EP1163427B1 - Gas turbine rotor with internally-cooled gas turbine blade - Google Patents

Abstract

The invention relates to a gas turbine rotor with an internally cooled gas turbine blade (1) which has a blade foot (2) and a blade platform (5), said blade platform having recesses (10) into which strip inserts (11) are introduced. The aim of the invention is to configure a gas turbine rotor of this type in such a way that the seal that is provided to prevent hot gas from entering and cold air from leaving and the fixing means of the gas turbine blade (1) can be produced simply and inexpensively while still being very reliable. To this end, the recess (10) extends as far as a plate-end base (13) of the blade platform (5) and the strip insert (11) has a positive fit on the plate (4) which prevents axial displacement in a direction of use (30) of the gas turbine blade (1).

Description

The invention relates to a gas turbine rotor with an interior-cooled Gas turbine blade that has a blade root and has a blade platform, and with a disc, has the disc transverse grooves in which the blade root is inserted is, the blade platform outside an outer circumference the disc is arranged and on an end wall portion one long side has a recess into which a Insert strip is inserted into a corresponding one Recess of a blade platform of a second gas turbine blade engages and a space between the two Bucket platforms bridged and sealed.

From DE-A1-198 10 567 is a sealing plate for a Gas turbine blade known. If cooling air, that of the gas turbine blade is fed into the high-temperature fuel gas channel escapes, this leads among other things to a belittling the performance of the gas turbine. The sealing plate, which in the gas turbine blade is used to exit prevent cooling air. The seal is made except by the named sealing plate by different sealing pins, built between the platforms of two blades are. A variety of sealing elements are required to the desired sealing function against the escape of cooling air manufacture.

DE-B-1 258 662 discloses a deck device for the Guiding the cooling gas of gas turbine disks, which consist of several individual segments, which are interlinked with sealing strips are sealed. Sealing takes place in one additional device in front of the gas turbine disc and the gas turbine blades inserted therein is. This increases the number of elements required to build the Seal are needed.

US-A-4 523 890 discloses sealing elements for the foot areas the turbine blades. The seal is used for reduction the loss of cooling air at the bottom of the feet. For the The sealing elements must hold grooves in the turbine disk be introduced into which the sealing elements are inserted are. So there are complex manufacturing steps necessary.

Similar arrangements of sealing elements continue to do so used, the entry of hot gas into the platform area respectively the internal cooling system of a gas turbine blade to prevent. Such hot gas entry can severe damage to the gas turbine blade. To prevent this, the hot gas flow facing side of the blade platform of the gas turbine blade several sealing elements in the blade platform used.

In the described structures for sealing the platform the gas turbine blade it turns out to be disadvantageous that the seal is constructed from a variety of elements and consequently the installation of the seal in the gas turbine blade is difficult. To do this, different must continue Fuse elements are attached to prevent that the gas turbine blade is rotating in the Disc of the gas turbine slipped sideways or even falls out.

The object of the invention is to provide a gas turbine rotor Specify indoor-cooled gas turbine blade, where both the seal against hot gas entry as well Cooling air outlet and securing the gas turbine blade to produce with little effort and at the same time very reliable are.

The object is achieved in that the recess up to one disc-side base of the blade platform is sufficient and the insert strip against axial displacement in Safeguarding the direction of use of the gas turbine blade Has positive locking on the disc.

Due to the specified design of the deployment strip in particular its extension to the bucket platform is on the one hand ensures that the blade platform on its End wall section against penetration of hot gas respectively Outflow of cooling air is sealed. The seal leaves easy to manufacture and is made by a single element done that in its form individually to different Platform configurations can be adapted.

At the same time there is an axial fixation through the insert strips the gas turbine blade in the disk of the gas turbine rotor given. The gas turbine blade, with its blade root is inserted in a disc transverse groove of the disc and the Platform is located outside the circumference of the disc, can not be undesirable relative to Move the disc transverse groove. The axial fixation is done by ensures the positive fit of the insert strip on the disc. This in particular causes the gas turbine blade to slip prevented in the direction in which the forces attacking the gas turbine are preferably directed could be. This type of fixation is special stable and easy to install and remove and has a low Susceptibility to failure.

After thermal expansion resulting from the stress through the hot gases flowing to the wing the insert strip completely returns to its zero position on the other hand, to shift continuously, for example which becomes a after a few runs of the gas turbine rotor Failure of the functions of the securing element against displacement in one direction of use of the gas turbine blade in the disc groove would lead.

