The present invention relates to the field of gas turbines. Specifically, it refers to a cooled blade for a gas turbine. The invention furthermore refers to a method for operating such a blade.
A stator blade of the first row of a gas turbine is known from printed publication EP-A1-1 113 145, which shows a typical cooling arrangement for the trailing edge of the blade. A combination of ribs and pins in the cooling air flow which is guided towards the trailing edge ensures effective cooling, wherein the cooling air mass flow is controlled by means of a restricting device on the trailing edge. This type of cooling, however, has the disadvantage that comparatively thick trailing edges are required, as a result of which significant aerodynamic losses ensue.
For the necessary optimization of efficiency and output power it is necessary:
A lower consumption of cooling air can be achieved by advanced cooling technology and by the use of recooled cooling air. The trailing edges can be designed thinner if the cooling air is released on the pressure side of the blade. Furthermore, the reduced cooling air flow requires restricting at the trailing edge which develops a high blocking action. A large blocking action, however, leads to a widthwise-uneven distribution of the cooling air film which is formed at the trailing edge, resulting in local overheating (“hot spots”).
The disclosure is directed to a cooled blade for a gas turbine. The blade includes a blade airfoil which extends between a leading edge and a trailing edge in a flow direction and on a suction side and on a pressure side is delimited by a wall. The walls include an interior space in which cooling air flows towards the trailing edge in the flow direction and discharges to the outside in the region of the trailing edge, the pressure-side wall terminating at a distance in front of the trailing edge in the flow direction forming a pressure-side lip, in such a way that the cooling air discharges from the interior space on the pressure side. The interior space, at a distance in front of the trailing edge, is sub-divided by a plurality of ribs, which are oriented parallel to the flow direction, into a plurality of parallel cooling passages which create a pressure drop. Turbulators are additionally arranged for increasing the cooling effect, and just before an outlet of the cooling air from the interior space a plurality of flow barriers are arranged in the flow path of the cooling air and distributed transversely to the flow direction.
In another aspect, the disclosure is directed to a method for operating a cooled blade in a gas turbine. The blade includes a blade airfoil and a blade root. The blade airfoil extends between a leading edge and a trailing edge in a flow direction and on a suction side and on a pressure side is delimited in each case by a wall. The walls include an interior space with cooling passages. In the interior space a cooling air flow flows towards the trailing edge of the blade airfoil and discharges to the outside in a region of the trailing edge. The method includes providing axial ribs, for enlarging a heat transfer surface between walls and cooling air flow, which act in the interior space. The method also includes providing rib-like turbulators in the cooling passages, which increase the heat transfer coefficient in the associated sphere of influence, the axial ribs and the turbulators bring about a pressure drop. Further, the method includes providing flow barriers, at an outlet of the trailing edge, which create a homogeneity of the cooling air flow in a associated sphere of influence with a minimized blocking action.
The invention shall subsequently be explained in more detail based on exemplary embodiments in conjunction with the drawing. All elements which are not necessary for the direct understanding of the invention have been omitted. Like elements are provided with the same designations in the various figures. In the drawings:
Introduction to the Embodiments
It is therefore an object of the invention to create a cooled blade for a gas turbine of the type referred to in the introduction which avoids the disadvantages of the previous blades and at the same time provides low aerodynamic losses and a significantly reduced consumption of cooling air.
The object is achieved by means of the entirety of the features of claim 1. It is preferable for the solution according to the invention that the pressure-side wall terminates at a distance in front of the trailing edge in the flow direction, forming a pressure-side lip, in such a way that the cooling air discharges from the interior space on the pressure side, that the interior space, at a distance in front of the trailing edge, is sub-divided by a large number of ribs, which are oriented parallel to the flow direction, into a large number of parallel cooling passages which create a large pressure drop, and in which turbulators are additionally arranged for increasing the cooling effect, and that provision is made just before the outlet of the cooling air from the interior space in the flow path of the cooling air for a multiplicity of flow barriers which are distributed transversely to the flow direction.
In one development of the invention, the linear density of the flow barriers is lower than the linear density of the ribs.
According to another development of the invention, the flow barriers have in each case a teardrop-shaped edge contour, wherein the pointed end points in the flow direction.
In a further development of the invention, a large number of pins are arranged in a two-dimensional grid arrangement between the cooling passages and the flow barriers and extend transversely to the flow direction through the interior space between the suction-side and pressure-side walls.
Obliquely disposed ribs on the inner sides of the suction-side and pressure-side walls can especially be used as turbulators in the cooling passages.
The cooled blade is also operated so that axial ribs act in the interior space of such a blade and create an enlargement of the surface for a heat transfer between walls and cooling air flow. Furthermore, advantages ensue if provision is made in the cooling passages for rib-like turbulators which increase the heat transfer coefficient in the associated sphere of influence. Advantages also then ensue if the axial ribs and the turbulators are installed at the same time, which then bring about a pressure drop so that as a result provision can specifically be made at the outlet of the trailing edge for flow barriers which create a homogeneity of the cooling air flow in the associated sphere of influence with a minimized blocking action. Furthermore, these flow barriers, as a result of a teardrop-shaped design, can minimize the lateral uneven distribution of the cooling air film which ensues there so that large trailing vortices cannot arise at all behind these flow barriers.
In the case of the blade of
The cooling air which is fed inside the blade 10, on its way to the trailing edge 13, is first directed through a large number of parallel cooling passages 23 which are oriented in the flow direction 25 and formed by means of axial ribs 17 between the two walls 11 and 12. In the cooling passages 23, turbulators 18 in the form of oblique ribs are arranged on the inner sides of the walls 11, 12, as a result of which the exchange of heat with the walls 11, 12 is increased. Pins 19, which are arranged in a distributed manner in a grid structure style, follow the flow passages 23 and, like the axial ribs 17, extend between the two walls 11, 12 and improve the cooling of the wall in this region. Finally, the cooling air passes an individual row of teardrop-shaped flow barriers 20 and then discharges from the blade 10 on the pressure side 16 between pressure-side lip 21 and trailing edge 13. In this case, the cross-sectional shape of these flow barriers 20 is not limited exclusively to a teardrop shape. Other flow shapes can be used from case to case. If the flow is to be influenced in a specific direction or intensity, then the flow barriers 20 are correspondingly designed. The linear density of the flow barriers 20 is lower in this case than the linear density of the axial ribs 17. This, however, is again not be understood as being compulsory because, depending upon the type of design, the density of the flow barriers 20 can be selected the same as or higher than the linear density of the axial ribs 17.
On the pressure side 16, upstream of the cooling passages 23, provision is additionally made for a row of film cooling holes 22, through which cooling air discharges on the pressure side 16 and forms a cooling film there.
The blade includes the following characteristics and provides the following advantages:
10 Blade (gas turbine)
11 Wall (suction side)
12 Wall (pressure side)
13 railing edge
14 Interior space
15 Suction side
16 Pressure side
17 Axial rib
18 Turbulator
19 Pin
20 Flow barrier
21 Pressure-side lip
22 Film cooling hole
23 Cooling passage
24 Blade airfoil
25 Flow direction
Number | Date | Country | Kind |
---|---|---|---|
00142/09 | Jan 2009 | CH | national |
This application is a continuation of International Application No. PCT/EP2010/05112 filed Jan. 29, 2010, which claims priority to Swiss Patent Application No. 00142/09, filed Jan. 30, 2009, the entire contents of all of which are incorporated by reference as if fully set forth.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/EP2010/051112 | Jan 2010 | US |
Child | 13193548 | US |