EP1219781B1 - Device and method to cool a platform of a turbine blade - Google Patents

Description

Technical area

The invention relates to an apparatus and a method for cooling a platform of a turbine blade, which provides a blade root, an airfoil with an arrival and trailing edge and a blade tip with a platform and which is at least partially penetrated radially by at least one cooling channel, with at least one, connected via an outlet opening on the platform outlet channel is connected.

State of the art

Cooling problems of the aforementioned type occur in particular in turbine blades, which are used in gas turbine plants. In particular, in the individual gas turbine stages, the turbine blades are flowed around by the hot gases generated within the combustion chamber. In order to avoid overheating when turbine blades are in operation, the aspect of targeted cooling of gas turbine blades plays a major role in the design and layout of such systems. Usually, part of the pre-compressed air within the compressor stage for cooling purposes is specifically discharged for cooling and thus removed from the further combustion process for cooling. Rather, the cooling air passes through cooling duct systems, which are provided both in rotating and stationary system components, in the area of the turbine stages to cool the there, the hot gases directly exposed plant components. For cooling on the rotor assembly, in a plurality of axially successively arranged blade rows seated blades, have Blades on radial cooling passages through which the cooling air fed from the side of the rotor assembly is guided longitudinally to the turbine blades, which exits through respectively provided on the blade surface cooling air openings and mixes with the hot gases.

In some cases, turbine blades have platforms or so-called shrouds on their side remote from the rotor assembly to minimize leakage currents that may form between the turbine blade tips and fixed equipment components. Likewise, such platforms and shrouds help to effectively damp vibrations that form along the turbine blades during operation of the gas turbine.

In order to cool such platforms, US Pat. No. 5,482,435 describes a cooling channel system within a platform through which cooling air is passed and thus effectively contributes to the cooling of the platform. The cooling air passes through a centrally oriented radially to the turbine blade cooling channel in the region of the platform in which the cooling air passes through two sub-channels to the outside. The partial cooling channels provided in the platform extend in such a way that the cooling air emerging from the platform is oriented almost perpendicular to the main flow direction of the hot gases flowing through the gas turbine. This, however, on the one hand causes the flow behavior of the main flow is significantly irritated, whereby the aerodynamic efficiency is permanently impaired. On the other hand, the cooling air emerging from the platform can not contribute to the energy gain or improved energy conversion within the gas turbine.

Presentation of the invention

The invention has for its object to provide an apparatus and a method for cooling a platform of a turbine blade according to the preamble of claim 1 such that on the one hand effective cooling of the platform is ensured, on the other hand, however, is ensured that the main flow, which rests directly on the turbine blade, as little as possible is impaired so as not to degrade the aerodynamic conditions within the turbomachine. Rather, it should be achieved that in addition to the above effective cooling effect, an additional energy gain can be achieved by the exit of the cooling air from the platform.

The solution of the problem underlying the invention is specified in claim 1, which describes a device according to the invention. The subject matter of claim 7 is a method according to the invention. The concept of the invention advantageously further features are the subject of the dependent claims and the entire description in particular with reference to the exemplary embodiments.

According to the invention, a device for cooling a platform of a turbine blade, which provides a blade root, an airfoil with an arrival and trailing edge, and a blade tip with a platform and which is at least partially penetrated radially by at least one cooling channel, with at least one, via a Outlet opening is connected to the platform emerging outlet channel, further developed in that the outlet channel adjacent to the outlet opening has a channel longitudinal direction which extends in projection along the turbine blade largely coparallel to the flow direction of the outlet directly overflowing, local flow field of a relatively flowing past the turbine blade mass flow.

Basically, the cooling device according to the invention is applicable to all turbine blades, which are provided with a platform. The advantages associated with the measure according to the invention are explained in more detail below using the example of the turbine guide vane within a gas turbine plant. Of course, it is also possible to use the cooling device according to the invention also on platforms of stationary vanes. The inventive measure is not limited to the use of turbine blades within gas turbine stages of gas turbine plants, but can be used in all turbomachinery in which appropriate Cooling problems occur, for example within compressors or similar turbomachines.

