EP2180193A2 - Flow work machine with edge energising near the suction side - Google Patents

Abstract

The fluid flow machine has a main flowing path, in which a set of blades is arranged. The originated fluid jet is aligned tangential to the contour of the main flowing path boundary by the form and orientation of an outlet (6) directly after its entry into the main flowing path during observation in the meridian plane and parallel to the local tangent at the mean line of the adjacent profile of a blade during observation in the plane formed through periphery direction and meridian direction and in the direction of the main stream at the blade ends.

Description

The invention relates to a fluid flow machine with suction side near Randenergetisierung according to the preamble of claim 1.

The aerodynamic load capacity and efficiency of fluid flow machines, such as fans, compressors, pumps, and fans, is limited by the growth and detachment of boundary layers on the blades, and particularly on the hub and casing walls. The prior art provides only limited solutions in the event of high aerodynamic loading and strong boundary layer growth on the annular channel sidewalls (hub or housing).

For blade surfaces (suction and pressure side), however, concepts are known. Related alternative solutions provide for direct passage of the fluid from the blade pressure side to the blade suction side. In addition, there is a concept for rotors for supplying air to the hub and housing by running in the circumferential direction of the machine slots to influence the local wall boundary layers. Finally, there are concepts in which rotors are blown on the housing from individual nozzles in order to favorably influence the radial gap flow there. The general idea of boundary layer control by fluid injection is thus included in the prior art, but there are no effective solutions for interfacing sidewall boundary flow in fixed blade end vane arrangements, i. H. at blade end and main flow path boundary junctions without gap.

• US 5,690,473
• US 6,334,753
• US 2,870,957
• US 2,933,238
• US 5,480,284

The state of the art is partly documented in the following publications:

• US 5,690,473
• US 6,334,753
• US 2,870,957
• US 2,933,238
• US 5,480,284

The flow in blade rows of aerodynamically highly loaded turbomachines has a very high flow deflection to be achieved. The required flow deflection can become so high either in parts of the blade height or along the entire blade height that a conventional arrangement leads to premature detachment of the boundary layer flow in the edge region at the hub and / or housing walls.

Usual rows of blades, as in Fig.1 are shown, without additional design features for stabilizing the wall boundary layers are due to extremely high pressure losses and the failure to achieve the desired flow deflection, both caused by strong secondary flows, boundary layer separation and backflow, unsuitable. The consequence is an overall poor performance of the fluid flow machine in terms of efficiency and available stability margin.

Blade rows with a design according to the prior art, see Fig.1 , due to the strong aerodynamic loading of the sidewall boundary layers, ie the boundary layers formed at the main flow path boundary, have too low a working range and too high losses to provide the operating characteristics required in modern fluid flow machines. Previously proposed solutions for fluid supply at the flow path edge were primarily used to influence the Spaltleckageströmung on rotor tips.

The present invention relates to blades of fluid flow machines such as fans, compressors, pumps, and fans of axial, semi-axial and radial type with gaseous or liquid working fluid. The turbomachine may include one or more stages, each having a rotor and a stator, in some cases the stage is merely formed by a rotor. The rotor consists of a number of blades, which are connected to the rotating shaft of the machine and deliver energy to the working fluid. The rotor can be designed with or without shroud on the outer blade end. The stator consists of a number of stationary blades, which can be designed on the hub side as the housing side with a fixed or free blade end. The rotor drum and the blading are usually surrounded by a housing, in other cases, z. As in propellers or propellers, no housing exists. The machine may also have a stator in front of the first rotor, a so-called leading wheel. At least one stator or Vorleitrad may - unlike the immovable fixation - be rotatably mounted to change the angle of attack. An adjustment is made for example by a spindle accessible from outside the annular channel. Alternatively, said multi-stage turbomachine may have two counterrotating shafts so that the rotor blade rows change direction of rotation from stage to stage. There are no stators between successive rotors. Finally, the fluid flow machine can alternatively have a bypass configuration such that the single-flow annular channel divides behind a certain row of blades into two concentric annular channels, which in turn accommodate at least one additional row of blades. Fig. 2 shows by way of example four possible configurations of the fluid flow machine.

The present invention has for its object to provide a fluid flow machine of the type mentioned, which has an effective boundary layer influence in the blade tip area while avoiding the disadvantages of the prior art.

According to the invention the object is achieved by the feature combination of the main claim, the subclaims show further advantageous embodiments of the invention.

In particular, the present invention thus comprises a turbomachine having a main flow path in which at least one row of blades is arranged, at least one blade end of a blade row having a fixed connection to the main flow path boundary and at least one fluid-supplied edge chamber being provided in the region of this blade end outside the main flow path boundary wherein at least one outlet is provided in the region of said fixed blade end in the vicinity of at least one blade suction side through which fluid from the at least one edge chamber passes substantially in the direction of the main flow onto the surface of the main flow path boundary.

According to the invention, for use in a fluid flow machine, a blade is provided which has a specially shaped tangential jet generation outlet in the vicinity of the blade suction side in at least one of its ends at the main flow path boundary, such that fluid from a chamber outside the main flow path boundary flows in a streamlined manner onto the surface the main flow path boundary can escape.

