WO2012113623A1

WO2012113623A1 - Turbine blade and method for producing a turbine blade

Info

Publication number: WO2012113623A1
Application number: PCT/EP2012/051654
Authority: WO
Inventors: Anett Berndt; Norbert Scheunert; Christian Seidel; Lutz Völker; Heinrich Zeininger
Original assignee: Siemens Aktiengesellschaft
Priority date: 2011-02-22
Filing date: 2012-02-01
Publication date: 2012-08-30

Abstract

The invention relates to a turbine blade (1) which consists at least in regions of a fiber composite material, comprising an erosion guard (2) which is arranged at least in regions on the surface of the turbine blade (1). The erosion guard (2) consists of at least two metal layers (3) and at least two polymer layers (4) which are arranged over each other in alternation. The invention further relates to a method for producing a turbine blade (1) having such an erosion guard (2).

Description

description

Turbine blade and method of producing a ^turbine blade

The invention relates to a turbine blade, in particular a turbine blade for a steam turbine, and a Ver ^¬ drive for producing such a turbine blade. Turbine blades of a turbine stage of a turbine are exposed to high stresses. In particular, in steam turbines, the turbine blades are ^¬ NEN affected by high Tropfenschlagerosi- onsbeanspruchung. The high loads affect the life of the turbine blade, in particular the final stage blades, a Kondensationsdampfturbine significantly ^¬ . To counteract the high drop impact erosion stresses, the turbine blades and in particular the turbine blades of steam turbines are currently predominantly made of steel. Due to the high weight of the steel turbine blade and the resulting high fly ^¬ forces are the speed, and the maximum blade length of Endstufenlaufschaufei limited. As a result, the Ab ^¬ strömfläche the Abströmgehäuses and thus the performance and the efficiency of the turbine are limited. In addition, the drop impact erosion, even with hardened steel, causes wear on the turbine blades, so that they must be replaced regularly.

In order to increase the resistance to drop impact erosion and to reduce the weight of the turbine blade, turbine blades made of titanium or titanium alloys are also used. Due to the higher material costs, however, the price of the turbine blades increases significantly. In order to increase turbine performance and efficiency, the use of fiber composite power stage blades is being increasingly considered. Fiber composites have the advantage of high specific strength at at the same time low weight. When using fiber composite ^¬ materials with a desired higher product of surface times speed, however, the erosion burden increases again significantly. Water drops with a size of about 25 to 400 microns, in particular of about 100 μπι and a relative speed of about 490 m / s can occur on the blade surface. Turbine blades of a fiber composite material, however, already destroyed at lower Geschwindigkei ^¬ th drop of water in a few minutes. In order to counteract the high level of wear on turbine blades made of fiber composite materials, it is therefore necessary to form them with special erosion protection.

From US 2003/0129061 Al a hybrid multi-component blade or vane of a steam turbine is known, the core of which is formed of a company server ^¬ composite material on the surface thereof and an erosion coating made of polyurethane is provided. At the front and / or trailing edge of the turbine blade a protective cap is additionally arranged on the erosion coating. This protective cap is made of titanium because titanium has greater erosion resistance than the fiber composite and erosion protection coating. Due to the solid ausgebil ^¬ Deten protective cap made of titanium, however, goes in the field of

Cap lost the damping property of erosion plating. The arrangement of the cap and its permanent attachment also prove to be difficult. In addition, the solid design protective cap ensures an increase in the Ge ^¬ weight of the turbine blade. From the Applicant's PCT / EP2010 / 066299 a turbine blade is known, which has on its blade surface a highly elastic ^¬ elastomer coating, which is provided with a thin energy-absorbing metal coating. The thin energy-absorbing metal coating is designed so that the lying below it highly elastic

Elastomeric coating can bring to bear its damping property in Wesentli ^¬ chen full. From the not previously published German patent application 10 2009 047 798.5 of the applicant, it is further known form trainees erosion protection component with a multi-layered structure. The multi-layered structure is a graduated structure with different layers. The outer layer consists of a very hard and erosi onsunempfindlichen material. Under the first layer ei ne second elastic and / or visco-elastic layer is integrally ^¬ arranged, which ensures that produced by the drop Kör ^¬ perschallwellen be largely absorbed. The following layer is a glass mat and the underlying one

