AT522086B1 - AERODYNAMIC COMPONENT - Google Patents

Abstract

An aerodynamic component (10), e.g. B. a rotor blade whose blade shape has an overpressure side (14) and a negative pressure side (13) between a leading edge (15) and a trailing edge (16). The overpressure side and the underpressure side have a surface with a corrugated structure (11) which is formed by a plurality of ribs which run parallel to one another in a direction (V) from the leading edge to the trailing edge and in the direction corresponding to a flow path along the sheet shape have a profile with alternating convex wave crests and concave wave troughs perpendicular to the course direction.

Description

description

AERODYNAMIC COMPONENT

TECHNICAL AREA

The invention relates to an aerodynamic component. In particular, the invention relates to an aerodynamic component with a sheet shape having an overpressure side and a negative pressure side, wherein the overpressure side and the negative pressure side run between a leading edge and a trailing edge of the sheet shape; the overpressure side and / or the underpressure side has / have a surface with a wave structure which is formed by a plurality of ribs which run parallel to one another in a direction corresponding to a flow path of the surrounding aerodynamic medium along the blade shape. An aerodynamic component of the type according to the invention can e.g. be used in a wind turbine as a rotor blade of a rotor consisting of several rotor blades; this rotor can be designed with a horizontal axis of rotation (e.g. with three rotor blades anchored in a central hub) or a vertical axis of rotation (e.g. Darrieus rotor). Other possible applications are that of a wing, a drive rotor (in air or water), etc.

STATE OF THE ART

In the laid-open specification DE 102006043462 A1, a component with a turbulent overflow trailing edge is shown, which has the purpose of reducing trailing edge noise. In EP 0724691 B1, a surface is presented, the task of which is to make a surface of a body around which fluid flows and with elevations protruding from the base area (and beyond it) more favorable to the flow. EP 1805412 shows a turbine having at least one aerodynamic component with a shaped profile nose which extends the length of the aerodynamic component to define a series of spaced, forwardly extending humps (also known as a so-called "whale blade").

DISCLOSURE OF THE INVENTION

The invention is based on the object of creating an aerodynamic component whose air resistance (in general: flow resistance) is lower than that of a blade with a smooth surface, in particular by preventing the (transverse) flow from flowing off to the wing tip (or rotor blade tip ). This should also improve the efficiency of the component and at the same time the efficiency by changing the blade geometry, whereby at least the transition point at which the laminar flow changes into a turbulent flow should be shifted as far as possible towards the trailing edge by at least partially channeling the fluid flow in the main flow direction.

To solve this problem, the invention proposes an aerodynamic component in which the ribs of the wave structure run parallel to each other from the leading edge to the trailing edge and have a profile with alternating convex wave crests and concave wave troughs in the direction perpendicular to the direction of travel. The aerodynamic component thus has on the negative pressure side or the positive pressure side, preferably on both sides, a substantially wavy (grooved) surface extending from the front edge to the rear edge. The flow along the aerodynamic component is generally considered to be laminar, with the occurrence of turbulent flow on the surfaces of the overpressure and underpressure side being avoided as far as possible and / or being limited to surface structures in the laminar boundary layer (see below).

The surface thus has a structure with waves, with a wave profile whose wave crests and valleys run along a direction transverse to the longitudinal direction of the component, the wave crests and wave troughs running essentially parallel to one another. The wave structure can run straight or have a curvature (viewed in a plan view of the respective area of the surface); in the case of a curved

The course of the wave structure means that “parallel” means that the wave peaks and valleys run at a constant distance from one another. For example, the corrugations on the positive pressure and negative pressure side can have a curvature towards the blade tip (i.e. protruding towards the blade tip, the center of curvature facing away from the blade tip); however, it is also possible that the curvature on one side is smaller than that on the other side and / or the curvatures run in opposite directions - e.g. the course on the positive pressure side can be curved towards the hub, while on the negative pressure side there is a curve towards the blade tip). The belly of the curve on the positive pressure side preferably also points towards the tip of the blade. In addition, the waves can also run straight in certain sections. In a further variant, the curvatures can also be provided in opposite directions.

