EP2644834A1 - Turbine blade and corresponding method for producing same turbine blade - Google Patents

Abstract

The turbine blade (10) has a mounting section (14), a platform (16) and a blade body (18), which follow each other along a longitudinal axis (12) of the turbine blade. The platform has an inner platform section (22) and an outer platform section (24) with respect to the longitudinal axis. The outer platform section is formed as an endless platform frame (28) engaging around an outer edge (26) of the inner platform section. The platform frame rests flat on the inner platform section. The contact surface forms an angle partially with the longitudinal axis. An independent claim is included for a method for manufacturing a turbine blade.

Description

The invention relates to a turbine blade with a mounting portion, a platform and an airfoil, which follow one another along a longitudinal axis of the turbine blade. The invention further relates to a method of manufacturing a turbine blade, comprising the step of producing a monolithic fuselage blade comprising an airfoil, a platform and a mounting section.

Turbine blades and methods of making turbine blades are known in a variety of ways from the extensive prior art. For example, turbine blades for gas turbines are often produced in a casting process. During casting, the blade root, platform and blade are formed from the casting material at the same time, so that such turbine blades are in one piece. Subsequently, the surfaces exposed to the hot gas of the turbine are still provided with a corrosion protection layer and a thermal protection layer in order to increase the service life of the turbine blade. The cast turbine blades are usually also hollow, so that a means for cooling the blade material can flow inside. Turbine blades of steam engines are mostly milled from solid or forged.

The turbine blades used in stationary turbomachinery are subject to a variety of stresses during operation of the turbomachinery which cause the turbine blades to age and wear down in both predictable and unpredictable ways.

In detail, both low-cycle and higher cyclic fatigue loads as well as thermo-mechanical loads occur. Also, turbine blades are to be protected from oxidation and creep. The above-mentioned loads relate in particular to the surfaces and components of the turbine blades which are directly exposed to the hot gas or superheated steam. On the mounting side, turbine blades are also exposed to so-called "bearing loads" and "friction loads". In the light of these varying loads and requirements, the material of integral turbine blades must be selected so that, if possible, a large number, if not all, loads are absorbed by the material without premature aging or premature end-of-life of the turbine blade being achieved. With regard to the thermal load and with regard to the corrosion load, it is known, for example, to equip turbine blades of gas turbines with a layer system which protects their material against corrosion as well as against excessive heat input.

Nevertheless, in various areas of the turbine blade wear such as cracks can occur, which jeopardize the operation of the turbomachine. For this reason, it is known to check turbine blades for such a defect after a predetermined period of use and to replace or reprocess the affected turbine blades in the presence of such a finding.

It is also known to design turbine blades modular and to produce the corresponding modules from those materials that are tailored to their local requirements. Here, however, there is often a lack of a permanent and reliable connection.

The object of the invention is to provide a turbine blade with a fastening portion, a platform and an airfoil, which follow one another along a longitudinal axis of the turbine blade, which turbine blade with particularly low effort is reprocessed. Another object of the invention is to provide a method of manufacturing turbine blades.

The task directed to the turbine blade is achieved with such according to the features of claim 1. The object directed to the method for producing a turbine blade is achieved with the method steps according to claim 8. Advantageous embodiments are specified in the respective subclaims. The features of the respective subclaims with the features of other claims are readily combinable.

The invention is based on the finding that, in particular in the case of operationally stressed turbine blades, it is also possible for defects caused by oxidation to occur at the outer edge of the platform. These oxidation problems occur, in particular, when the thermal insulation layer, which is often provided there, locally flakes off. Such findings can lead to an increased operating risk in the turbine blade, which is why such turbine blades are replaced or processed. The reprocessing of the turbine blade has been comparatively expensive. At the same time, the work-up rate, i. the proportion of recycled blades that actually continue to qualify for use in the turbomachinery after reprocessing is likely to be low. To counteract these effects, it is proposed with the invention that the platform comprises - in relation to a central longitudinal axis - an inner platform part and an outer platform part, the outer platform part being designed as an endless platform frame encompassing the outer edge of the inner platform part.

