DE102008052030B4 - Method for connecting at least one turbine blade with a turbine disk or a turbine ring - Google Patents

Abstract

Method for joining at least one turbine blade (10) which can not be melt-welded or melted with a melt-weldable turbine disk (18) or a melt-weldable turbine ring for a turbine stage of a turbomachine, in particular a thermal gas turbine, in which first a geometrically defined connector body (16) is produced by means of a cold gas spraying method formed on the at least one turbine blade (10) and the connecting body (16) is then connected by means of a fusion welding process with the turbine disk (18) or with the turbine ring, wherein the connecting body (16) in the region of a blade root (14) of the turbine blade (10). and / or as a blade root (14) of the turbine blade (10) is formed depending on a geometry of the turbine blade (10) and / or the turbine disk (18) or the turbine ring and is finished before the fusion welding process.

Description

The invention relates to a method for connecting at least one turbine blade with a turbine disk or a turbine ring for a turbine stage of a turbomachine, in particular a thermal gas turbine. The invention further relates to a turbine stage specified in the preamble of claim 7 type for a turbine of a turbomachine and a turbomachine specified in the preamble of claim 10. Art.

Such a method of joining at least one turbine blade to a turbine disk or turbine ring and such a turbine stage comprising a turbine disk or turbine ring at least indirectly connected to one or more turbine blades are known in the art. The turbine stage in turn serves for arrangement in a single-stage or multi-stage turbine of a turbomachine designed in particular as a thermal gas turbine. The progress in gas turbine construction, however, places ever higher demands on the materials used. The turbine blades serving as guide vanes or blades are therefore essentially produced as polycrystalline, monocrystalline or directionally solidified castings made from high-temperature-resistant base alloys. Also known are turbine blades, which are made of high-temperature composite materials.

However, this configuration leads to the fact that the turbine blades are not or only very difficult melt-weldable. A connection with a fusion weldable turbine disk or a corresponding turbine ring, which may be made of a nickel-based alloy is therefore not possible via conventional fusion welding and leads to significant additional costs. Alternatively friction welding or diffusion welding methods are known for at least indirect connection between turbine blade and turbine disk or turbine ring, but which require a high expenditure on equipment. In addition, temperatures can occur in these welding processes, which are incompatible for common base alloys.

The publication EP 1 698 423 A1 From the Applicant's house relates to a method for joining a blade to a rotor body. For connecting the rotor blade and rotor body, a joining body is provided, which is moved translationally for producing a welded joint between the blade and the rotor body.

The publication DE 10 2006 060 021 A1 relates to a method for producing a heavy-duty coating. In this case, a so-called bearing metal is applied by cold gas spraying.

The patent 10 2006 029 619 B3 relates to a method for coating a component by cold gas spraying. In the patented process, the layer thickness is varied by vibrations.

The publication DE 10 2006 056 489 A1 relates to a method for producing a steel / aluminum composite component as required in particular in the automotive industry. Aluminum particles are applied to steel. In a further step, a fusion welding process is then applied between the applied layer and the aluminum component.

The publication EP 1 903 127 A1 relates to a method for manufacturing components by cold gas spraying. The method serves generatively to build a turbine component.

Object of the present invention is therefore to provide a method of the type mentioned, which is cheaper and more flexible feasible. Another object of the invention is to provide a corresponding turbine stage with a turbine disk or a turbine ring and at least one turbine blade, which is less expensive and more flexible to produce.

The object is achieved by a method according to claim 1, a turbine stage with the features of claim 4 and by a turbomachine with the features of claim 6. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the respective subclaims, wherein advantageous embodiments of the method - where applicable - are to be regarded as advantageous embodiments of the turbine stage and vice versa.