It was recognized that the wave structure according to the invention, in which the wave peaks (and valleys) extend from the leading edge to the trailing edge of the sheet surface (s), channels the air flow. A medium (for example air) flowing over the rotor blade can in this way be efficiently guided in such a way that an undesired lateral drift flow along the longitudinal axis is reduced. This also has an advantageous effect on noise emissions during operation. For this purpose, it is advantageous if the air guiding grooves are aligned essentially parallel to one another. The flow velocity in the channel is significantly increased.

The wave structure can preferably extend beyond the leading edge and trailing edge (protrude), so that the wave crests begin in front of the leading edge of the sheet (i.e. profile nose) and end after the trailing edge of the sheet. In this case, the chord length of the blade in the area of the wave crests around the protrusion at the leading edge and trailing edge of the blade is longer than the chord length of the wave troughs; In other words, the wave crests protrude both on the leading edge of the sheet and on the trailing edge of the sheet and thus form a more or less wavy line or even a comb-like structure on the leading or trailing edge. This structure leads to a further improved guidance of the flow, with a wave crest projecting over the profile nose and extending over the entire length to the protrusion at the rear edge of the blade channels the flow.

In another embodiment, the wave crests and wave troughs are arranged alternately on the positive and negative pressure side; in this case, the widths of the wave crests and those of the wave troughs are preferably the same. If the wave peaks and valleys here extend to the rear edge (possibly also the front edge), this can result in a wave shape of the edge due to the alternating wave structure ending there.

The waves according to the invention are thus arranged along a direction transverse to the direction of longitudinal extension of the component, and preferably over the entire longitudinal extension from the blade root to the blade tip. The wave peaks and troughs preferably run right up to the edge formed by the rear or front edge or even extend beyond this, as already mentioned above.

In a further embodiment, the wave crests are not the same height over their entire length. In this case, the wave peaks can vary in their longitudinal direction, and / or wave peaks lying next to one another can have different heights.

The cross section of a wave crest can, for example, be approximately a parabola, whereas that of the wave trough preferably has a basket arch-like cross section. In this context, basket arch is understood to mean the shape (known, for example, from architecture) of an arch composed of circular arc sectors, the curvature of an arch sector located further out being less than that of an arch sector further inward. It is also beneficial if a wave trough is between half and five times as wide as the height of a wave crest. The height of a wave crest - especially when used in air or another gaseous flow medium - can assume any suitable value, for example between 5 nm and 250 mm; a preferred range of height is between 50 mm and 150 mm.

[0012] The height of the wave crest can be adjusted along the longitudinal direction of the aerodynamic

mix component vary. For example, starting from the blade root, the height can pass through a first maximum and a subsequent relative minimum, but the height preferably assumes a maximum at the blade tip. For example, starting from a small initial value at the leaf root, the height of the wave crests increases to about 15-20% of the longitudinal extension, and then decreases in the range up to about 55% of the longitudinal extension, and increases again from 75% of the longitudinal extension and ends at 100%. (ie at the tip of the blade) with a maximum. In the area of 20-45% of the longitudinal extent, the wave crests can also be designed in such a way that at least one wave crest increases in height from the front edge to the rear edge. The height of the wave crests is preferably based on the thickness of the boundary layer of the air flowing onto the blade.

The length of the aerodynamic component denotes the distance between a root and a tip of the aerodynamic component or (with approximately central suspension) between two tips of the aerodynamic component.

With a constant-length design of the component, at least two different leaf profiles (wave crest module and wave valley module) are coupled to one another in width, firmly connected at the connection point.