Fig.1

eine Schaufel nach dem Stand der Technik,

Fig.2

eine mögliche Konfigurationen erfindungsrelevanter Strömungsarbeitsma- schinen,

Fig.3a

ein Beispiel einer erfindungsgemäßen Schaufel, Stator mit freiem Schaufel- ende an der Nabe,

Fig.3b

ein Beispiel einer erfindungsgemäßen Schaufel, Stator mit Deckband an der Nabe,

Fig.3c

ein Beispiel einer erfindungsgemäßen Schaufel, Rotor mit freiem Schaufel- ende am Gehäuse,

Fig.3d

ein Beispiel einer erfindungsgemäßen Schaufel, Rotor mit Deckband am Gehäuse,

Fig.4a

eine erfindungsgemäße Seitenwandstrahlerzeugung, Ringkanalwandan- sicht an einem festen Schaufelende, orthogonale Anordnung der Aus- lasstrajektorie,

Fig.4b

eine erfindungsgemäße Seitenwandstrahlerzeugung, Ringkanalwandan- sicht an einem festen Schaufelende, stromauf geneigte Anordnung der Aus- lasstrajektorie,

Fig.4c

eine erfindungsgemäße Seitenwandstrahlerzeugung, Ringkanalwandan- sicht an einem festen Schaufelende, Auslasstrajektorie vor der Engstelle,

Fig.4d

eine erfindungsgemäße Definition der Trajektorienneigung,

Fig.5a

eine erfindungsgemäße Form des Auslasses, knickartiger Konturübergang, Schnitt Z-Z,

Fig.5b

eine erfindungsgemäße Form des Auslasses, allmählicher Konturübergang, Düsenform, Schnitt Z-Z,

Fig.5b

eine Definition des erfindungsgemäßen Auslasses, Betrachtung in einer freien Schnittebene, Düsenform,

Fig.5c

ein erfindungsgemäßer Übergang des Auslasses zur Oberfläche, Schnitt Z- Z,

Fig.5d

ein erfindungsgemäßer Auslass mit Trennsteg oder Umlenkhilfe, Schnitt Z- Z.

In the following the invention will be described by means of embodiments in conjunction with the figures. Showing:

Fig.1

a blade according to the prior art,

Fig.2

a possible configuration of invention-relevant turbomachines,

3a

an example of a blade according to the invention, stator with free blade end on the hub,

3b

an example of a blade according to the invention, stator with shroud on the hub,

3 c

an example of a blade according to the invention, rotor with free blade end on the housing,

3 d

an example of a blade according to the invention, rotor with shroud on the housing,

4a

a sidewall beam generation according to the invention, annular channel wall view on a fixed blade end, orthogonal arrangement of the outlet trajectory,

4b

a side wall beam generation according to the invention, annular channel wall view on a fixed blade end, upstream arrangement of the outlet trajectory,

4c

a sidewall beam generation according to the invention, annular channel wall view on a fixed blade end, outlet trajectory in front of the constriction,

Fig.4d

a definition according to the invention of the trajectory inclination,

5a

an inventive shape of the outlet, kinky contour transition, section ZZ,

5 b

an inventive shape of the outlet, gradual contour transition, nozzle shape, section ZZ,

5 b

a definition of the outlet according to the invention, viewing in a free sectional plane, nozzle shape,

5c

an inventive transition of the outlet to the surface, section ZZ,

5d

an inventive outlet with divider or Umlenkhilfe, section Z Z.

A conventional blade row according to the prior art, as in Fig. 1 has no outlets provided at the main flow path boundary near the suction side for generating a tangential jet. The right side of the Fig. 1 shows a simplified rotor or Statorschaufelreihe 5 in the meridian section with flow from left to right (thick arrow). In the case of conventional blades 5, although the flow runs around the individual profile sections of the blades 5 (see view XX) following the course of the blade passage from the leading edge (VK) to the trailing edge (HK), adverse effects occur near the flow path boundary at hub 3 or housing 1 Secondary flows on the local Rückströmgebiete with partially detached flow result (see dashed arrows in the left and right part of the picture).

The Fig. 3a shows the example of a blade row according to the invention, here a stator with a fixed blade end on the housing 1, where the occurring mechanical loads are further transferred to the structural structure of the fluid flow machine and which is hereinafter referred to as "load-transmitting fixed blade end". At the hub there is a free blade end with running gap.

The blade 5 is shown in the meridian section with flow from left to right, see left part of the picture and in the view X-X (housing view) in the right part of the picture.

The stator has at its load-carrying fixed blade end at least one fluid-supplied, located outside the main flow path primary edge chamber, which is outlined in simplified form and emerges from the at least one outlet fluid to the surface of the Hauptströmungspfadberandung.

The Fig. 3b shows the example of a blade according to the invention 5, here a stator with load-transmitting fixed blade end on the housing 1, and fixed blade end to the hub 3. Between the shroud 10 on the hub 3 and the rotor shaft is a rotating relative motion, wherein sealing tips 11 in a the Shroud 10 surrounding cavity 12 provide a seal. Such a fixed blade end is referred to below as "load-free fixed blade end".

The bucket is in the meridian section with flow from left to right, see left part of the picture and in the view Y-Y (hub view) in the right part of the picture.

The stator has at its load-carrying fixed blade end at least one fluid-supplied primary edge chamber 13 outside of the main flow path 2 from which fluid exits through an outlet 6 fluid to the surface of the Hauptströmungspfadberandung.

The stator also has at least one flow path in the interior of at least one blade 5 connecting the at least one primary edge chamber 13 at the load transmitting fixed blade end to at least one secondary edge chamber 14 defined by its location outside the main flowpath at the other fixed blade end of the stator, at least a secondary edge chamber 14 also exits fluid through at least one outlet 6 onto the surface of the main flow path boundary.

An inventively favorable case is when, as shown in FIG Fig. 3b , the fixed blade end with secondary edge chamber 14 is a load-free solid Blade end is and the at least one secondary edge chamber 14 is provided within the shroud 10.

