WO2010037659A1 - Vane for a gas turbine - Google Patents

Abstract

A vane (20) for a gas turbine comprises a vane blade (11) extending in a longitudinal direction, said blade extending perpendicular to the longitudinal direction between a front edge (15) and a rear edge (16) and comprising a pressure side (13) and a suction side (14) and transitioning at one end to a platform (12) that lies perpendicular to the longitudinal direction, wherein a slotted coolant outlet (18) is provided at the rear edge (16) extending along the rear edge (16), with coolant which is fed from the inner space (17) of the vane (20) being discharged through said slotted outlet. In such a vane (20), the life span is increased by providing the transition from the vane blade (11) to the platform (12) with a transition thickness profile (21) at the rear edge (16) whereby the thickness (D) increases disproportionally with increasing approach to the bottom side (12') of the platform (12), and that the coolant outlet (18) is extended (19) into the platform (12) for the purposes of reducing the temperature in the area of the transition from the vane blade (11) to the platform (12).

Description

 SHOVEL FOR A GAS TURBINE

Technical area

The present invention relates to the field of gas turbines. It relates to a blade for a gas turbine according to the preamble of claim 1.

State of the art

The demands for an increase in the efficiency of gas turbines lead to the fact that the thickness at the trailing edges of the blades of the blades used in the gas turbine engines must be reduced more and more. This results in a geometry of the blade, as shown by way of example in cross section in FIG. 1. The blade 10 of FIG. 1 extends in the manner of a wing profile transversely to its longitudinal direction between a rounded front edge 15 and a comparatively tapered trailing edge 16 The blade 10 has a (concave) pressure side 13 and a (convex) suction side 14 with corresponding walls 13 'and 14'. In the hollow interior 17, a gaseous coolant or cooling medium is supplied and ejected inter alia by a formed on the trailing edge 16 coolant outlet into the environment. A particularly tapered, slim trailing edge 16 is thereby achieved in that the coolant outlet 18 is arranged completely on the pressure side 13 of the blade 10, and the two walls 13 'and 14' are made particularly thin in the region of the trailing edge 16.

If, as indicated in the perspective view of Fig. 2, the blade 11 at the end of its extension in the longitudinal direction in a transverse to the longitudinal direction of the platform 12 and is bounded by this platform 12, the transition of the airfoil 11 to this platform 12 in the region of the trailing edge 16 a typical, the life of a gas turbine component limiting factor because it is with a superposition of high thermal stress caused by the thermo-mechanical mismatch between platform 12 and blade 11, and mechanical stress peaks, caused by the load of the blades by the gas flow, is applied. The reduction in the thickness of the trailing edge 16 causes an increase in the stress in this critical area, so that in the design of the blade measures must be considered in order to achieve a sufficiently long life and to ensure.

Presentation of the invention

The invention aims to remedy this situation. It is therefore an object of the invention to develop a blade of the type mentioned for a gas turbine so that despite a small thickness at the trailing edge of the airfoil sufficient life is achieved.

The object is solved by the entirety of the features of claim 1. Essential to the invention is that the transition from the blade to the platform at the trailing edge has a transition thickness profile in which the thickness increases disproportionately with increasing approach to the underside of the platform, and that the coolant outlet to reduce the temperature in the transition from Blade sheet is extended to the platform into the platform. By extending the thickness of the trailing edge to the platform, the mechanical stress in the transition area is safely reduced. The extension of the coolant outlet into the platform leads there to improved cooling, so that thermally induced stresses are also significantly reduced.

An embodiment of the invention is characterized in that the transition thickness profile has a substantially exponential shape, which resembles an upside down very slender truncated pyramid or an inverted quasi pyramid. This achieves a particularly "soft" transition between the trailing edge and the platform. Another embodiment is characterized in that the transition from the blade to the platform has an approximately elliptical transition edge profile, which also reduces the stresses.

Furthermore, it is advantageous if, according to another embodiment, the trailing edge at the transition from the blade to the platform is pulled up to the edge of the platform.

A further embodiment of the invention is characterized in that the coolant outlet is formed between a pressure-side wall of the airfoil and a suction-side wall of the airfoil, and that the pressure-side wall has a curved transition edge profile in the transition from the airfoil to the platform, such that the wall thickness of the pressure-side wall in the region of the transition from the blade to the platform is approximately equal to the wall thickness in the remaining region of the airfoil.

Brief explanation of the figures

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. All elements not essential to the instant understanding of the invention have been omitted. Identical elements are provided with the same reference numbers in the various figures. Show it

Fig. 1 is a greatly simplified cross-section through an exemplary

A gas turbine blade having a narrow trailing edge and a pressure side disposed coolant outlet at the trailing edge as appropriate for the practice of the invention;

FIG. 2 shows a blade according to FIG. 1 showing the previously used abrupt transition between the blade leaf and the platform; FIG. and Fig. 3 shows the low-voltage transition between the blade and the platform according to an embodiment of the invention.

