DE4110540C2 - Wind turbine - Google Patents

Description

The present invention relates to a wind turbine a rotatable wind turbine, the same among themselves, profiled blades, each along a generatrix extend a circular cylinder, evenly on the circumference of the wind turbine, forming a blade ring, are distributed and that a shovel has a wing profile over its entire length has and with the bulging side of the wing profile in Direction of rotation of the wind turbine points.

A flow system is described in US Pat. No. 4,236,866, with the greatest possible flow energy of air or liquid converted into electrical energy for driving pumps shall be. For this purpose, two are along for example a surface line of different diameters profiled rows of blades used, arranged so are that the outer ring in a first direction and the second inner ring in a second direction, the opposite is facing the first direction. The current is in some areas within the system Direction of the longitudinal axis of rotation of the system led to driving of the two rings with the profiled blades. The formation of the blade ring is due to its spatial Geometry relatively complicated and structurally complex.

The FR-PS 557 416 describes a wind turbine in which Inside is a circular cylinder element. This circular cylinder element is surrounded by a rotating blade ring. The blades are thin strip elements educated.

The two German utility models G 87 01 130 and G 82 29 696 show wind turbines with appropriately trained windscreen blades  or blades that are specially rotatably mounted are.

The present invention has for its object a To design wind turbines of the type mentioned at the outset, that in addition to the implementation of the highest possible proportion of possible kinetic energy of the incoming wind enables low-loss conversion into rotational energy of the wind turbine and beyond that the rotational energy into electrical Energy converting aggregate even at high occurring Wind speeds kept in the optimal operating range can be.

The wind turbine according to the invention is characterized by the features of independent claim 1. An advantageous embodiment is the subject of dependent claim 2.

The wind turbine according to the invention is accordingly distinguished characterized in that the wind turbine via a planetary gear the wind turbine is coupled to a rotor of a dynamo machine directly an outer wheel of the planetary gear drives, the dynamo torsionally rigid on the sun gear of the planetary gear is mounted between the outer wheel and Intermeshing sun gear meshed planet gears on a carrier are rotatably mounted on the counter element for the dynamo is torsionally rigid, coaxial to the wind turbine Rotatable circular cylinder element made of air-impermeable material is provided, the outer surface of which is in the form of a circular cylinder jacket has and between the circular cylinder element and the vane ring has a gap, the carrier is torsionally rigid on the circular cylinder element and the Dynamo machine from the circular cylinder element to the first Dynamo rotor rotating in opposite directions due to the Koanda effect is driven.  

A preferred embodiment of the wind power plant according to the invention is characterized in that the space 50 to 200% (percent), preferably 100%, of the greatest starch of the blade profile is.

The invention will now be described with reference to the accompanying drawing explained.  In the drawing shows

Situated Fig. 1 shows a wind power plant according to the invention,

Fig. 2 shows the wind turbine of FIG. 1 in perspective,

Fig. 3, in partial section according to the arrow III of FIG. 1, a blade with a portion of the adjacent circular cylindrical element,

Fig. 4 shows the blade of FIG. 3 in the view according to the arrow IV of FIG. 3,

Fig. 5, the installation of FIG. 1 in a longitudinal sectional plane parallel to the plane of Fig. 1,

Fig. 6 shows the section VI of Fig. 5,

Fig. 7, the windmill in the representation accordingly Fig. 6 with indicated Strö mung lines,

, Greatly enlarged Fig. 8 to 15 sections from Fig. 7 and in further detail, each standing for eight in different angular positions with respect to the oncoming wind direction blade,

Fig. 16 shows the flow line, which result for the circular cylinder element alone, and

FIG. 17 shows a pressure diagram for FIG. 16.

In the drawing, 1 denotes a wind turbine which is placed outdoors on a stand 2 , specifically with a vertical axis of rotation 3 . The outer circumference of the wind power plant 1 forms a wind wheel 4 shown in FIG. 2, which is configured cylindrically symmetrically to the axis 3 and is rotatably mounted. The wind turbine 4 has several, in the illustrated embodiment, eight identical profi lated blades 5 to 12 , which each extend along a generatrix of a circular cylinder and are evenly distributed over the circumference of the wind turbine 4 , forming a blade ring.

