WO2007057294A1 - Turbine blade for a steam turbine - Google Patents

Abstract

A turbine blade (10, 110, 210) for a steam turbine, comprising an aerofoil section (12) and a root section (14, 43, 52), is characterized according to the invention in particular in that the aerofoil section (12) is designed for use in a low-pressure stage of the steam turbine and contains fibre composite materials at least in regions.

Description

Turbine blade for a steam turbine

The invention relates to a turbine blade for a steam turbine ^¬ with an airfoil section and a Fußab ^{¬ section} . Moreover, the invention relates to a steam turbine ^¬ turbine with such a turbine blade.

Such turbine blades, in particular designed as blades turbine blades of this type are made in the prior art of steel or titanium. Turbine blades in general and in particular stage blades are exposed to high centrifugal stresses functional reasons, since they are intended to represent the highest possible outflow to achieve a high efficiency and a large display ^¬ coat length must have. High-strength steels are therefore used for common applications. Where these are no longer applicable for reasons of centrifugal stresses, titanium vanes are used, which also experience lower centrifugal force stresses due to the lower density. However, these blades are much more expensive than steel blades. However, even with titanium blades, the outflow surfaces for full-speed machines (50 Hz) are limited to approximately 16 m ² , which entails corresponding consequences for the achievable blade lengths.

Due to the practical limitation with regard to the blade length, the number of low-pressure floods is often increased in the prior art in low-pressure stages of steam turbines. This can be done, for example, by switching from single-flow to double-flow turbine stages or by using several low-pressure turbine parts. Also, the speed of the turbo set can be reduced. In this case larger outflow areas can be used. However, all these measures are associated with sometimes considerable costs. One of the problem underlying the invention is to provide a steam turbine having a turbine blade of the initially named ge ^¬ provide kind, which allows a particularly high efficiency of the steam turbine and can be operated at the same time reliable in operation in the steam turbine.

This object is achieved according to the invention with a generic turbine blade, ^wherein the Schaufelblattab ^{¬ section is designed} for use in a low-pressure stage of the steam turbine and at least partially contains Faserver ^¬ composite material. The object is further achieved according to the invention with a steam turbine having such a fiction, ^¬ contemporary turbine blade.

Fiber composite blades are thus used according to the invention as low-pressure stage or final stage blades. Comparing the relative strengths of different materials clearly shows the advantage of fiber composites for use as a final stage blade material. For example, the FES is ACTION on the density (R _P o, 2 / p) for high-strength Compensation ^¬ steel 115 m ² / s ² for titanium 221 m ² / s ² for the fiber-reinforced material CFK-HM other hand, 563 m ² / s ² . Due to the Wesent ^¬ Lich higher strength of the fiber composite material can either be utilized with conventional dimensions turbine blades made higher or the turbine blades are made with a greater length. The thereby passing on ^¬ centrifugal stresses may density ratio are then added in the blade or vane without sacrificing reliability readily available from the turbine due to the substantially increased strength /.

Due to the high strength / density ratio of OF INVENTION ^¬ dung according fiber composite material containing turbine acting ^¬ fel can be provided due to the design of the airfoil section for use in a low pressure stage of the steam turbine in spite of the high centrifugal stresses is a greatly enlarged outflow. This can be done in particular by providing a particularly large blade length. hen. Thus, the efficiency of the steam turbine can be significantly increased.

In the field of industrial turbines, for example, by allowing a higher counter-pressure of the output stages (air-cooled), turbines by a higher allowable rotation speed of the drive ^¬, or by increasing the stage blades for variable speed drives by the inventive Ver ^¬ of the fiber composite material application to a turbine blade of predetermined dimension higher be utilized. This also results in a higher efficiency of the steam turbine.