As in Fig. 3b illustrated, it is furthermore particularly advantageous according to the invention if, starting from at least one flow path in the interior of at least one blade 5, at least one outlet 15 is provided to at least one of the two blade surfaces (convex suction side SS, concave pressure side DS) through which additional fluid can escape. wherein it is furthermore advantageous if, when a plurality of outlets 15 are provided on blade surfaces, at least three slot-like outlets 15 arranged side by side and in a row substantially in the main flow-transverse direction are provided on the suction side.

The Fig. 3c shows the example of a blade row according to the invention, here a rotor with load-transmitting fixed blade end to the hub. On the housing 1 is a free blade end with running gap.

The blade 5 is shown in the meridian section with flow from left to right, see left part of the image and in the view Y-Y (hub view) in the right part of the picture.

The rotor has at its load-carrying fixed blade end at least one supplied with fluid, located outside of the main flow path primary edge chamber 13, which is outlined in simplified form and exits through at least one outlet fluid 6 on the surface of the Hauptströmungspfadberandung.

The Fig. 3d shows the example of a blade 5 according to the invention, here a rotor with load-transmitting fixed blade end to the hub 3 and load-free fixed blade end (with shroud 10) on the housing 1. Between shroud 10 and housing 1 is a rotating relative motion, with sealing tips 11 in a the Shroud 10 surrounding cavity 12 provide a seal. The blade 5 is shown in the meridian section with flow from left to right, see left part of the picture and in the view XX (housing view) in the right part of the picture.

The rotor has at its load-carrying fixed blade end at least one fluid-supplied primary edge chamber 13 outside of the main flow path, from which exits fluid through an outlet 6 to the surface of the main flow path boundary.

The rotor also has at least one flow path in the interior of at least one blade 5 connecting the at least one primary edge chamber 13 at the load transmitting fixed blade end to at least one secondary edge chamber 14 defined by its location outside the main flowpath at the other fixed blade end of the rotor, at least one of the at least a secondary edge chamber 14 also exits fluid through at least one outlet 6 onto the surface of the main flow path boundary.

An inventively favorable case is when, as shown in FIG Fig. 3d in that the fixed blade end with secondary edge chamber 14 is a load-free fixed blade end and that at least one secondary edge chamber 14 is provided inside the cover strip 10.

As in Fig. 3d illustrated, it is furthermore particularly advantageous according to the invention if, starting from at least one flow path in the interior of at least one blade 5, at least one outlet 15 to at least one of the two blade surfaces (convex suction side SS, concave pressure side DS) is created, through which additional fluid can escape. wherein it is furthermore advantageous if, when a plurality of outlets 15 are provided on blade surfaces, at least three slot-like outlets arranged side by side and in a row essentially in the main flow-transverse direction are provided on the suction side.

The opening of at least one outlet 6 at the main flow path boundary of the relevant blade row is provided according to the invention in the vicinity of the suction side.

The blade 5 has in the illustration shown in Fig. 3a, 3b . 3c and 3d only one outlet 6 per bucket passage. Notwithstanding this representation, according to the invention, in each case a plurality of outlet openings 6 can also be arranged in a blade passage.

According to the invention, the outlet 6 has an inclined, preferably nozzle-like, shape in the main flow direction, the fluid jet emerging from the outlet 6 through the outlet opening receiving an essential component parallel to the main flow and in this way substantially tangential to the main flow path boundary.

According to the invention, the edge contour can run smoothly in the area of the outlet opening or can have a local recess which is recessed in the main flow direction.

The Fig. 4a shows on its left and right sides of the blade row according to the invention with a fixed blade end in a developed streamline section near a main flow path boundary, as it corresponds approximately to the view XX or YY, ie in the meridian flow direction m and the circumferential direction u formed plane. For the sake of clarity, only two profile sections of the blade row 5 according to the invention are shown. The flow takes place according to the thick arrow obliquely from left to right. Each profile has a skeleton line SL which, for purposes of the present invention, should be within the profile through the center line between the pressure and suction sides and outside the profile through the respective tangential continuation of this center line at the leading and trailing edges.

In the left part of the picture, W indicates the width of the blade passage at the narrowest point between two adjacent blade profiles at the main flow path boundary. The thickness of the profile at the bottleneck is denoted by d.

In addition to the skeleton lines SL of the two profiles shown, a boundary line GL is drawn, which extends according to the invention through the passage formed between two blade profiles and thereby has a constant distance a = W + 0.5-d from the convex side of the skeleton line. This boundary line limits the range of the invention useful positions of outlet openings. Thus, according to the invention, outlet openings are always upstream of the back wall line HKL in the region between the convex side of a skeleton line SL and the concave side of the next one, in FIG Direction of the pressure side of the adjacent profile encountered boundary line GL provided.

The left-hand side of the invention shows examples according to the invention of slot-like outlet openings arranged approximately transversely to the main flow, within the area between the skeleton line SL and the boundary line GL. A small arrow indicates the exiting fluid jet.

According to the invention, positioning of an outlet opening 6 directly on the profile suction side SS (see middle opening) or also on the edge RF of the rounding radius usually provided at the blade ends, also called fillet radius (see rear opening), is favorable. When placed upstream of the leading edge line VKL, the vicinity of the skeleton line is favorable (see front opening).

Through each illustrated outlet opening 6 extends transversely or obliquely to the main flow and the beam exit direction, the respective center line. If, as shown in this example, it is an individually arranged opening, the center line of the opening is defined as the so-called outlet trajectory TJ.

The right-hand side of the invention shows examples according to the invention of rows of outlet openings arranged approximately to the main flow. A small arrow indicates the exiting fluid jet. The individual openings may have an angular or round / oval shape and be regularly or irregularly spaced from each other.

