage corresponding axial grooves of the outer sealing ring, in particular at a rear end face in the flow direction the outer sealing ring can be arranged. An extent of a radial projection in the circumferential direction may be smaller, equal to or greater than a distance in the circumferential direction between two circumferentially adjacent walls of two circumferentially adjacent grooves.

Correspondingly, in one embodiment, the outer sealing ring and the housing are frictionally secured to each other in one embodiment and are not secured or fixed in the circumferential direction and / or in the flow direction, but not counter to the direction of flow, in particular not by means of a circumferential groove.

In this way, in one embodiment, an initial tilting of the outer sealing ring or outer sealing ring parts can be avoided by initially displacing them axially against the direction of flow. Hereby, it advantageously becomes possible to reduce a sealing gap between the outer sealing ring and the rotor, which otherwise has to be increased to permit tilting, which, however, deteriorates the sealing effect.

Depending on the structural design of the rotor to be dismantled in its mounting position may be opposed to a radial displacement of the outer sealing ring parts. In particular, therefore, in one embodiment of the present invention, the rotor is first displaced axially or in the flow direction before or before the radial displacement of the outer sealing ring parts. In this way, in one embodiment (further) space for the radial displacement of the outer sealing ring parts radially inward, if necessary. Under superimposition of an axial displacement against the flow direction, are provided. Equally, however, it may also be provided that the outer sealing ring or outer sealing ring parts are initially displaced axially counter to the direction of flow without first having to displace or displace the rotor in the throughflow direction.

The housing may be connected at its front end side with a connection flange. This connection flange may in particular be part of a high-pressure turbine, which is upstream of a low-pressure turbine, part of an upstream combustion chamber or the like or a connecting piece for this purpose. Similarly, the connection flange may also be part of a transport cover for closing the channel or the like.

Accordingly, in one embodiment of the present invention, prior to the axial displacement of the outer sealing ring against the flow direction, a connection flange connected to the housing, whose inner diameter facing the rotor is smaller than the maximum outer diameter of the outer sealing ring, detached from the housing. Also, a connecting flange without through-hole is referred to as a connecting flange, the inner diameter facing the rotor is equal to zero and thus smaller than the maximum outer diameter of the outer sealing ring.

In one embodiment of the present invention, prior to the axial displacement of the outer sealing ring against the flow direction, a, in particular frictional, connection of the outer sealing ring with the housing, in particular a C-ring solved.

In one embodiment, one or more further rotors of the gas turbine can be radially and / or axially supported or mounted via the rotor to be dismantled. In a disassembly of the rotor without prior disassembly of the other rotors eliminates this support or storage. Accordingly, in one embodiment, one or more further rotors of the gas turbine are otherwise fixed against the axial displacement of the rotor to be dismantled against the direction of flow. For this purpose, they can be fixed in particular by means of a detachable tool that is detachably, in particular frictionally and / or positively secured to at least one of the other rotors and in turn is supported. The tool can in particular, preferably frictionally and / or positively, be supported on the housing of the gas turbine.

Accordingly, one aspect of the present invention relates to a tool for fixing one or more further rotors in the assembly or disassembly of a rotor of a gas turbine according to a method described here, in particular its use for fixing one or more further rotors in the assembly or disassembly of a rotor of a gas turbine according to a method described here. The tool has, in one embodiment, a fastening means for positive and / or frictional fastening to the housing and / or one or several other rotors of the gas turbine. The fastening means may in particular have one or more recesses and / or projections for the positive fastening and / or one or more clamping means, in particular screws, for frictional fastening. In one embodiment, the tool includes a radial flange for attachment to the housing and an axial web for radially and internally engaging and attaching one or more other rotors.

One aspect of the present invention relates to the first or re-assembly of the rotor, in particular a frontmost rotor in the direction of flow from the front into the housing. The assembly can essentially be carried out in the opposite way to the dismantling explained above, so that reference is additionally made to this.

Accordingly, in one embodiment, first the rotor to be mounted is displaced axially in the direction of flow, in particular into the housing, and then the outer sealing ring is axially displaced in the direction of flow, in particular into the housing.

