EP3124744A1 - Vane with impingement cooled platform - Google Patents

Abstract

The invention relates to a guide vane (1) for a turbomachine, comprising a vane platform (2) and an airfoil (3) and a blade root (4) projecting from the vane platform on opposite sides, a wall section (5) of the vane platform An impingement cooling plate (9) is assigned, which is at least partially spaced within the blade platform to form an impingement cooling chamber (10) of the wall portion and by impingement cooling openings (11, 12) is penetrated, through which the impingement cooling chamber, a cooling fluid can be supplied, wherein the impingement cooling openings at least an elongated baffle cooling slot (12) and preferably additionally baffle cooling bores (11).

Description

Guide vane for a turbomachine, with a blade platform and with a blade and a blade root projecting from the blade platform on opposite sides, wherein a wall portion of the blade platform is associated with a baffle plate disposed within the blade platform to form an impingement cooling chamber at least partially spaced from the wall portion is and is penetrated by impingement cooling through which the impact cooling a cooling fluid can be supplied.

Such guide vanes are known in the prior art in different configurations and are used in turbomachines to make the enthalpy contained in a hot gas usable. For this purpose, the guide vanes are usually arranged in the form of a blade ring and held on a blade carrier, which is provided in a housing of the turbomachine and fixedly connected thereto. Further, a turbine is provided within the housing adjacent to the vanes. The turbine comprises moving blades, which usually also form a blade ring and are held on a further blade carrier. The further blade carrier is rotatably connected to a housing passing through and rotatably mounted turbine shaft, which is coupled to a drive shaft of a working machine, such as a generator.

During operation of the turbomachine, the enthalpy contained in the hot gas is completely or partially converted into flow energy by the guide vanes. The flowing hot gas is then deflected on the blades, thereby exerting a circumferential force on them. The turbine shaft is activated by the circumferential force acting on the blades Rotation displaces and finally drives the work machine.

Such a vane includes a vane platform and an airfoil and blade root projecting from the vane platform on opposite sides. The blade root serves to secure the vane to the blade carrier while the airfoil is formed so that a directional flow can form in the expanding hot gas.

During operation of the turbomachine, the vanes are exposed to a high thermal load due to the high temperature of the hot gas. The concomitant temperature-induced wear of the guide vanes can be reduced for example by a heat-resistant coating of the outer surface.

Another way to increase the thermal load capacity of a guide vane, is in the cooling. For cooling, a cavity can be formed within a guide vane, through which a cooling fluid, for example compressed air, can flow.

In addition to the airfoils, wall sections of the blade platforms of the vanes are usually overflowed by the hot gas, suggesting suitable measures for cooling the blade platforms. The EP 0 789 806 B1 proposes an improved guide vane whose vane platform is cooled by impingement cooling. In this case, a baffle plate is associated with a wall portion, which is arranged within the blade platform spaced from the wall portion to form a baffle cooling space. The impingement cooling plate is penetrated by impingement cooling bores, through which the cooling fluid can be fed to the impingement cooling chamber. Due to a pressure difference on both sides of the baffle cooling plate, the cooling fluid flows through the baffle cooling bores into the baffle cooling chamber, bounces substantially perpendicularly from the inside to the wall section the blade platform, absorbing heat from the wall section. Finally, the heated cooling fluid leaves the impingement cooling chamber, whereby the absorbed heat is removed from the guide vane.

However, the cooling performance of the cooling fluid flowing into the impingement cooling space through the impingement cooling holes may be insufficient. In addition, in the impingement cooling space between the impingement cooling plate and the wall section of the blade platform, transverse secondary flows of the cooling fluid can be formed, which reduce the achievable cooling capacity, for example by causing a deflection of the cooling fluid flowing through the impingement cooling bores before it impacts on the wall section from the inside.

Based on this prior art, it is an object of the present invention to provide a vane with improved cooling of the blade platform.