If, as shown in this example, a row of openings arranged transversely or obliquely to the main flow and to the jet exit direction, the connecting line of the centroids of the row belonging to the row is defined as outlet trajectory TJ.

According to the invention it is favorable if the outlet trajectory is oriented in its entire course substantially orthogonal to the local tangent to the skeleton line.

The Fig. 4b shows on the left side a passage between two adjacent profiles on the main flow path boundary. In the passage, dashed lines show a typical structure of isobars (lines of constant static pressure). As can be seen, the isobars are inclined upstream in a wide range and uniformly curved. For functional reasons, it is therefore particularly advantageous according to the invention if an outlet trajectory is inclined upstream and uniformly curved in accordance with the course of the isobars. For clarity, an isobar drawn is drawn through.

In the right part of the picture, the solid isobar is shown again. A part of these isobars is congruent with the trajectory TJ of the likewise marked outlet opening.

In addition, according to the invention, it may be particularly favorable to arrange outlet openings even closer to the suction side of the profile, limited by a boundary line GL which is at a smaller constant distance a = 0.7 * W + 0.5 * d from the convex side of the skeleton line located.

The Fig. 4c shows the inventively particularly favorable position of the exhaust traverse upstream of the line extending in the narrowest cross section between two adjacent profiles LW.

The Fig. 4d clarifies the definition of the inclination of an outlet trajectory according to the invention. A blade profile and an outlet opening are shown dotted in the background as a guide.

The trajectory runs between the starting point TA and the end point TE. According to the invention, the range of angular amounts is decisive, in which the angle of inclination α, which the trajectory TJ travels along its course locally with the skeleton line, is maintained. In order to determine the angle of inclination α at a specific point T of the trajectory TJ, the perpendicular is first to be dropped in the direction of the suction side of the next profile onto the skeleton line SL. As a result, the solder point C is given. The inclination angle α is finally drawn between the picture as in the picture Tangent to the trajectory in the considered point T and the tangent to the skeleton line included in the soldering point C.

According to this definition, for all outlet trajectories according to the invention, the inclination angle α along the entire trajectory has values in the range 0 ° <α <100 °.

Looking at the outlet in an enlarged view in the in Fig. 4b drawn section ZZ, the course of the outlet and the nature of the transition from the outlet to the surface of the main flow path boundary may have different features according to the invention.

Corresponding Fig. 5a the simplest form of an outlet 6 according to the invention is an oblique opening into the surface of the main flow path boundary with the formation of a bend at the entry point (point G) with a smooth course of the contour of the main flow path boundary. The orifice angle β is measured at the point of inflection G between the tangent to the inner contour of the outlet and the tangent to the contour of the main flow path boundary and according to the invention should be less than 25 ° (β <25 °).

The 5 b shows in section ZZ a nozzle-shaped in the direction of the main flow inclined and curved course of the outlet, here with a shoulder in the contour of the Hauptströmungspfadberandung at the confluence. The features of this outlet according to the invention will be described with the aid of two inscribed circles and the center line of the outlet in the plane considered here. First of all, the narrowest cross section of the outlet is found coming from outside the blade. The narrowest cross-section has the width e, but does not have to lie directly at the exit opening of the outlet, as shown here. The center of the circle found in the narrowest cross-section is marked ME. Further into the outlet, further continuously increasing circles may be inscribed to determine the centerline GML of the outlet. Along the center line GML, the effective length k of the outlet is measured, which is limited further inside the blade by the center MI of a last inscribed circle.

The 5c shows in section ZZ further features of the outlet according to the invention, with regard to its transition to the surface of the main flow path boundary. As already in 5 b the narrow section of the outlet 6 has the width e. The point of contact of the inscribed in the narrow cross-section circle with the inner, at this point convex boundary contour of the outlet 6 is denoted by P. The tangent TGA and the tangent TGO serve to describe the transition of the outlet 6 into the surface of the blade. TGA is the tangent at point P to the inner outlet boundary contour. TGO results as a tangent to a circle (not shown in the picture) through the blade surface points X, Y and Z. The point X is obtained as an intersection of an orthogonal to TGA applied tangent to the throat section. The point Y is located in a distance measured along the blade outer contour of two Engquerschnittsweiten (2e) upstream of point X. The point Z is located in a measured along the blade outer contour distance of two Engquerschnittsweiten (2e) upstream of point Y.

Of particular importance is the heel height f, which is measured as the orthogonal distance of the point Q from the tangent TGO. The point Q is located two narrow cross-sectional widths (2e) downstream of point P.

• a.) der Engquerschnitt des Auslasses befindet sich an oder nahe der Auslassöffnung
• b.) der Auslass besitzt vom Engquerschnitt ins Innere der Schaufel gehend eine über der gesamten effektiven Länge k kontinuierlich steigende Querschnittsweite (Düsenförmigkeit zwischen den Anfangs- und Endkreismittelpunkten MI und ME)
• c.) die effektive Länge k, bezogen auf die Engquerschnittsweite e, liegt im Wertebereich k/e > 0,7
• d.) der zwischen den Tangenten TGO und TGA eingeschlossene Mündungswinkel γ liegt im Wertebereich 0° < γ < 60°
• e.) die Absatzhöhe f, bezogen auf die Engquerschnittsweite e, liegt im Wertebereich 0 < f/e < 3.

Finally, according to the invention, the following definitions apply to the shape of the outlet:

• a.) the narrow section of the outlet is located at or near the outlet opening
• b.) the outlet has from the throat cross-section into the inside of the blade a continuously increasing cross-sectional width over the entire effective length k (nozzle shape between the start and end circle centers MI and ME)
• c.) the effective length k, based on the narrow section width e, lies in the value range k / e> 0.7
• d.) included between the tangents TGO and TGA outlet angle γ is in the range 0 ° <γ <60 °
• e.) The heel height f, with respect to the throat width e, lies in the value range 0 <f / e <3.