The inventive arrangement of the outlet channel within the platform through which cooling air exits through an outlet opening is according to the invention oriented such that the cooling air that flows out of the platform preferably has the same flow direction, with the main flow of hot gases, the turbine blade and thus the The platform itself flows around. If the outlet opening of the outlet channel is provided on the platform of the turbine blade which faces radially away from the turbine blade, the cooling channel preferably runs slightly inclined to the platform top side. Alternatively, the outlet opening may be attached to the downstream end edge of the platform, so that the cooling air flowing out of the platform is oriented co-parallel to the hot gases flowing around the platform. In all cases, the outlet opening of the cooling channel on the platform is preferably downstream of the leading edge of the turbine blade, so that it is ensured that the longest possible cooling channel section extends within the platform, so that the most effective cooling effect can be achieved.

Cooling provisions within the platform, which in the case of turbine blades are subject to high centrifugal forces due to their radial spacing from the axis of rotation, play an important role in positively influencing the creep behavior of the blade material in the region of the platform, i. Material distortions or deformations by softening of the material with simultaneous action of high centrifugal forces are reduced or eliminated by effective cooling measures. Due to the cooling measure according to the invention within the platform material creep can be significantly reduced.

However, the main advantage associated with the inventive cooling channel system within the platform is the additional energy gain associated with the targeted co-parallel flow exit of the cooling air relative to the turbine blade flowing around mainstream, can be achieved. Thus, it could be demonstrated that the cooling air flowing out of the cooling channel oriented according to the invention through the outlet opening on the platform contributes to a measurable energy gain, which results from the interplay of an additional impulse contribution to the drive of the turbine blade and a comparatively negligible irritation or disturbance Main flow of the turbine blade flows around the hot gases.

Preferably, a plurality of correspondingly oriented cooling channels are incorporated within a platform, whereby the advantageous effects described above with regard to cooling effect and additional energy contribution can be increased. Further details regarding possible exemplary embodiments can be taken in detail from the following exemplary embodiments.

To produce the platform designed according to the invention, a multiplicity of techniques known per se are suitable for introducing the cooling channel or a multiplicity of appropriately oriented cooling channels into the platform. Particularly suitable for this purpose are EDM (Electro-Discharge Machining) or conventional drilling techniques using laser beam, electrochemical methods and water jet techniques.

Of course, it is also possible to provide platforms of turbine blades at their respective turbine blade feet with appropriately oriented cooling channels. Although the aspect of additional energy gain in platforms in the blade root area plays only a minor role, the outflowing cooling air through the corresponding outlet openings does not affect the main flow, even in the region of the blade roots, only insignificantly.

Brief description of the invention

Fig. 1

Draufsicht auf die axiale Anordnung einer in einer Laufschaufelreihe angeordnete Turbinenlaufschaufel sowie einer entsprechend axial stromauf angeordneten Turbinenleitschaufel,

Fig. 2

Teildarstellung durch einen radialen Längsschnitt durch eine Turbinenschaufel mit Plattform sowie

Fig. 3

Draufsicht auf eine Plattform in radialer Richtung.

The invention will now be described by way of example without limitation of the general inventive idea by means of embodiments with reference to the drawing. Show it:

Fig. 1

Top view of the axial arrangement of a arranged in a row of blades turbine blade and a corresponding axially upstream turbine vane,

Fig. 2

Partial view through a radial longitudinal section through a turbine blade with platform and

Fig. 3

Top view of a platform in the radial direction.

Ways to carry out the invention, industrial usability

FIG. 1 shows a plan view of an axial arrangement consisting of a row of guide blades 1 and a blade row 2 arranged downstream in the direction of flow. In detail, the platforms 3 of a vane 4 and a rotor blade 5 can be seen, with the vane 4 or blade 5 extends perpendicularly away from the viewer along the plane of the drawing. By the appropriate employment of the guide or moving blades relative to the main flow 6, which flows axially through the turbine blade assembly, the main flow 6 is deflected by the turbine blades from the pure axial direction. Thus, the main flow 6 is directed immediately after flowing through the guide vane row 1 in the circumferential direction upwards, whereas the main flow is deflected after flowing around the blade row 2 counter to the direction of rotation. The inclination of the flow direction with respect to the axial direction immediately downstream of a turbine blade row is essentially due to the inclination of the turbine blade blades relative to the main flow and the peripheral speed. For cooling the platforms 3 are cooling channels 7, preferably arranged in the region of the downstream end edge 8 of the platforms 3 such that cooling air escapes parallel to the main flow 6 from the cooling channels 7. For this purpose, the longitudinal axes of the cooling channels 7 are arranged parallel to the turbine blade in the region immediately upstream of the outflow edge 9.

