WO2008141813A2

WO2008141813A2 - Blade for wind turbines with a vertical rotational axis

Info

Publication number: WO2008141813A2
Application number: PCT/EP2008/004062
Authority: WO
Inventors: Lucio Zancai
Original assignee: Ropatec Srl
Priority date: 2007-05-24
Filing date: 2008-05-21
Publication date: 2008-11-27
Also published as: ITBZ20070022A1; EP2147210A2; WO2008141813A3

Abstract

The invention relates to a blade for wind turbines with a vertical rotational axis, said blade being supported by a single arm (2), which projects radially from a hub (1) that is mounted to rotate (R) around the vertical axis (A). Said blade has a substantially elliptical linear (3) or hastate (30) contour that is symmetrical about a horizontal axis (H), the cross-section having a substantially elliptical form in relation to the vertical cross-section, which contains the vertex of the dorsal and ventral surfaces of the blade (3, 30), said form being defined by the curved profile (3i, 3e, 13e; 30i, 30e, 130e) of said surfaces. The vertexes of said curves dip in the region of greatest width (chord) of the blade (3, 30), forming the region, to which the single supporting arm (2) can be attached or fixed (3f, 30f).

Description

WING TURBINE WINGS WITH VERTICAL THREE AXIS

description

It is known that the wind turbines have a vertical axis of rotation, e.g. use of Darrieus type at least two spaced from the rotation axis wings; These wings can be straight, curved or in the shape of a helix. In general, these wings extend vertically straight, have rectangular more or less slender shape and have the cross-section of a wing. The connection between the wings and the central hub consists of plates which are connected to the wing tips or of arms which are arranged like a spoke and in different ways, with or without the use of encompassing mounting brackets, are attached.

The support arms are usually two per wing, the one arm per wing systems are currently limited to wind generators of considerable dimensions.

It is known that the rectangular shape of the wing loses a not to be underestimated percentage of the aerodynamic thrust surface in that the area of the fluid dynamic pressure and vacuum distribution is distributed on an elliptical surface of the rectangular wing surface. This has the consequence that the rectangular wings are weighted by a ballast which causes various disadvantages:

Loss of aerodynamic efficiency in all speed ranges due to the increase in drag typical of rectangular or tapered vanes, problems in static and dynamic balancing,

- loads caused by increased weight and centrifugal force,

- oversizing of the support and fixing structures, Loss of efficiency due to aerodynamic drag as a whole, caused by the aforementioned disadvantages,

- greater moment of inertia.

The structural elements of said known vertical generators are further burdened by increased expenses resulting from the project creation for the purpose of correct shaping. In particular, attempts to reduce the number of arms to possibly a single arm have not yielded satisfactory results today because the proposed solutions provide little rigidity, generate mechanical resonances, and provide little safety and durability because of their aerodynamic performance

Efficiency should not be exaggerated, not dimensioned accordingly.

The invention has as its object to provide a wing for wind turbines with vertical axis of rotation which, in relation to the weight and the

Dimensions, remarkable aerodynamic efficiency and such stability provides that the connection with the hub is favored by a single arm.

As a solution to this problem, the invention proposes to provide the wing with a substantially elliptical outline with a straight or arrow-shaped arrangement, symmetrical according to a horizontal axis and possibly, in the case of a straight arrangement, also according to a vertical axis, wherein the cross section of the wing in the area is the largest of the horizontal axis of symmetry and decreases in the direction of both ends of the wing, top and bottom, such that a cross-section is formed in the region of the vertical axis elliptical shape or at least the maximum dimension in the horizontal axis and the minimum extent in the range the two ends has.

The elliptical outline of the wing allows the optimization of the aerodynamic and fluidodynamic efficiency and thus the Performance with a minimum of wing surface and therefore with a minimum of weight. The section according to the vertical axis which has an elliptical or conical, symmetric or asymmetrical shape along the vertical axis makes it possible to achieve considerable stability of the wing shape with a sturdy mounting or connecting area for the support arm, this Area through the zone of the vertex or the apex of the curvature or conicity which substantially coincides with the area of the center of mass, possibly with the geometric center of the wing surface and the center of the aerodynamic and inertial loads acting on the wing, this area includes the intersection between the horizontal and the possible vertical axis of symmetry, or between the horizontal axis of symmetry and a substantial central line between the leading edge and the trailing edge of the wing, or between the horizontal axis of symmetry and the line which aerodynami connecting pressure centers; in the case of an elliptical wing with an arrow shape, this area is determined by the intersection of the two lines connecting the printing centers, this intersection being on the horizontal axis of symmetry.