In order to achieve the object according to the invention, the present invention provides a guide vane of the type mentioned in the introduction, in which the impact cooling openings comprise at least one oblong impingement cooling slot and preferably additionally impact cooling bores. The invention is based on the idea of forming the baffle cooling openings at least partially slit-shaped. Since the cooling fluid flow through a baffle cooling slot is more extensive than that through an impingement cooling bore, a corresponding improvement in the area-related baffle cooling performance is achieved. In addition, baffle cooling slots can direct the cooling fluid flowing through it more precisely than baffle cooling bores, so that particularly hot areas of the wall section can be specifically cooled. In addition, the cooling fluid walls created by the impingement cooling slots in the impingement cooling space can favorably influence the secondary flow of the cooling fluid in the impingement cooling space. In other words, baffle cooling slots can direct the cooling fluid in the impingement cooling space such that a reduction in the achievable cooling capacity due to unfavorable secondary flow is largely avoided. In one embodiment of the present invention, the wall portion is penetrated by film cooling channels, through which the cooling fluid flows from an inner surface to an outer surface of the wall portion. The film cooling causes an immediate cooling of the outer surface of the wall portion and protects the wall portion from the overflowing hot gas, which further increases the thermal load capacity of the blade platform. However, a closed cooling film along the outer surface of the wall section requires a favorable distribution of the cooling fluid to the film cooling channels. In particular, in combination with an impingement cooling can suitably arranged impingement cooling slots direct the cooling fluid in the impingement cooling chamber such that an unfavorable distribution of the cooling fluid is counteracted to the film cooling channels.

Advantageously, a plurality of impingement cooling slots is provided. With a suitable arrangement of a plurality of impingement cooling slots, even more expansive areas of the wall section can be efficiently cooled if necessary and / or complex complex secondary flows of the cooling fluid in the impingement cooling compartment can be modeled.

Preferably, a plurality of impingement cooling slots are arranged behind one another in the impingement cooling plate in such a way that they lie on a line. In this way, a wall-shaped cooling fluid flow with even greater effective length expansion and / or steering effect can be produced from a plurality of impact cooling slots.

Preferably, a plurality of impingement cooling openings and in particular a plurality of impingement cooling slots are arranged behind one another in the impingement cooling plate such that they lie on a plurality of lines. Multiple lines in the impingement cooling plate allow for differentiated modeling of the secondary flow of cooling fluid in the impingement refrigerator when a single line does not perform the intended or sufficient effect. In an advantageous variant, a plurality of impingement cooling openings / impingement cooling slots are arranged one behind the other in the impingement cooling plate in such a way that they lie on at least two lines extending substantially parallel. Impact cooling slots arranged on parallel lines can produce channel-like structures in the impingement cooling chamber for the precise steering of the secondary flow.

In one embodiment of the guide vane according to the invention, impingement cooling bores and impingement cooling slots are arranged alternately on at least one line. The alternating arrangement of impingement cooling bores and impingement cooling slots makes it possible to combine the respective advantages of both opening forms in the impingement cooling plate.

In one variant, at least one line has a straight shape. A straight-shaped line may result in a straight secondary flow of the cooling fluid in the impingement refrigerator.

Alternatively or additionally, at least one line has a curved shape. A curved line may cause a correspondingly curved secondary flow of the cooling fluid in the impingement cooling space.

According to another alternative or additional variant, at least one line has a kinked shape. With a kinked line, abrupt changes of direction in the secondary flow of the cooling fluid can be produced.

In one embodiment of the present invention, at least one impingement cooling slot and in particular each impingement cooling slot has a width between 0.1 mm and 0.3 mm, preferably a width of 0.2 mm. Impingement cooling slots of this small width ensure that a sufficient pressure difference is maintained on both sides of the impingement cooling plate, which causes the cooling fluid to flow through the impingement cooling plate into the impingement cooling space.

In a guide blade according to the invention, at least one impingement cooling slot and in particular each impingement cooling slot may have a length between 15 mm and 25 mm, preferably a length of 20 mm. Impingement cooling slots of this length produce sufficiently extensive wall-like flow patterns to affect the direction of secondary flows in the impingement cooling space.

In a further embodiment of the guide vane according to the invention, the impact cooling bores have a diameter between 0.2 mm and 0.8 mm, preferably a diameter of 0.5 mm. Impact cooling bores of this diameter can on the one hand maintain the required pressure difference on both sides of the impingement cooling plate, but on the other hand allow sufficient cooling fluid flow to cool a certain point of the wall section of the blade platform.

In a variant of the present invention, the impingement cooling bores and / or the at least one impingement cooling slot are introduced into the wall section by means of a laser. This fabrication process is easy to apply and provides the precision needed to produce small diameter baffles and / or baffles.

According to one embodiment of the present invention, separating elements are provided in the impingement cooling space, which segment the impingement cooling space. For example, solid walls may also be arranged in the impingement cooling space between the wall section of the blade platform and the impingement cooling plate in order to prevent undesired secondary flow progressions.

Preferably, the separating elements are held on the baffle cooling plates. For this purpose, the separating elements can be provided on the baffle cooling plates by embossing. Separating elements held on the baffle plates offer the advantage that they are automatically positioned correctly when the baffle plates are inserted.

