EP1653049A1 - Vane ring assembly for gas turbines and method to modify the same - Google Patents

Abstract

Flanges (12,13) are formed to the foot (11) of a vane group (6). Radially spaced contact zones (18) are formed individually to the front and rear sections (14,15) of the flanges and rest against the vane supporting regions of the guide vane ring. An independent claim is also included for modification method of a guide vane ring.

Description

Technical area

The present invention relates to a guide vane ring of a turbomachine, in particular an axially flow-through turbine or a compressor, in particular a gas turbine. The invention also relates to a method of modifying such a vane ring.

State of the art

A vane ring usually consists of a plurality of blades, which are arranged side by side in the circumferential direction and are thereby fastened individually or in groups of a plurality of blades on an annular blade carrier. This blade carrier, which usually consists of two semi-annular or semicircular parts, is in turn attached to a housing of the turbomachine. Usually, the vane carrier for the vane ring has an upstream inlet groove and a downstream outlet groove. These grooves extend in the circumferential direction. The blades or the blade groups each have a blade root, which has an inlet-side inlet flange and a downstream outlet flange. The flanges extend in Circumferential direction and stand axially from the respective blade root. When assembled, the inlet flanges engage the inlet groove and the outlet flanges engage the outlet groove. The terms "upstream side" and "downstream side" refer to the flow direction prevailing during operation of the turbomachine in the region of the guide blade ring.

In the case of large blades and in particular in the case of large blade groups, it is customary for the flanges to be supported on the blade carrier both radially inward and radially outwardly in the region of the respective groove. In this way, a particularly intensive attachment of the blades on the blade carrier can be achieved, which is also required to support the large flow forces or pressure differences that may occur during operation of the turbomachine. Especially with large blades and the blade carrier are very large components that are exposed during operation of the turbomachine different thermal loads. On the one hand, during operation of the turbomachine, in particular in the case of a turbine, there are large temperature differences between a cooling gas and a hot gas. On the other hand, it also comes in the hot gas to large temperature differences, if this relaxes when passing through the respective turbine stage. The thermal loads vary during transient operating conditions, that is, for example, during startup and when switching off the turbomachine. Varying thermal loads on the blade carrier can deform it. It is regularly observed a kind of ovalization, in which the two blade carrier halves, which abut one another at their peripheral ends in a parting plane, expand along the parting plane, so that the radii of the blade carrier parts increase at abutting peripheral ends or contract in the region of the parting plane, thereby reduce the radii of the blade carrier parts at abutting circumferential ends. At the same time this can lead to a twist within the blade carrier.

In addition, it comes at the lower blade carrier part regularly to larger deformations than the upper blade carrier part, which is usually much better integrated into the housing of the turbomachine. The said deformations of the blade carrier are transmitted via the grooves on the flanges and thus via the blade roots in the blades or in the blade groups, whereby these high voltages are exposed. In addition, the blades can be supported radially inwardly over shrouds in the circumferential direction to each other, which generates additional stresses in these, when the blades change their position by deformation of the blade carrier.

The stresses mentioned can cause cracks and reduce the life of the blades. In the worst case, there may be a failure of the turbomachine.

Presentation of the invention

The invention aims to remedy this situation. The invention, as characterized in the claims, deals with the problem for a guide vane ring of the type mentioned to show a way that reduces the risk of cracking on the blades.

According to the invention, this problem is solved by the subject matters of the independent claims. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the general idea, the attachment of the blades or the blade groups on the blade carrier in such a way that they can accommodate a change in shape of the blade carrier, without that it comes to particularly high stresses in the blade. This is achieved by the fact that within the connection between the blade root and blade carrier degrees of freedom are provided which allow deformations of the blade carrier, which typically occur during thermal loading of the blade carrier, so that such deformation of the blade carrier to no or only to a reduced strain in the Shovel foot and thus in the respective blade or blade group leads.