The gas turbine blade is sealed and fixed accordingly with a single element, the insert strip. This represents a significant improvement over the state the technology, in which a large number of elements and associated with a great effort in the facility was. In addition to the simplicity of the backup, it is advantageous a single insert strip also makes it easy to handle and the ability to quickly replace it to clean or repair.

It is preferably highly heat-resistant and resistant to chemical attacks stable material to use, so that the inflowing Hot gas does not deform the insert strip, respectively destroyed corrosively. The proposed training of the Insert strips can be made with these materials due to their simple shape can be easily produced and also exhibit great durability with brittle materials.

Comprehensive protection against axial displacement in both directions of use of the disc transverse groove are delivered that on the end wall portions of a long side of the Bucket platform each has a recess, and that their insert strips on two opposite one another Face the front of the pane and against axial displacement secure the gas turbine blade relative to the disc. The Securing against axial displacement or against a forward and Slipping back of the gas turbine blade inserted into the transverse disk groove is through the two opposite Insert strips guaranteed, each a hedging Form-fit on the two opposite disc ends own the disc. The axial movement will inhibited to the extent that axial displacements of the gas turbine blade either completely inhibited relative to the disc are or only in a predetermined small frame possible are.

If on the end wall sections of each long side of the bucket platform each has a recess and in it Insert strips are inserted, every gas turbine blade secured by four insert strips, two strips each ensure security in one direction. In this way, the gas turbine blade itself is closed a failure or loss of a deployment strip in the Disk transverse groove non-displaceable through the remaining three Stripes held. Two gas turbine blades each share the one between them in the long side of the bucket platform seated two insert strips.

The insert strips can thus be attached with little effort and held particularly securely in the recess that the recess obliquely in the direction of a longitudinal axis of the rotor Gas turbine rotor runs and at its disc end into a chamfer on the disc head corresponding to the recess empties. The hot gases are due to the inclination of the insert strip used in the direction of the gas turbine wing distracted and thus optimally used without too to be swirled heavily by the bucket platform respectively the blade platform too strong with high temperatures to charge. By protruding from the deployment strip about the bucket platform and the close contact with the sloping chamfer is a good seal against penetration of the Hot gases in the blade platform or an escape of the Cooling air guaranteed.

The adjusted bevels provide an even, one-sided Applying the deployment strip to the recess or the chamfer of the disc head, whereby attacking forces to Example shear forces caused by a relative displacement the gas turbine blade compared to another gas turbine blade or the gas turbine blade opposite the disk transverse groove arise without too much selective stress of the deployment strip can be safely intercepted.

A simple safeguard against loss of the deployment strip for example due to attacking centrifugal forces given that the recess is open on the disc side and the insert strip when inserted in the disc transverse groove Push the gas turbine blade into the recess on the disc side is. The insert strip is inserted after insertion thereby, for example, through the closed wing-side End of the recess or held by his disc-side end is widened and a Undercut of the recess, so that a Form fit against the attacking centrifugal forces.

Forces acting on the insert strips can be effective without interruption of the emergency lane is prevented, that it is between the disc-side end of the recess and the outer circumference of the disk a relative movements between the gap and the blade platform allowing gap gives. Attacking forces are, for example, shear forces that due to relative movements between the disc and the blade platform or by the relative to each other in the disc transverse grooves shifting gas turbine blades arise. The Dimensions of the gap will be at the bottom of the recess designed so that the attacking people of different sizes Forces due to appropriate elastic deformations of the attached Insert strips can be intercepted so that a kind of "springback effect" is achieved. Movements of the The end of the insert strip is in the direction of use of the gas turbine blade as well as possible perpendicular to it, depending on which of the attacking forces are intercepted particularly strongly Need to become. Are the axially displacing forces in particular Shear forces particularly large, it makes sense to leave a gap to choose with a very low height so that the insert strip has sufficient rigidity to the axial To be able to exercise security reliably.

The insert strip is preferably made of a material that has sufficient elastic deformation properties.

For example, this is the case with a high-temperature alloy Given nickel-based alloys. This allows the material of the insert strip to avoid contamination or diffusion damage and to ensure a uniform thermal expansion of the blade platform and insert strips on the material of the gas turbine blade selected is selected.