Each blade has a Tragflä chenprofil over its entire length, as can be seen for the blade 5 from FIG. 3, and has with its bulging side 13 in the direction of rotation according to arrow 14 of the wind turbine. Each blade, for example blade 5 , has a thick profile nose 15 at one profile end and a slender profile 16 at the other profile end. With its profile nose, it is directed to the center, ie to axis 3 of the wind turbine, during the operation of the wind turbine.

Coaxial with the wind turbine 4 , a circular cylinder element 17 - ver same Fig. 5 - is provided, which is arranged within the wind turbine, made of air-impermeable material and whose outer surface is smooth and has the shape of a circular cylinder dermantels 18 . Between the circular cylinder element 17 and the blade ring formed by the blades 5 to 12 , an intermediate space 19 - compare FIG. 3 - is cut out, which according to double arrow 20 is approximately as large as the greatest thickness according to double arrow 21 of the blade profile.

The circumference of the blades is formed by a jacket 23 made of corrosion-resistant metal sheet. The blades are solidly filled with a polyurethane filling 24 . The show fences are stiffened by a worked longitudinal rods 26 , 27 , 28 in the polyurethane filling 24 .

The close to the profile nose 15 located longitudinal rod 26 is at both ends at the end faces out of the blade and is rotatably mounted, so that the blade, as shown in dashed lines in Fig. 3, are pivoted from the functional position drawn there in a rest position ge can, in which it extends approximately tangentially to the circumference of the wind turbine. If all the blades are in this tangential position, the wind turbine does not offer a point of attack for destructive forces in the event of excessive wind flow.

The longitudinal rods 27 and 28 also protrude at both ends from the end faces of the blade and there to grip points for pivot mechanisms not shown for pivoting the blade from the drawn in Fig. 3 ge drawn position in the positions shown in dashed lines and for fixing the blades in the set angular positions. The swivel mechanism is preferably designed so that all the blades are in the same position and at the same time swung out of their functional position into their Ru position and back.

As can be seen from FIG. 5, the wind wheel 4 has a cover part 30 and a base ring 31 , between which the blades 5 to 12 are fastened. The cover part 30 consists of an upwardly curved protective cap 32 and a traction sheave 33 . In the traction sheave 33 is coaxially to the axis 3 se the inner gear 34 provided external gear 35 of a planetary gear 36 is attached.

The outer wheel 35 drives over the circumference angeord Nete three planet gears 37 , 38 , 39 a central sun gear 40th Planet gears and sun gear are provided with external teeth. The planet gears mesh with the outer gear 35 and the sun gear 40 .

The sun gear 40 is torsionally rigid on the axis 41 of a rotor 42 he most of a dynamo 43 which is arranged coaxially to the axis 3 . The cup-shaped Kreiszylin derelement 17 has a cover plate 45 and a Bodenplat te 47 and the cylinder jacket part 44 . The planet gears 37 , 38 , 39 are rotatably mounted on the cover plate 45 . On the cover plate 45 , a second rotor 46 - an external rotor - the dynamo 43 is attached.

During operation, that is to say when the wind is flowing, the wind wheel 4 rotates in the direction of the arrow 14 and the circular cylinder element 17 is stopped or, driven by the wind, it rotates in the direction opposite to the direction of the arrow 14 .

With 50 is a stub axle coaxial to the axis 3 , on which the first rotor 42 of the dynamo 43 , the bottom ring 31 and the bottom plate 47 are rotatably mounted. On the rotor 42 , a shaft 51 is fastened coaxially to the axis 3 , which rotates with the rotor 42 and is rotatably mounted on the cover part 30 in rotary bearings 48 and 53 . The cover plate 45 is rotatably mounted on the axis 41 with the rotary bearing 52 .

A horizontally flowing wind acts on all swings driving more or less strongly in the direction of arrow 14 . The relevant aerodynamic contexts result from FIGS . 7 to 17.

The circular cylinder element 17 rotates, driven by the same inflowing wind flow, in the opposite direction of the arrow 14 if it is rotatably mounted, otherwise it is kept stationary.

In all Figs. 7 to 17, the wind direction is indicated by the arrow W, and the direction of rotation of the wind wheel by the arrow 14.

The aerodynamic effect, which the blades drive in any angular position at the flow direction W in the direction of the arrow 14 , is explained below.