As already mentioned, there is the potential for a very considerable extension of existing final-stage blades for the area of power plant turbines, along with a substantial increase in the achievable outflow areas. For example, half speed previously executed Turbo ^¬ can rates with flow-off of 20 m ² per flood using the inventive ER turbine blades by the same volltourige turbine sets outflow be replaced. Due to the smaller size of full-speed turbo sets a erhebli ^¬ che cost savings is possible. The number of low-pressure floods can also be reduced by using the turbine blades according to the invention. For multi-flow power plant ^¬ applications, for example, one of three low-pressure parts can be saved. Low-pressure twin-flow turbines can also be replaced by single-flow machines, which can also result in significant cost savings. In addition, by means of the invention

In any case, a reduction in the size of the system with the same outflow cross-section can be achieved.

The turbine blade according to the invention is particularly suitable for the last row of blades of a steam turbine, but can also be used according to the invention for the second and possibly the third last row of blades. You can just ^¬ if combined with precursor blades made of steel or titanium become. The present invention at least partially Faserver ^¬ composite material containing the airfoil section of the turbine blade OF INVENTION ^¬ to the invention preferably has at least in the outer wall area of the fiber composite material. Advantageously, the entire airfoil section can also be made

Consist of fiber composite material. Further advantageously assumes ^¬ legally at leaner werdendem the blade tip blade ^¬ sheet section the number of fibers in the longitudinal direction of the aerofoil section from.

The aforementioned object is further achieved according to the invention with a generic turbine blade, in which the blade section at least partially Faserver ^¬ composite material, wherein at least the fiber composite material containing area is surrounded with a deformable moisture-impermeable protective layer, the selection of moisture in the fiber composite currency ^¬ prevents the operation of the turbine blade. In addition, the object is achieved with a steam turbine, which is provided with such a turbine blade.

Thus, a moisture absorption of the Schaufelblattab ^{¬ section} can be effectively prevented during operation in the steam turbine ver ^¬ . Moisture absorption is an undesirable time-dependent process that can cause weight gain of the component and thus potential rotor imbalance. May further such moisture uptake a deformation of the fiber composite material, as well as exemplary in continuous ^¬ action cause the damage to the matrix and thus a failure of the fiber composite material containing the component. The inventive provision of a ^{moisture-¬-impermeable} protective layer, the above run on ^¬, the reliability of the steam turbine will jeopardize ^¬ avoided the consequences. So that the protective layer endures the to be expected deformations of the basic material of Schaufelblattab ^¬ section without damage or loss of their sealing function, the protective layer of the invention is designed Transform ^¬ bar. Here, the protective layer is within the meaning of In such a way that the protective layer does not lose its moisture impermeability over its service life, despite deformations of the area of the airfoil section containing the fiber composite material occurring during operation of the blade. This can be achieved in particular by the protective layer has a elas ^¬ tables application range which exceeds the elongation unused area of the base material. In addition to the invention by the use of the fiber composite material in the airfoil portion enabled larger steam turbine efficiency, the inventive embodiment of the turbine blade to be used particularly reliably by the invention further damp ^¬ tigkeitsundurchlässige protective layer.

Advantageously, the moisture-repellent protective layer encloses the airfoil section completely. Moreover, it may also be desirable for the protective layer to cover the entire turbine blade, i. also the blade foot, encloses. In accordance with the invention advantageous embodiment, the protective layer should be designed so that a secure adhesion of the protective layer is given even in drops. Furthermore, the design of the base material of the airfoil section should be such that continued droplet impacts do not cause any fatigue or disruption of the base material.

The aforementioned object is further achieved according to the invention with a generic turbine blade, in which both the airfoil section and the foot section in each case at least partially contains fiber composite material. In addition, the object is achieved with a steam turbine, which is provided with such a turbine blade.

The use of fiber composite material in the blade ^¬ sheet section due to the low density of the fiber composite material may, as already mentioned above, the ^turbine blade with a large outflow surface be designed. This increases the efficiency of the steam turbine. Furthermore, a correspondingly secure and reliable anchoring of the turbine blade in the rotor shaft of the steam turbine can be ensured by the simultaneous use of fiber composite material in the root section of the turbine blade. In particular, fibers of the fiber composite material by ^¬ be continuously fed through the airfoil portion and the root portion so that the aerofoil section and the root section received a stable connection and a brief outline of the aerofoil section during the operation of the turbine shop ^¬ fel itself can be effectively prevented the occurrence of large forces. The operational reliability of the ^turbine blade is guaranteed in operation.