The invention proposes for this purpose, in which a flange, for example at the inlet flange, both at a front end portion in the circumferential direction and at a rear end portion in the circumferential direction both radially inside and radially outside each provide a contact zone which bears against the blade carrier. In contrast, at the other flange, so for example at the outlet, at the one end portion, for example at the front end portion, provided radially inward a contact zone which bears against the blade carrier, while this end portion is spaced radially outward from the blade carrier. At the respective other end section, that is to say for example at the rear end section, a contact zone is again provided radially on the outside, which contacts the blade carrier, while this end section is then spaced radially inward from the blade carrier. In this way, in one of the flanges, that is to say here exemplarily on the outflow-side outlet flange, the contact zones are arranged diametrically opposite one another with respect to the end sections, or the end sections are positioned diametrically opposite to the blade carrier. This results in each end portion of the blade root a degree of freedom that allows a change in radius of the blade carrier and a distortion of the blade carrier. At the same time it is proposed that the flanges are spaced between their end portions both radially inwardly and radially outwardly from the blade carrier. In this way, have the contact zones the front end portion as large a distance from the contact zones of the rear end portion, whereby a particularly large elasticity is provided in the blade root. Accordingly, the blade root in the region of its flanges can absorb relatively large changes in shape of the blade carrier elastically, so that critical loads and stresses of the blade root and thus the blades or blade groups can be avoided or reduced.

According to a particularly advantageous embodiment, the diametrically arranged with respect to the end portions spacings between the flange and the blade carrier can be dimensioned so that in a normal operation of the turbomachine prevailing between inflow and outflow pressure difference by elastic bending deformation of the blade or the blade group and / or the blade carrier reduces the spacing and brings the corresponding end portion to the blade carrier for conditioning. In other words, in normal operation, the respective blade root is supported on both end portions and on both flanges both radially inwardly and radially outwardly on the blade carrier, resulting in a particularly intensive fixation of the blade or the blade group on the blade carrier. In transient operating conditions, in which there are thus reduced pressure differences between inflow side and outflow side and in which the deformations of the blade carrier mainly take place, the desired spacings between the blade root and blade carrier can then form diametrically with respect to the one flange relative to the end sections. Accordingly, the blade root can then better follow the changing geometry of the blade carrier, which reduces the load on the blades.

Other important features and advantages of the present invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

Brief description of the drawings

Fig. 1

einen stark vereinfachten Querschnitt durch eine Strömungsmaschine im Bereich eines Leitschaufelrings,

Fig. 2

eine perspektivische Ansicht auf eine Schaufelgruppe,

Fig. 3a und 3b

vereinfachte Darstellungen wie in Fig. 1, jedoch bei unterschiedlichen Verformungszuständen,

Fig. 4a - 4c

vergrößerte Schnittdarstellungen im Bereich einer Nut eines Schaufelträgers mit darin eingreifendem Flansch eines Schaufelfußes bei unterschiedlichen Verformungszuständen des Schaufelträgers,

Fig. 5

einen Axialschnitt durch einen Schaufelträger bei unterschiedlichen Verformungszuständen,

Fig. 6

einen Axialschnitt durch einen Schaufelfuß bei unterschiedlichen Verformungszuständen,

Fig. 7

eine vereinfachte axiale Ansicht auf einen Schaufelfuß nach der Erfindung,

Fig. 8

eine Ansicht wie in Fig. 7, jedoch bei einem Schaufelfuß eines Leitschaufelrings vor dessen Modifikation,

Fig. 9

einen Ansicht wie in Fig. 8, jedoch bei einer anderen Ausführungsform des Schaufelfußes.

Preferred embodiments of the invention are illustrated in the drawings and will be explained in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components. Show, in each case schematically,

Fig. 1

a greatly simplified cross-section through a turbomachine in the region of a guide vane ring,

Fig. 2

a perspective view of a blade group,

Fig. 3a and 3b

simplified representations as in Fig. 1, but at different deformation states,

Fig. 4a - 4c

enlarged sectional views in the region of a groove of a blade carrier with a flange of a blade root engaging therein in the case of different deformation states of the blade carrier,

Fig. 5

an axial section through a blade carrier at different deformation states,

Fig. 6

an axial section through a blade root at different deformation states,

Fig. 7

a simplified axial view of a blade root according to the invention,

Fig. 8

7 is a view similar to FIG. 7, but with a blade root of a vane ring before its modification,

Fig. 9

a view as in Fig. 8, but in another embodiment of the blade root.