Layer a glass fabric. The glass mat and the glass fabric sor conditions for a particularly good connection to the fiber composite material of the turbine blade. However, a disadvantage of the use of the glass mat or the glass fabric is the low Umfor ^¬ mungsvermögen. As a result, the erosion protection layer can be adapted to the complex geometry of the turbine blade only with difficulty, so that full application of the

Protective layer is difficult. Further, in the NEN-described ^¬ layered structure only the outer layer very hard for the actual protection against drops blow Rosi on makes. Upon destruction of this layer, there is a rapid destruction of the underlying layers and thus subsequently destroying the entire turbine blade.

Based on the present state of the art, it is therefore an object of the invention to provide a turbine blade, which has an improved erosion protection against Tropfenschlagero sion. Furthermore, it is an object of the present invention to provide a method for producing such a turbine blade.

The object is achieved with regard to the turbine blade by the features of independent claim 1.

With regard to the method, the invention is solved by the features of independent claim 7. Advantageous embodiments of the invention which are used individually or in combination with each other are the subject of the dependent claims. The turbine blade according to the invention, which consists of a fiber composite material at least be ^¬ includes an erosion protection, which is at least partially disposed on the surface of the turbine blade, the Erosi ^¬ onsschutz consists of at least two polymeric layers and at least two metallic layers, the alternating are arranged one above the other. The essential advantage of this multilayer coating compared to an erosion protection, which consists only of a metallic and a polymeric layer, is that the multi-layer erosion protection has a higher forming capacity. This ensures a simple and robust geometry adjustment and a full-surface application of the protective layer, especially in the area of the leading edge. The application of the multilayer coating can take place during the manufacturing process of the turbine blade or afterwards.

The erosion protection, consisting of alternately arranged polymeric and metallic layers, offers over the known from the prior art layers, with only a metallic layer and an elastic or viscoelastic layer and underlying glass mats or glass fabrics, a significantly increased erosion protection. In a destruction of the first sheet layer consisting of a metal and a polymeric layer does not occur UNMIT ^¬ telbar to the destruction of the entire turbine blade, since the underlying sheet layer consisting of another metal and a further polymeric layer further provide an effective protection against erosion. Due to the additional arrangement of further metallic polymeric layers erosion protection can be easily adapted to the respective requirements.

A particularly preferred embodiment of the invention provides that the outer layer of the erosion protection a metal lische layer is. The metallic layer has the advantage that it ensures a particularly good erosion protection with high energy absorption. The polymeric layer disposed under the metallic layer essentially provides mechanical damping.

A particularly preferred embodiment of the invention provides that the metallic layer consists of steel, of aluminum, of an aluminum alloy, of titanium, of a titanium alloy, of magnesium or of a magnesium alloy. Due to their high energy- ^{absorbing capacity,} these materials have a particularly high protection against drop impact erosion.

A further preferred embodiment of the invention provides that the polymeric layer of polyurethane, a thermoplastic elastomer, in particular a thermoplastic polyurethane, or a rubber, in particular a hydrogenated acrylonitrile butadiene rubber, chloroprene, isoprene, ethylene-propylene-diene rubber (EPDM ) or a fluororubber. These polymers have a particularly good damping property.

The turbine blade according to the invention has a metallic layer with a layer thickness of 0.05 to 0.5 mm in a particular ^¬ DERS preferred embodiment of the invention. A layer thickness of this order of magnitude ensures, on the one hand, a high formability of erosion protection and, on the ^{other hand,} sufficient protection against drop ^impact erosion.

A further preferred embodiment of the invention provides that the polymeric layer has a layer thickness of 0.02 to 1 mm. A layer thickness in this size ge ^¬ ensures a sufficient mechanical damping and enables maintaining a high forming capability of the erosion protection. The inventive method for producing a turbine blade according to the invention is characterized by the following method steps:

- Manufacture of the turbine blade and subsequent or simultaneous

- Material and / or positive connection of the erosion ^¬ protection with the turbine blade.

