EP1654441B1 - Run-in coating of a gas turbine and method for fabricating such a coating - Google Patents

Description

The invention relates to an inlet lining for gas turbines according to the preamble of patent claim 1, as from the publication US 4,155,755 A and US 5667898 is known. Furthermore, the invention relates to a method for producing a Einlaufbelags according to the preamble of claim 9.

Gas turbines, such as aircraft engines, typically include a plurality of rotating blades and a plurality of fixed vanes, the blades rotating together with a rotor, and wherein the blades and the vanes are enclosed by a fixed housing of the gas turbine. To increase the performance of an aircraft engine, it is important to optimize all components and subsystems. These include the so-called sealing systems in aircraft engines. Particularly problematic in aircraft engines is keeping clean a minimum gap between the rotating blades and the stationary housing of a high pressure compressor. Namely, the highest absolute temperatures and temperature gradients occur in high-pressure compressors, which makes it more difficult for the rotating blades to cling to the stationary housing of the compressor. This is partly due to the fact that in compressor blades on shrouds, such as those used in turbines, is dispensed with.

As mentioned earlier, blades in the compressor have no shroud. Thus, tips of the rotating blades are exposed to direct frictional contact with the housing during so-called rubbing into the stationary housing. Such a rubbing of the tips of the blades into the housing is caused by setting a minimum radial gap by manufacturing tolerances. As is removed by the frictional contact of the tips of the rotating blades on the same material, can over the entire circumference of the housing and rotor set an undesirable gap magnification. To avoid this, it is already known from the prior art to armor the ends or tips of the rotating blades with a hard coating or with abrasive particles.

Another way to avoid wear on the tips of the rotating blades and to provide an optimized seal between the ends or tips of the rotating blades and the fixed housing, consists in the coating of the housing with a so-called inlet lining. In a material removal at an inlet lining of the radial gap is not increased over the entire circumference, but usually only sickle-shaped. As a result, a power loss of the engine is avoided. Housings with an inlet lining are known from the prior art.

On this basis, the present invention is based on the problem of creating a novel inlet lining for gas turbines.

This problem is solved in that the input said inlet lining is further developed by the features of the characterizing part of claim 1.

The inlet lining for gas turbines according to the invention serves to seal a radial gap between a stationary housing of the gas turbine and rotating blades thereof. The inlet lining is attached to the housing. According to the invention, the inlet lining is produced from an intermetallic titanium-aluminum material, wherein the inlet lining made of the Ti-Al material has a graduated or graded material composition over the thickness of the inlet lining.

According to an advantageous embodiment of the invention, the inlet lining of the titanium-aluminum material has a graded or graded porosity. Particularly preferred is an embodiment in which the inlet lining in an inner, directly adjacent to the housing area and at an outer, immediately adjacent to the blades lying area is less porous than between these two areas. The inlet lining is accordingly denser and harder on the inner region immediately adjacent to the housing and on the outer region immediately adjacent to the rotor blades. The inner, immediately adjacent to the housing area serves to provide adhesion; the outer area immediately adjacent the blades serves to provide erosion protection.

The inventive method for producing an inlet lining is defined in the independent claim 9.

Preferred embodiments of the invention will become apparent from the dependent subclaims and the following description.

Fig. 1:

eine stark schematisierte Darstellung einer Laufschaufel einer Gasturbine zusammen mit einem Gehäuse der Gasturbine und mit einem auf dem Gehäuse angeordneten Einlaufbelag.

Hereinafter, embodiments of the invention, without being limited thereto, explained in more detail with reference to the drawing. In the drawing shows:

Fig. 1:

a highly schematic representation of a blade of a gas turbine together with a housing of the gas turbine and arranged on the housing inlet lining.

Fig. 1 shows a highly schematic of a rotating blade 10 of a gas turbine, which rotates relative to a fixed housing 11 in the direction of the arrow 12. On the housing 11, an inlet lining 13 is arranged. The inlet lining 13 serves to seal a radial gap between a tip or end 14 of the rotating blade 10 and the stationary housing 11. The requirements placed on such an inlet lining are very complex. Thus, the inlet lining must have an optimized abrasion behavior, ie it must be ensured good chip formation and Entfembarkeit the abrasion. Furthermore, no transfer of material to the rotating blades 10 may take place. The inlet lining 13 must furthermore have a low frictional resistance. Furthermore, the inlet lining 13 must not ignite when rubbed by the rotating blades 10. As further requirements, which are placed on the inlet lining 13, its here the erosion resistance, temperature resistance, thermal shock resistance, corrosion resistance to lubricants and seawater exemplified. Fig. 1 illustrates that due to the centrifugal forces occurring during operation of the gas turbine and the heating of the gas turbine, the ends 14 of the blades 10 come into contact with the inlet lining 13 and so an abrasion 15 is released. This pulverized abrasion 15 must not cause any damage to the rotating blades 10.