Ways to carry out the invention

According to FIG. 1, a guide blade ring 1 has a turbomachine, not shown otherwise, preferably a turbine or a compressor, preferably a gas turbine, a plurality of stator blades or short blades 2, which are arranged adjacent to one another in the circumferential direction 3. The blades 2 are attached to a blade carrier 4, which in turn is attached to a housing 5 of the turbomachine.

In this case, the blades 2 may be fastened individually to the blade carrier 4 or combined into blade groups 6, which are formed from two or more blades 2 and are fastened together on the blade carrier 4. In this case, the blade carrier 4 is of annular design and expediently divided in the region of a dividing plane 7, in which preferably also a rotational axis 8 or longitudinal central axis 8 of the turbomachine, so that according to FIG. 1 an upper blade carrier part 4a and a lower blade carrier part 4b are present. It is clear that such a blade carrier 4 can in principle also serve for fastening the blades 2 of a plurality of guide blade rings 1 adjacent one another in the axial direction.

For example, FIG. 5 shows a longitudinal section through a blade carrier 4, in which the blades 2 of a plurality of stator blade rings 1, that is to say a plurality of turbine stages or compressor stages, can be fastened. For each vane ring 1, the vane carrier 4 has an inflow-side inflow groove 9 and an outflow-side outlet groove 10. In FIG. 5, the grooves 9 and 10 of different vane rings 1 are indicated in the reference numerals by apostrophes. The two grooves 9, 10 - each vane ring 1 - extend in each case in the circumferential direction 3 and thereby run closed in a closed ring.

Referring to FIG. 2, a blade group 6 comprises, for example, three blades 2 having a common blade root 11 which is at the same time the blade root 11 of the blade group 6. The following explanations for the blade root 11 of the blade group 6 also apply correspondingly to a blade root 11 of a single blade 2.

At the blade root 11 an inflow-side inlet flange 12 is formed, which extends in the circumferential direction 3 and thereby projects axially from the blade root 11. Correspondingly, the blade root 11 also has a downstream outlet flange 13, which likewise extends in the circumferential direction 3 and projects axially from the blade root 11. In this case, the flanges 12 and 13 are in opposite directions from the blade root 11 each axially outward.

In the assembled state, the inlet flange 12 engages in the inlet groove 9, while the outlet flange 13 engages in the outlet groove 10. The engagement takes place in each case axially, which forms a positive connection between the blade root 11 and the blade carrier 4 in the radial direction.

The blade root 11 and thus also its flanges 12 and 13 have a front end portion 14 in the circumferential direction 3 and spaced therefrom a rear end portion 15 in the circumferential direction 3. Between the end portions 14 and 15, a central portion 16 is formed, which is preferably approximately the same in the circumferential direction 3 Length, as the two end portions 14 and 15 together. Likewise, the central portion 16 may be longer in the circumferential direction 3 than the two end portions 14, 15 together.

According to FIGS. 3 a and 3 b, deformations of the blade carrier 4 may occur during operation of the turbomachine due to thermal loads, in particular under transient operating conditions. In this case, in Figs. 3a and 3b, the original circular shape of the blade carrier 4 is shown with a broken line, while the respective deformation form is shown by a solid line.

The two blade carrier parts 4a and 4b abut each other in the circumferential direction at circumferential ends 14 and 15. The thermal loading of the blade carrier 4 leads to ovalization, which is exaggeratedly indicated in FIGS. 3 a and 3 b. On the one hand, in the case of such an ovalization according to FIG. 3 a, a kind of constriction can form in the region of the parting plane 7 that results from the abutting circumferential ends 14 and 15 moving towards one another along the dividing plane 7, which results in a reduction in the bending radius of the bending radius Blade carrier parts 4a and 4b goes along. On the other hand, the ovalization according to FIG. 3b can also lead to the adjoining circumferential ends 14 and 15 moving away from one another along the dividing plane 7. This is equivalent to the fact that the bending radius of the blade carrier parts 4a, 4b increases. This ovalization leads at the same time to a distortion of the blade carrier 4. Furthermore, as a rule, the deformation of the lower blade carrier part 4b is significantly greater than that Deformation of the upper blade carrier part 4a, since the upper blade carrier part 4a is regularly more strongly connected to the housing 5, which leads to a stiffening of the upper blade carrier part 4a.