In one embodiment, parts of the outer sealing ring are displaced radially toward the housing of the gas turbine and then joined together to form the outer sealing ring, in particular clamped in the circumferential direction and / or connected in a form-fitting manner. This radial displacement can also be superposed with an axial displacement of the entire outer sealing ring or the outer sealing ring parts, at least in sections or in phases.

In one embodiment, the rotor is moved axially against the flow direction after the radial displacement of the outer sealing ring parts. As a result, temporarily movement space for the radial displacement can be created.

In one embodiment, after the axial displacement of the outer sealing ring in the throughflow direction, a connecting flange whose inner diameter facing the rotor is smaller than the maximum outer diameter of the outer sealing ring, with the housing, preferably releasably connected. Additionally or alternatively, after the axial displacement of the outer sealing ring in the flow direction, the outer sealing ring, preferably releasably attached to the housing or a connection of the outer sealing ring to the housing can be closed. In particular, a C-ring can be placed, the outer sealing ring and housing frictionally clamped.

As stated above, one or more further rotors can be fixed during assembly, in particular by means of a detachable tool and / or on the housing. In particular, after the rotor to be mounted mounted, in particular supported or mounted on the housing, a corresponding fixation or the tool can be solved.

Fig. 1

einen Teil einer Gasturbine mit einem Werkzeug nach einer Ausführung der vorliegenden Erfindung;

Fig. 2A - 2C

Schritte eines Verfahrens zur Demontage eines Rotors einer Gasturbine nach einer Ausführung der vorliegenden Erfindung;

Fig. 3

einen Teil einer Gasturbine nach einer weiteren Ausführung der vorliegenden Erfindung;

Fig. 4

ein vergrößertes Detail der Gasturbine der Fig. 3; und

Fig. 5

einen Schnitt längs der Linie V-V in Fig. 4.

Further advantageous developments of the present invention will become apparent from the dependent claims and the following description of preferred embodiments. This shows, partially schematized:

Fig. 1

a portion of a gas turbine with a tool according to an embodiment of the present invention;

Fig. 2A - 2C

Steps of a method for disassembling a rotor of a gas turbine according to an embodiment of the present invention;

Fig. 3

a portion of a gas turbine according to another embodiment of the present invention;

Fig. 4

an enlarged detail of the gas turbine of Fig. 3 ; and

Fig. 5

a section along the line VV in Fig. 4 ,

Fig. 1 shows a low-pressure gas turbine 1 with a housing 3 and a channel 5, in a flow direction (from left to right in Fig. 1 ) diverges by its diameter is substantially monotonously expanded in the direction of flow.

In the channel a front in the flow direction of the rotor 19 and a plurality of further, rear rotors 21, 23 and 25 are arranged one behind the other in the flow direction.

Between or in front of the rotors guide grid 11, 13, 15 and 17 are arranged and fixed to the housing.

At its front end (left in Fig. 1 ), the housing is releasably connected to a connection flange 9 of a low-pressure turbine 1 upstream high-pressure turbine, at its rear end (right in Fig. 1 ) with an outlet housing. 7

Between each rotor and the housing, an outer sealing ring 27, 29, 31 and 33 is arranged.

The dismantling rotor 19 has a plurality of circumferentially distributed blades, of which in Fig. 1 a partially shown, and a rotor disk (not shown) on which the blades are mounted.

Fig. 2A-C shows on the basis of an enlarged partial view steps of a method for disassembling a rotor of a gas turbine of an aircraft engine according to an embodiment of the present invention, which substantially the above explained Fig. 1 corresponds, so that corresponding elements are denoted by identical reference numerals and alternately referred to the rest of the description and will be discussed only differences.

The blades have on the outside radially outer shrouds, which together form an outer ring. The outer diameter of this outer ring widens in the flow direction. The outer ring has two axially spaced radial flanges or sealing tips 19a (cf. Fig. 2A ) which extend radially outward, wherein an outer diameter of a front radial flange (left in Fig. 2A ) is smaller than an outer diameter of a rear radial flange (right in FIG Fig. 2A ).