A comprehensive hold of the deployment strip is given that the recess is designed as a groove. The groove is preferably characterized by at least three surrounding them Walls that have a positive connection to prevent the Form the deployment strip. It also provides the sealing strip surrounding groove a better seal against inflowing Hot gas or cooling air flowing out. The groove can be designed so that they are close to the Insert strips and thus without additional sealing materials seals. Another form of training are on the groove attached cutting edges which engage in the insert strip.

The groove continues to provide increased security against Effects of forces on the deployment strip, for example shear forces caused by relative displacements the platforms with each other or the platforms relative to the disc. The groove is open on the side, which is closest to the neighboring platform. To this The insert strip can easily be placed in the two opposite one another Grooves are inserted and sits there very sure.

A slip of a deployment strip in the event of attacks by Centrifugal forces can easily be prevented by the Recess at its disc-side end is wider than at their remaining part. In this way, a positive connection is against a slipping of the deployment strip, which by the disc-side end of the recess can be used prevented without simultaneously closing the groove at the top have to be.

A secure hold of the insert strip with the gas turbine stopped results from the fact that the insert strip in its Insert position is fixed on the disc. In this way is the insert strip slipping out of the recess even when stationary, if not due to the centrifugal force is pushed out due to the rotational movement, prevented. The fixation on the disc is still an improved hold against axial slippage. she can be done for example by a screw or a bolt be present below the deployment strip is and does not have to intervene in the latter. This especially simple type of fixation can be made quickly and undo quickly even if corrosion occured.

To ensure that the slip resistance against loosening due to the centrifugal force load, it is advantageous that a screw part is used to fix the insert strip, which engages in a recess of the insert strip and which is supported under centrifugal force on the insert strip. By engaging in the recess of the insert strip, the screwed part secures the insert strip against slipping out when the gas turbine is stopped. At the same time, the insert strip prevents the screw part from slipping out due to the fact that the screw part is supported on the insert strip by centrifugal force. Accordingly, the two elements secure each other.
This reduces the number of elements required. At the same time, the insert strip can in turn be easily removed if, for example, gas turbine blades are to be replaced.

This can support the screw part on the insert strip happen that the screw part has a projection, that immediately when the gas turbine blade is at a standstill on the surface of the insert strip facing the pane is applied, with another part of the screw part through the Recess of the insert strip passes through. This must be sure that the one supported on the insert strip Part of the screw part not by the ordinary below thermal stress on the insert strip reaches into the void. This can be easily ensured be that the projection of the screw part all around around the recess of the insert strip on the disc side Side of the insert strip.

A fall protection of the deployment strip and / or a Protection against ejection of the deployment strip Centrifugal attack, with no additional parts required are achieved in that the insert strip on a disc-side end in a safety recess Engages the face of the disc. The insert strip can be used for intervening in the safety recess, for example already have a bent end after insertion or after be inserted into the securing recess. Another possibility is that the insert strip one has a projection that is in the inserted position corresponds to the safety recess.

By such interventions in a security recess in the The front of the pane is the insert strip for any Maintenance purposes or in the event of a failure of the gas turbine blade without additional tools or without the danger caking of the securing element with the material due to a diffusive or corrosive attack at high Easy to remove operating temperatures. On the other hand, can the part of the Insert strip designed almost any dimension be, so that the fuse even with large external forces is given reliably. Furthermore, there is a certain game the insert strip, which engages in the securing recess, possible so that thermal expansions respectively attacking gravity without failure respectively damage to the deployment strip is more easily intercepted can be.

A fuse independent of the disc can be supplied that a security strip under the bucket platform through two insert strips and on its ends are bent. The anti-slip device is open given this way regardless of the disc. This is beneficial when large shear forces occur, Put a lot of strain on the attached panel and possibly would detach. This additional security aspect is particularly with high temperature fluctuations respectively strongly changing attacking forces important.

Good lateral hold and sealing of the insert strip is given in that the insert strip with a predetermined Depth of engagement in the recess of the blade platform engages and that the depth of engagement of the insert strip in the recess is larger than the space between two adjacent blade platforms. Even with strong ones relative shifts between the blade platforms the insert strip is captive in the two Recesses held and seals well here like a labyrinth.

FIG 1

eine perspektivische Ansicht eines Ausschnitts der Scheibe mit eingesetzter Gasturbinenschaufel,

FIG 2

eine Seitenansicht einer Gasturbinenschaufel mit Einsatzstreifen,

FIG 3

eine Seitenansicht einer Schraubfixierung des Einsatzstreifens,

FIG 4a,b

Sicherungsnutfixierungen des Einsatzstreifens,

FIG 5

eine perspektivische Ansicht einer Gasturbinenschaufel mit eingesetzten Sicherungsstreifen,

FIG 6a

eine Aufsicht auf einen scheibenseitig verbreiterten Einsatzstreifen und

FIG 6b

eine perspektivische Ansicht eines verbreiterten Einsatzstreifens.