The section through the wing according to a vertical substantially central line or according to the possible vertical axis of symmetry, or in the case of an arrow-shaped wing according to a vertical axis which passes through the intersection of the lines through the printing centers, has an elliptical shape resulting from the curvature of the back and the abdominal surfaces, resulting in the creation of a resilient self-supporting and possibly reinforced wing structure in this area, which is provided for the efficient and stable permanent attachment of the support arm. In particular, the oppositely arched back and abdominal surfaces of the wing, in the case of a shell structure, impart a remarkable dimensional stability to the wing, due to the fact that the domes act as a self-supporting arch or cone structure which in particular acts on the loads which are perpendicular to the vertexes of the domes . resist. Said features give the wing more shape-related structural properties which further material savings and thus a weight saving is possible. Alternatively, it is also possible to use materials which have lower structural properties and are thus less costly. Thus, on the wing according to the invention, the aerodynamic and mechanical loads are spontaneously directed to the center of the wing of elliptical contour corresponding to the area of the vertex of the sash of the sash where attachment or attachment of the end of the single girder arm is provided which has a cross-section and rigidity which are suitable to achieve the necessary stability and resistance to generally avoid induced resonances and vibrations.

In general, the wings of a wind rotor are arranged with the vertical axis parallel to the vertical axis of rotation, but the constructive features proposed by the invention do not rule out that the wings are arranged with the axis of the wing extension to the vertical angled, in which case all the above aerodynamic and mechanical advantages are maintained.

The invention will be explained in more detail with reference to two, in the accompanying drawings schematically illustrated, preferable embodiments of a wing according to the invention for wind turbines with a vertical axis of rotation closer, the drawings meet purely explanatory and non-limiting purpose.

Fig. 1 is a schematic perspective view of a vertical axis of rotation wind turbine with three blades according to the invention, each carried by a single arm which projects radially from a hub; it is the wind direction and the direction of rotation marked. Fig. 2 shows the plan view of the substantially elliptical wing according to the invention with an indication of the area of attachment of the single support arm by hatching and hinting of the different wing cross-section in two spaced-apart positions.

Fig. 3 shows the longitudinal section of the wing shown in Fig. 2 according to a vertical sectional area which includes the vertical axis of the wing.

Fig. 4 shows the elliptical outline of an arrow-shaped wing according to the invention with an indication of the area of attachment of the single support arm by hatching and with an indication of the wing profile in two spaced-apart positions.

FIG. 5 shows the section according to a vertical sectional area which passes through the intersection of the lines which connect the aerodynamic pressure points on the wings shown in FIG.

FIG. 6 shows the section according to a sectional area containing the line connecting the aerodynamic printing centers on the wing shown in FIG.

The wind turbine with a vertical axis of rotation is essentially composed of a central hub 1 mounted to rotate about a vertical axis of rotation A, consisting of support arms 2 which project radially from said hub 1 and wings 3 secured to the outer ends of these arms 2. The wing 3 according to the invention has a substantially elliptical outline in the sense that, be it the leading edge 3b and the trailing edge 3c arcuate, substantially elliptical arc-shaped with stronger or weaker expression, are. At the two ends of the wing 3, the connecting or transition lines 3g between the leading edge 3b and the trailing edge 3c may be substantially rectilinear 3g or arcuate 13g. The wing 3 has a horizontal axis of symmetry H and possibly a vertical axis of symmetry V, for example when the leading edge has a curved course 13b which is identical to the course of the trailing edge 3c. If, however, said two edges of the wing 3 have different course, the axis V will be a substantially central line which vertically, geometrically at half the distance between the two edges through the center of gravity of the wing 3, which is slightly closer to the leading edge 3b extends or passes through the aerodynamic pressure centers of the wing.

According to the invention, the wing in the region of the horizontal axis of symmetry H has the largest width (chord) and also the wing profile here corresponds to the largest cross-section. As the distance from said horizontal axis of symmetry H _{1 increases} in the direction of the upper and lower end of the wing, the wing profile changes by becoming progressively narrower and having a minimal cross-section at both ends. Near the horizontal axis H, the wing profile may be of the type "naca 0021", for example, while the wing profile may be of the "naca 0012" type in the direction of the two ends. These progressive changes in the cross-section of the wing 3 cause both surfaces of the wing, those on the back and on the belly side, to have an outwardly curved shape with the vertexes substantially located in that region where the intersection between the horizontal axis of symmetry H and the vertical axis of symmetry V, or the vertical center line is located, or where the wing 3 has the maximum width (chord). The shape of the vertical section (FIG. 3) of the wing will therefore be elliptically symmetrical according to the invention or be asymmetrical if, for example, the curvature on one side of the wing is more pronounced, as illustrated by the dashed line 13e. Regarding the extent of the progressive change of the cross-section of the wing, the curvature may also be "conical", in which case the lines 3i, 3e and 13e will essentially be rectilinear oblique and form a vertex (a curve tip) in the region of the horizontal axis of symmetry H.

After all, the invention does not exclude that one of the lines of the longitudinal section of the wing is arc-shaped, for example elliptical, runs while the corresponding line on the opposite side is rectilinear, wherein, in the region of the horizontal axis H, the vertex of an obtuse angle is formed.