In the following, the invention together with further refinements and advantages will be explained with reference to some exemplary embodiments, which are shown in the accompanying figures. The figures show:

[0016] FIG. 1 shows a partial view of an aerodynamic component according to a first embodiment in a perspective view;

[0017] FIG. 2 illustrates a straight course of the wave structure along the course direction;

3 illustrates a curved course of the wave structure, a curvature towards the blade tip (i.e. to the right in the image) being recognizable here;

[0019] FIG. 4 shows a first example of a shape of the wave crests and wave troughs of the wave structure;

[0020] FIG. 5 shows a second example of a shape of the wave crests and wave troughs of the wave structure;

6 shows a third example of a shape with alternating wave profiles;

7 shows a fourth example of a design with alternating wave profiles;

8 shows several exemplary shapes of wave crests;

[0024] FIG. 9 illustrates two possible ways in which the wave structure at the rear edge is

closes, namely on the one hand it ends directly at the rear edge, on the other hand it runs over the rear edge so that a comb-like structure is formed;

10 illustrates a further type of termination of the wave structure at the rear edge, namely a "run-out" in which the total height decreases to zero towards the rear edge,

11 shows a first example of a surface design of the wave structure with a groove structure as a superstructure,

Fig. 12 shows a further example of a surface design of the wave structure with lattice-like arranged dimples as a superstructure,

13 shows another example of a surface design, namely with hemispherical knobs as a superstructure in a wave trough,

14-16 show, each in perspective detailed views z. B. the upper side, various examples of a course of the height of the wave structure oscillating along the course direction, namely FIG. 14 a sinusoidal course, FIG. 15 an asymmetrical wave-like course, and FIG. 16 a sawtooth-like course.

It is understood that the embodiments discussed here are exemplary in nature and not restrictive of the present invention. It is also understood that all embodiments can be combined with one another wherever this can be useful, in particular the special features of one embodiment can be combined with the special features of another embodiment.

Fig. 1 shows an aerodynamic component 10 according to a first embodiment of the invention, which is a rotor blade of a wind turbine. Only part of the component 10 is shown in the figure, namely the hub-side end (“root”) of the rotor blade with an end surface 12, which at the same time also realizes a cross-sectional area according to an airfoil profile of a type known per se. In Fig. 1, the negative pressure side 13 of the component 10 is shown oriented upwards, and the overpressure side 14 (of which only the hub-side edge 14 'is visible in Fig. 1) is shown oriented downwards.

The flow direction of the aerodynamic medium - here air - is in Fig. 1 along the course direction V coming from the right at the front edge 15 (profile nose) over the surfaces of the positive and negative pressure side to the rear edge 16 and beyond.

According to the invention, the surfaces of the overpressure and underpressure sides 13, 14 have a wave structure 11, the wave crests and wave troughs running essentially parallel to one another and preferably along the direction V. In the embodiment shown in FIG. 1, the wave structure runs continuously from the positive pressure side 14 over the rounding of the front edge 15 to the negative pressure side 13; the waves of the wave structure meet at the rear edge 16 and form a comb-like shape there.

In this embodiment, the wave structure 11 runs straight along the direction V. In a plan view of the relevant surface - see FIG. 2 - the wave peaks (or wave troughs) thus form straight lines.

Alternatively, as illustrated in FIG. 3, the wave structure 18 can have a curvature; In the case of a curved course of the wave structure, “parallel” means that the wave peaks and troughs run at a constant distance from one another. For example, the waves on the overpressure and underpressure side can have a uniform curvature towards the blade tip (i.e. protruding towards the blade tip, the center of curvature is facing away from the blade tip); in Fig. 3, the blade tip is on the right outside the area shown. This is advantageous in the case of a rotor blade, for example. Furthermore, in variants (not shown) it is possible for the curvature on one side to be smaller than that on the other side and / or for the curvatures to run in opposite directions - e.g. the course on the positive pressure side can be curved towards the hub, while on the negative pressure side the curve towards the blade tip exists. The “belly” of the curve on the positive pressure side preferably also points towards the tip of the blade. In another variant (not shown), the waves can also run straight in certain sections. In addition, the curvatures of the two sides can also be designed in opposite directions, wherein the rear edge can have an S-shaped profile.