At the in Fig. 1 schematically illustrated housing 11 is in the preferred embodiment, the housing of a high pressure compressor. Such housing of high-pressure compressors are increasingly made of intermetallic materials of the type TiAl or Ti ₃ Al. Such titanium-aluminum intermetallic materials have a lower density and are superior in temperature resistance to conventional titanium alloys.

It is now within the meaning of the present invention, on a housing 11 which is made of an intermetallic titanium-aluminum material, an inlet lining 13 also applied from an intermetallic titanium-aluminum material. It should be noted that such an inlet lining of an intermetallic titanium-aluminum material can also be applied to a housing which consists of a conventional titanium alloy.

For the purposes of the present invention, the inlet lining 13 of the intermetallic titanium-aluminum material has a stepped, i. gradually changing, or over a graded, i. over a nearly infinitely variable, material composition and / or porosity. By the targeted adjustment of the material composition and / or porosity, the properties of the inlet lining 13 can be adapted to the specific requirements of the same.

According to a preferred embodiment of the inlet lining 13 according to the invention, it has a low porosity in an inner region 16 immediately adjacent to the housing 11, as well as in an outer region 17 immediately adjacent to the moving blades 10. Between this inner region 16 and this outer region 17, on the other hand, the porosity of the inlet lining is increased. The inner, directly on the housing 11 adjacent area 16 of the inlet lining 13 serves for bonding between inlet lining 13 and housing 11. The outer, immediately adjacent to the blades 10 area 17 of the inlet lining 13 forms an erosion protection. Depending on the requirements of the inlet lining 13, however, this erosion protection can also be dispensed with.

The ratio of titanium and aluminum within the inlet lining 13 produced from the intermetallic titanium-aluminum material is preferably approximately constant. This means that in this case only the porosity of the inlet lining 13 is graded or graded to influence the hardness and strength thereof.

However, it is also conceivable that the ratio of titanium and aluminum within the inlet lining 13 is graded or graded. In this case, more titanium is preferably contained in the inner lining immediately adjacent to the housing 11 in the inlet lining 13 than in the outer region 17 of the inlet lining 13. This means that in the outer region 17 of the inlet lining 13 more aluminum is contained than in the inner region 16 thereof, which is adjacent to the housing 11.

The use of an inlet lining of a titanium-aluminum intermetallic material on a housing, which is also formed of an intermetallic titanium-aluminum material or a titanium alloy, has the advantage that the connection of the inlet lining to the housing takes place via chemical bonds and so that the connection is safer and more durable than with inlet coverings according to the prior art. Furthermore, there will be no high-temperature diffusion between the housing and the inlet lining between an inlet lining and a housing, which have the same basic composition. Furthermore, there are no thermal expansion problems, since the housing and inlet lining evenly expand or contract with temperature increase or decrease in temperature. As a result, a more uniform gap position and a longer service life of the inlet lining can be achieved. An inventively formed inlet lining further has a high oxidation resistance and high thermal shock resistance. The blade tips of the rotating blades are subject to minimal blade tip abrasion.

It is within the meaning of the present invention to produce the inlet lining 13 according to the invention by providing the inlet lining 13 in the form of a slip material and applying it to the housing 11 using the slip technique. Such a slip material based on an intermetallic Titanium-aluminum material is preferably applied to the housing 11 by brushing, dipping or spraying. This is preferably done in several steps or layers, so that a multi-layer inlet lining 13 is formed.

To adjust the desired porosity in the respective layers, additional materials are incorporated into the slip material. After application of the slip material, hardening or burning in of the slip material takes place on the housing 11. During the burn-in, the additives added to the slip material evaporate, as a result of which the pores within the inlet lining 13 remain. The number and type of added additives allows the porosity, namely the number and size of the pores, to be adjusted.

Alternatively, the run-in pad 13 can also be made by applying it using a directional matter vapor jet. Such a directed matter vapor jet may be generated by a PVD (Physical Vapor Deposition) process or a CVD (Chemical Vapor Deposition) process. Shortly before the impact of the directed matter vapor jet based on a sintered metallic titanium-aluminum material, at least one additive is introduced or stored in the material vapor jet, these additives being evaporated again during the subsequent baking and leaving behind the pores within the or each layer of the inlet lining 13 ,

The porosity adjunct additives may be so-called microballs, i. filled or hollow plastic beads, polystyrene beads, or other materials that vaporize upon firing of the titanium-aluminum intermetallic material.