Figur 1

eine schematische Querschnittsansicht einer Leitschaufel gemäß einer Ausführungsform der vorliegenden Erfindung;

Figur 2

eine vergrößerte Ansicht des mit dem Bezugszeichen II gezeichneten Details der in Figur 1 dargestellten Leitschaufel;

Figur 3

eine perspektivische Ansicht des innerhalb der Schaufelplattform der in Figur 1 dargestellten Leitschaufel angeordneten Prallkühlblechs; und

Figur 4

eine schematische Ansicht von Prallkühlschlitzen und Prallkühlbohrungen, die jeweils abwechselnd entlang zweier paralleler geknickter Linien angeordnet sind.

Further features and advantages of the present invention will become apparent from the following description of an embodiment of the guide vane according to the invention with reference to the accompanying drawings. Are in it

FIG. 1

a schematic cross-sectional view of a vane according to an embodiment of the present invention;

FIG. 2

an enlarged view of the drawn with reference numeral II details of in FIG. 1 illustrated vane;

FIG. 3

a perspective view of within the blade platform of in FIG. 1 illustrated vane arranged impingement cooling plate; and

FIG. 4

a schematic view of impingement cooling slots and impingement cooling holes, which are each arranged alternately along two parallel kinked lines.

The FIGS. 1 to 4 show a guide vane 1 of a gas turbine according to an embodiment of the present invention. The guide vane 1 can be used in other turbomachinery without further ado. In a gas turbine several guide vanes 1 are arranged in the form of a blade ring, which is held on a fixedly connected to a housing of the gas turbine blade carrier. In each guide vane 1, a cavity is formed for cooling in each case, to which a cooling fluid such as compressed air can be supplied.

The vane 1 comprises a blade platform 2 and an airfoil 3 and a blade root 4, which protrude from the blade platform 2 on opposite sides. The blade platform 2 has a wall section 5, whose Outside surface 6 is covered by a hot gas, and an inner surface 7, which is covered by a cooling fluid on. The wall portion 5 is penetrated by film cooling channels 8, through which the cooling fluid from the inner surface 7 of the wall portion 5 can flow to the outer surface 6 to cool the outer surface 6 and to protect against the overflowing hot gas.

The wall section 5 of the blade platform 2 is associated with an impingement cooling plate 9, which is arranged within the blade platform 2 spaced from the wall section 5 to form an impingement cooling chamber 10. The impingement cooling plate 9 is penetrated by a plurality of impingement cooling bores 11 and elongate impingement cooling slots 12, through which the cooling fluid can be fed to the impingement cooling chamber 10.

The impingement cooling holes 11 have a diameter of 0.5 mm. The diameter of the impingement cooling bores 11 can also be between 0.2 mm and 0.8 mm. The impingement cooling slots 12 have a width of 0.2 mm and a length of 20 mm. The width of the baffle cooling slots 12 may be between 0.1 mm and 0.3 mm, the length between 15 mm and 25 mm. The impingement cooling bores 11 and impingement cooling slots 12 are introduced into the impingement cooling plate 9 by means of a laser in the embodiment described here. But you can also in an alternative manner, for example, by drilling or cutting or milling in the impingement cooling plate 9 bring.

The impingement cooling bores 11 and impingement cooling slots 12 are arranged one behind the other in such a way that they lie on two lines 13. The two lines 13 extend parallel to each other and have a bent shape. On each of the two lines 13, the impingement cooling bores 11 and impingement cooling slots 12 are arranged alternately. However, the number and shapes of the lines 13 may vary depending on the blade platform 2 and the particular cooling demand. For example, straight and / or curved lines 13 are possible. Likewise, on a line 13, an arbitrary sequence of Impeller cooling bores 11 and impingement cooling slots 12 may be arranged, in particular, only impingement cooling bores 11 or impingement cooling slots 12 may be provided.

In the impingement cooling chamber 10 separating elements 14 are provided, which are held on the impingement cooling plate 9 and segment the impingement cooling chamber 10.

During operation of the turbomachine, due to a pressure difference, the cooling fluid first flows through the impingement cooling bores 11 and the impingement cooling slots 12 of the impingement cooling plate 9 into the impingement cooling chamber 10 and collides against the inner surface 7 of the wall section 5, absorbing heat of the wall section 5. From the impingement cooling chamber 10, the heated cooling fluid flows through the film cooling channels 8 provided in the wall section 5 onto the outer surface 6 of the blade platform 2. On the outer surface 6, the cooling fluid forms a cooling film that cools the outer surface 6 of the wall section 5 and the outer surface 6 of the wall section 5 protects the overflowing hot gas.