In order to ensure the resistance to breakage of the components of the fiber composite contained enthal ^¬ , the fiber composite ^¬ material advantageously contains glass fibers, plastic fibers, such as aramid fibers, and / or plastic fibers. In particular, the fiber-reinforced material CFK-HM can be used as a fiber composite material.

In a further advantageous embodiment of the composite fiber material has fibers which in the region of the display ^¬ felblattabschnittes under a binenschaufel deviating from a main axis of the turbo angular, in particular

Angle ± 15 °, ± -30 ° and / or ± 45 ° relative to the main axis are performed. For a high torsional rigidity of the airfoil section is achieved. The fiber composite layers Kgs ^¬ NEN arranged mirror-symmetrically to the sheet surface means the advertising, thereby twisting avoided.

An asymmetric arrangement, however, leads to distortion. This may optionally be used for self-tuning purposes in an advantageous alternative embodiment. By the nature of the arrangement of such fibers or plies of the anisotropy can also be used to within a limited range, to achieve a targeted change of the blade geometry in Ab ^¬ dependence on the operating stresses. This- With regard to such a twist can be provided, in which the blade grid opens at overspeeds, so that the flow of less energy and thus does not contribute to a further run-up. Likewise, the twisting can be used to adjust an optimized flow profile depending on the flow and load. Thus, for example, the blade grid can be closed with a smaller flow and be opened correspondingly with a larger flow.

In order to achieve a cost and stiffness optimization of the blade, it is expedient if the blade blade section has a packing arranged in the middle of the blade, which is completely enclosed by the fiber composite material.

In order to be able to monitor the function of the deformable moisture-impermeable protective layer surrounding the area with the fiber composite material and to preclude failure of the airfoil section, it is expedient if an electrically conductive layer is arranged under the protective layer. This electrically conductive layer serves as Warnmecha ^¬ mechanism, whereby damage to the protective layer can be detected, after which countermeasures, such as a replacement or replacement of the affected component, or a repair of the protective layer can be taken in time. Such an electrically conductive layer can individually either a ^¬ or be provided in pairs with an intermediate insulating layer.

In the latter case results for the layer structure of the airfoil section in the surface region thereof a successive arrangement of the fiber composite material, an electrically conductive, in particular metallic layer, an insulating layer, another electrically conductive, in particular metallic layer and the protective layer. To monitor the function of the protective layer, the insulation resistance to the environment or between the two electrically conductive layers can then be measured. Also, the electrical capacity of the electrically conductive layer, the insulating layer, and the further electrically conductive layer comprising arrangement for monitoring the function of the protective layer are measured. With the provision of only one electrically conductive layer ge ^¬ the function of the protective layer has in accordance with the measurement of the insulation resistance genüber surroundings or of the electrical resistance of the electrically conductive layer for flame supervision.

In a further advantageous embodiment, water-soluble chemical substances are arranged under the protective layer, which are detectable in dissolved form, in particular in a chemical, optical and / or radiological manner. This measure represents an alternative monitoring possibility of the function of the protective layer. Thus, for example, the condensate of the water-steam circuit of the steam power plant can be continuously checked ^¬ . If the chemical substances arranged under the protective layer are detectable in this, this indicates damage to the protective layer.

In a further expedient embodiment, a leading edge of the turbine blade is provided with an edge reinforcement for protection against droplet impact. Such edge reinforcement may be provided by adhering to the turbine blade or by laminating into the turbine blade. Also, such an edge reinforcement can be made by means of a sealed protective or intermediate layer. Furthermore, it is possible to thicken the protective layer entspre ^¬ accordingly or glue or embed aufzu- an additional protection device. Also, the basic component of the turbine blade itself can be designed with a turbine-like edge reinforcement. Alternatively, protection against gobbing may be achieved by a laminate construction of the turbine blade in which the fibers are transverse.