The outer sealing ring 27, which is disposed between the rotor 19 and the housing 3, is releasably secured to the channel or housing. For this purpose, a rear axial flange (right in Fig. 2A ) of the outer sealing ring between the housing and a subsequent guide grid 13 mounted, a front axial flange (left in Fig. 2A ) of the outer sealing ring is fixed to the housing by means of a C-ring 45.

The outer sealing ring is frictionally and releasably attached to the housing against the flow direction without frictional locking: it can be seen, in particular with reference to the sequence of figures described below Fig. 2A → Fig. 2B in that, after loosening the C-ring, the outer sealing ring is axially opposite to the direction of flow (to the left in FIG Fig. 2A ) is displaceable without being hindered by a stop of the friction contact surface between the outer sealing ring and the housing.

The inner peripheral surface of the housing 3 for frictional engagement with the radially opposite outer peripheral surface of the outer sealing ring 27 has a plurality of radial projections 3.1 (see. Fig. 2B ), which extend radially inward and in axial grooves in a rear direction of flow (right in Fig. 2 Engage the end face of the outer sealing ring, in order to secure or fix it in the circumferential direction and in the direction of flow in a form-fitting manner to the housing.

The outer sealing ring, facing radially inward or facing the rotor, has an inlet lining 59 designed as a honeycomb seal.

The inner diameter of the outer sealing ring extends monotonously in the flow direction in several paragraphs, with a shoulder of the assembled outer sealing ring a radial flange (left in Fig. 2A ) of the outer ring of the rotor to be disassembled, a further shoulder of the mounted outer sealing ring another radial flange (right in Fig. 2A ) of the outer ring.

A minimum, foremost inner diameter d _{27 of} the outer sealing ring 27 is smaller than a maximum outer diameter D _{19 of} the rotor 19, in particular as the outer diameter of its rearmost radial flange 19 a.

For disassembly of the foremost rotor 19 against the flow direction forward from the housing 3 out first connected to the housing 3 connecting flange 9 (see. Fig. 1 ), whose inner diameter facing the rotor (on the right in FIG Fig. 1 ) is smaller than the maximum outer diameter D _{27 of} the outer sealing ring (see. Fig. 2A ), detached from the housing 3.

Then, the connection of the outer sealing ring 27 is released with the housing 3 in the form of the C-ring 45, as in Fig. 2B indicated by an arrow.

In advance, simultaneously or subsequently, as also in Fig. 2B indicated by an arrow, the rotor 19 axially displaced in the flow direction to provide space for a radial displacement of outer sealing ring parts radially inward available. In a modification, not shown, this step can also be omitted.

Since the maximum outer diameter D _{27 of} the outer sealing ring is greater than the minimum (inner) diameter d _{5 in} the direction of displacement (from right to left) in front of him section of the channel, the outer sealing ring axially against the flow direction can not be completely displaced from the channel. Therefore, for disassembly, the outer sealing ring 27 is first displaced axially against the flow direction and then divided into two or more parts, which are then displaced radially inward or toward a rotational axis of the gas turbine and in this way are also guided past the smaller inner diameter of the channel, as in Fig. 2C indicated by arrows. This inward radial displacement is, as indicated by these arrows, superimposed on a further axial displacement of the outer sealing ring or its parts counter to the direction of flow.

Subsequently, the rotor 19 is then displaced axially outward against the direction of flow forward out of the housing 3 and so directly without Dismantling of the rear rotors 21, 23 and 25 dismantled. In this way, the inspection and / or maintenance, in particular an exchange, of the rotor can be simplified.

These further rotors 21, 23 and 25 of the gas turbine 1 are fixed against axial displacement of the rotor 19 to be dismantled counter to the direction of flow by means of a detachable tool, which in turn is supported on the housing 3 of the gas turbine, as in Fig. 1 indicated by dashed lines.

The tool has a radial flange 101 for attachment to the housing 3 and an axial web 102 and a fastening means 103, 104 - 106 for positive and / or frictional fastening to the housing 3 and the further rotors 21, 23 and 25. The fastening means may in particular have one or more recesses and / or projections for positive fastening and / or one or more clamping means, in particular screws, for frictional fastening (not shown).