In Figure 2, the upper part of a longitudinal section through a turbine blade is shown, which is for example designed as a blade 5 and in its upper Area provides a platform 3. The blade 5 has a radially extending main cooling channel 10, in which cooling air from the side of the blade root, not shown, enters the region of the platform 3. In the main cooling channel 10 unilaterally open a plurality of cooling channels 11, which extend obliquely to the platform top 12 and each provide an outlet opening 13 at this. Cooling air, which exits through the outlet channels 11 through the respective outlet opening 13 on the platform top 3, is slightly inclined to the platform top 12, however, directed in the flow direction of the main flow 6. Further cooling channels 14 open via corresponding further outlet openings on the platform top and are supplied via suitable provided additional cooling air channels 15 with cooling air.

The platform 3 of the rotor blade 5 shown in FIG. 2 provides a typically formed labyrinth seal 16 under which a cooling channel volume 17 with a correspondingly downstream outlet 18 is provided directly.

FIG. 3 shows a plan view of a platform 3, under which, extending in the longitudinal direction, a moving blade 5 is provided. The rotor blade 5 has various hollow channels extending longitudinally of the turbine blade, from which cooling air flows out of the hollow channel 10 in the direction of the platform. Immediately to the formed as a cooling channel hollow channel 10, a cooling air system connects, through which the individual cooling channels 13 and 14 is supplied with appropriate cooling air. The cooling air flows along the arrow directions indicated in the individual channels and exits at the corresponding outlet openings 13, 14 on the upper side 12 of the platform 3.

LIST OF REFERENCE NUMBERS

1

vane row

2

Blade row

3

platform

4

vane

5

blade

6

mainstream

7

cooling channels

8th

downstream end of the platform 3

9

trailing edge

10

Main cooling channel

11

cooling channel

12

Platform top

13

outlet opening

14

outlet opening

15

Besides cooling channel

16

labyrinth seal

17

Cooling channel volume

18

exhaust port

Claims (7)

1. Device for cooling a platform (3) of a turbine blade which has a blade root, an aerofoil with a leading and trailing edge, and a blade tip with a platform (3) and through which at least one cooling passage passes radially at least partly, which cooling passage is connected to at least one outlet passage discharging via an outlet opening on the platform, characterized in that the outlet passage (7, 11) has, adjacent to the outlet opening (13), a passage longitudinal direction which in projection runs along the turbine blade largely parallel to the flow direction of a local flow zone (6), flowing directly over the outlet opening, of a mass flow flowing past the turbine blade in a relative manner, and in that the platform (3) has a platform top side (12) which faces radially away from the turbine aerofoil and on which the outlet opening (13) is provided.
2. Device according to Claim 1, characterized in that the outlet passage (7, 11) has, adjacent to the outlet opening (13), a passage longitudinal direction which in projection runs along the turbine blade largely parallel to the axial section of the turbine aerofoil in the region directly upstream of the trailing edge.
3. Device according to Claim 1 or 2, characterized in that a cooling medium, preferably cooling air, can flow through the outlet passage (7, 11), which cooling medium leaves the outlet opening (13) virtually in the flow direction relative to the local flow zone (6).
4. Device according to one of Claims 1 to 3, characterized in that the turbine blade is integrated in a turbomachine, preferably in a gas turbine, through which the mass flow is directed axially.
5. Device according to one of Claims 1 to 4, characterized in that the outlet opening (13) is arranged close to the downstream end of the platform (3).
6. Device according to one of Claims 1 to 5, characterized in that the turbine blade is a guide blade, preferably a moving blade, inside the gas turbine.
7. Method for cooling a platform of a turbine blade which has a blade root, an aerofoil with a leading and trailing edge, and a blade tip with a platform (3) and through which at least one cooling passage passes radially at least partly, which cooling passage is connected to at least one outlet passage discharging via an outlet opening on the platform, characterized in that the platform (3) has a platform top side (12) which faces radially away from the turbine aerofoil and on which an outlet opening (13) is provided, in that a cooling medium, preferably cooling air, is directed through the cooling passage and the outlet passage and discharges from the platform in such a way that the cooling medium leaves the platform in a direction virtually parallel to a mass flow flowing around the turbine blade.

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