EP1402152A1

EP1402152A1 - Securing system for the rotor blades of axial flow turbo engines

Info

Publication number: EP1402152A1
Application number: EP02737718A
Authority: EP
Inventors: Wolfgang Di Diebold
Original assignee: ABB Turbo Systems AG
Current assignee: Accelleron Industries AG
Priority date: 2001-07-03
Filing date: 2002-06-25
Publication date: 2004-03-31
Anticipated expiration: 2022-06-25
Also published as: JP4315801B2; WO2003004834A1; KR20040018409A; DE50209295D1; CN100416045C; EP1402152B1; JP2004532952A; KR100837134B1; CN1524160A

Abstract

The invention relates to a securing system for rotor blades (10) of axial flow turbo engines, wherein the rotor blades (10) are radially and peripherally secured by means of a rotor base (12) that is inserted in a radially disposed axial groove (14) of a blade support (16). In the axial relation, the rotor blade (10) is secured by a securing body (22) disposed between the rotor base end (13) and the axial groove bottom (15) and engaging behind the back (40) of the blade support (16) opposite the effective axial force with its first end section (26). In addition to these axial and radial securing elements, the inventive securing system (20) is further provided with a securing element (24) that is axially disposed adjacent to the first end section (26) of the securing body (22) and that forms an axial stop (34) for said end section. The invention further relates to a securing body for such a securing system, whose end sections (26, 26') are wider than the axial groove (14) and that, in the mounted state, project only radially outwards from a base element (28) interlinking them.

Description

Safety system for rotor blades of axially flowed turbomachinery

description

Technical field

The invention relates to an axial securing system for rotor blades of axially flowing turbomachinery according to the preamble of claim 1 and a securing body for the securing system according to the preamble of claim 8.

Due to the rotation, centrifugal forces act on the blades of turbomachines with axial flow. These forces are generally absorbed by a fir-tree or dovetail-shaped, radially arranged and axially extending tongue-and-groove connection between the rotor blade and the blade carrier. The axial forces that occur due to the axial direction of flow of the flow medium, on the other hand, have to be seized by means of a separate one Safety device to be caught.

State of the art

To secure the blades in the axial direction, securing bodies arranged in the radial gap between the blade root end and the axial groove base are generally used today.

There are fuse bodies that only extend from the downstream end over part of the radially arranged axial groove, as is known, for example, from US Pat. No. 2,641,443. These securing bodies generally have an upstream projection which engages in an associated groove in the blade root. The downstream end area overhangs the Axial groove and is bent to axially secure the blade so that it engages behind the downstream rear of the blade carrier. A projection on the blade root engages behind the pressure side of the blade carrier at the opposite end of the blade root.

Other securing bodies used for the axial securing extend over the entire length of the axial groove and protrude beyond it on both sides. This is described for example in US-2,928,651 and GB-A-643,1914. In the securing body described in GB-A-643, 1914, a projecting end region is designed as a shoulder-like projection which extends past the pressure side of the blade carrier, while the other projecting end region is brought into a position in the installed state by bending over, in which position it is engages downstream end of the blade carrier. The securing body disclosed in US Pat. No. 2,928,651 consists of a sheet metal, the two projecting end regions of which are designed by bending so that they engage behind the two end faces of the blade carrier in the installed state. In both of these cases, too, the axial support connection to the blade root is produced by projections or tongues which protrude from the respective securing bodies and engage in corresponding grooves in the blade roots.

The manufacture of the securing bodies described is complex because, on the one hand, the material must be selected so that it can be bent into the required shape but can still absorb the forces that occur. On the other hand, because the end areas of the sheets have to be bent with high precision in order to fix the blades in their axial position exactly. Such a securing body can only be designed to a limited extent for the possible shear and shear forces, with additional bending of the material being introduced by the bending. At the very high speeds that are used today, the bent ends do not always withstand the load and be bent up by the high forces. The blades slide axially out of their position and rub against the housing.

Presentation of the invention

It is therefore an object of the invention to provide a simple and economical production and assembly 5 safety system for blades of axially flowed turbomachinery, in which the axial thrust and shear forces are safely absorbed and the blades are held in their exact position.