Furthermore, it is expedient if the foot portion of the turbine blade ^¬ nenschaufel a contact element for making contact with a Schaufelfußhalterung in a rotor shaft of a Steam turbine, wherein the contact ^element fiber composite ^¬ material and / or contains a metallic material. Optionally, the contact element made of fiber composite or metallic materials. The corresponding metallic materials should be chosen such that they allow a stable and dimensionally stable connection to the rotor shaft and prevent overstressing of the fiber composite surrounding the contact element of the blade root. In particular ^¬ sondere the contact element can be constituted by a metallic sleeve. When providing the deformable moisture-impermeable protective layer described above, this should advantageously be reinforced in the foot area, in particular in the contact area, or protected against damage by protective elements.

In a particularly advantageous embodiment of the root section has a deflection element by means of which a substantial An ^¬ is paid diverted from fibers of the airfoil, and / or a guide element, by means of which an advantageous fiber routing in the blade root in a to the geometry of the blade ^¬ sheet section adapted to the fiber guide is redirected to. Also, the deflecting element and / or the guide element may each consist of fiber composite material or a metallic material. In particular, the contact element and the guide element or the contact element and the deflecting ^¬ element can each be formed by the same element.

Advantageously, the root portion of plug ^¬ is still running foot, the radially into a blade root mounting of a rotor shaft of the turbine in relation to the rotor shaft direction is inserted. Conveniently, the fibers of the fiber composite material are guided around serving as contact elements sleeves. Furthermore, in the case of such a plug-in foot, the curvature of the leaf in the foot region can advantageously be modeled by an assignment to different pin positions of the plug-in foot, so that advantageously low deflections from the foot region to the leaf region are achieved. give. The effort for guide elements remains so ^¬ limited.

In an advantageous embodiment, the deformable moisture-impermeable protective layer also surrounds the Fußab ^¬ cut. So the penetration of moisture is also contained in the root portion of a fiber composite material we ^¬ kung prevented. As a result, the life of the turbine blade can be further increased.

In a further advantageous embodiment, the foot section of the turbine blade is designed as a sliding foot, which can be inserted into a blade root holder of a rotor shaft of the turbine in a direction substantially axial with respect to the rotor shaft. Under substantially axial direction is to be understood that the insertion direction can deviate by up to + 40 ° from the axial direction. In particular, the foot portion is curved, with the foot curvature substantially following the curvature of the airfoil portion present in the vicinity of the foot. By deflection and contact ^¬ elements power transmission is achieved on blade grooves. Contact elements and the function of Füh ^¬ can approximate elements perceive. This minimizes the cost of guide elements.

In an advantageous embodiment of the steam turbine according to the invention, this has a device for monitoring the vibration behavior of the turbine blade. Thus, a change in the natural frequency of the turbine blade can be detected, which may be due to a moisture absorption of the fiber composite ^¬ material in the airfoil section during operation of the steam turbine. Such amendments ^¬ tion to the natural frequency of the turbine blade should then be taken as an opportunity to check the functionality of the aforementioned deformable moisture-impermeable protective layer and the protective layer, if necessary, to repair, so that a failure of the component can be prevented. In a further advantageous embodiment, the steam turbine has at least one heatable guide blade. By heating, moisture on the guide vane ver ^{¬ be} evaporated and a corresponding damage to other turbine blades are prevented by gushing.

Alternatively, a device for extracting moisture on at least one vane may be provided.