If an operationally loaded turbine blade is to be worked up in the region of the edge of the platform, the flaws indicated above near the edge of the platform are to be removed, for example by passing the edge of the platform Milling or grinding is reset. According to the invention it is provided that not only the local defect is removed when resetting the edge of the platform. Rather, the platform edge is reset along the entire circulation so as to produce a monolithic fuselage bucket whose platform provides an abutment surface for a platform frame as an inner platform part of the turbine bucket to be produced. After attaching an endless platform frame to the inner platform portion, the turbine bucket thus produced then has a platform whose dimensions correspond to the original turbine bucket.

Although not impaired or damaged blade material is removed in this process. However, this has the advantage that the reprocessing does not have to be performed individually - that is, depending on the defective location - but can be automated. This reduces the effort for reprocessing and the reject rate.

Of course, according to the method, it is also possible to produce new components, ie turbine blades not subjected to operation, by first providing a so-called fuselage blade comprising an airfoil, a platform and a fastening section in a monolithic embodiment. The monolithic fuselage bucket can be produced conventionally by casting and, for example, also be monocrystalline or directionally solidified. After making the fuselage shovel, the platform edge of the fuselage shovel may need to be brought to the predetermined, exact extent along the entire cycle by slight grinding or milling to provide the inner platform portion of the turbine bucket with a dimensionally bearing surface for the platform frame. Before, during or after the platform frame is to produce as a mostly rectangular structure. After attaching or mounting the platform frame to the dimensionally stable edge of the inner platform part, the turbine blade is then produced as a new component.

The platform frame may have different shapes in cross section. Preferably, however, such forms, which bring about a positive connection with the edge of the inner platform part. For example, the cross-sectional shape may be diamond-shaped or C-shaped. The edge of the inner platform part is always executed corresponding to the cross-sectional shape.

A particular advantage of the turbine blade according to the invention and also of the method is that in particular also two different materials can be used for the fuselage bucket and for the platform frame. Thus, in addition to the different local loads consideration be taken, which possibly leads to an extended life of the turbine blade.

A further advantage of the turbine blade according to the invention is the higher precision with regard to the external dimensions of the platform, since these can be produced more easily when producing the platform frame than when casting a purely monolithic turbine blade.

Different methods can be used for permanently connecting the platform frame to the fuselage bucket. Since the platform frame is designed as an endless frame, it is preferable to shrink the platform frame to the peripheral edge of the inner platform part. Prior to shrinking, the platform frame may be heated and / or the fuselage shovel may be cooled. After assembly of the platform frame and fuselage bucket and subsequent temperature adjustment, the platform frame then sits firmly against the peripheral edge of the inner platform portion. Also soldering and welding - at points as well as along the connecting line from the edge of the inner platform part and platform frame - are possible.

According to a first advantageous development of the platform frame is flat against the inner platform part, wherein the contact surface at least partially encloses an angle with the longitudinal axis which is greater than 0 ° and less than 90 °. Such an arrangement prevents at least in one direction a parallel displacement of the platform frame along the longitudinal axis, which is particularly advantageous when using the invention on turbine blades. In this case, the centrifugal force acting on the platform frame during operation of the turbomachine is also transferred into the platform part by positive engagement due to the contact surface inclined with respect to the longitudinal axis. This reliably prevents the loss of the platform frame due to the centrifugal force.

Preferably, the angle is a size between 15 ° and 35 °, for example, the angle is 20 °.

According to a second advantageous development of the platform frame on at least one laterally outwardly facing surface on a slot for receiving a sealing element. Such a configuration has the advantage that when worn by existing in the platform edge slots due to the seated therein sheet-shaped sealing elements with the now provided invention is a simple and reliable way to work up even such betriebsbeanspruchte turbine blades again. In addition, such slots can be produced more cost-effectively than with purely monolithic turbine blades.

Conveniently, the turbine blade may be formed both as a vane or as a blade.