The 5d shows an outlet 6 with additional design elements. In a particular embodiment according to the invention, at least one separating web 9 can be provided in the area of the outlet 6 or also in the area of the cavity, dividing the supplied fluid flow or similarly deflecting it like a blade lattice before it emerges as a tangential jet onto the blade surface.

The invention can also be described as follows:

1. a.) durch die Form und Orientierung des besagten mindestens einen Auslasses der entstehende Fluidstrahl unmittelbar nach seinem Eintritt in den Hauptströmungspfad bei Betrachtung in der Meridianebene (x-r-Ebene) im Wesentlichen tangential zur Kontur der Hauptströmungspfadberandung und bei Betrachtung in der durch Umfangsrichtung u und Meridianrichtung m gebildeten Ebene im Wesentlichen parallel zur örtlichen Tangente an die Skelettlinie des nächst gelegenen Profils und somit etwa in Richtung der Hauptströmung am besagten Schaufelende ausgerichtet ist,
2. b.) die Öffnung des mindestens einen Auslasses an der Hauptströmungspfadberandung in der durch die Umfangsrichtung u und die Meridianrichtung m gebildeten Ebene stromauf der Hinterkantenlinie zwischen der konvexen Seite der Skelettlinie des nächst gelegenen Profils und einer Grenzlinie vorgesehen ist, wobei die Skelettlinie hier durch die Mittellinie des Profils und ihre tangentialen Verlängerungen an Vorder- und Hinterkante gebildet wird und die Grenzlinie in einem gleichbleibenden Abstand a=W+0,5·d von der konvexen Seite der Skelettlinie durch die zwischen zwei Schaufelprofilen gebildete Passage verläuft, wobei W die Weite der Schaufelpassage an der engsten Stelle und d die Dicke des Profils an dieser Engstelle ist,
3. c.) die Erstreckung und der Verlauf einer einzeln vorgesehenen Auslassöffnung an der Hauptströmungspfadberandung durch eine Auslasstrajektorie charakterisiert wird, wobei die Auslasstrajektorie durch die transversale Mittellinie der Auslassöffnung (quer beziehungsweise schräg zur Hauptströmungsrichtung) gebildet wird,
4. d.) die Erstreckung und der Verlauf einer Reihe nebeneinander vorgesehener Auslassöffnungen an der Hauptströmungspfadberandung durch eine Auslasstrajektorie charakterisiert wird, wobei die Auslasstrajektorie durch die Verbindungslinie durch die Mittelpunkte der in Reihe formierten Auslassöffnungen gebildet wird,
5. e.) mindestens eine Auslasstrajektorie in ihrem gesamten Verlauf Werte des relativen Neigungswinkels α im Bereich 0°< α < 100° aufweist, wobei der relative Neigungswinkel α zwischen der örtlichen Tangente an die Auslasstrajektorie in einem Punkt T und der örtlichen Tangente an die Skelettlinie im Fusspunkt des Lots von T auf die Skelettlinie gemessen wird,

