EP2129871A1

EP2129871A1 - Arrangement for axially securing rotating blades in a rotor, and gas turbine having such an arrangement

Info

Publication number: EP2129871A1
Application number: EP08717999A
Authority: EP
Inventors: Darren T. Engle
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2007-04-04
Filing date: 2008-03-19
Publication date: 2009-12-09
Also published as: JP4942844B2; CN101680304B; RU2009140744A; US20110027092A1; RU2427713C2; EP1978211A1; JP2010523873A; WO2008122492A1; CN101680304A

Abstract

The invention relates to an arrangement (10) of rotating blades (14) in a rotor, having a shaft collar (21), on the outer circumference (52) of which blade retaining grooves (12) are provided, wherein rotating blades (14) are disposed in said blade retaining grooves, having a projection disposed on an end side surface (56) of the shaft collar (21) in the region of the retaining grooves, wherein a circumferential groove (20) being open radially toward the outside is provided in said projection, and having securing grooves (24) that are radially open toward the inside disposed in each rotating blade (14), said securing grooves being positioned radially opposite the circumferential groove (20), wherein sheet metal-shaped sealing elements (42), each engaging in the circumferential groove (20) and in the securing groove (24), are provided for axially securing the rotating blades (14). In order to propose an alternative securing of the sealing elements (42) against displacement in the circumferential direction within the groove (20), the invention provides that a blocking element (67) inserted in a recess (65) from the end side of the shaft collar (21) blocks the displacement path of the sealing element (42). In order for the blocking element (67) to be secured against unintentional releasing, the same is fastened on the rotor disk by means of a plastic deformation.

Description

description

Arrangement for axial securing on blades in a rotor and gas turbine with such an arrangement

The invention relates to an arrangement for axial securing of rotor blades in a rotor, with a shaft collar, on the outer circumference of which are provided in the axial direction of the rotor blade holding grooves, in each of which rotor blades with corresponding to the blade holding groove

Shovel feet are arranged, with one on a stirnseiti ^¬ gen side surface of the shaft collar, arranged in the region of the retaining projection in which a radially outwardly open circumferential groove is provided and arranged in each blade radially inwardly open securing grooves, each of the circumferential groove radially opposite, being provided for axial securing the Laufschaufein each engaging in the circumferential groove and in the securing groove sheet-shaped sealing elements which form a frontal sealing ring in the circumferential direction, wherein to secure the

Sealing elements against displacement in the circumferential direction of at least one of the sealing elements has a means. Furthermore, the invention relates to a gas turbine with such An ^¬ order.

There are rotors of gas turbines are known in which arranged on the outer circumference in the blade holding grooves turbine blades are secured by means of sealing plates against axial displacement. It is known, for example, from US 3,957,393 to fasten these sealing plates by rivets on the rotor.

It also shows an arrangement according to FIG. 1. It shows a generic arrangement in a plan view and FIG. 2 in a cross section according to section line II-II in FIG. 1. For each blade 14 to be secured against an axial displacement within its blade holding groove 12, sealing elements are used two slightly overlapping sealing sheets 16 is provided, which cover in each case the frontal opening of the blade holding groove 12 in half. Each sealing plate 16 is inserted at its radially inner end 18 in an end face on a rotor disk 19 provided circumferential groove 20 and at its radially outer end 22 in a

Securing groove 24 which is provided on the underside 26 of a platform 28 of the rotor blade 14. In order to secure each sealing plate 16 against displacement in the circumferential direction U, a rectilinear sheet metal strip 30 is fixed to each, which extend substantially in the radial direction of the rotor 23. Each sheet metal strip 30 terminates at its radially outer end 32 in a uniform converging point 34. Chamfered edges 36 are provided on the platforms 28 of the rotor 14, with two opposite edges 36 of immediately adjacent turbine blades 14 forming a tapered recess 38 into which the tip 34 of the sheet metal strip 30 can protrude against the shift in the circumferential direction U to secure the sealing plate 16 and can rest.

The sealing plates 16 also provide for a separation of two areas 37, 39, in which on the one hand cooling air and on the other hand may enter a part of the hot gas.

For fastening the metal strips 30 on the sealing plate 16 two parallel slots 40 are provided in the latter, through which the already U-shaped pre-bent sheet metal strip 30 is ^¬ sets. The tip 41 of the opposite end 41 of the sheet metal strip 30 is bent before the assembly of the sealing plate 16 on the rotor disk 19 in the position shown in FIG 2 for fixing the metal strip 30.