In a method according to the invention for connecting at least one turbine blade with a turbine disk or a turbine ring for a turbine stage of a turbomachine, in particular a thermal gas turbine, a connecting body is firstly formed on the at least one turbine blade by means of a cold gas spraying method and the connecting body is subsequently connected to the turbine disk by means of a fusion welding method connected to the turbine ring. A cold spraying method is a coating method in which the material of the subsequent connecting body is applied in powder form to the turbine blade at very high speed. For this purpose, it may be provided that a comparatively Low temperature heated gas is accelerated by expansion in a nozzle (called Laval nozzle) to supersonic speed. In this gas, the powder particles are then introduced and thereby accelerated to such high speeds that they form a firmly adhering layer with a high density and compactness without melting or on impact with the turbine blade. The cold gas spraying process is preferably carried out in such a way that the kinetic energy of the powder particles at the time of the impact is not sufficient for complete melting. As a result, a minimum heat input is ensured at the same time in the serving as a substrate turbine blade. Depending on the material used, the impact velocity of the powder particles can be specifically adapted, for example, by optimized nozzle design, modified gas temperatures, higher gas pressures or altered particle sizes. By the material of the thus formed connecting body is neither or not melted, oxidation of the materials involved is reliably prevented. Subsequently, the turbine blade is connected by means of the fusion welding process via the connecting body indirectly with the turbine disk or the turbine ring. In principle, therefore, all materials which can be plastically deformed, melt-weldable and withstand the later stresses during operation of an associated turbomachine can be used as the material of the connecting body. The inventive method can thus be carried out considerably less expensive without high equipment costs. Since the connection between the turbine blade and the turbine disk or with the turbine ring takes place by means of the connecting body, moreover, the material and the geometry of the turbine blade of minor importance, whereby the method is particularly flexible feasible. It can basically be provided that the connecting body is formed in several parts.

In an advantageous embodiment of the invention, it is provided that the connecting body is processed, in particular finished, before the fusion welding process. Finely machined here is understood to mean preferably machining, whereby both a desired surface quality and a required dimensional accuracy of the connecting body can be ensured simply and inexpensively.

Further advantages result if the connecting body is formed in the region of a blade root of the turbine blade and / or as a blade root of the turbine blade. This allows a simple and mechanically stable connection of the turbine blade with the turbine disk or the turbine ring via the connecting body.

In a further advantageous embodiment of the invention it is provided that the connecting body is formed in dependence on a geometry of the turbine blade and / or the turbine disk or the turbine ring. As a result, the method can be used particularly flexibly for the representation of different turbine stages.

In another embodiment, it has proven to be advantageous if an electron beam welding method and / or a laser welding method and / or an inductive high frequency compression welding method and / or an inductive low frequency compression welding method is used as the fusion welding method. As a result, high welding speeds with extremely deep and narrow seams with low thermal distortion are possible.

By connecting a plurality of turbine blades to the turbine disk or the turbine ring via respective connecting bodies, a complete turbine stage for a turbomachine with the advantages according to the invention and in particular with reduced costs and increased flexibility can be produced.

Another aspect of the invention relates to a turbine stage for a turbine of a turbomachine, wherein the turbine stage is cheaper and more flexible to produce by at least one turbine blade is connected via a means of a cold gas spraying method formed on the turbine blade connecting body with the turbine disk or the turbine ring. Further resulting advantages can be taken from the previous descriptions.

By connecting the connecting body to the turbine disk or the turbine ring by means of a fusion welding method, the manufacturing costs of the turbine stage can be additionally reduced.

In a further advantageous embodiment of the invention, it is provided that the turbine disk or the turbine ring and / or the turbine blade of a nickel-based alloy and / or a cobalt-based alloy and / or a titanium aluminide and / or a metal-matrix composite material and / or a ceramic matrix composite material is made. As a result, the turbine stage reliably has the required mechanical and thermal properties for later use in an associated turbomachine and, moreover, can be adapted particularly flexibly to the respective requirement profile.

A further aspect of the invention relates to a turbomachine, in particular a thermal gas turbine, with a turbine, which comprises a turbine stage with a turbine disk or a turbine ring, which is at least indirectly connected to at least one turbine blade, wherein it is provided according to the invention that the Turbine disk or the turbine ring and the at least one turbine blade of the turbine stage by means of a method according to one of the preceding embodiments are interconnected or that the turbine stage is formed according to one of the preceding embodiments. The resulting combinations of features and their advantages can be found in the corresponding descriptions.

Further advantages and details of the invention will become apparent from the following description of an embodiment and with reference to the drawings. Showing:

1 a front perspective view of a turbine blade;

2 a perspective oblique view of a on a blade root of in 1 shown turbine blade trained connecting body; and

3 a fragmentary and perspective frontal view of a turbine disk, which is connected via the connecting body with the turbine blade.