Ways to carry out the invention

In Fig. 3, a blade 20 for a gas turbine with a low-voltage transition between the blade 11 and platform 12 is shown according to an embodiment of the invention. The bucket 20 of the exemplary embodiment comprises a longitudinally extending airfoil 11, which extends in the manner of a wing transversely to the longitudinal direction between a front edge 15 and a trailing edge 16 and has a pressure side 13 and a suction side 14. At the upper (or lower) end, the airfoil 11 merges into a transverse to the longitudinal direction platform 12, the laterally projecting beyond the blade cross-section. At the trailing edge 16 of the airfoil 11 there is provided a slot-shaped coolant outlet 18 extending along the trailing edge 16, through which a coolant supplied via the (hollow) interior 17 of the blade 20, e.g. Cooling air, is ejected. The trailing edge 16 is designed with its thin walls 13 'and 14' is very narrow. In order to reduce the thermal stresses at the transition between the narrow trailing edge 16 and the solid platform 12, the transition according to the invention has a transitional thickness profile 21, in which the thickness D increases disproportionately with increasing approach to the bottom 12 'of the platform 12. At the same time, the coolant outlet 18 is extended to reduce the local temperature in the region of the transition from the blade 11 to the platform 12 into the platform 12 (extension 19).

The transition thickness profile 21 has a substantially exponential shape and thus resembles an upside-down Eiffel tower. It is particularly favorable with regard to the stress distribution if the transition from the blade 11 to the platform 12 has an approximately elliptical transition edge profile 22. While in the conventional blade of FIG. 2, the trailing edge 16 of the airfoil 11 terminates within the platform 12 and does not extend to the edge of the platform 12, in the embodiment of FIG the trailing edge 16 at the transition from the blade 11 to the platform 12 to the edge 12 "of the platform 12 is pulled forward.

As can be seen in FIG. 3, the coolant outlet 18 is delimited by the pressure-side wall 13 'and the suction-side wall 14' of the airfoil 11. The pressure-side wall 13 'has in the transition from the blade 11 to the platform 12 a curved transition edge profile 23, such that the wall thickness of the pressure-side wall 13' in the region of the transition from the blade 11 to the platform 12 is approximately equal to the wall thickness in the remaining area of Blade sheet 11 is.

Overall, the invention achieves a significant improvement in service life at the transition between the airfoil trailing edge and the gas turbine blade platform by: (1) extending the coolant outlet (cooling slot) into the platform to move in the critical area by bringing Coolant to reduce the metal temperature, with a convective cooling of the walls takes place on both sides.

(2) shifting the blade trailing edge to the edge of the platform to lower the tension and make the blade design independent of variations in the radial position of the casting core.

(3) Introduce an "Eiffel Tower" type transitional thickness profile by increasing the size and introducing a special elliptical contour of the throat at the transition between the airfoil and platform at the trailing edge.

(4) Inserting a specially curved transition edge profile to the pressure side of the airfoil at the throat at the transition between the airfoil and platform in the region of the trailing edge, in the transition region to a wall thickness corresponding to the wall thickness of the airfoil, which reduces stress and metal temperature and the life be increased at the transition. LIST OF REFERENCE NUMBERS

10.20 shovel (gas turbine)

11 airfoil

12 platform

12 'bottom (platform)

12 "edge (platform)

13 print side

13 'wall (printed side)

14 suction side

14 'wall (suction side)

15 leading edge

16 trailing edge

17 interior

18 coolant outlet (slot-shaped)

19 extension (coolant outlet)

21 transition thickness profile

22 transition edge profile

23 transitional edge profile

D thickness (transition thickness profile)

Claims

claims A blade (20) for a gas turbine, which blade (20) comprises a longitudinally extending blade (11) extending transversely to the Extends longitudinally between a front edge (15) and a trailing edge (16) and has a pressure side (13) and a suction side (14), and merges at one end into a transverse to the longitudinal platform (12), wherein at the trailing edge (16 ) is provided along the trailing edge (16) extending slot-shaped coolant outlet (18) through which a via the interior (17) of the blade (20) supplied coolant is discharged, characterized in that the transition from the blade (11) to Platform (12) at the trailing edge (16) has a transition thickness profile (21) whose thickness (D) increases disproportionately with increasing proximity to the underside (12 ') of the platform (12), and that the coolant outlet (18) for Reduction of the temperature in the region of the transition from the blade (11) to the platform (12) is extended into the platform (12) (19). 2. A blade according to claim 1, characterized in that the transition thickness profile (21) has a substantially exponential shape, which is similar to an upside-down Eiffel Tower. 3. A blade according to claim 1 or 2, characterized in that the transition from the blade (11) to the platform (12) has an approximately elliptical transition edge profile (22). 4. Blade according to one of claims 1 to 3, characterized in that the trailing edge (16) at the transition from the blade (11) to the platform (12) to the edge (12 ") of the platform (12) is pulled forward. 5. Blade according to one of claims 1 to 4, characterized in that the coolant outlet (18) between a pressure-side wall (13 ') of the airfoil (11) and a suction-side wall (14') of the airfoil (11) is formed, and that the pressure - side wall (13 ') in the transition from the blade (11) to the platform (12) has a curved transition edge profile (23), such that the wall thickness of the pressure side wall (13') in the region Transition from the blade (11) to the platform (12) is approximately equal to the wall thickness in the remaining region of the airfoil (11).