wobei bevorzugt die Öffnung des mindestens einen Auslasses an der Hauptströmungspfadberandung in der durch die Umfangsrichtung u und die Meridianrichtung m gebildeten Ebene stromauf der Hinterkantenlinie zwischen der konvexen Seite der Skelettlinie des nächst gelegenen Profils und einer Grenzlinie vorgesehen ist, wobei die Grenzlinie in einem gleichbleibenden Abstand a=0,7*W+0,5*d von der konvexen Seite der Skelettlinie durch die zwischen zwei Schaufelprofilen gebildete Passage verläuft,
wobei bevorzugt die Öffnung des mindestens einen Auslasses an der Hauptströmungspfadberandung in der durch die Umfangsrichtung u und die Meridianrichtung m gebildeten Ebene stromauf stromauf des engsten Querschnitt der zwischen zwei benachbarten Profilen gebildeten Passage vorgesehen ist,
wobei bevorzugt die Auslasstrajektorie in ihrem gesamten Verlauf im Wesentlichen orthogonal zur örtlichen Tangente an die Skelettlinie ausgerichtet ist,
wobei bevorzugt die Auslasstrajektorie entsprechend dem Verlauf der Isobaren an der Hauptströmungspfadberandung stromaufwärts geneigt und einheitlich gekrümmt ist,
wobei bevorzugt mindestens eine Auslassöffnung unmittelbar an die Profilsaugseite angrenzt,
wobei bevorzugt mindestens eine Auslassöffnung unmittelbar an den Rand des Rundungsradius des Schaufelendes angrenzt,
wobei bevorzugt mindestens eine Auslassöffnung stromauf der Vorderkantenlinie in unmittelbarer Nähe der Skelettlinie vorgesehen ist,
wobei bevorzugt im Bereich des Auslasses oder auch im Bereich der Randkammer mindestens ein Trennsteg vorgesehen ist, der den herangeführten Fluidstrom unterteilt oder auch, ähnlich wie ein Schaufelgitter, umlenkt, bevor er auf die Hauptströmungspfadberandung austritt,
wobei bevorzugt das feste Schaufelende der Schaufelreihe ein lastübertragendes festes Schaufelende ist, und demzufolge das feste Schaufelende und die das Schaufelende umgebende bauliche Struktur keine rotierende Relativbewegung zueinander ausführen,
wobei bevorzugt mindestens eine Randkammer am lastübertragenden festen Schaufelende als Primärrandkammer vorgesehen ist, von der zusätzlich mindestens ein Strömungsweg in das Innere mindestens einer Schaufel führt,
wobei bevorzugt auf der gegenüberliegenden Seite des Hauptströmungspfades die Schaufelreihe ebenfalls ein festes Schaufelende besitzt und dort außerhalb der Hauptströmungspfadberandung mindestens eine Sekundärrandkammer vorgesehen ist, wobei die mindestens eine Sekundärrandkammer durch den mindestens einen Strömungsweg im Innern mindestens einer Schaufel mit der Primärrandkammer in Verbindung steht und durch mindestens einen Auslass Fluid aus der mindestens einen Sekundärrandkammer auf die Oberfläche der Hauptströmungspfadberandung austritt,
wobei bevorzugt das auf der gegenüberliegenden Seite des Hauptströmungspfades vorgesehene Schaufelende ein lastfreies Schaufelende ist und dementsprechend das feste Schaufelende ein von einer Kavität umgebenes Deckband besitzt, wobei das Deckband und die das Deckband umgebende bauliche Struktur eine rotierende Relativbewegung ausführen und die Sekundärrandkammer innerhalb des Deckbandes vorgesehen ist,
wobei bevorzugt ausgehend von mindestens einem Strömungsweg im Innern mindestens einer Schaufel zu mindestens einer der beiden Schaufeloberflächen (konvexe Saugseite und konkave Druckseite) zusätzlich mindestens ein Auslass geschaffen ist, durch den Fluid in den Hauptströmungspfad austritt,
wobei bevorzugt bei Vorsehung mehrerer Auslässe an Schaufeloberflächen mindestens drei schlitzartige im Wesentlichen in hauptströmungstransveraler Richtung nebeneinander und in einer Reihe angeordnete Auslässe an der Saugseite vorgesehen sind,
wobei bevorzugt der mindestens eine Auslass schräg in die Oberfläche der Hauptströmungspfadberandung einmündet und an der Einmündestelle ein Knick zur Kontur der Hauptströmungspfadberandung gegeben ist, wobei der Mündungswinkel β, gemessen am Knickpunkt zwischen der Tangente an die innere Kontur des Auslasses und der Tangente an die Kontur der Hauptströmungspfadberandung, Werte kleiner als 25° aufweist,
wobei bevorzugt der mindestens eine Auslass die Form einer Düse aufweist,
wobei bevorzugt die Kontur der Hauptströmungspfadberandung im Bereich einer Auslassöffnung glatt verläuft,
wobei bevorzugt die Kontur der Hauptströmungspfadberandung im Bereich einer Auslassöffnung einen lokalen, auf die Hauptströmungsrichtung bezogen rücksprungartigen Absatz aufweisen,
wobei bevorzugt die Gestalt mindestens eines Auslasses an einer Strömungspfadberandung an einem festen Schaufelende wie folgt festgelegt ist:

• a.) der Engquerschnitt des Auslasses befindet sich an oder nahe der Auslassöffnung
• b.) der Auslass besitzt, vom Engquerschnitt in die Wandung der Hauptströmungspfadberandung hineingehend, eine über der gesamten effektiven Länge k kontinuierlich steigende Querschnittsweite sowie eine Krümmung einheitlichen Vorzeichens zwischen den Anfangs- und Endkreismittelpunkten MI und ME
• c.) die effektive Länge k, bezogen auf die Engquerschnittsweite e, liegt im Wertebereich
  k/e > 0,7
• d.) Der zwischen den Tangenten TGO und TGA eingeschlossene Mündungswinkel γ liegt im Wertebereich
  0° < γ < 60°
• e.) die Absatzhöhe f, bezogen auf die Engquerschnittsweite e, liegt im Wertebereich
  0 < f/e < 3.

A turbomachine having a main flow path in which at least one row of blades is arranged, wherein at least one blade end of a blade row has a fixed connection to the main flow path boundary and at least one fluid-supplied edge chamber is provided in the area of this blade end outside the main flow path boundary, wherein in the region of said fixed Blade end is provided in the vicinity of at least one Schaufelsaugseite at least one outlet through which fluid from said at least one edge chamber in a flow-favorable manner on the surface of the Hauptströmungspfadberandung in the main flow path passes, wherein:

1. a.) by the shape and orientation of said at least one outlet, the resulting fluid jet immediately after its entry into the main flow path as viewed in the meridian plane (xr plane) substantially tangential to the contour of the main flow path boundary and as viewed in the circumferential direction u and meridian direction m aligned substantially parallel to the local tangent to the skeleton line of the nearest profile and thus approximately in the direction of the main flow at the said blade end,
2. b.) the opening of the at least one outlet is provided at the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m upstream of the trailing edge line between the convex side of the skeleton line of the nearest profile and a boundary line, the skeleton line here through the center line of the profile and their tangential extensions at front and the trailing edge is formed and the boundary line runs at a constant distance a = W + 0.5 · d from the convex side of the skeleton line through the passage formed between two blade profiles, where W is the width of the blade passage at the narrowest point and d is the thickness of the blade Profile at this bottleneck is,
3. c.) the extent and the course of an individually provided outlet opening at the main flow path boundary is characterized by an outlet trajectory, wherein the outlet trajectory is formed by the transverse center line of the outlet opening (transverse or oblique to the main flow direction),
4. d.) the extent and the course of a row of juxtaposed outlet openings on the main flow path boundary is characterized by an outlet trajectory, wherein the outlet trajectory is formed by the connecting line through the centers of the outlet openings formed in series,
5. e.) at least one outlet trajectory has values of the relative inclination angle α in the range 0 ° <α <100 °, the relative inclination angle α between the local tangent to the outlet trajectory at a point T and the local tangent to the skeleton line in the Foot of the lot of T is measured on the skeleton line,