This object is achieved by a security system in accordance with the features of patent claim 1.

According to the invention, the securing system for each rotor blade has a radially arranged axial groove in the blade carrier, into which the rotor blade with its blade root of opposite design can be inserted. A securing body is arranged between the blade root end and the axial groove base, with its first end region lying opposite the axial force acting on it

15 reaches behind the back of the shovel carrier. A securing element, which is formed in one piece with the blade carrier, is arranged axially adjacent to the first end region of the securing body and forms an axial stop for the latter. The first end region of the securing body comes to lie in a circumferential groove between the stop and the blade carrier. The attack prevents

20 of the securing body can be axially displaced from its position or the end region can be bent open by the forces which occur, as a result of which the blade root and with it the moving blade are held in their exact position. Due to the one-piece design of the securing element with the blade carrier, manufacture and assembly are particularly simple and inexpensive. The easiest way to manufacture the securing element, which is formed in one piece with the blade carrier, is by means of turning and / or milling; with high-quality material by grinding.

It is particularly simple and inexpensive to work with this safety system with a safety body which protrudes axially with its two end regions beyond the axial groove and whose end regions each engage behind an end face of the blade carrier in the installed state. This has the advantage that the blade root can be designed in a simple manner since it does not have to engage behind the blade carrier on the pressure side. But also fuse bodies that only extend over part of the axial groove from the downstream end, and rotor blades with suitably designed blade feet can be used.

If the end regions of the securing body are wider than a base part of the securing body connecting them, the force acting on the end region is distributed over a larger area. This leads to a more favorable ratio of force per area also with respect to the stop formed by the securing element and assigned to the end region.

If the end regions of the securing body are wider than the base part and also wider than the axial groove, it is very advantageous if the end regions of the securing body protrude radially outward from the base part in the installed state and engage behind the end faces of the blade root and the end faces of the blade carrier. If this is the case, there is no need for an additional tongue or a projection which engages in a suitable groove in the blade root in order to establish the connection between the blade root and the securing body. This simplifies both the manufacture of the blade root and that of the securing body. Such a fuse body according to the invention can of course not only be used in connection with the security system according to the invention, but also instead of known fuse bodies without the fuse element. If the securing element is manufactured as a separate securing disk or as a securing ring, which is then welded or glued to a body integral with the blade carrier, then existing turbomachinery can be retrofitted with the securing system.

Further advantageous embodiments of the invention are the subject of further dependent claims.

Brief description of the drawings

The subject matter of the invention is explained in more detail below on the basis of preferred exemplary embodiments which are illustrated in the accompanying drawings. It shows purely schematically:

1 shows a safety system according to the invention using part of a blade carrier with a moving blade attached to the blade carrier, in perspective and in section along an axial groove bottom of the blade carrier; 2 shows in perspective an inventive fuse body of the security system;

3 also shows a security system according to the invention in a representation analogous to FIG. 1; and

FIG. 4 shows the embodiment from FIG. 3 in another perspective view without a rotor blade;

The reference symbols used in the drawings and their meaning are summarized in the list of reference symbols. In principle, the same parts are provided with the same reference symbols in the figures.

FIGS. 1 and 3 each show a rotor blade 10 which is fastened with its 12 in a radially arranged axial groove 14 of a blade carrier 16. For the sake of clarity, only part of the blade carrier 16 is in the Section to the axial groove 14 shown. The blade root 12 is designed as a fir tree root and the axial groove 14 as an opposite groove, so that the blade root 12 is anchored radially and in the circumferential direction in the groove 14 so that it cannot move. For axial securing, a securing body 22 is arranged between a blade root end 13 belonging to the blade root 12 and an axial groove bottom 15 which delimits the axial groove 14 radially inward, the two end regions 26, 26 'of which protrude axially beyond the axial groove 14. As can be seen from FIG. 2, the two end regions 26, 26 'are each wider than a base part 28 of the securing body 22 connecting them. In the installed state, the end regions 26, 26' each protrude radially outward from the base part 28 and each engage behind one end face 38 ", 40 'of the blade root 12 and part of the end faces 38, 40 of the blade carrier 16. Because the end regions 26, 26' of the securing body 22 are wider than the base part 28 and wider than the axial grooves 14, they also engage behind Parts of the end faces 38, 40 of the blade carrier 16 when they protrude radially outward from the base part 28.