In order that the turbine blade with the inner platform part and the outer platform part in the form of the endless platform frame enclosing the inner platform part can also be used in high-temperature applications, it is advantageous if the inner platform part and the platform frame are coated in a coating process. Thus, can a seamless protective layer can be applied to both platform parts.

Figur 1

in perspektivischer Darstellung die Seitenansicht auf eine erfindungsgemäße Turbinenschaufel,

Figur 2

in perspektivischer Darstellung die Draufsicht auf einen Plattformrahmen,

Figur 3

den Querschnitt durch eine Turbinenschaufel gemäß Figur 1 und

Figur 4

einen Ausschnitt von der Ecke einer Plattform der Turbinenschaufel nach Figur 1 beim Zusammensetzen von Rumpfschaufel und Plattformrahmen.

Further advantages and features of the invention are given in the description of the figures. Show it:

FIG. 1

in a perspective view the side view of a turbine blade according to the invention,

FIG. 2

in a perspective view the top view of a platform frame,

FIG. 3

the cross section through a turbine blade according to FIG. 1 and

FIG. 4

a section from the corner of a platform of the turbine blade behind FIG. 1 when assembling the fuselage bucket and platform frame.

In all figures, identical features are provided with the identical reference numerals.

FIG. 1 shows a perspective view of a turbine blade 10. The turbine blade 10 is formed as a blade. However, it could also be designed as a guide vane. The turbine blade 10 comprises, along its longitudinal axis 12, a fastening section 14, a platform 16 and an airfoil 18 in direct succession. The mounting section 14 is contoured in a manner typical of a blade in the manner of a fir tree profile. Guide vanes for turbines, instead of the fir-tree-shaped attachment portion 14 mostly a plurality of hooks, which are inserted into a not shown guide vane carrier of the turbomachine.

The attachment portion 14 merges into the platform 16. According to the in FIG. 1 selected representation, the platform 16 has an upwardly facing platform surface 20, where the blade 18 settles. In the illustrated embodiment, the platform 16 includes an inner platform portion 22 and an outer platform portion 24 radially relative to the longitudinal axis 12, the outer platform portion 24 being formed as an endless platform frame 28 encompassing the outer edge 26 of the inner platform portion 22. According to the illustrated embodiment, both attachment portion 14, the inner platform portion 22 and the blade 18 are monolithic - that is, in one piece - formed. This monolithic unit is also referred to as a fuselage bucket 19. The surfaces 20 of the inner platform part 22 and of the outer platform part 24 pointing in this illustration to the blade leaf 18 are mutually offset so that they - when using the turbine blade 10 in a turbomachine - have an edge-free and boundary-free boundary wall for the working medium flowing in the turbomachine provide.

The turbine blade 10 may be formed internally cooled in any way by means of a cooling medium. Film cooling openings and trailing edge openings for coolant can also be provided. Of course, the turbine blade can also be uncooled.

FIG. 2 shows in perspective view the platform frame 28. The platform frame 28 comprises two mutually parallel longitudinal struts 30 and two mutually parallel transverse struts 32. The platform frame 28 may be made of a different material than those in FIG. 1 illustrated fuselage bucket 19. The platform frame 28 may also be made of the same material. The platform frame may also be made by welding the longitudinal struts 30 to the cross struts 32. It can also be cast or milled from solid.

FIG. 3 shows a section through the turbine blade 10 along the longitudinal axis 12. In contrast to the in FIG. 1 shown turbine blade is the mounting portion according to FIG. 3 not fir-tree-shaped, but dovetail-shaped. In addition shows FIG. 3 the platform frame 28 during assembly to the fuselage 19, just before the platform frame 28 reaches its final mounting position. According to the illustrated embodiment, the platform frame 28 has a diamond shape in cross section. Other shapes are possible.