wherein preferably the opening of the at least one outlet at the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m is provided upstream of the trailing edge line between the convex side of the skeleton line of the nearest profile and a boundary line, the boundary line being at a constant distance a = 0.7 * W + 0.5 * d from the convex side of the skeleton line through the passage formed between two blade profiles,
wherein preferably the opening of the at least one outlet is provided at the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m upstream of the narrowest cross section of the passage formed between two adjacent profiles,
wherein preferably the outlet trajectory is aligned in its entire course substantially orthogonal to the local tangent to the skeleton line,
wherein preferably the outlet trajectory is inclined upstream and uniformly curved according to the course of the isobars at the main flow path boundary,
wherein preferably at least one outlet opening directly adjoins the profile suction side,
wherein preferably at least one outlet opening directly adjoins the edge of the radius of curvature of the blade end,
wherein preferably at least one outlet opening is provided upstream of the leading edge line in the immediate vicinity of the skeleton line,
wherein at least one separating web is preferably provided in the region of the outlet or also in the region of the edge chamber, which diverts the introduced fluid flow or, similarly as a blade grid, deflects before it exits onto the main flow path boundary,
wherein preferably the fixed blade end of the blade row is a load-carrying fixed blade end, and consequently the fixed blade end and the structural structure surrounding the blade end do not perform a rotating relative movement to each other,
wherein preferably at least one edge chamber is provided on the load-transmitting fixed blade end as a primary edge chamber, from which additionally at least one flow path leads into the interior of at least one blade,
wherein preferably on the opposite side of the main flow path, the blade row also has a fixed blade end and there is provided outside the Hauptströmungspfadberandung at least one secondary edge chamber, wherein the at least one secondary edge chamber through the at least one flow path in the interior of at least one blade with the primary edge chamber in Connected and emerges through at least one outlet fluid from the at least one secondary edge chamber on the surface of the main flow path boundary,
wherein preferably the blade end provided on the opposite side of the main flow path is a load-free blade end and, accordingly, the fixed blade end has a shroud surrounded by a cavity, wherein the shroud and the structural structure surrounding the shroud perform a rotating relative movement and the secondary edge chamber is provided within the shroud .
wherein at least one outlet is additionally provided, starting from at least one flow path in the interior of at least one blade to at least one of the two blade surfaces (convex suction side and concave pressure side), through which fluid exits into the main flow path,
wherein preferably at Vorsehung multiple outlets on blade surfaces at least three slit-like in the main flow transversal direction side by side and arranged in a row outlets are provided on the suction side,
Preferably, the at least one outlet opens obliquely into the surface of the main flow path boundary and at the injection point a kink is given to the contour of the main flow path boundary, wherein the orifice angle β, measured at the inflection point between the tangent to the inner contour of the outlet and the tangent to the contour of the Main flow path boundary, values smaller than 25 °,
wherein preferably the at least one outlet is in the form of a nozzle,
wherein preferably the contour of the main flow path boundary runs smoothly in the region of an outlet opening,
wherein preferably the contour of the main flow path boundary in the region of an outlet opening has a local, in the main flow direction related recession-like paragraph,
wherein preferably the shape of at least one outlet is defined at a flow path boundary at a fixed blade end as follows:

• a.) the narrow section of the outlet is located at or near the outlet opening
• b.) the outlet has, from the throat cross-section in the wall of the main flow path boundary in going over the entire effective length k continuously increasing cross-sectional width and a curvature uniform sign between the start and Endkreismittelpunkten MI and ME
• c.) the effective length k, in relation to the narrow section width e, lies in the value range
  k / e> 0.7
• d.) The muzzle angle γ enclosed between the tangents TGO and TGA lies in the value range
  0 ° <γ <60 °
• e.) The heel height f, related to the narrow cross section width e, is within the value range
  0 <f / e <3.

The present invention allows a significantly higher aerodynamic load capacity of rotors and stators in turbomachines, with constant or increased efficiency. A reduction in the number of parts and the component weight of more than 20% seems attainable. Using the concept in the high-pressure compressor of an aircraft engine with around 25,000 pounds of thrust results in a reduction in specific fuel consumption of up to 0.5%.

LIST OF REFERENCE NUMBERS

1

casing

2

Ring channel / main flow path

3

Rotor drum (hub)

4

machine axis

5

Blade / blade row

6

outlet

7

peripheral chamber

8th

Tangentialstrahl

9

Divider / diverter

10

shroud

11

sealing tip

12

cavity

13

Primary peripheral chamber

14

Secondary peripheral chamber

15

outlet

Claims (15)