The preparation of the fiber composite blades preferably with the conventional methods in which fibers wound and impregnated with the matrix material or in the form of so-called prepregs ^¬ be applied. Thereafter, they are brought in a so-called die in its final form, whereby a curing of the matrix takes place. For this purpose, optional contact, deflection or guide elements are already inserted or attached. Thereafter, it may be necessary to edit the blades at certain points, eg by grinding, in order to achieve, for example, the required dimensional accuracy, tolerance compliance and surface quality. Also already mounted contact, deflection or guide ^¬ elements can be edited or these elements after the molding ^¬ gebungsvorgang be attached. As mentioned above, he imagines ^¬, an edge protector to be mounted further, which is integrated by subsequent Anpassarbeit, such as by fen mucilages in the blade profile. This is followed by coating with the layers required for the protective layer and the warning system. In this case, individual layers can be reinforced at certain points in order to improve protection or amplification functions.

Exemplary embodiments will be described an inventive ^¬ SEN turbine blade with reference to the accompanying diagrammatic drawings.

It shows:

1 is a view of a first embodiment of a turbine blade according to the invention, 2 shows the section II-II of FIG. 1,

2a shows a first embodiment of the detail X of FIG. 2,

2b shows a second embodiment of the detail X of FIG. 2,

2c shows the detail Y according to FIG. 2, FIG.

3a shows a partial view of a second embodiment of the turbine blade according to the invention,

3b shows the section III-III of FIG. 3a,

4a is a sectional view of a third Ausführungsbei ^¬ game of a turbine blade according to the invention with a view towards the foot portion of the blade,

4b is a sectional view of a rotor shaft of a

Steam turbine in the region of a shaft groove with a foot section of a turbine blade according to FIG. 4 a fastened therein, as well as

4c shows the detail Z according to FIG. 4b.

Fig. 1 shows a first embodiment of a modern turbine blade of invention 10 which in particular for the dung USAGE ^¬ is designed in a low-pressure stage of a steam turbine. The turbine blade 10 comprises a Schaufelblattab ^{¬ section} 12 and a foot portion 14 in the form of a plug foot. The foot section 14 has insertion tabs 16 for a pin connection. The airfoil section 12 is made of fiber composite material 18 containing glass fibers and / or carbon fibers. The main fiber direction 20 runs along a main axis 21 of the turbine blade 10. In a region near the root portion 14 has the blade ^¬ sheet section 12, a additional fiber composite sheet 22. The set-fiber composite sheet to ^¬ 22 includes additional fibers which under deviant angle to the main axis 21 of the turbine blade or vane 10, for example, are extending at an angle of ± 15 °, ± 30 ° or ± 45 ° and are provided for stiffening the aerofoil section 12th It is also possible to provide a plurality of such additional fiber composite layers 22. In this case, these layers can be arranged mirror-symmetrically to the blade center surface, whereby a distortion is avoided. An asymmetrical arrangement of the additional fiber composite layers leads to a twist. This may possibly be used for self-adjustment purposes.

Fig. 2 shows the section II-II in the aerofoil section 12 of FIG. 1. This shows a large sheet thickness in the range for weight and stiffness optimization arranged packing 24. This is ben 18 vice ^¬ from the fiber composite material. The turbine blade 10 is flown by means of turbine steam 26 according to FIG. 2 from the left. To protect against Trop ^¬ fenschlag which the inflowing steam turbine 26 facing the leading edge of the turbine blade 10 having an edge reinforcement is provided ^¬ 28th Edge reinforcement 28 is shown in greater detail in FIG. 2c. Is composed of metal and is of the turbine show ^¬ fel fixed by means of an adhesive compound 40 with a bonding faserverbundge- right outlet 42 at the leading edge 27 10th