Both using the slip technology and the PVD or CVD technique, the inlet lining according to the invention can be produced particularly favorable.

Claims (15)

1. A run-in coating for gas turbines, for sealing a radial gap between a housing (11) of the gas turbine and rotating rotor blades (10) of the same, wherein the run-in coating (13) is applied to the housing (11), wherein the run-in coating (13) is produced from an intermetallic titanium-aluminium material, characterised in that the run-in coating (13) consisting of the titanium-aluminium material has a material composition that is stepped or graded over the thickness of the run-in coating and/or a stepped porosity.
2. A run-in coating according to claim 1, characterised in that the run-in coating (13) consisting of the titanium-aluminium material is formed so as to be less porous at a region facing the housing (11) than at a region facing the rotating rotor blades (10).
3. A run-in coating according to one or more of claims 1 to 2, characterised in that the run-in coating (13) is formed so as to be less porous in an inner region lying directly adjacently to the housing (11) and at an outer region lying directly adjacently to the rotor blades (10) than between these two regions.
4. A run-in coating according to one or more of claims 1 to 3, characterised in that the ratio of titanium and aluminium within the run-in coating (13) is approximately constant, wherein exclusively the porosity is stepped for the adjustment of a density and/or hardness and/or solidity of the same.
5. A run-in coating according to one or more of claims 1 to 3, characterised in that also the ratio of titanium and aluminium within the run-in coating (13) is stepped or graded, wherein the run-in coating (13) contains more aluminium at a region facing the rotating rotor blades (10) than at a region facing the housing (11).
6. A run-in coating according to one or more of claims 1 to 5, characterises in that the run-in coating (13) consisting of the titanium-aluminium material is applied to a housing (11) consisting of an intermetallic titanium-aluminium material.
7. A run-in coating according to claim 6, characterised in that the run-in coating (13) consisting of the titanium-aluminium material is applied directly to the housing (11) of titanium-aluminium material.
8. Method for producing a run-in coating for gas turbines, for sealing a radial gap between a housing (11) of the gas turbine and rotating rotor blades (10) of the same, wherein the run-in coating (13) is provided on the housing (11), having the following steps:

   a) provision of a housing (11),

   b) application of the run-in coating (13) consisting of an intermetallic titanium-aluminium material to the housing,

   characterised in that the run-in coating (13) consisting of the titanium-aluminium material is applied in such a way that the same has a material composition that is stepped or graded over the thickness of the run-in coating and/or stepped porosity.
9. Method according to claim 8, characterised in that the run-in coating (13) consisting of the titanium-aluminium material is applied in such a way that the same is formed so as to be less porous at a region facing the housing (11) than at a region facing the rotating rotor blades (10).
10. Method according to one or more of claims 8 to 9, characterised in that the run-in coating (13) consisting of the titanium-aluminium material is applied to a housing (11) consisting of an intermetallic titanium-aluminium material.
11. Method according to one or more of claims 8 to 10, characterised in that in conjunction with step b) the run-in coating (13) is applied to the housing (11) in such a way that for this at least one layer of a titanium-aluminium slip material is applied to the housing (11), wherein subsequently the or each layer of the titanium-aluminium slip material is hardened by baking.
12. Method according to claim 11, characterised in that additives are intercalated into the or each layer of the titanium-aluminium slip material, wherein these additives are vaporized during baking and thereby leave behind the pores within the or each layer of the run-in coating (13).
13. Method according to claim 11 or 12, characterised in that the or each layer of the titanium-aluminium slip material is applied by painting, dipping or spraying.
14. Method according to one or more of claims 8 to 10, characterised in that in conjunction with step b) the run-in coating (13) is applied to the housing (11) in such a way that for this at least one titanium-aluminium layer is applied to the housing (11) with the aid of a directed substance-vapour jet, in particular a PVD substance jet, wherein subsequently the or each layer of the substance-vapour jet is hardened by baking.
15. Method according to claim 14, characterised in that shortly before the directed titanium-aluminium-substance-vapour jet impinges, additives are introduced into the titanium-aluminium-substance-vapour jet, wherein these additives are vaporized during baking and thereby leave behind the pores within the or each layer of the run-in coating (13).

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