Each strut 30, 32 of the platform frame 28 has an inwardly directed first abutment surface 34 and a second abutment surface 36. Likewise, the outer edge 26 of the inner platform portion 22 has a laterally outwardly facing first abutment surface 38 and a second abutment surface 40. After assembly of the platform frame 28 are the first bearing surface 34 on the first abutment surface 38 of the inner platform portion 22 and the second abutment surface 36 on the second abutment surface of the inner platform portion 22 on a flat. The thus forming first contact surfaces and second contact surfaces are inclined differently with respect to the longitudinal axis 12. The first contact surface is aligned in cross section parallel to the longitudinal axis 12. The second contact surface is inclined in cross-section, however, at an acute angle α with respect to the longitudinal axis 12. This embodiment also prevents by positive engagement, the release of the platform frame 28 of the fuselage blade 19 when acting on the turbine blade 10 centrifugal forces.

FIG. 4 shows in perspective a corner of the inner platform part 22 and the platform frame 28 during assembly. In addition to the features already described is also in FIG. 4 on a laterally outwardly facing surface 42 of the platform frame 28, a slot 44 for receiving a sheet-like sealing element shown.

Overall, the invention thus relates to a turbine blade 10 having a mounting portion 14, a platform 16 and an airfoil 18, which follow one another along a longitudinal axis 12 of the turbine blade directly on each other. To one To provide particularly durable turbine blade 10, it is proposed that the platform 16 - in relation to the longitudinal axis 12 - an inner platform portion 22 and an outer platform portion 24, wherein the outer platform portion 24 as an outer edge 26 of the inner platform portion 22 encompassing endless Platform frame 28 is formed. With regard to the method, it is proposed to use a monolithic manufactured fuselage shovel 19 or to adjust or reset an already operational turbine bucket 10 along the entire circumference of the platform rim and to produce an endless platform frame 28, which can subsequently be mounted to the platform edge 26, thus retaining the original ones or scheduled dimensions of the turbine blade 10 produce.

Claims (12)

A turbine blade (10) having a mounting portion (14), a platform (16) and an airfoil (18) which follow one another along a longitudinal axis (12) of the turbine blade (10),
characterized in that
the platform (16) comprises - in radial relation to the longitudinal axis (12) - an inner platform part (22) and an outer platform part (24), the outer platform part (24) acting as the outer edge (26) of the inner platform part (24). 22) encompassing endless platform frame (28) is formed. Turbine blade (10) according to claim 1,
in that the platform frame (28) bears flat against the inner platform part (22) and the contact surface at least partially encloses an angle with the longitudinal axis (12) which is greater than 0 ° and less than 90 °. Turbine blade (10) according to claim 2,
in which the angle has a size between 10 ° and 35 °. Turbine blade (10) according to claim 1, 2 or 3,
in the
the inner platform portion (22) and the attachment portion (14) and / or
the inner platform portion (22) and the airfoil (18) are monolithic. Turbine blade (10) according to one of the preceding claims,
wherein the platform frame (28) has a slot (44) for receiving a sealing element on at least one laterally outwardly facing surface (42). Turbine blade (10) according to one of the preceding claims,
wherein the platform frame (28) is shrunk onto the inner platform part (22) and / or soldered and / or welded thereto. Turbine blade (10) according to one of the preceding claims,
formed from a vane or as a blade. A method of manufacturing a turbine blade (10) comprising the steps of: Producing a monolithic fuselage shovel (19) comprising an airfoil (18), a platform (16) and a fixing section (14), - Making an endless platform frame (28) and - Mounting the endless platform frame (28) on the platform edge (26). Method according to claim 8,
wherein for producing the fuselage shovel (19) the platform edge of a powered turbine bucket is recessed along its entire circumference to produce an abutment surface (36, 38) for an endless platform frame (28). Method according to claim 8,
in which the fuselage shovel (19) is produced by a casting method comprising a fastening section (14), a platform (16) and an airfoil (18), and the platform edge (26) acts as a contact surface (36, 38) for an endless platform frame (28). is designed. Method according to claim 8, 9 or 10,
with the step that
the platform frame (28) is shrunk onto the inner platform part (22) and / or brazed and / or welded to the fuselage shovel (19). Method according to claim 8, 9, 10 or 11,
with the step of coating the inner platform part (22) and the platform frame (28) in a coating process.

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