The substantially elliptical longitudinal section of the wing 3 gives the wing, due to the curved or conical, a remarkable stability and creates in the area of the horizontal axis of symmetry H a zone 3f which, regarding the structure and the dimensions, for the effective and resistant attachment of the outer end of the support arm 2 is suitable.

The shape of the blade 3 according to the invention lends itself to a one-piece or a composite shell construction, with or without internal filling material, to the advantages of, caused by the curved "dome-shaped" shape of the shell, stability as well as a construction with internal supporting structure which is covered by said shell, used, in which case said shell exclusively aero- and fluidodynamic functions fulfilled or, together with said internal structure, has a supporting function.

The thickness of the one-piece or composite shell forming the shape of the wing 3 may be constant or different in relation to the loads acting thereon.

In the case of an arrow-shaped wing with an elliptical contour (FIGS. 4, 5, 6), this invention always has a horizontal axis of symmetry H and the area of attachment or attachment 3Of of the single beam 2 lies substantially in the region of the horizontal axis of symmetry H and the point of intersection the lines G connecting the aerodynamic pressure centers. In this case too, this area 30f corresponds to the circle tip or the vertex of the curvature of the back-side surface 30e and the belly-side surface 30i of the vane 30. The curvature of said surfaces may be symmetrical, according to a vertical axis S, or, for example, if the back surface 3Oe is more curved than the curvature 3Oi of the abdominal surface, is asymmetrical.

Of course, even in the arrow-shaped embodiment, the transition lines between the leading edge 30b and the trailing edge 30c at the two ends of the wing 30 arcuately 130g or pointed 30g run. The progressive reduction of the wing profile from the region of the horizontal axis of symmetry H to the two ends of the wing 30 causes substantially in the region of the lines G which connect the aerodynamic pressure centers, the back surface and the abdominal surface curved or straight angled 30h, 30k run.

The curved course 3Oi ₁ 3Oe ₁ 13Oe of the back and the abdominal surface in the region of the horizontal axis of symmetry H causes that in the area 3Of the vertex of the said bulges, the ideal, most resistant point, with the largest cross-section, for the attachment or connection of the single support arm 2 is.

The bulges which are represented by the lines 3h and 30k bring about the necessary stability and rigidity in the region of the lines G for those parts of the wing 30 which extend "backwards" beyond the attachment region 3Of to the rear less pronounced, with the lines G forming an angle between an obtuse angle near 180 ° and an acute angle smaller than 90 °.

Claims

1. Wing for wind turbines with a vertical axis of rotation which is supported by a single, radially from a, according to the vertical axis (A) rotatably mounted (R) hub (1) arm (2), characterized in that the wing substantially elliptical straight (3 ) or arrow-shaped (30), symmetrical contour according to a horizontal axis (H), that the section according to a vertical sectional area which includes the vertexes of the back and the belly side surface of the wing (3, 30) has substantially elliptical shape which of the arched Course (3i, 3e, 13e, 3Oi, 3Oe, 13Oe) of these surfaces is defined and that the vertexes of the said bulges in the region of the greatest width (chord) of the wing (3, 30) fall and the area for attachment or attachment (3f, 30f) of the single support arm (2).

2. Wing according to claim 1, characterized in that the course of the leading edge (13b) of the wing (3) and / or the positioning of this, in relation to the course of the trailing edge (3c), takes place symmetrically according to a vertical axis (V).

3. wing according to claims 1 and 2, characterized in that one of the transition edges or both transition edges at the two ends of the wing substantially straight (3g), arcuate (13g, 130g) or pointed (30g) can extend.

4. wing according to claims 1 and 2, characterized in that each cross section of the wing has a wing profile wherein the largest cross section in the region of the horizontal axis of symmetry (H) and progressively smaller cross-sections in the direction of the two ends of the wing (3, 30) appear and the progressive reduction of the cross-section shows a straight or curved course of the lines (3i, 3e, 13e, 3Oi, 3Oe, 13Oe) causes the curvature of the back and the belly side surfaces of the wing (3, 30).

5. A wing according to claims 1 and 2, characterized in that the curvature (3i, 3e, 13e; 3Oi, 3Oe, 13Oe) of the back and the belly side surfaces of the wing (3, 30) symmetrically according to a vertical axis (V, S) runs.

6. wing according to claims 1 and 2, characterized in that the curvature of the back and the abdominal surfaces of the wing (3,

30), according to a vertical axis (V, S) is asymmetrical.

7. wing according to claims 1 and 2, characterized in that the supporting structure of the wing (3, 30) consists of a one-piece or a composite shell which is consistent or, in

Depending on the loads acting on the structure with or without internal filler material, different wall thicknesses in the different areas.

8. wing according to claims 1 and 2, characterized in that the

Strains which act on the wing (3, 30) are predominantly absorbed by a structure located inside the shell, the shell in this case having predominantly aerodynamic functions.