After mounting the Laufschaufein 14 in the rotor disks 19, the sealing plates 16 are successively threaded with the pre-assembled metal strips 30 in the endless circumferential, arranged on the rotor disk 19 circumferential groove 20 and arranged in the bottom 26 of the platform 28 securing groove 24. The sealing plates 16 are so along the circumference the circumferential groove 20 positions each sheet metal strip 30 opposite a recess 38. Subsequently, the tips 34 of the sheet metal stiffeners 30 are bent into the recesses 38 in order to preclude a displacement of the sealing sheets 16 in the circumferential direction U.

Since the sheet metal strips may only be bent once due to the extremely high mechanical requirements, in the case of service when replacing a blade, the strip of sheet metal that has then been raised must be replaced by a new sheet metal strip. In addition, the slots provided for receiving the metal strips in the sealing sheets weaken the sealing sheets.

Object of the present invention is to provide an alternative arrangement for securing the sealing elements against a threatening in the circumferential direction shift, in which the assembly and disassembly times are improved. More ^¬ On transfer of the invention is to provide a gas turbine with such an arrangement.

The object directed to the arrangement for the axial securing of rotor blades in a rotor is solved by the features of claim 1.

The invention provides that in the generic arrangement, the means for securing the sealing elements against displacement in the circumferential direction provided in the sealing element opening and provided in the side surface of the shaft collar, with the opening approximately aligned recess and in the recess and in the opening includes seated position-secured blocking element. The invention differs from the previous embodiment, in which a sheet metal strip entangled with the sealing element engages positively in a recess. Instead of the metal strip now a blocking element is provided in the front side on

Shaft collar provided recess can be used. The blocking element blocks a displacement of the sealing element in the circumferential direction, since, in the region of the sealing element arranged, extending transversely to the circumferential groove, in which the sealing element sits and engages in the opening provided on the sealing element. A slight and tolerable play of the sealing element along the circumferential groove is only possible insofar as in

Width seen in the circumferential direction of the opening is greater than the width to be considered in the circumferential direction of the blocking element.

By using a blocking element which engages in the Öff ^¬ tion of the sealing element and the front side of the shaft ^¬ collar is fixed by a blocking element plastically deforming Anstemmung, a particularly reliable and easy axial securing of the sealing element against displacement in the circumferential direction can be achieved. In addition, the assembly is quick and easy to accomplish. For this purpose, the blocking element with a suitable Stemmwerkzeug, such as tool on the type of hammer and chisel, plastically deform the front side, so that it rests in the recess under tension. As a result, a very reliable frictional engagement between the wall of the recess and the blocking element is brought about, which reliably prevents the unwanted release of the blocking element during operation of the gas turbine. To disassemble the blocking element, the deformed region of the blocking element can be removed by grinding, thus loosening the frictional connection for removal.

Further, the sealing element omitted with the embodiment of the invention previously debilitating slots which were designed to buildin ^¬ account the locking plate on the sealing element. The rigidity of the sealing element is thus further increased, as is its sealing effect.

Advantageous embodiments are specified in the subclaims. In an advantageous embodiment of the invention, the blocking element - based on its installation position - in the region of the recess in cross-section wedge-shaped and also includes a frontally outstanding bolt, which is insertable into the opening of the sealing element.

Due to the wedge shape of the blocking element and the recess corresponding to the wedge shape, a defined position of the blocking element in the rotor is predetermined. In addition, the orientation of the wedge shape of the recess is selected so that the mutually running side walls facing outward, as well as the corresponding edges of the blocking element. As a result, the wedge-shaped blocking element will strive outward under the action of centrifugal force and thereby become wedged or jammed in the recess, which further increases the frictional engagement between the flanks and the side walls and further complicates unintentional release of the blocking element. Consequently, a particularly secure arrangement can be specified.

According to an alternative embodiment of the invention, the blocking element receiving recess is seen radially outwardly open. In this case, the blocking element used in relation to the rotor can be plastically deformed circumferentially, instead of the frontal deformation. If then additionally circumferentially arranged pockets are provided in the side walls of the recess, can escape into the parts of the deformed material of the blocking element, in addition to the jamming of the blocking element also a positive connection for securing the position of the blocking element can be provided.

As a result, the blocking element is secured against loss particularly reliable.