FIGS. 4a to 4c show enlarged sectional views through one of the grooves 9 or 10 into which one of the flanges 12 or 13 engages. The curvature that results in the circumferential direction 3, greatly exaggerated. It can be seen that, in an undeformed starting position according to FIG. 4 a, the groove 9, 10 has the same curvature as the flange 12, 13, so that a uniform contact with the blade carrier 4 takes place along the flange 12, 13. The simultaneous contacting is represented here for better illustration by a game 21, which is radially equal to the outside and radially in the ideal case ideally.

In the case of an ovalization according to FIG. 3b, a deformation corresponding to FIG. 4b arises in the region of the groove 9, 10, which results in the respective flange 12, 13 being radially inward in the region of its end sections 14, 15 and radially outside in the region of its central section 16 extremely strong pressure is applied, which is indicated by corresponding arrows 17. The aforementioned game 21 disappears in these areas.

In an ovalization according to Fig. 3a, it comes to the reproduced in Fig. 4c deformation state in which the respective flange 12, 13 radially inward in the region of its central portion 16 and radially outward in the region of its end portions 14, 15 exposed to extreme pressure loads, the again are indicated by arrows 17. In this case, the above-mentioned game 21 disappears. It is clear that such a game 21 does not have to be present in the actual installed state, it serves only to explain the self-adjusting deformations and loads.

In Fig. 5, the blade carrier 4 is shown once in a solid line in a deformed state usually resulting in operation and with a broken line in an undeformed initial state, which occurs in cold turbomachine.

FIG. 6 shows an axial section through the foot 11 of a blade 2 or a blade group 6, two different operating states being reproduced here as well. Hatched is the cut in the normal operating state, ie with a hot turbomachine. In contrast, an undeformed initial state, which occurs in cold turbomachine, unhatched reproduced. It can be seen that the inlet-side inlet flange 12 can tilt by an angle α, while the downstream-side outlet flange 13 can tilt by an angle β. To make matters worse, that the two angles α and β can vary in size. In Fig. 6, the deformations are exaggerated again clearly shown and are not to take to scale in particular.

FIG. 7 now shows an inflow-side axial view of the blade root 11 of the blade group 6. The inlet flange 12 facing the viewer is arranged farther down, ie radially further inward, than the outlet flange 13, which faces away from the viewer and is hidden from view. So radially further out, is arranged. From the arrangement of the flanges 12, 13 it follows that this must be a blade group 6 of a turbine.

It is now essential to the invention that the flanges 12 and 13 are machined on their radial sides so that they contact the blade carrier 4 in the associated grooves 9, 10 in selected contact zones, which will be explained in more detail below. The contact zones are in Figs. 7 to 9 with greater line width indicated and designated 18. Furthermore, arrows 19 indicate where in the installed state a force transmission between blade root 11 and blade carrier 4 takes place.

According to the invention, the contact zones 18 are distributed as follows:

One of the flanges 12, 13, in this case the outflow-side outlet flange 13, is provided both at its front end section 14 and at its rear end section 15, both radially inward and radially outwardly, with such a contact zone 18 which in the installed state on the blade carrier 4, So lie radially within the Auslaßnut 10. For the outlet flange 13 thus results in a kind of 4-point storage. In contrast, here the inlet flange 12 is provided only at one end portion, here at the front end portion 14, radially outwardly with such a contact zone 18 which rests in the installed state on the blade carrier 4, while radially inwardly formed so that the end portion 14 in Installation state is spaced from the blade carrier 4. Furthermore, the inlet flange 12 is provided at its other end portion, so here at the rear end portion 15 radially inwardly with such a contact zone 18 which rests in the installed state on the blade carrier 4, while radially outwardly shaped so that the rear end portion 15 in the installed state of Blade carrier 4 is spaced. In that regard, results for the inlet flange 12 is a kind of 2-point storage. In this case, the two contact zones 18 and accordingly the two unspecified distance zones with respect to the end sections 14 and 15 are arranged diametrically opposite one another on the inlet flange 12.

As a result of this design proposed according to the invention, the connection of the blade root 11 to the blade carrier 4 is given defined degrees of freedom which, in the case of the typical deformations of the blade carrier 4, which it thermally effects in transient operating conditions, results in a reduction of the blade carrier Force transmission between blade carrier 4 and blade root 11 effect. In this way, the blade roots 11 and thus the blades 2 or the blade groups 6 are less heavily loaded by the deformations of the blade carrier 4.