In general, the wave structure according to the invention is arranged transversely to the direction of longitudinal extension of the component. The corrugated structure is preferably present over the entire length of the component and can have constant or varying characteristics.

The shape of the wave crests and troughs in the wave structure according to the invention and their height and width can be selected depending on the desired application. In the context of this disclosure, the terms height and width are to be understood to mean that the height and width of the wave crests are measured in relation to that level that the edge of the

corresponds to concave curvature of the wave troughs. The height and width of the wave troughs are also measured in relation to the level mentioned, thus in relation to the concavely curved area of a wave trough. The height of the wave structure (total height) is the height of the "peak" of a wave crest above the "bottom" of an adjacent wave trough, i. H. the sum of the height of the wave crest and wave valley.

FIG. 4 shows an example of a shape based on a perspective sectional view of the rear edge H, the cutting plane running along the rear edge H transversely to the central plane of the component (i.e. "vertical" in FIG. 4). It can be seen that the wave crests 21, like the wave troughs 22, are designed with a cross section in the form of a parabola. Here, the wave troughs are preferably significantly flatter than the wave crests, i.e. H. their width is greater and their height is less than that of the wave crests.

The wave structures of the negative and positive pressure sides are here, for example, symmetrical to one another, but the wave structures of the two sides can optionally also be designed differently.

In another favorable shape, which is shown in Fig. 5, the wave crests 25 are constructed on the top (low pressure side) with a trapezoidal cross-section, preferably according to an isosceles trapezoid. The wave crests can be designed in modified variants so that they represent a generally non-symmetrical trapezoid.

The parabolic shape of a groove structure enables a comparatively greater height of the wave structure, which means that a thick boundary layer can also be reliably guided. The trapezoidal shape is a shape that can effectively guide thinner boundary layer thicknesses in channels, in addition, the cross-section of a trapezoidal groove is also larger, and the effective cross-sectional area of the blade of the aerodynamic component increases by the height of the wave crests.

As can also be seen in Fig. 4, the height of the wave crests can vary transversely to the direction of travel, i.e. different wave crests can have different height values. For example, different areas along the longitudinal extent of the component can have wave crests (or wave structures) of different heights. This is illustrated in FIG. 4 using the smaller wave crest 23. For example, the height of the wave structure can vary in certain areas depending on the expected flow velocity over the respective area of the aerodynamic component (e.g. in the case of a rotor blade).

Fig. 6 shows a further embodiment of a wave structure, wherein the wave crests on the top and bottom (low and high pressure side) each have alternating heights. This can also be done e.g. B. go hand in hand with a different shape of the wave crests of different heights (here alternating parabolic and trapezoidal). The position of the wave crests is symmetrical with regard to the top and bottom, but in the embodiment shown, with regard to its position, a “large” wave crest 61 on the upper side corresponds to a “small” wave crest 63 on the bottom and vice versa (wave crests 62, 64). This results in a design with a "zigzag" band in the direction of view along the center plane towards the rear edge, and stabilization of the blade in the flow is to be expected, in particular the vibration in the turbulence is reduced. The wave troughs 60 here preferably have the same height (on both sides), which, however, is less than the smallest height of the wave crests.

Fig. 7 shows another embodiment, wherein the wave structures of the top and bottom are offset from one another so that a wave crest 71, 72 of the top is opposite a wave trough 70 of the bottom and vice versa. A “corrugated” trailing edge of this type provides a favorable way of merging the currents on the top and bottom of the rotor blade, since the flow threads on the two sides that are guided between the wave crests alternately intermesh. The resistance and glide ratio remain essentially the same, but the noise emission is significantly reduced.

Fig. 8 shows some further examples of useful crest shapes, indicated by letters (a) through (g); the shape is characterized by its cross-section.

ized: The shape (a) is a trapezoidal shape with rounded flanks (truncated parabola); shape (b) is a symmetrical trapezoid; Forms (c) and (d) are asymmetrical trapezoids, with one edge in form (d) standing at right angles to the top surface. The shapes (e), (f) and (g) show different arch shapes, namely (e) and (f) parabolic shapes with different height-to-width ratios and (g) a parabolic arch placed on a trapezoid. The outwardly rounded “feet” in shapes (a), (e) and (f) do not belong to the wave crest, but are already part of the adjacent wave valley.