According to a further advantageous embodiment, in the side surface of the shaft ring extending in the axial direction of the rotor recess is arranged such that it extends into the circumferential groove. A weakening of the shaft collar or a rotor disk, which preferably the Wellenbund forms is thereby avoided. Accordingly, the opening provided on the sealing element is then provided at the radially inner end of the sealing element. This area of the log message ^¬ ments heated at least during operation, so that the stiffness and temperature resistance of the seal member through the opening are not affected.

It has proven to be particularly advantageous if every second or each sealing element has the means for securing the sealing elements against displacement.

Conveniently, the arrangement is provided on a rotor of a sta tionary ^¬, passing through in the axial direction of the gas turbine.

The invention will be explained with reference to several embodiments shown in a drawing. From the explanation, there are further advantages and features. Show it:

FIG. 1 shows the arrangement for the axial securing of a sliding disk in a rotor according to the prior art, FIG.

2 shows the cross-sectional view according to FIG. 1 along the section line II-II, FIG.

3 shows the detail of a plan view of a rotor disk with a ^¬ arranged thereon as a blade assembly for an axial securing of the blade by means of a sealing element,

4 shows a perspective view of a blocking element according to the invention and

5 is a perspective view of one in the

Recess of the rotor used blocking element according to a second embodiment.

FIG. 3 shows a section of the frontal plan view of the shaft collar 21 formed by a rotor disk 19 a rotor 23 of a gas turbine. The rotatable around the axis of rotation 50 rotor 23 has distributed on its outer circumference along the circumference 52 U, extending in the axial direction running ^¬ scoop holding grooves 12, in each of which a blade 14 with the bucket holding groove 12 corresponds executed ^¬ tem blade foot 54 can be inserted. In the blade holding groove 12 shown centrally in FIG. 3, a blade 14 has already been inserted. As in the prior art illustrated in FIG. 1 and FIG. 2, a projection 58 extending in the axial direction or widening with a circumferential groove 20 open radially outwards is arranged on an end face of the rotor disk 19 or on an end face 56 of the shaft collar 21. The circumferential groove 20 is arranged, for example, radially further inward than the blade retaining grooves 12. The rotor blade 14 has a platform arranged between the blade root 54 and profiled blade 28, on the underside of which an open groove 20 is provided for the locking groove 24, while being opposite this. Analogously to the prior art, a sealing element 42 is inserted into the endless circumferential groove 20 and into the securing groove 24 which secures the blade 14 against displacement along the blade holding groove.

In contrast to the closest prior art, the sealing element 42 covers the frontal opening of one of the running ^¬ blade ^retaining grooves 12 completely. Thus, in each case only one of the rotor blades 14 is secured by one of the sealing elements 42 against displacement along the blade retaining groove 12.

But the sealing elements 42 may also be distributed over the circumference, as in the prior art, so that two immediately adjacent sealing elements each engage in half in the securing groove 24 of the blade 14. Then, two adjacent seal members secure one of the blades 14 against axial displacement. Analogous to the prior art forms a completely montier ^¬ ter ring of sealing elements 42, which overlap each slightly, a sealing ring, the ab separates a through which a coolant region 37 from another region 39 in which a hot gas can occur under certain circumstances (FIG 2).

In order to secure the sealing element 42 itself against displacement in the circumferential direction, an opening 63 is provided at the radially inner end 61 of the sealing element 42, which can be a notch, but also a bore.

In addition, in each case a recess 65 is provided on the side surface 56 of the shaft collar 21 in the region of the projection 58, which recess is substantially in the axial direction of the

Rotor 23, d. H. runs parallel to the axis of rotation 50. Each recess 65 has two opposite side surfaces 66, which, viewed from the outside, extend in a wedge shape toward one another, but do not touch each other to form a gap.

Instead of an outwardly open recess 65, an outwardly closed recess may be present. In this case, the two mutually extending side walls 66 touch in a rounded tip.

In the recess 65, the blocking element 67 shown in perspective in FIG. 4 can be used. The blocking element 67 comprises a section with a wedge shape corresponding to the recess 65 with flanks 70 extending toward one another and a bolt 69 arranged on the wedge-shaped section. When the blocking element 67 is inserted in the recess 65, its bolt 69 engages in the opening 63 of the sealing element 42.

Overall, therefore, comprises the means for securing the sealing element 42 against displacement in the circumferential direction U, the opening 63 in the sealing element 42, in the front side the rotor disk 19 arranged recess 65 and the blocking element 67 insertable therein.