A first or re-assembly of the foremost rotor 19 in the direction of flow from the front into the housing 3 takes place substantially inversely to the dismantling explained above, so that reference is additionally made to this.

Accordingly, the rotor 19 to be mounted and then the outer sealing ring 27 are first displaced axially into the housing 3 in the throughflow direction. In this case, the parts of the outer sealing ring are displaced radially to the housing of the gas turbine and then joined together to form the outer sealing ring, in particular clamped in the circumferential direction and / or positively connected (see. Fig. 2C in the reverse direction of the arrow). This radial displacement is superposed with the axial displacement of the entire outer sealing ring or the outer sealing ring parts. In particular, in a last step (cf. Fig. 2B → Fig. 2A ) the entire outer sealing ring axially displaced in the flow direction, so that the radial projections 3.1 of the housing in the axial grooves of the outer sealing ring engage and secure this in addition to the frictional engagement by the C-ring in the circumferential direction and in the flow direction or set.

After the radial and axial displacement and assembly of the outer sealing ring parts of the outer sealing ring 27 are releasably secured to the housing 3 by the C-ring 45 is placed, the outer sealing ring and housing frictionally clamped, and the rotor 19 axially against the flow direction (see. Fig. 2B in the reverse direction of the arrow).

Subsequently, the tool 101-106 is released and the connecting flange 9 releasably connected to the housing 3.

Fig. 3 shows in Fig. 2 corresponding representation of a part of a gas turbine according to another embodiment of the present invention, Fig. 4 an enlarged detail of a Reibkontaktfläche between outer ring and housing, and Fig. 5 a section along the line VV in Fig. 4 , Corresponding elements are designated by identical reference numerals, so that reference is made to the above description and will be discussed below only differences.

Also in the execution of Fig. 3-5 the outer sealing ring 27 on the housing 3 against the flow direction form fit frictionally and releasably secured by the C-ring 45: after releasing the C-ring, the outer sealing ring axially against the flow direction (to the left in Fig. 3 ) are moved without being hindered by a stop of the Reibkontaktfläche between outer seal and housing.

In contrast to the execution of Fig. 2 points in the execution of Fig. 3-5 , as in particular on average Fig. 5 Recognizable, the outer peripheral surface of the outer sealing ring 27 for frictional engagement with the radially opposite inner peripheral surface of the housing 3, a plurality of radial projections 27.1, which extend radially outwardly and in axial grooves 3.2 in a forward flow direction (left in Fig. 3-5 ) Engage the end face of the housing to the outer sealing ring in To secure or fix the circumferential direction and in the flow direction positively to the housing.

As also in particular on average Fig. 5 Recognizable, the extent of the radial projections 27.1 in the circumferential direction is greater than a distance in the circumferential direction between two circumferentially adjacent walls of two circumferentially adjacent axial grooves 3.2. In this respect, the term groove and projection includes no restriction of generality, since in some circumferentially distributed grooves and projections in each case one or the other can be regarded as a groove or projection.

Although exemplary embodiments have been explained in the foregoing description, it should be understood that a variety of modifications are possible. It should also be noted that the exemplary embodiments are merely examples that are not intended to limit the scope, applications and construction in any way. Rather, the expert is given by the preceding description, a guide for the implementation of at least one exemplary embodiment, with various changes, in particular with regard to the function and arrangement of the components described, can be made without departing from the scope, as it turns out according to the claims and these equivalent combinations of features.