FIG. 2a 2 illustrates a first embodiment of assembly construction of the turbine blade 10 of FIG. Oberflä in a ^¬ chenbereich thereof. The inner fiber composite material 18 is surrounded by a first electrically conductive layer 36 in the form of a metallic layer, an Iso ^¬ lationsschicht 34, a second electrically conductive layer 32 in the form of a metallic layer, and finally a protective layer 30. The protective layer 30 is moisture-repellent for sealing the Schaufelblattab ^{¬ section} 12 performed against liquid. The protection So that layer 30 prevents the penetration of moisture into the composite fiber material 18. Further, the protective layer formed so ^¬ deformable 30 so as to the currency ^¬ rend the operation of the turbine blade 10 deformations anticipated encryption compensates without loss of its sealing function. The sequential arrangement of the electrically conductive layer 32, the insulating layer 34 and the electrically lei ^¬ Tenden layer 36 serves to monitor the function of the protective layer 30. For this purpose, the insulation resistance of the electrically conductive layers 30, 32 from the environment or between the layers or measured the capacitance of the layer assembly to determine whether moisture has penetrated through the protective layer 30 in the interior of the airfoil section 12.

FIG. 2b shows a second embodiment of the construction of the turbine blade 10 according to FIG. 2 in a surface area thereof. Here, the fiber composite material 18 is surrounded by a layer of indication material 38, which in turn is surrounded by the protective layer 30. The indication material 38 is in the form of water-soluble substances which are detectable in dissolved form in a chemical, optical and / or radiological manner. The indication material 38 thus serves to detect a leak in the protective layer 30. That is, moisture penetrates into the interior of the protective layer

Blade sheet ^portion 12, so the water-soluble chemicals of the indication material 38 are dissolved and Kings ^¬ nen be detected in the condensate from the steam leaving the turbine.

Fig. 3a shows a second embodiment of a turbine blade OF INVENTION ^¬ to the invention to a 110th only partially ge ^¬ showed aerofoil section 12 with a fiber composite material 18, a foot portion 43 connects. The fibers of the fiber composite material 18 are, starting from the scene ^¬ felblattabschnitt performed in the foot section 43 and 12 therein whereupon the fiber guided around a contact and deflection element 46 in the form of a metal ^¬ metallic sleeve, then again runs back into the airfoil section 12. The element 46 thus fulfills a deflection function. At the same time it also fills a contact function in which it makes contact with a shaft groove 48 of a rotor shaft 47 of a steam turbine. Further towards 3a includes the turbine blade 110 shown in FIG. A so-called. Guide member 44 by means of which an advantageous Faserfüh ^¬ tion in the blade root in a 12 adapted fiber guide of the fiber composite ^¬ material is diverted 18 to the geometry of the blade ^¬ blade portion.

In Fig. 3b the section III-III of Fig. 3a is shown. The foot portion 43 is designed in the form of a plug foot with plug-in ^¬ tabs 45 for insertion into corresponding transverse to a longitudinal axis 50 of a rotor shaft 47 extending grooves 48. The push-in tabs 45 are then secured in the shaft grooves 48 by means of insertion pins arranged transversely thereto. Each of these plug-in feet 45 has one of the contact and deflection elements 46.

In Fig. 4a, a third embodiment of an inventions to the invention ^¬ turbine blade 210 is illustrated with a foot portion 52 in the form of a sliding foot. The Fußab ^{¬ section} 52, the detail in Fig. 4b in sectional view Darge ^¬ represents is inserted into a running in the axial direction of the rotor shaft shaft groove 60. The foot section 52 is provided with a curvature, as shown in Fig. 4a and has a deflecting element 56 around which a substantial number of fibers of the fiber composite material 18 is guided around. These fibers are surrounded by a guide or contact element 54. This element initially fulfills the function of redirecting an advantageous fiber guide in the foot section 52 into a fiber guide adapted to the geometry of the blade section 12. Furthermore, the element 54 fulfills the function of making contact with a shaft groove 60 of the rotor shaft 58. The guide and contact element 54 completely surrounds the fiber composite material 18 of the foot section 14 and also adjoins the fiber composite material 18 in the lower region of the fiber blade leaf section 12. This area is shown in more detail in Fig. 4c. To case of deformations of the aerofoil section 12 no Beschädi ^¬ conditions of the guide and the contact element 54 or of the fiber composite material causing 18, a gap 62 between the fiber composite material 18 and the element 54 is provided.