The gas turbine rotor with interior-cooled gas turbine blades is explained in more detail using the exemplary embodiments illustrated in the drawings. Show it:

FIG. 1

2 shows a perspective view of a section of the disk with the gas turbine blade inserted,

FIG 2

a side view of a gas turbine blade with insert strips,

FIG 3

a side view of a screw fixation of the insert strip,

FIG 4a, b

Securing groove fixings of the insert strip,

FIG 5

1 shows a perspective view of a gas turbine blade with inserted security strips,

6a

a supervision of an insert strip widened on the pane side and

6b

a perspective view of a widened insert strip.

In Figure 1 is a schematic and not to scale a principle Construction of part of the gas turbine rotor, namely a outer part - the head part 6 - the disc 4 shown. The disc 4 has circumferential, open to its periphery 7 Disk transverse grooves 3, which are substantially parallel to the longitudinal axis of the rotor 16 run, but also inclined to it can wine. The disc transverse grooves 3 are with undercuts 15 equipped. In a disc transverse groove 3 is one Gas turbine blade 1 with its blade root 2 along the Direction of use 30 of the disc transverse groove 3 used. The Blade root 2 is supported with longitudinal ribs 41 on the undercuts 15 of the disc transverse groove 3. That way the gas turbine blade 1 when the disc 4 rotates around the Rotor longitudinal axis 16 in the direction of the longitudinal axis 50 of the Gas turbine blade 1 centrifugal forces occurring. A Additional protection against loss then only has to prevent it slipping out along the direction of use 30 in the disc transverse groove 3. In the present invention is secured with the aid of the insert strip 11 as shown below.

The gas turbine blade has above the blade root 2 1 a broadened area, the so-called Bucket platform 5. On a disc-side base 13 the outside of the blade platform 5 43 of the Blade platform 5 is a wing 40 of the gas turbine blade 1. On the wing 40 flow to operate the Gas turbine blade 1 required hot gases to pass and generate a torque of the disc 1. At high operating temperatures of the gas turbine rotor requires the blade 40 of the gas turbine blade 1 an internal cooling system, which is not complete here is shown. Only the supply lines are shown 55 to the internal cooling system through which the Cooling air is introduced into the internal cooling system.

The cooling air is through a supply line, not shown through the disc 4 in the blade root 2 of the gas turbine blade 1 passed and from there to the supply lines 55 of the internal cooling system. To leave early the cooling air in the area of the blade root 2 or the blade platform 5 are to be prevented Insert strips 11 available.

In particular, hot gas will be prevented from between two gas turbine rotor blades 1 in the blade platform 5 or the internal cooling system penetrates and this Areas damaged. A second, in an adjacent disc transverse groove used gas turbine blade 1 is dashed shown. The long sides 9 of the two gas turbine blades 1 have a space 12. The long sides 9 have recesses 10 into which an insert strip 11 is used.

For this purpose, the recess 10 is up to the disc-side base 13 of the blade platform 5 is designed to be sufficient. The Insert strip 11 in turn extends over the disc side End 14 of the recess 10 and lies on its disc-side End 34 on a chamfer 17 on the end face 22 of the Disc 4. The insert strip 11 thus has one against axial displacement of the gas turbine blade 1 in the direction of use 30 of the gas turbine blade 1 securing positive engagement the disc 4.

The insert strip 11 fulfills in this way by the tight Bearing in the recess 10 as well as on the chamfer 17 sealing against both hot gas and cooling air leaks Function, as well as one against slipping of the gas turbine blade 1 in the disk transverse groove 3 respectively function in the direction of use 30. For the insert strip 11 is preferably a highly heat-resistant material related, for example a nickel-based alloy.

If on both end wall sections 8 of a long side 9 each a recess 10 is present, and one each Insert strip 11 is inserted into a recess 10 and on one of the two opposite disc ends 22 is present, the gas turbine blade 1 in both possible directions of use 30 secured relative to the disc 4. The opposite long side 9 of the blade platform 5 in turn has 8 at its end wall sections the long side 9 recesses 10, in the insert strips 11th are used. A gas turbine blade 1 is thus through secured a total of four insert strips 11. For improvement the seal is a sealing strip in the groove 35 of the Longitudinal sides 9 inserted lengthways.