The cohesive connection can simply rely on the surface of the turbine blade he ^¬ followed by gluing or melting. The positive connection is effected by plasti ^¬ cal forming the erosion protection for optimized mechanical connection. A preferred embodiment according to the invention the method for producing the turbine blade provides that the Her ^¬ position the turbine blade and the connection of the turbine blade with the erosion protection by means of a prepreg or resin transfer molding method (RTM) take place. As a result, the production of the turbine blade and the application of erosion protection can be done in one step. This shortens the manufacturing time and cost it ^¬ considerably and makes for a very secure connection between the turbine blade and the erosion control.

The special design or the specific characteristics ^¬ shaft of the multi-layer film comprising at least two me ^¬-metallic and two polymeric layers, which are laminated in alternie ^¬ render sequence above one another, results in an erosion protection with a particularly high and good forming property, thereby a simple and robust geo ^¬ metric adjustment and a full-surface application of the protective layer is ensured especially in the area of the leading edges. The erosion protection layers used hitherto have only limited reshaping capability, whereby a coating with an erosion protection layer proved to be difficult or even impossible especially in the area of the leading edges. The turbine blade according to the invention with the multilayer protective layer comprises at least two polymeric protective ^¬ layers and at least two metallic layers, thus ensuring an improved protection against erosion and thus egg ne increased service life of the turbine blade. The ^turbine blade is particularly suitable for use in steam turbines and ^¬ especially for Endstufenlaufschaufei at Kon ^¬ densationsdampfturbinen, where an increased drop erosion load occurs.

In the following, further advantages of the invention will be explained in more detail with reference to an ^exemplary embodiment.

It shows schematically:

- Figure 1:

A side view of a turbine blade according to the invention;

- Figure 2:

A detail view of the turbine blade shown in Figure 1;

- Figure 3:

A detailed view of a leading edge of an inventive ^¬ SEN turbine blade of FIG. 1

The figures each show highly simplified schematic representations of the invention, in which only the essential components necessary for the invention are shown. The same or functionally identical components are cross-figured with the same reference numerals.

FIG. 1 shows a side view of a turbine blade 1, which can be used in particular as an end stage rotor blade for a steam turbine. The turbine blade 1 is formed from a fiber composite material. For this purpose, several layers of fiber mats are arranged one above the other. To take advantage of the fibers, ie, the high tensile strength to be able to Chamfering ^¬ zen in the fiber direction are placed one above the other, the mats so that the main fiber direction are aligned according to the main ^{stress ¬} direction of the turbine blade 1. As a fiber ^¬ material is particularly suitable glass fiber or carbon fiber. The fiber mats are embedded in a matrix. The matrix is preferably made of a synthetic resin and provides for a connection of the fiber mats with each other. However, the matrix itself can not absorb high tensile forces.

The turbine blade 1 is due to the Faserverbundwerkstof ^¬ fes very sensitive to drop impact erosion. For this reason, the turbine blade 1 comprises an erosion protection 2, which is at least partially arranged on the surface of the ^turbine blade. 1 In the exemplary embodiment, the erosion protection 2 is arranged at the leading edge 6 of the turbine blade 1. The leading edge 6 is most of Trop ^¬ fenschlagerosion risk because the water drops substantially impinge here. The erosion protection 2 is mounted in the embodiment only in the upper half of the leading edge 6. In this region of the leading edge 6, there is the greatest erosion stress, since during operation of the turbine here the largest peripheral speeds occur. The erosion protection 2 is preferably inserted into the blade contour of the turbine blade 1 in such a way that a smooth ^{transition occurs} without edges between the erosion protection 2 and the turbine blade 1.