The wave troughs are designed in cross section in the form of parabolas or preferably of basket arches. More generally, of course, other concave shapes are also possible.

The height of the wave crests can be constant or vary along their course. The height of the wave crests can vary in sections, the height and optionally also the width of the wave crests varying in a running manner. Likewise, the height of the wave troughs can, if desired, vary in sections, wherein this variation can be independent of that of the wave crests or z. B. can be done synchronously with a corresponding variation in the height of the wave crests (varying height of the wave structure). For example, FIG. 10 shows a wave structure 19, the total height of which decreases to zero towards the rear edge.

The tip of a wave crest thus forms a “peak line” running in the direction of its course, which, depending on the location on the aerodynamic component, runs at a varying or constant height, or can be jagged. Jagged is to be understood as a formation of the summit line in general with minima and maxima, possibly also with steps. Some examples of a serrated course of the wave crests are illustrated in FIGS. 14 to 16. The height of the wave structure thus oscillates along the course direction (spatial oscillation), with the height of a wave crest increasing and decreasing. In FIG. 14, each wave crest has a sinusoidal profile 94 between a local minimum value and a local maximum value. At the same time, the shape of the profile changes between trapezoidal and parabolic; Of course, in variants (not shown), the shape of the profile can remain the same (e.g. parabola with modulated height), with only the size or height of the wave crest being varied along the course direction. In FIG. 15, the rising and falling edges of the oscillation of the wave crest height are designed asymmetrically in the course 95. In FIG. 16, the oscillating height has a sawtooth-like profile 96.

The wave structure can preferably extend (protrude) beyond the leading edge and trailing edge, so that the wave crests begin in front of the leading edge of the sheet and end after the trailing edge of the sheet. In this case, the chord length of the sheet in the area of the wave crests around the protrusion at the leading and trailing edge of the sheet is longer than the chord length of the troughs; In other words, the wave crests protrude both on the leading edge of the sheet and on the trailing edge of the sheet and thus form a more or less wavy line or even a comb-like structure on the leading or trailing edge.

Two different ways of terminating the wave structure at the trailing edge H are illustrated in FIG. In the area 91, the wave structure ends directly at the rear edge.

The profile of the wave structure at the rear edge is clearly visible through. Alternatively (not shown) the wave crests could be rounded, running around the rear edge H from the top to the bottom. In the area 92, the wave crests extend beyond the rear edge H and thus form a comb-like structure 93.

This structure 93 at the trailing edge leads to a further improved guidance of the flow, with a wave crest projecting over the profile nose and extending over the entire length to the protrusion on the trailing edge of the blade channels the flow.

The wave structure can also be equipped with a surface design in which the surface of the wave peaks and / or valleys have an additional structure in the manner of a superstructure, the size scale of which is of course smaller than that of the wave structure itself, namely by at least one order of magnitude ( ie a factor of at least e or 10), preferably by at least two orders of magnitude. Preferably the surface consists of

a fabric whose basic substance is coated with nanofilaments, for example made of silicone or Teflon fibers.

The aerodynamic properties of a rotor blade are essentially determined by the formation of a boundary layer flow on its surface, and the surface design can significantly improve the boundary layer flow and in particular the flow resistance determined by it.

Referring to the first variant of the surface design shown in FIG. 11, it has proven to be advantageous if the wave crests and wave troughs, in particular the surface on the overpressure side of the aerodynamic component, have a plurality of substantially parallel air guiding grooves. Preferably, these grooves cover the entire surface of the wave structure, as shown in FIG. 11.

Referring to FIG. 12, in a second variant of the surface design, the wave peaks and troughs are formed with polygonal dimples.

In a third variant (not shown), the surface of the wave crests and wave troughs can be designed with a net-like or grid-like structure pattern.