The first end face 38 of the blade carrier 16 forms the pressure side of the blade carrier 16. A very large axial force acts on this side due to the direction of flow A (see arrow). Via the blade root 12, this axially acting force is also transmitted to the first end region 26 of the securing body 22, which engages behind the opposite end face 40 of the blade carrier - also called the rear side 40. In order to prevent the first end region 26 from bending open, a securing element 24 is arranged on the rear side 40 of the blade carrier 16 and forms a stop 34 for the first end region 26 downstream in the axial direction, so that the first end region 26 can no longer be bent open. The securing element 24 forms, together with the securing body 22, the axial groove 14 and the blade root 12, a securing system 20 which connects the moving blade 10 to the blade carrier 16 in a positionally secure manner even at very high speeds in the axial, radial and circumferential directions. In the example shown, the securing body 22 is formed from sheet metal and both end regions 26, 26 'are brought to the base part 28 by bending radially outward into their position. Of course, the first end region 38, which engages behind the rear side 40 of the blade carrier, can also be designed as a solid projection and only the second end region 26 'can be brought into position by bending.

Figures 3 and 4 show the securing element 24 integrally formed with the blade carrier 16. In the manufacture of this one-piece embodiment, the axial grooves 14 are first milled or cleared into the base body of the blade carrier 16. Then, on the rear side 40 of the blade carrier 16, a strip measuring approximately twice the thickness of the securing body 22 is twisted, radially inwards to such an extent that the stationary shoulder projects radially outwards beyond the axial groove base 15 somewhat more than the first, which protrudes radially outwards End region 26 of the securing body 22. Finally, on the side of the existing shoulder facing the axial grooves 14, a circumferential groove 42 is created by turning, which extends radially inward somewhat beyond the axial groove bottom 15 and whose width is dimensioned such that it is the first with little play End portion 26 of the fuse body 22 can accommodate. When using very high quality material, such as Nimonic 901 with approx. 40% nickel, the circumferential groove 42 can also be formed by grinding. As a result of this procedure, incisions resulting from the milling of the axial grooves 14 and elements remaining therebetween are left over from the originally rotated shoulder. The remaining elements now each form an axial stop 34 for the first end region 26 of the securing body 22, which because of its width projects beyond the axial groove 14 and thus also the incision in the circumferential direction, so that the stop can develop its effect. The axial extension of each blade root 12 and the base part 28 of each securing body 22 corresponds to the axial extension of the axial grooves 14 which have remained after turning, so that after installation no blade root 12 and no part of a base part 28 protrude into the circumferential groove 42 or over the pressure side 38 of the Blade carrier protrudes. The securing element 24 can be combined with arbitrarily designed securing bodies and then forms a securing system 20 according to the invention. Corresponding adaptations of the circumferential groove 42 do not pose a problem.

However, as shown in FIG. 1, the securing element 24 can also be designed as a separate securing washer 32 which, for example, is connected to the blade carrier 16 by means of a welded connection 30 to form an integral body. The locking washer 32 has on its side facing the blade carrier 16 a shoulder which is designed such that when connected to the blade carrier 16 there is a circumferential groove 42 in which the respective first end regions 26 of the locking bodies 22 for the rotor blades 10 engage. Depending on the configuration of the blade carrier 16, the securing element 24 can also be designed as a securing ring. Instead of using a welded connection 30, it is also conceivable to connect the securing element 24 to the blade carrier 16 by means of an adhesive connection to form an integral body.

An advantage of the separate configuration of the securing element 24 is that existing blade carriers 16 with axial groove / securing body connections can be retrofitted with this securing element 24 and connected to the securing element to form one-piece bodies. In this way, a security system according to the invention can be installed subsequently. This is possible regardless of the design of the fuse body. This is because the security system 20 also works with other security bodies, as are known, for example, from the patents mentioned at the beginning. For this purpose, the securing element 24 may then have to be adapted in accordance with the configuration of the circumferential groove 42 or the stop 34.