A turbomachine having a main flow path (2) in which at least one row of blades (5) is arranged, at least one blade end of a blade row having a fixed connection to the main flow path boundary and at least one fluid-supplied edge chamber (7) in the area of this blade end outside the main flow path boundary is provided, wherein in the region of the fixed blade end in the region of at least one Schaufelsaugseite at least one outlet (6) is provided, through which fluid from the at least one edge chamber (7) on the surface of the Hauptströmungspfadberandung in the main flow path can be diverted, characterized in that a.) by the shape and orientation of the at least one outlet (6) of the resulting fluid jet immediately after its entry into the main flow path when viewed in the meridian plane (xr-plane) substantially tangential to the contour of the main flow path boundary and when viewed in the circumferential direction u and Meridianrichtung m plane aligned substantially parallel to the local tangent to the skeleton line of the nearest profile of a blade (5) and substantially in the direction of the main flow at the blade end, b.) the opening of the at least one outlet (6) is arranged on the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m upstream of the trailing edge line between the convex side of the skeleton line of the nearest profile of a blade (5) and a boundary line wherein the skeleton line is formed by the center line of the profile of a blade (5) and tangential extensions at a leading and a trailing edge and the boundary line at a constant distance a = W + 0.5.d from the convex side of the skeleton line through the Passage formed between two blade profiles, where W is the width of the blade passage at the narrowest point and d is the thickness of the profile at this bottleneck, c.) the extension and the course of a individually provided outlet opening (6) is formed at the main flow path boundary by an outlet trajectory, wherein the outlet trajectory is formed by the transverse center line of the outlet opening (6), d.) the extension and the course of a row of juxtaposed outlet openings (6) is formed at the main flow path boundary by an outlet trajectory, wherein the outlet trajectory is formed by the connecting line through the centers of the outlet openings (6) formed in series, e.) at least one outlet trajectory has values of the relative inclination angle α in the range 0 ° <α <100 °, the relative inclination angle α between the local tangent to the outlet trajectory at a point T and the local tangent to the skeleton line in the Base of the Lots of T is measured on the skeleton line. A turbomachine according to claim 1, characterized in that the opening of the at least one outlet (6) at the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m is upstream of the trailing edge line between the convex side of the skeleton line of the nearest profile of a blade (5 ) and a boundary line, wherein the boundary line runs at a constant distance a = 0.7.W + 0.5.d from the convex side of the skeleton line through the passage formed between two blade profiles. Turbomachine according to claim 1 or 2, characterized in that the opening of the at least one outlet (6) at the main flow path boundary in the plane formed by the circumferential direction u and the meridian direction m upstream upstream of the narrowest cross section of between two adjacent profiles of blades (5) formed passage is provided Turbomachine according to one of claims 1 to 3, characterized in that the outlet trajectory is aligned in its entire course substantially orthogonal to the local tangent to the skeleton line or that the outlet trajectory is inclined according to the course of the isobars at the main flow path boundary upstream and uniformly curved. Turbomachine according to one of claims 1 to 4, characterized in that at least one outlet opening (6) directly adjacent to the Profilsaugseite or immediately adjacent to the edge of the radius of curvature of the blade end or is provided upstream of the leading edge line in the immediate vicinity of the skeleton line. Flow working machine according to one of claims 1 to 5, characterized in that in the region of the outlet (6) and / or in the region of the marginal chamber (7) at least one separating web (9) is arranged, which divides the supplied fluid flow and / or deflected before this exits on the main flow path boundary. A turbomachine according to any one of claims 1 to 6, characterized in that the fixed blade end of the blade row (5) is a load-carrying fixed blade end, and the fixed blade end and the structural structure surrounding the blade end do not make a rotational relative movement to each other. Turbomachine according to claim 7, characterized in that the at least one marginal chamber (7) is provided on the load-carrying fixed blade end as a primary edge chamber (13), from which additionally at least one flow path leads into the interior of at least one blade (5). Turbomachinery according to claim 8, characterized in that on the opposite side of the main flow path, the blade row (5) has a fixed blade end and outside the Hauptströmungspfadberandung at least one secondary edge chamber (14) is formed, wherein the at least one secondary edge chamber (14) through the at least one flow path in the interior of at least one blade (5) is in communication with the primary edge chamber (13), and through at least one outlet (6), fluid exits the at least one secondary edge chamber (14) onto the surface of the main flow path boundary. In particular, the blade end provided on the opposite side of the main flow path is a load-free blade end and, accordingly, the fixed blade end has a shroud (10) surrounded by a cavity, wherein the shroud (10) and the structural structure surrounding the shroud perform a rotating relative motion and the Secondary edge chamber (14) within the shroud (10) is formed. Flow working machine according to one of claims 8 or 9, characterized in that starting from at least one flow path in at least one blade (5) at least one of the two blade surfaces (convex suction side and concave pressure side) additionally at least one outlet (15) is provided through the Fluid exits into the main flow path. Turbomachine according to claim 10, characterized in that at a plurality of outlets (15) on blade surfaces at least three slot-like outflows (15) arranged side by side and in a row substantially in the main flow-transverse direction are formed on the suction side. Fluid flow machine according to one of claims 1 to 11, characterized in that the at least one outlet opens obliquely into the surface of the Hauptströmungspfadberandung and at the point of introduction a kink is given to the contour of the Hauptströmungspfadberandung, wherein the mouth angle β, measured at the break point between the tangent to the Inner contour of the outlet and the tangent to the contour of the Hauptströmungspfadberandung, values smaller than 25 ° Turbomachine according to claim 12, characterized in that the at least one outlet has the shape of a nozzle. Turbomachine according to claim 12, characterized in that the contour of the main flow path boundary in the region of an outlet opening is smooth running or in the region of an outlet opening (6) have a local, related to the main flow direction recess-like paragraph. A turbomachine according to any one of claims 1 to 11, characterized in that the shape of at least one outlet (6) at a flow path boundary at a fixed blade end is defined as follows: a.) The narrow section of the outlet (6) is located at or near the outlet opening b.) the outlet (6), extending from the throat cross-section into the wall of the main flow path boundary, has a continuously increasing cross-sectional width over the entire effective length k and a curve of uniform sign between the start and end circle centers MI and ME c.) the effective length k, based on the narrow section width e, lies in the value range k / e> 0.7 d.) included between the tangents TGO and TGA outlet angle γ is in the range 0 ° <γ <60 ° e.) The heel height f, with respect to the throat width e, lies in the value range 0 <f / e <3.

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