Claims

claims A turbine blade (10, 110, 210) for a steam turbine having an airfoil portion (12) and a foot portion (14, 43, 52), characterized in that the airfoil portion (12) is designed for use in a low pressure stage of the steam turbine and at ^¬ least partially fiber composite material (18) contains. 2. turbine blade (10, 110, 210) for a steam turbine with an airfoil section (12) and a foot section (14, 43, 52), in particular according to claim 1, characterized in that the blade blade section (12) at least partially fiber composite material (18), wherein at least the fiber composite material (18) enthal ^¬ tende range of a deformable moisture-impermeable protective layer (30) which prevents the penetration of moisture into the fiber composite material (18) during operation of the turbine blade (10, 110, 210). 3. turbine blade (10, 110, 210) for a steam turbine with an airfoil section (12) and a foot section (14, 43, 52), in particular according to claim 1 or 2, characterized in that both the blade blade section (12) and the Fußab ^¬ cut (14, 43, 52) each at least partially fiber composite material (18). 4. turbine blade according to one of the preceding claims, characterized in that the fiber composite material (18) glass fibers, plastic fibers and / or carbon fibers contains. 5. Turbine blade according to one of the preceding claims, characterized in that the fiber composite material (18) comprises fibers in the region of the airfoil section (12) under one of a major axis (21) of the turbine blade (10, 110, 210) deviating angle, in particular at angles of ± 15 °, ± 30 ° and / or ± 45 ° to the main axis (21). 6. turbine blade according to one of the preceding claims, characterized in that the airfoil section (12) has a arranged in the middle of the sheet filler (24) which is completely enclosed by the fiber composite material (18). 7. Turbine blade according to one of claims 2 to 6, characterized by an under the protective layer (30) arranged electrically conductive layer (32, 36). 8. Turbine blade according to one of claims 2 to 7, characterized in that below the protective layer (30) water-soluble chemical substances (38) are arranged, which are detectable in dissolved form, in particular in a chemical, optical and / or radiologi ^¬ cal manner , 9. turbine blade according to one of claims 2 to 8, characterized in that a leading edge (27) of the turbine blade (10, 110, 210) is provided with an edge reinforcement (28) for protection against droplet impact. 10. turbine blade according to one of the preceding claims, characterized in that the foot portion (14) has a contact element (46, 54) for producing a contact with a Schaufelfußhalterung (48, 60) in a rotor shaft (47, 58) of a steam turbine, wherein the contact element (46, 54) comprises fiber composite material (18) and / or a metallic material. 11. turbine blade according to one of the preceding claims, characterized in that the foot portion (14, 43, 52) a deflecting element (46, 56), by means of which a substantial number of fibers of the Schau ^¬ felblattabschnitts (12) is deflected, and / or a guide element (44, 54) by means of which an advantageous fiber guide in the foot section (14, 43, 52) is diverted into a fiber guide adapted to the geometry of the airfoil section (12). 12. Turbine blade according to one of the preceding claims, characterized in that the foot portion (14, 43, 52) as a plug foot (14, 43) is out ^¬ leads, in a Schaufelfußhalterung (48) of a rotor shaft (47) of the turbine in respect the rotor shaft (47) radial direction can be inserted. Turbine blade according to one of the preceding claims, characterized in that the moisture-repellent protective layer (30) also surrounds the foot section (14, 43, 52). 14. Turbine blade according to one of the preceding claims, characterized in that the foot portion (14, 43, 52) is designed as a sliding foot (52) in a Schaufelfußhalterung (60) of a rotor shaft (58) of the turbine with respect to the rotor shaft (58) can be inserted substantially in the axial direction. 15. Steam turbine with a turbine blade (10, 110, 210) according to one of the preceding claims. 16. Steam turbine according to claim 15, characterized by means for observing the vibration behavior of the turbine blade (10, 110, 210). 17. Steam turbine according to claim 15 or 16, characterized by at least one heatable guide vane.