The turbine blade 1 additionally comprises a second Erosi ^¬ onsschutz 2 at the trailing edge 7 of the turbine blade. 1 In normal operation, the trailing edge 7 is not very susceptible to erosion, as there is no drop impact here. The erosion protection 2 at the trailing edge 7, the turbine blade 1, is provided for the ventilation operation. In the ventilation operation of the steam turbine, in order to avoid overheating ^¬ pollution, water is sprayed from behind against the Turbinenschau- fei. 1 In this case, under unfavorable conditions, water drops may impinge on the outlet edge 7 of the turbine blade 1. This can then lead to an increased erosion load on the trailing edge 7. The Erosion protection component 2 at the trailing edge 7 can We ^¬ kungsvoll prevent damage to the turbine blade in this area. The erosion protection device can thereby be connected to the turbine blade 1 directly to the lung herstel ^¬ the turbine blade 1 by means of a resing Transfer Mode ling method (RTM) or by means of prepreg process. Connecting the Erosi ^¬ onsschutzes 2 with the turbine blade 1 can also retrospectively borrowed by means of mass and / or form-locking connection. As cohesive bonding is gluing or melting on. The form-fitting connection takes place by plastic deformation of the erosion shield 2. To secure the erosion ^¬ protection 2 addition, additional fastening can restriction means in particular be ver ^¬ employs screws, rivets or pins, which connects the turbine blade 1 with the erosion ^¬ protection. 2

Figure 2 shows a detailed view of the turbine blade 1 with the erosion protection 2. The erosion protection 2 is at least two metal layers 3 are formed, which are arranged one above the other ternierend al ^¬ a so-called multi-layer of at least two polymeric layers 4 and. A variety of demands on the erosion protection ^¬ second The erosion protection 2 must be erosion-stable, ie have a high mechanical stability against drop impact erosion. In addition, he must offer a good formability, so that he can adapt well to the profile of the turbine blade 1 and thus can be arranged over the entire surface of the turbine blade 1. Moreover, high Energieaufnahmefä ^¬ ability and a good hydrolysis resistance are necessary. These requirements are achieved by the formation of erosion protection 2 as a multilayer, with alternately arranged over ^¬ layers of a polymer and a metal. In order to ensure a high mechanical stability and thus a good erosion stability, the outer layer of erosion protection 2 is a metallic layer 3. As a metallic layer 3 is particularly suitable steel, aluminum or aluminum alloys, titanium or titanium alloys, magnesium or magnesium alloys. These materials offer a high erosion protection, high mechanical stability and high energy absorption capability ^¬ ness. As the polymeric layer 4 is particularly Polyu ^¬ rethane, thermoplastic elastomers, thermoplastic Polyu ^¬ Rethane, or rubber are suitable, especially hydrogenated acrylonitrile butadin rubber, chloroprene, isoprene, ethylene-propylene-diene rubber (EPDM) or fluorine rubber. These polymers provide good damping of the impact energy of the on ^¬ impinging water droplets.

Particularly suitable have metal layers 3 having a thickness of 0.05 to 0.5 mm, in particular of titanium herausge ^¬ represents. Particularly suitable polymer layer 4 ei ^¬ ne polymer layer of polyurethane having a layer thickness Zvi ^¬ rule 0.02 and 1.0 mm has been found. The production of a multilayer layer 2 of rubber and metal can be carried out by pressing the metal with the rubber, wherein the rubber is applied with or without adhesion promoter or primer on the metal layer. In the case of multilayer layers of thermoplastic elastomer, in particular thermoplastic polyurethane, the connection between the layers can be effected by lamination (hot lamination) or compression (hot-pressing) or by means of melting-on bonding techniques by means of other methods. In order to achieve a good connection of the erosion shield 2 with the ^turbine blade 1, an additional layer between the erosion shield 2 and the turbine blade 1 can be arranged at ^¬ play, from fiber mats or resin-impregnated fiber mats (prepregs). 5

Due to the formation of erosion protection 2 as a multilayer with layers of polymer and metallic layers arranged alternately one above the other, an erosion layer results. contactor 2, which has a particularly high formability. This specific property of the multilayer structure allows a simple and rugged geometry adjustment and a full-surface (part-area) applying the erosion ^¬ guard 2 specifically in the field of Anströmkantekante (leading edge) during the bucket manufacturing process or subsequent to the manufacturing process of the turbine blade.

Erosion protection layers or components which are formed from only one or two layers, as is the state of the art, do not offer this high formability, as a result of which adaptation of the erosion protection 2 to the turbine blade 1 is considerably more difficult. In addition, the use of a multilayer with layers of metal and polymer results in particularly good erosion protection. The metallic layer 3 provides through its high hardness for a particularly good mecha ^¬ American protection against drop impact erosion and ensures high energy absorption capability. The polymeric layers 4 ensure that the drops impact energy is attenuated and can not propagate into the fiber composite material of the ^turbine blade. 1 By combining the two layer materials a particularly good erosion ^¬ protection is guaranteed.