Figure 2 shows a side view of the gas turbine blade 1 with an inserted insert strip 11. The recess 10 runs obliquely, inclined in the direction of a longitudinal axis of the rotor 16 of the gas turbine rotor and opens at its disc-side End 14 in one of the recess 10 beveled accordingly Chamfer 17 of the disc head 6. In this way, the disc head is Area of the blade platform 5 very well against Secured entry of hot gas. The cooling air through access 29 to the internal cooling system in the gas turbine blade cannot be initiated before reaching the Wing tip of the blade wing 40 through the space 12 escape.

Due to the support on the bevel 17 there is a large contact surface of the insert strip 11, whereby axially attacking Forces can be intercepted well. At the end of the disc 14 of the recess 10, the insert strip 11 from below in the recess 10 are used. That way he is secured against slipping out by attacking centrifugal forces.

FIG. 3 shows an end 14 of the recess 10 on the disk side with insert strip 11. Between the pane side End 14 of the recess 10 and the outer circumference 7 of the Disc 4 there is an axial relative movement between the Washer 4 and the blade platform 5 gap 19. The gap 19 enables lateral forces to be applied elastic deformation of the insert strip used 11, so that a kind of "springback effect" is achieved. The Recess 10 is here, as in the previous illustrations, formed as a groove. In this way the insert strip sits 11 held securely and well sealed in the recess 10th

The insert strip 11 is in its insertion position on the Disc 4 fixed. In this way, the Prevention strip under the action of gravity and the securing effect of the insert strip 11 against axial Displacements of the gas turbine blade 1 are increased. to A screw part 20 is used to fix the insert strip 11. The screw 20 is in the chamfer 17 in the washer head 6 used. The screw part 20 has a head 36 and circumferential shoulders 37. The head 36 protrudes into a recess 60 of the deployment strip 11 and the shoulders 37 support itself on the inside 38 of the insert strip 11. The Shoulders 37 lie close to the inside 38 of the insert strip 11 on, so that the insert strip 11 slipping out of the screw part 20 is prevented in the case of attacking centrifugal forces and at the same time the insert strip 11 through the Head 36 of the screw 20 against slipping out stationary gas turbine rotor is secured.

Figure 4a shows another possible formation of the disc side End 34 of the deployment strip 11. The deployment strip 11 engages at its disc-side end 34 in a securing recess 70 of the disc end face 22. The safety recess 70 supports the insert strip 11 against Fall out, as well as against slipping sideways. The End 14 is preferably after inserting the insert strip 11 bent into the recess 70. The insert strip 11 can also in front of its disc-side end 34 be bent and inserted before insertion. requirement this is sufficient resilience of the Strip 11 and / or a sufficient bevel of the recess 70th

Figure 4b shows the disk-side securing of the insert strip 11 from Fig.4a, however, the securing recess 70 has a flatter bevel. In this way the insert strip 11 is used even with light axial displacements kept captive.

Figure 5 shows a further security option in the area of the disc-side end 34 of the insert strip 11. A Security strip 24 engages under the blade platform 5 and leads through a passage opening 56 in each case in two opposing insert strips 11 and is bent 80 at its ends. That way is a Prevents the insert strips 11 from slipping out. The disc 4 is not in this way with holes or openings for Securing the deployment strips 11 affected. This type of backup offers increased durability against attacking Shear forces, since such an insert strip 11 has some play to move. Furthermore, securing easily without permanent damage to the Disk 4 can be removed again. Removing the fuse is also easier because such a backup generally not undesirable even at high temperatures material connection with the surrounding material received or if necessary easier to detach from this is. The security strip 24 should accordingly as well as the insert strips 11 made of highly heat-resistant material consist. The openings 56 should if possible on the security strips 24 be well adjusted so that no hot gas in the Blade platform 5 penetrates. The width of the security strip 24 can be adapted to the strength of the attacking forces ends 80 can also be placed under the insert strips 11 reach through and possibly wider than their Width 25.

Figures 6a, 6b show an exemplary embodiment of a Insert strip 11, the 34 at its disc end has an enlarged width 25 compared to the rest of the part. Correspondingly, the recess 10 is on its disc side End 14 formed wider than the rest of its part. It has undercuts 85. This is a Slipping out of the insert strip 11 when attacking Centrifugal forces even with an open wing end 75 the recess 10 prevented. No gap 19 is provided and the distance of the blade platform 5 from the disk circumference 7 kept small. This way one can go through strong gas turbine blade acting in the direction of use 30 loads 1 be kept safe.