A slight and tolerable game of the sealing element 42 along the circumferential groove 20 is possible only insofar as seen in circumferential direction width of the opening 63 is big ^¬ SSER than that to be viewed in the circumferential direction width or the diameter of the bolt. In order to achieve a particularly tight separation of the region 37 from the region 39 corresponds, preferably, the width of the opening 63 in the Wesentli ^¬ chen speaks to the diameter of the bolt 69th

After insertion of the blocking element 67 in the recess 65, the former is slightly plastically deformed by means of a Anstemmvorgangs. The blocking element 67 is plastically deformed in the area 71. As a result, the still existing for insertion of the blocking element 67, but slight play is eliminated, so that a secure fit of the blocking element 67 results. By eliminating the game, the flanks 70 are pressed against the side walls 66. This results in a reliable frictional engagement between the walls 66 of the recess 65 and those flanks 70 of the blocking element 67, which reliably prevents the unwanted release of the latter.

The Anstemmvorgang can be done by means of a suitable, slightly rounded at the top bit, which is attached to the blocking element in the area 71, provided with a hammer blow. For controlled positioning of the chisel, the blocking element has a front-side pre-machined recess 71, in which the chisel is to be set.

An alternative embodiment of the invention is shown in perspective in FIG. In this case, the blocking element 67 shown in FIG 4 is used with only a slight change in the recess 65. Instead of the front-side trough 71 has to be used for FIG 5 Blocking element 67 two - relative to the rotor - shell-side (circumferential) troughs 71 as an aid to the Anstemmvorgang on, if the blocking element 67 is inserted in the recess 65 shown in FIG 5, each opposite one in the side walls 66 circumferentially provided pockets 72. By a Anstemmvorgang according to the aforementioned manner, the troughs 71 adjacent material of the blocking element can be introduced into the pockets 72, so that there is a positive connection for secure positioning of the blocking element 67 in the recess 65.

Overall, the invention provides an arrangement in which the known from the prior art disadvantages are eliminated by a blocking element inserted from the end face of the shaft collar into a recess blocking the displacement of the sealing element. So that the blocking element itself is secured against unintentional loosening, this is fastened to the rotor disk by means of a plastic deformation.

Claims

claims

1. arrangement (10) for axial securing of rotor blades (14) in a rotor (23), with a shaft collar (21), on the outer circumference (52) in the axial direction of the rotor (23) extending blade holding grooves (12) are provided in each of which blades (14) korrespondie- with the Laufschaufelhaltenut (12) in power blade roots (54) are arranged, are arranged with a on a front side surface (56) of the Wel ^¬ lenbundes (21) in the area of Laufschaufelhaltenuten (12) projection (58 ), in which a radially outwardly open circumferential groove (20) is provided and in each blade (14) angeord ^¬ Neten radially inwardly open securing grooves (24), which in each case the circumferential groove (20) radially opposite ^¬ , wherein for axially securing the rotor blade (14) in each case in the circumferential groove (20) and in the securing groove (24) a ^¬ cross-plate-shaped sealing elements (42) are provided which form a frontal sealing ring in the circumferential direction (U), dadurc H characterized in that for securing the sealing elements (42) against displacement in the circumferential direction (U) of at least one of the sealing elements (42) has an opening (63) and in the side surface (56) of the shaft collar (21) one with the opening (63 ) approximately flush recess (65) and in the recess (65) seated blocking element (67) provided with a frontally projecting pin (69), which pin (69) engages in the opening (63), wherein the blocking element (67) a this plastically deforming Anstemmung is secured against loss.

2. Arrangement (10) according to claim 1, wherein the blocking element (67) - based on its installation position - in the region of the recess (65) is wedge-shaped in cross-section.

3. Arrangement (10) according to claim 2, wherein the recess (65) to the wedge shape of the blocking element (67) is designed to correspond and in which the side walls (66) of the recess (65) seen from the outside are inclined to each other.

4. Arrangement (10) according to one of the preceding claims, wherein the recess (65) is open radially outward.

5. Arrangement (10) according to claim 4, wherein in the side walls (66) of the recesses (65) - relative to the rotor - are provided peripheral side pockets, in the material of the blocking element (67) by the plastic deformation at least partially introduced ,

6. Arrangement (10) according to one of the preceding claims, wherein the shaft collar (21) of a rotor disk (19) ge ^¬ forms.

7. Arrangement (10) according to one of the preceding claims, wherein at least each second sealing element (42) has the ^¬ tel for securing the sealing elements (42) against displacement.

8. Gas turbine with an arrangement (10) according to one of

Claims 1 to 6 for securing blades (14).