To FIG. 8, the blade 6 acts as a turbine blade. The air deflected by the cylinder jacket part 44 presses the wind turbine 4 in the direction of the arrow 14 . The resulting Koanda effect acts on the circular cylinder element 17 and rotates it in the opposite direction of rotation.

To Fig. 9: The blade 5 engages the wind of the half of the drum diameter. The tangential speed can balance itself out depending on the speed of the wind. In this blade position, the Koanda effect, which rotates the circular cylinder element 17 in the direction opposite the arrow 14 , is expressed even more strongly than in the position according to FIG. 8.

To FIG. 10, the blade 12 swirls the air flow in a position of larger depression, whereby the positive Drehmo ment of wind wheel and circular cylindrical element 17 is increased.

To Figure 11. The blade 11 is at an angle of 180 °, which is the moment at which the blade ceases with the steering air in the layers of high depression. However, this is at the same time the situation in which the largest eddies and depressions form on the profile nose of the blade and this has a positive effect on the torques of the wind wheel 4 in the arrow direction 14 and circular cylinder element 17 in the opposite direction.

To Fig. 12: determined by the position of the blade 10 against the wind flow to the wind speed increases to the front face and causing depression. There is an increase in pressure on the rear surface. This difference between positive and negative pressure generates a torque of the wind turbine in the direction of arrow 14 .

To Fig. 13: As the vane 9 moves as in the angren collapsing positions against the oncoming wind, ver, the relative wind speed enlarges with respect to the actual wind speed. This creates a larger depression on the surface of the blade, while a stronger negative pressure is formed on the underside. The different overpressure and underpressure result in a positive force component, which in turn leads to a positive torque on the wind turbine 4 according to arrow 14 and in the opposite direction to the circular cylinder element 17 .

To Fig. 14: The real speed of the wind, be attracted to the blade 8 is increased, firstly because of the deviation of the wind flow around the circular cylinder member 17, and secondly because of the direction of rotation of the blade against the wind direction in the direction of arrow 14, and finally because of the Wind circulation on the surface of the blade. These three factors increase the speed of the relative wind flow. This results in a pressure difference on both sides of the blade. This results in a tangential force which drives the blade in the direction of arrow 14 and the circular cylinder element 17 in the opposite direction.

To Fig. 15: The blade 7 undergoes through the oncoming wind a negative pressure on the blade top side and a positive pressure on the blade base and thus a Drehmo ment in the arrow direction 14.

Claims (2)

1. Wind turbine with a rotatably mounted wind wheel, with the same, profiled blades ( 5-12 ), each extending along a generatrix of a circular cylinder, evenly distributed over the circumference of the wind wheel ( 4 ), forming a blade ring, and that a blade has a wing profile over its entire length and points with the bulging side of the wing profile in the direction of rotation of the wind turbine. characterized in that
- The wind wheel ( 4 ) is coupled via a planetary gear ( 36 ) to a rotor ( 42 ) of a dynamo machine ( 43 ),
- The wind wheel ( 4 ) drives an outer wheel ( 35 ) of the planetary gear ( 36 ) directly,
- The dynamo rotor ( 42 ) is mounted torsionally rigid on the sun gear ( 40 ) of the planetary gear,
- The intermeshed planet gears ( 37-39 ) intermeshing between the outer gear and sun gear are rotatably mounted on a carrier ( 45 ) on which the counter element ( 46 ) for the dynamotor is fastened in a torsionally rigid manner,
a coaxial circular cylinder element ( 17 ) made of air-impermeable material is provided coaxially with the wind wheel ( 4 ), the outer surface of which has the shape of a circular cylinder jacket and a space ( 20 ) is left between the circular cylinder element and the blade ring,
- The carrier ( 45 ) is torsionally rigid on the circular cylinder element ( 17 ) and
- The dynamo ( 43 ) has a second dynamo rotor ( 46 ) which forms the counter element and from the circular cylinder element ( 17 ) to the first dynamo rotor ( 42 ) is driven in opposite directions due to the Koanda effect. 2. Installation according to claim 1, characterized in that the intermediate space ( 20 ) is 50 to 200% (percent), preferably 100%, of the greatest thickness of the blade profile.