The width 25 of the insert strip 11 can be in an alternative Training also from its disc-side end 34 to steadily decrease to its wing-side end 75. To secure of such insert strip 11 against falling out with the gas turbine rotor at a standstill, a screw part 100 or a bolt below the insert strip 11 be arranged on the disc end face 22.

The insert strip 11 provides for the narrow space 12 a particularly small contact surface compared to hot gases, or is well sealed against the ingress of hot gases. The insert strip 11 engages with a predetermined one Depth of engagement 95 in the recess 10 of the blade platform 5 of depth 90 a. The depth of engagement 95 of Insert strip 11 in the recess 10 is larger than that Gap 12 between two adjacent blade platforms 5. This enables the insert strip to be held very securely 11 in the recess 10.

Claims (13)

1. Gas turbine rotor, with an internally cooled gas turbine blade (1) which has a blade root (2) and a blade platform (5), and with a disc (4) possessing transverse disc grooves (3), into which the blade root (2) is inserted, the blade platform (5) being arranged outside an outer circumference (7) of the disc (4) and possessing, on an end wall portion (8) of one longitudinal side (9), a recess (10) into which is inserted an insert strip (11) which engages into a corresponding recess (10) of a blade platform (5) of a second gas turbine blade (1) and bridges and seals off an interspace (12) between the two blade platforms (5), characterized in that the recess (10) reaches as far as a disc-side base (13) of the blade platform (5), and the insert strip (11) has a form fit to the disc (4) which protects against axial displacement in a direction of insertion (30) of the gas turbine blade (1).
2. Gas turbine rotor according to Claim 1, characterized in that there is a recess (10) on each of the end wall portions (8) of one longitudinal side (9) of the blade platform (5), and in that its insert strips (11) bear on two mutually opposite disc end faces (22) and protect against axial displacements of the gas turbine blade (1) relative to the disc (4).
3. Gas turbine rotor according to one or more of Claims 1 and 2, characterized in that the recess (10) runs obliquely in the direction of a longitudinal rotor axis (16) of the gas turbine rotor and at its disc-side end (14) issues into a chamfer (17) of the disc head (6), said chamfer being oblique corresponding to the recess (10).
4. Gas turbine rotor according to one or more of Claims 1 to 3, characterized in that, with the gas turbine blade (1) inserted into the transverse disc groove (3), the insert strip (11) can be pushed into the recess (10) on the disc side and is secured counter to centrifugal forces by form fit on the disc and/or on the blade platform.
5. Gas turbine rotor according to one or more of Claims 1 to 4, characterized in that between the disc-side end (14) of the recess (10) and the outer circumference (7) of the disc (4) there is a gap (19) allowing relative movements between the disc (4) and the blade platform (5).
6. Gas turbine rotor according to one or more of Claims 1 to 5, characterized in that the recess (10) is designed as a groove.
7. Gas turbine rotor according to one or more of Claims 1 to 6, characterized in that the recess (10) is wider at its disc-side end (14) than in its remaining part.
8. Gas turbine rotor according to one or more of Claims 1 to 7, characterized in that the insert strip (11) is fixed in its push-in position on the disc (4).
9. Gas turbine rotor according to one or more of Claims 1 to 8, characterized in that there serves for fixing the insert strip (11) a screw part (20) which engages into a recess (60) of the insert strip (11) and is supported on the insert strip (11) under the action of centrifugal force.
10. Gas turbine rotor according to one or more of Claims 1 to 9, characterized in that the insert strip (11) engages at its disc-side end (14) into a securing recess (70) of the disc end face (22).
11. Gas turbine rotor according to one or more of Claims 1 to 10, characterized in that a securing strip (24) leads through two insert strips (11) below the blade platform (5) and is bent round at its ends (80).
12. Gas turbine rotor according to one or more of Claims 1 to 11, characterized in that the insert strip (11) is designed in the form of a wire or of a metal sheet.
13. Gas turbine rotor according to one or more of Claims 1 to 12, characterized in that the insert strip (11) engages with a predetermined engagement depth (95) into the recess (10) of the blade platform (5), and in that the engagement depth (95) of the insert strip (11) into the recess (10) is greater than the interspace (12) between two adjacent blade platforms (5).

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