Reference numeral List

1

Low pressure gas turbine

3

casing

3.1

radial projection

3.2

axial groove

5

channel

7

outlet housing

9

flange

11, 13, 15, 17

guide grid

19

foremost rotor

19a

radial flange

21, 23, 25

another, rear rotor

27, 29, 31, 33

Outer sealing ring

27.1

radial projection

45

C-ring (connection)

59

Honeycomb seal inlet lining

101

Radial flange of the tool

102

axial web of the tool

103-106

Fastening means of the tool

d ₅

minimum inner diameter of the channel 5 of the housing 3

D ₁₉

maximum outer diameter of the foremost rotor 19

d ₂₇

minimum inner diameter of the outer sealing ring 27

D ₂₇

maximum outer diameter of the outer sealing ring 27

Claims (17)

Method for dismantling a, in particular foremost, rotor (19) of a gas turbine (1), in particular according to one of the following claims, comprising a housing (3) and a channel (5) which diverges in a flow direction and in which the rotor is arranged , with the steps;
axially displacing an outer sealing ring (27) radially opposite the rotor, whose minimum inner diameter (d ₂₇ ) is smaller than a maximum outer diameter (D ₁₉ ) of the rotor, counter to the direction of flow; and subsequently
axial displacement of the rotor against the direction of flow, in particular out of the housing. Method according to the preceding claim, with the steps: Dividing the outer seal whose maximum outer diameter (D ₂₇ ) is greater than a minimum diameter (d ₅ ) of the channel; and then radial displacement of the outer sealing ring parts towards a rotational axis of the gas turbine. Method according to the preceding claim, characterized in that the rotor is displaced axially in the flow direction before the radial displacement of the outer sealing ring parts. Method according to one of the preceding claims, characterized in that before the axial displacement of the outer sealing ring against the flow direction, a connection flange (9) connected to the housing, whose inner diameter facing the rotor is smaller than the maximum outer diameter of the outer sealing ring, is detached from the housing , Method according to one of the preceding claims, characterized in that before the axial displacement of the outer sealing ring against the flow direction, a connection of the outer sealing ring with the housing, in particular a C-ring (45) is released. Method according to one of the preceding claims, characterized in that at least one further rotor (21, 23, 25) of the gas turbine, in particular by means of a releasable tool (101-106) and / or on the housing, is fixed. Method for mounting a, in particular foremost, rotor (19) of a gas turbine (1), in particular according to one of the following claims, with a housing (3) and a channel (5) diverging in a flow direction, with the steps;
axial displacement of the rotor in the flow direction, in particular into the housing; and subsequently
axially displacing an outer sealing ring (27) which is radially opposite the rotor and whose minimum inner diameter (d ₂₇ ) is smaller than a maximum outer diameter (D ₁₉ ) of the rotor in the throughflow direction. Method according to the preceding claim, with the steps: radially displacing parts of the outer sealing ring toward the housing of the gas turbine; and subsequently Joining the parts to the outer sealing ring whose maximum outer diameter (D ₂₇ ) is greater than a minimum diameter (d ₅ ) of the channel. Method according to the preceding claim, characterized in that the rotor is moved axially against the flow direction after the radial displacement of the outer sealing ring parts. Method according to one of the preceding claims, characterized in that after the axial displacement of the outer sealing ring in the flow direction, a connecting flange (9) whose inner diameter facing the rotor is smaller than the maximum outer diameter of the outer sealing ring, is connected to the housing. Method according to one of the preceding claims, characterized in that after the axial displacement of the outer sealing ring in the flow direction, a connection of the outer sealing ring with the housing, in particular a C-ring (45) is closed. Method according to one of the preceding claims, characterized in that a fixation, in particular by means of a releasable tool (101-106) and / or on the housing, at least one further rotor (21, 23, 25) of the gas turbine is achieved. Tool (101-106) for fixing at least one further rotor (21, 23, 25) during assembly or disassembly of a rotor (19) of a gas turbine (1) according to a method according to one of the preceding claims. Tool according to the preceding claim, with a fastening means (103-106) for positive and / or frictional fastening to the housing and / or at least one further rotor of the gas turbine. Gas turbine with a housing and an outer sealing ring which is frictionally attached to the housing, releasably and against a flow direction form-fitting. Gas turbine according to the preceding claim, wherein the outer sealing ring is secured in a circumferential direction positively on the housing. A gas turbine according to the preceding claim, wherein one of the outer sealing ring and the housing has at least one radial projection and the other of the outer sealing ring and the housing has a corresponding axial groove for receiving this projection.

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