As already explained above, it is advantageous if the end portions 14, 15 and thus the contact zones formed thereon 18 in the circumferential direction 3 are relatively far apart. Accordingly, the central portion 16 in the circumferential direction 3 is dimensioned comparatively large, in particular equal to or greater than the two end portions 14, 15 together.

The contact zones 18 can also be made specifically so that there is a linear contact or contact on the blade carrier 4, which may be oriented, for example, radially or in the circumferential direction. Likewise, the contact zones 18 can also be designed so that point-like contacts with the blade carrier 4 result.

Particularly advantageous is an embodiment that provides the desired degrees of freedom substantially only for the connection of the blade roots 11 on the blade carrier 4, when the blade carrier 4, for example due to transient operating conditions of the turbomachine, deformed, while said additional degrees of freedom in favor of increased support can be omitted if the turbomachine is in a nominal or normal operation. Appropriately, therefore, the distances between the inlet flange 12 in the region of the end sections 14 and 15 relative to the blade carrier 4 can be dimensioned so that a pressure difference between inflow side and downstream side of the respective guide vane ring 1, which occurs during normal operation of the turbomachine, an elastic bending deformation of the blades 2 and of the blade group 6 and / or the blade carrier 4, which reduces said distances, and preferably so far that the corresponding end portions 14 and 15 then also come to rest on the blade carrier 4. In the load state then the said additional degrees of freedom are canceled. In transient conditions, said pressure difference decreases, whereby the end portions 14 and 15 lift off the blade carrier 4 again to restore the degrees of freedom, which reduce the stresses in the blade root 11 in the deformations of the blade carrier 4.

Although in the present example the inlet flange 12 is provided with two contact zones 18 and the outlet flange 13 is provided with four contact zones 18, the distribution of the contact zones 18 may also be reversed. Likewise, the distribution of the contact zones 18 in the case of the flange 12 equipped with only two contact zones 18 at the two end sections 14, 15 can be reversed with respect to the arrangement inside and outside.

According to FIG. 2, the blades 2 can be connected to one another radially on the inside via cover bands 20 and can be supported in the circumferential direction in the mounted state.

In the following, a method according to the invention for modifying a conventional blade ring is explained in more detail:

First, the blades 2 or the blade groups 6 are removed from the blade carrier 4. The removed blade groups 6 can be configured in the region of the blade root 11, for example, as in FIG. 8. This means that both the inlet flange 12 and the outlet flange 13 both at the front end portion 14 and at the rear end portion 15 both radially inwardly and radially outwardly each with a contact zone 18 and 18 'is equipped. A developed blade 2 may, for example, be designed in the region of its blade root 11 as in FIG. 9 and accordingly have a particular distribution of contact zones 18 or 18 '.

In a further method step, the flanges 12 and 13 of the blade roots 11 are now processed in the removed blades 2 or in the removed blade groups 6.

In the case of a blade group 6 according to FIG. 8, the radially inner contact zone 18 'is removed, for example by means of a milling cutter or the like, at the inlet flange 12 at its front end section 14. Likewise, at the inlet flange 12 at its rear end portion 15, the radially outer contact zone 18 'is removed. As a result, the machined blade root 11 in the region of its flanges 12, 13 then has the same shape as the blade root 11 according to the invention as shown in FIG. 7.

When the blade root 11 as shown in FIG. 9, the two radially outer sides of the flanges 12 and 13 are each formed as a continuous contact zones 18 '. Furthermore, the outlet flange 13 has radially inside only a single contact zone 18 ', which is also arranged in the central portion 16. The machining of this blade root 11 takes place in such a way that at the outlet flange 13 on the radially outer side of the central portion 16 is removed so far that only one of the desired contact zones 18 remains only in the end portions 14 and 15. Furthermore, on the radially inner side, the contact zone 18 'in the middle section 16 is removed by appropriate material removal. In addition, radially inward at the end portions 14 and 15 by a suitable material application, for. B. by welding or soldering, respectively, the desired inner contact zone 18th created here to obtain a corresponding shape, as shown in Fig. 7.