How out FIG. 3 can be seen, can be achieved by the illustrated kinked shape of the lines 13 indicated by arrows kinking secondary flow of the cooling fluid in the impingement cooling chamber 10. But other directions of flow can be achieved by appropriate arrangement and shaping of the lines 13.

An advantage of the guide blade 1 according to the invention lies in an improved cooling of the wall section 5 of the blade platform 2. Firstly, a strong flow of cooling fluid, which can be directed specifically to particularly hot regions of the wall section 5, onto the inner surface 7 of the wall section 5 can be provided by the cooling slots 12 be directed. On the other hand, the cooling fluid in the impingement cooling chamber 10 can be influenced by the relative arrangement of the impingement cooling bores 11 and the impingement cooling slots 12 in such a way that no secondary flow reducing the cooling capacity in the impingement cooling chamber 10 the cooling fluid is formed. In contrast to impingement cooling bores 11, the impingement cooling slots 12 generate wall-like cooling fluid streams which segment the impingement cooling chamber 10 like dividing elements 14. In this way, it is possible to prevent secondary flows in the impingement cooling chamber 10 from reducing the efficiency of impingement cooling, for example, by deflecting the cooling fluid flowing through the impingement cooling bores 11 or by unfavorably distributing the cooling fluid onto the film cooling channels 8.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (16)

Guide vane (1) for a turbomachine, with a vane platform (2) and with an airfoil (3) and a blade root (4), which protrude from the vane platform (2) on opposite sides,
wherein a wall section (5) of the blade platform (2) is associated with an impingement cooling plate (9) which is at least partially spaced from the wall section (5) within the blade platform to form an impingement cooling space (10) and penetrated by impingement cooling openings (11, 12) is, through which a cooling fluid can be fed to the impingement cooling chamber (10),
characterized in that
the impingement cooling openings (11, 12) comprise at least one elongated impingement cooling slot (12) and preferably additionally impingement cooling bores (11). Guide vane according to claim 1,
characterized in that
the wall portion (5) is penetrated by film cooling passages (8) through which the cooling fluid flows from an inner surface (7) to an outer surface (6) of the wall portion (5). Guide vane according to one of the preceding claims,
characterized in that
in the impingement cooling plate (9) a plurality of impact cooling slots (12) are formed. Guide vane according to claim 3,
characterized in that
a plurality of impact cooling slots (12) are arranged one behind the other in the impingement cooling plate (9) so that they lie on a line (13). Guide vane according to claim 3,
characterized in that
a plurality of impingement cooling slots (12) are arranged one behind the other in the impingement cooling plate (9) so that they lie on a plurality of lines (13). Guide vane according to claim 5,
characterized in that
a plurality of impingement cooling slots (12) are arranged one behind the other in the impingement cooling plate (9) so that they lie on at least two substantially parallel extending lines (13). Guide vane according to one of claims 4 to 6,
characterized in that
on at least one line (13) impingement cooling bores (11) and impingement cooling slots (12) are arranged alternately. Guide vane according to one of claims 4 to 7,
characterized in that
at least one line (13) has a straight shape. Guide vane according to one of claims 4 to 8,
characterized in that
at least one line (13) has a curved shape. Guide vane according to one of claims 4 to 9,
characterized in that
at least one line (13) has a kinked shape. Guide vane according to one of the preceding claims,
characterized in that
at least one impingement cooling slot (12) and in particular each impingement cooling slot (12) has a width between 0.1 mm and 0.3 mm, preferably a width of 0.2 mm. Guide vane according to one of the preceding claims,
characterized in that
at least one impingement cooling slot (12) and in particular each impingement cooling slot (12) has a length between 15 mm and 25 mm, preferably a length of 20 mm. Guide vane according to one of the preceding claims,
characterized in that
at least one impingement cooling bore (11) and in particular each impingement cooling bore (11) have a diameter between 0.2 mm and 0.8 mm, preferably a diameter of 0.5 mm. Guide vane according to one of the preceding claims,
characterized in that
the impingement cooling bores (11) and / or the at least one impingement cooling slot (12) are introduced into the wall section by means of a laser. Guide vane according to one of the preceding claims,
characterized in that
in the impingement cooling chamber (10) separating elements (14) are provided, which segment the impingement cooling chamber (10). Guide vane according to claim 15,
characterized in that
the separating elements (14) are held on the baffle cooling plates (9).

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