1 shows a front perspective view of a turbine blade 10 whose general structure is known from the prior art. The turbine blade 10 , which is made as a casting of a high temperature resistant nickel-based alloy, includes a radially outer shroud 12 and a radially inner blade root 14 , As the material from which the turbine blade 10 is made, is not or is very difficult melt weldable, is by means of a cold gas spraying a in 2 in a perspective oblique view shown connecting body 16 in the region of the blade root 14 the turbine blade 10 educated. The connecting body 16 which is formed of a plastically deformable and melt-weldable material, allows the turbine blade 10 in a subsequent step via a cost-effective fusion welding process with a turbine disk 18 connect to. Basically, instead of the turbine disk 18 a turbine ring (not shown) may be provided, wherein both the turbine disk 18 as well as the turbine ring may be formed one or more parts. It may further be provided that the connecting body 16 the blade foot 14 forms. Likewise, it can basically be provided that the connecting body 16 is formed in multiple or multi-piece or is, so that the connection between the turbine blade 10 and the turbine disk 18 indirectly via a plurality of partial connection body (not shown) takes place.

3 shows a fragmentary and perspective frontal view of the turbine disk 18 , in the marked with arrow III area over the present integrally formed connecting body 16 with the turbine blade 10 connected is. As a fusion welding method, for example, an electron beam welding method, a laser welding method, an inductive high frequency pressure welding method and / or a low frequency inductive pressure welding method can be used. In principle, however, other welding methods familiar to the person skilled in the art can also be provided. Furthermore, it can be provided that the connecting body 16 is finished prior to fusion welding, whereby a simple geometric adjustment between the turbine blade 10 and the turbine disk 18 is possible. By having multiple turbine blades 10 in an analogous manner with the turbine disk 18 be connected to produce a complete turbine stage for a turbine of a thermal gas turbine. It can be provided in principle that the method is also used for the production of compressor stages for a compressor of a turbomachine or for connecting compressor blades with a compressor disk.

Claims (6)

Method for connecting at least one turbine blade which is difficult or impossible to melt-weld ( 10 ) with a fusion weldable turbine disk ( 18 ) or a melt-weldable turbine ring for a turbine stage of a turbomachine, in particular a thermal gas turbine, in which first by means of a cold gas spraying process a geometrically defined connecting body ( 16 ) on the at least one turbine blade ( 10 ) and the connecting body ( 16 ) subsequently by means of a fusion welding process with the turbine disk ( 18 ) or is connected to the turbine ring, wherein the connecting body ( 16 ) in the region of a blade root ( 14 ) of the turbine blade ( 10 ) and / or as a blade root ( 14 ) of the turbine blade ( 10 ) in dependence on a geometry of the turbine blade ( 10 ) and / or the turbine disk ( 18 ) or the turbine ring is formed and finished before the fusion welding process. A method according to claim 1, characterized in that as a fusion welding method, an electron beam welding method and / or a Laser welding method and / or an inductive high-frequency welding method and / or a low-frequency induction welding method is used. Method according to claim 1 or 2, characterized in that a plurality of turbine blades ( 10 ) via respective connecting bodies ( 16 ) with the turbine disk ( 18 ) or the turbine ring. Turbine stage for a turbine of a turbomachine, in particular a thermal gas turbine, with a turbine disk ( 18 ) or a turbine ring, which at least indirectly with at least one turbine blade ( 10 ), characterized in that the at least one turbine blade ( 10 ) via a by means of a cold gas spraying process on the turbine blade ( 10 ) formed, geometrically defined connecting body ( 16 ) with the turbine disk ( 18 ) or the turbine ring, wherein the connecting body ( 16 ) in the region of a blade root ( 14 ) of the turbine blade ( 10 ) and / or as a blade root ( 14 ) of the turbine blade ( 10 ) in dependence on a geometry of the turbine blade ( 10 ) and / or the turbine disk ( 18 ) or the turbine ring, for its connection to the turbine disk ( 18 ) or the turbine ring is finished and by means of a fusion welding process with the turbine disk ( 18 ) or connected to the turbine ring. Turbine stage according to claim 4, characterized in that the turbine disk ( 18 ) or the turbine ring and / or the turbine blade ( 10 ) is made of a nickel-based alloy and / or a cobalt-based alloy and / or a titanium aluminide and / or a metal matrix composite material and / or a ceramic matrix composite material. Turbomachine, in particular thermal gas turbine, with a turbine, which has a turbine stage with a turbine disk ( 18 ) or a turbine ring, the or at least indirectly with at least one turbine blade ( 10 ), characterized in that the turbine disk ( 18 ) or the turbine ring and the at least one turbine blade ( 10 ) of the turbine stage are connected to one another by means of a method according to one of claims 1 to 3 and / or that the turbine stage is designed according to one of claims 4 or 5.

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