FIG. 3 shows a detailed view of the turbine blade 1 shown in FIG. 1. The detailed view shows the leading edge 6 of the turbine blade 1. FIG. 3 shows clearly how the erosion protection 2 fits into the blade contour of the turbine blade 1. The turbine blade 1 is prepared so that after inserting the erosion protection 2, the final blade contour of the turbine blade 1 results. Between the erosion protection 2 and the turbine blade 1 results in a smooth transition without any edge. The flow conditions on the turbine blade 1 thus remain completely intact and tearing off of the flow at the transition from the erosion protection 2 to the turbine blade 1 is avoided. In the exemplary embodiment, the compound Zvi ^¬ rule of the turbine blade 1 and the erosion shield 2 by the lamination of the erosion protection is 2. In addition, the Erosion protection part 2 secured with additional fastening means 7, in particular screws, rivets or pins. The fastening means 7 provide additional security against loosening of the erosion protector 2, in particular in an ^error-¬ exemplary lamination.

The turbine blade according to the invention provides by the Erosi ^¬ onsschutz consisting of at least two polymeric layers and at least two metallic layers which are arranged alternately one above the other, onsschutzbauteilen improved protection against drop impact erosion compared to the previously used Erosi-. The use of the alternately stacked layers results in a particularly high deformation capacity of the erosion protection, whereby a full-surface arrangement of the erosion protection is also possible on kompli ^¬ ed geometric shapes of the turbine blade. Due to the high deformation capacity of the erosion protection, in particular the heavily loaded leading edge of the turbine blade can be effectively protected against drop ^impact erosion. By the use of multilayers he erosion protection turbine blades, which are made of Fa ^¬ server composite material can be used also in Tropfenschlag- prone environment, especially in the wet steam region of condensing steam turbines, without causing premature destruction of the turbine blade.

By selecting a suitable number of alternating layers arranged one above another, iterative erosion protection can take place. Depending on the ambient conditions, more or fewer layers can be arranged alternately one above the other. Another advantage of the alternately stacked layers of metal and polymer is that when it comes to a destruction of a layer, the underlying layer continues to ensure adequate erosion protection, so it does not lead to a rapid destruction of the turbine blade, as in the past erosion protection components used is the case.

Claims

claims

Turbine blade, which at least partially consists of a fiber composite material, comprising an erosion ^¬ protection, which is at least partially disposed on the surface of the turbine blade,

wherein said erosion protection of at least two polymeric layers and at least two metallic layers be ^¬ stands, which are arranged alternately one above the other.

Turbine blade according to claim 1,

characterized in that the outer layer of Erosi ^¬ onsschutzes is a metallic layer.

Turbine blade according to claim 1 or 2,

characterized in that the metallic layer consists of steel, of aluminum, of an aluminum alloy, of titanium, of a titanium alloy, of magnesium or of a magnesium alloy.

Turbine blade according to one of the preceding claims, characterized in that the polymeric layer of poly urethane, a thermoplastic elastomer, in particular a thermoplastic polyurethane, or a rubber, in particular a hydrogenated acrylonitrile butadiene rubber, chloroprene, isoprene, ethylene-propylene-diene rubber ( EPDM) or a fluororubber.

Turbine blade according to claim one of the preceding claims,

characterized in that

the metallic layer has a layer thickness of 0.05-0.5 m.

6. turbine blade according to one of the preceding claims, characterized in that the polymeric layer has a layer thickness of 0.02-1.0 mm.

7. A method of manufacturing a turbine blade according to any one of claims 1 to 6,

characterized by the following process steps:

Manufacturing the turbine blade;

and subsequent or simultaneous

Material and / or positive connection of erosion ^¬ protection with the turbine blade.

8. A method of manufacturing a turbine blade according to claim 7,

characterized in that

the manufacture of the turbine blade and the joining of the turbine blade with the erosion protection by means of a prepreg, resin transfer molding (RTM) or wet lamination process takes place.