To assemble the rotor blades 10 in the blade carrier 16 with the securing system 20 according to the invention, the securing body 22 is first inserted into the axial groove 14, specifically in such a way that the first end region 26, which is already radially from the base protrudes steeply 28, is received by the circumferential groove 42. The first end region 26 is then inserted with little play between the stop 34 of the securing element 32 and the corresponding parts of the end face 40 of the blade carrier 16. The moving blade with its blade root 14 is then inserted from the pressure side 38 over the securing body 22 into the axial groove 14 of the blade carrier 16 inserted. Finally, the second end region 26 'of the securing body 22 is bent radially outward, so that the blade root 12 is axially fixed with the aid of the two end regions 26, 26'.

LIST OF REFERENCE NUMBERS

A axial flow direction

10 moving blades

12 blade root

13 blade foot end

14 axial groove

15 axial groove bottom

16 shovel carriers

20 security system

22 securing body

24 securing element

26, 26 'end region

28 base part

30 weld seam

32 separate locking washers

34 stop

36 screw

38 upstream end face of the blade carrier, pressure side

38 'upstream end face of the blade root, pressure side

40 downstream end of the blade carrier, rear

40 'downstream end of the blade root, rear

42 circumferential groove

Claims

claims

1.Safety system for rotor blades (10) of axially flow-through turbomachinery, in which the rotor blades (10) are secured radially and in the circumferential direction by means of a blade root (12) inserted into a radially arranged axial groove (14) of a blade carrier (16), with a between Blade root end (13) and axial groove base (15) arranged securing body (22) which, with its first end region (26), engages behind the rear side (40) of the blade carrier (16) opposite the acting axial force, characterized in that a one-piece with the Blade carrier (16) designed securing element (24) is arranged axially adjacent to the first end region (26) of the securing body (22) and forms an axial stop (34) for the latter.

2. Safety system according to claim 1, characterized in that in the installed state, the first end region (26) of the fuse body (22) is arranged in a circumferential groove (42) between the stop (34) and the blade carrier (16).

3. Security system according to claim 1 or 2, characterized in that the securing element (24) is produced by means of turning and / or milling.

4. Safety system according to claim 1 or 2, characterized in that the securing element (24) is manufactured as a separate locking washer (32) or as a separate locking ring and is welded or glued to the vane carrier (16) to form a one-piece body.

5. Security system according to one of claims 1 to 4, characterized in that the fuse body (22) with its two end regions (26, 26 ') projects axially beyond the axial groove (14) and the end regions (26, 26') in the installed state each reach behind one end face (38, 40) of the blade carrier (16).

6. Security system according to claim 5, characterized in that the end regions (26, 26 ') are wider than the base part (28) connecting them and wider than the axial groove (14), so that they project beyond the axial groove (14) in the circumferential direction.

7. Security system according to claims 5 and 6, characterized in that in the installed state, the end regions (26, 26 ') of the fuse body

(22) protrude radially outward from the base part (28) and they engage behind the end faces (38 ', 40') of the blade root (12) and parts of the end faces (38, 40) of the blade carrier (16).

8. Securing body for axially securing rotor blades (10) in a blade carrier (16), the base part of which extends over the entire axial extent of an axial groove (14) accommodating the securing body (10) in the blade carrier (16) and the first end region (26) a rear side (40) of the blade carrier (16) opposite the attacking axial force engages, characterized in that it has a second end region (26 "), and the two end regions (26, 26 ') in the installed state only radially outwards from the base part (28) protrude and, in addition to the end faces (38 ', 40') of the blade root (12), they also engage behind parts of the end faces (38, 40) of the blade carrier (16).

9. Fuse body according to claim 8, characterized in that the two end regions (26, 26 ') are wider than a base part (28) connecting them and wider than the axial groove (14), so that they contain the axial groove (14) Extend circumferential direction.