The inlet flange 12 is here processed so that the provided in the front end portion 14, radially inward contact zone 18 'is completely removed. Furthermore, the radially outer, continuous contact zone 18 'is removed so far radially outward in the region of the middle section 16 and in the region of the rear end section 15 until the shape shown in FIG. 7 results. Thus, also in the blade foot type shown in Fig. 9, the contour of the present invention shown in Fig. 7 can be produced.

Overall, therefore, the method shown here is particularly suitable for retrofitting a conventional vane ring in the guide vane ring 1 according to the invention, the blades 2 can absorb the deformations of the blade carrier 4 better.

LIST OF REFERENCE NUMBERS

1

vane ring

2

shovel

3

circumferentially

4

blade carrier

4a

upper blade carrier part

4b

lower blade carrier part

5

casing

6

scoop group

7

parting plane

8th

Longitudinal center axis / axis of rotation

9

inlet groove

10

exhaust groove

11

blade

12

inlet flange

13

outlet flange

14

front end section

15

rear end section

16

midsection

17

pressure load

18

contact zone

19

pressure load

20

shroud

21

game

Claims (8)

Guide vane ring of a turbomachine, comprising a number of blades (2), which are fastened individually or in groups (6) of a plurality of blades (2) to an annular blade carrier (4), which in turn is fastened to a housing (5) of the turbomachine, - wherein the blade carrier (4) has an inlet-side inlet groove (9) and an outlet-side outlet groove (10), - Wherein the grooves (9, 10) extend in the circumferential direction (3), - Wherein the blade (2) or the blade group (6) each having a blade root (11) having an upstream inlet flange (12) and a downstream Auslassflansch (13), - Wherein the flanges (12, 13) extend in the circumferential direction (3) and project axially from the respective blade root (11), - Wherein in the mounted state at the blade root (11) of the inlet flange (12) in the inlet groove (9) and the outlet flange (13) engages in the outlet groove (10), - wherein the one flange (13) has a contact zone (18) both at a circumferential (3) front end portion (14) and in a circumferential direction (3) rear end portion (15) both radially inwardly and radially outwardly, which rests against the blade carrier (4), - Wherein the other flange (12) at the one end portion (15) radially inwardly a contact zone (18) which bears against the blade carrier (4) and radially outwardly from the blade carrier (4) is spaced, and at the other end portion (14) radially outside a contact zone (18), the on Blade carrier (4) rests, and radially inwardly from the blade carrier (4) is spaced, - Wherein the flanges (12, 13) between their end portions (14, 15) both radially inwardly and radially outwardly from the blade carrier (4) are spaced. Guide vane ring according to claim 1,
characterized,
in that the two end sections (14, 15) of the respective flange (12, 13) in the circumferential direction (3) are approximately equal to or smaller than a central section (16) arranged between the end sections (14, 15). Guide vane ring according to claim 1 or 2,
characterized,
in that the blades (2) in the mounted state are connected to one another radially inside via cover bands (20) and / or are supported on one another. Guide vane ring according to one of claims 1 to 3,
characterized,
in that the contact zones (18) are designed in such a way that a linear or a punctiform contact is formed on the blade carrier (4). Guide vane ring according to one of claims 1 to 4,
characterized,
that the spacing of the other flange (12) at its end portions (14, 15) is dimensioned by the blade carrier (4) so that in normal operation of the turbomachine a ruling between the inflow side and the outflow side pressure difference by elastic bending deformation of the blade (2) or group of blades (6 ) and / or the blade carrier (4) the spacing reduced and in the corresponding end portion (14, 15) on the blade carrier (4) brings to bear. Guide vane ring according to claim 1, characterized in that the turbomachine is an axially flowed turbine or a compressor. Guide vane ring according to claim 6, characterized in that the turbomachine is a gas turbine. Method for modifying a guide blade row (1) of a turbomachine, in particular an axially flow-through turbine or a compressor, in particular a gas turbine, in which blades (2) and / or blade groups (6) are made up of a plurality of blades (2) from an annular blade carrier (4), in which flanges (12, 13) of blade roots (11) of the removed blades (2) and / or the removed blade groups (6) are machined, in which the machined blades (2) and / or blade groups (6) are re-installed in the blade carrier (4), - Wherein the processing of the removed blades (2) and / or blade groups (6) takes place so that after installation of the blades (2) and / or the blade groups (6) a guide blade ring (1) according to one of claims 1 to 5 is present ,

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