In a fourth variant, the surface can in particular of the wave troughs with convex structures which, for. B. needle-shaped and / or pin-shaped and / or knob-like are designed to be equipped. 13 shows an example of a surface design of a wave trough with small hemispherical knobs placed on the surface. Here, the pins can be made with the help of natural bristles, glass fibers or hair, the length of which is preferably 5 nm to 5 mm.

Claims (16)

Claims 1. Aerodynamic component (10) with a sheet shape having an overpressure side (14) and a negative pressure side (13), wherein the overpressure side and the negative pressure side between a leading edge (15) and a rear edge (16, H) of the sheet shape run, the overpressure side and / or the negative pressure side have a surface with a corrugated structure (11) which is formed by a plurality of ribs which run parallel to one another in a direction (V) corresponding to a flow course along the blade shape, the ribs of the wave structure (11) to one another run parallel from the front edge to the rear edge and have a profile with alternating convex wave peaks (21, 25, 61, 62, 63, 64, 71, 72) and concave wave troughs (22, 60, 70) in the direction perpendicular to the direction of extension, characterized in that _ the wave structure is additionally equipped with a superstructure, the size scale of which is at least one order of magnitude smaller than that of the wave structure. 2. Aerodynamic component according to claim 1, in which in the profile of the wave structure (11) the wave troughs are wider than the wave crests. 3. Aerodynamic component according to claim 2, in which the wave crests (21, 61, 71, 72) have a parabolic cross-sectional shape. 4. Aerodynamic component according to claim 2, in which the wave crests (25, 62) have a trapezoidal cross-sectional shape, preferably a symmetrical trapezoidal cross-sectional shape. 5. Aerodynamic component according to one of claims 2 to 4, in which the wave troughs (22, 60, 70) have a basket arch-like cross-sectional shape, while the wave crests (21, 61-64, 71, 72) preferably have a width smaller than their height . 6. Aerodynamic component according to one of claims 2 to 5, in which the wave troughs have a width which is between 0.5 and 5 times the height of the wave crests. 7. Aerodynamic component according to one of the preceding claims, designed for operation in a gaseous medium, in particular air, the height of a wave crest in the profile of the wave structure being between 5 nm and 150 mm. 8. Aerodynamic component according to one of the preceding claims, in which the wave crests (61-64, 71, 72) have varying heights in the profile of the wave structure, while the height of the wave troughs (60, 70) remains essentially the same. 9. Aerodynamic component according to one of the preceding claims, in which on both the positive pressure side and the negative pressure side the ribs of the wave structure begin at the front edge (15) and end at the rear edge (16), the wave crests of the wave structure over the front edge and / or the rear edge protrudes. 10. Aerodynamic component according to claim 9, wherein the protruding wave peaks of the wave structure at the front edge and / or the rear edge form a comb-like structure. 11. Aerodynamic component according to one of the preceding claims, in which the ribs of the wave structure on at least one of the positive pressure side and the negative pressure side have a curved course (18), the curved course preferably having a curvature oriented towards a tip of the blade. 12. Aerodynamic component according to one of claims 1 to 11, in which the wave structure on the positive pressure side and the negative pressure side is designed identically, preferably symmetrically to one another. 13. Aerodynamic component according to one of claims 1 to 11, in which the wave structure on the positive pressure side and the negative pressure side is designed identically, the wave structures of the two sides being offset from one another so that a wave crest (71, 72) on one side has a wave trough ( 70) is arranged opposite the other side. 14. Aerodynamic component according to one of the preceding claims, in which the height of the wave structure oscillates along the course direction, in particular with regard to the height of one or more wave crests (94, 95, 96). 15. Aerodynamic component according to one of the preceding claims, wherein the superstructure is designed as a net-like or grid-like structure pattern. 16. Aerodynamic component according to one of the preceding claims, wherein the superstructure is designed as a plurality of convex knobs placed on the surface and / or concave dimples recessed into the surface, the knobs or dimples preferably being polygonal or hemispherical. In addition 6 sheets of drawings