DE10318162A1 - Wind energy converter with buoyancy or resistance runners has rotor with preferably at least 5 per cent of its surface forming buoyancy and/or resistance runners covered by film with recesses - Google Patents

Abstract

The wind energy converter has a rotor with preferably at least 5 per cent of its surface forming buoyancy and/or resistance runners covered by a film with recesses (1). Turbulence generated by the recesses carry energy into the boundary layer surrounding the rotor. The recesses have a circular, oval and/or polygonal cross-section. An independent claim is also included for the following: (a) the use of recesses in the surface of a rotor as buoyancy and/or resistance runners.

Description

The The present invention relates to a wind energy converter with buoyancy and / or resistance runners, where at least 25% of the surface area of a rotor has indentations, with which turbulence can be generated, the energy into which the buoyancy and / or resistance runners Enter the surrounding boundary layer. Furthermore, the present concerns Invention the use of indentations on the surface of Buoyancy and / or resistance runners to generate buoyancy, suction and / or to reduce the formation of vortices.

renewable Energies are becoming increasingly important in today's energy supply. Are particularly important so-called wind energy converters, the wind energy into electrical Convert energy. However, these wind energy converters have nowadays the disadvantage that behind the rotating rotors, which act as and / or resistance runners are trained, great Form vortices that adversely affect the efficiency of the Wind energy converters affects, especially because the following wing in one immersed in swirling air.

It there was therefore the task of making a wind energy converter available ask who does not have the disadvantages of the prior art.

Is solved this task according to the invention a wind energy converter according to claim 1. Preferred embodiments of the wind energy converter are covered by the features of the subclaims.

It was for the specialist extremely amazing and not to be expected that with the energy converter according to the invention succeeds in reducing the air resistance of the lift and / or drag rotor considerably to reduce, create better buoyancy and suction conditions as well as to reduce the formation of vortices, but individually also to better convert wind energy into leads electrical energy.

According to the invention at least 25% of the flow surface the buoyancy and / or resistance rotor indentations, with where turbulence can be generated, the energy into which the buoyancy and / or resistance runners Enter the surrounding boundary layer. This will expand the Boundary layer specifically manipulated to improve the efficiency of wind turbines to increase.

On Buoyancy and / or drag runners In the sense of the invention, any rotor rotor is used in wind turbines can be mounted and with which the wind flow in a rotational movement is converted. Exemplary, but not exhaustive here for Resistance runner of the Savonius rotor, Darrius rotor, H-Darrius rotor and the cup anemometer called.

The existing according to the invention Indentations can have any shape and size. However, the indentations preferably have a circular, oval and / or polygonal cross-section. The indentations can be any Have depth, the shaping of the depth using tools an even or uneven radius, whose center is preferably outside the surface, can be generated. The depressions on a surface can be the same or be shaped differently. Furthermore, the Wells can be arranged one behind the other or with an offset. It it is also conceivable that indentations of different shape and Depth on a surface are located.

The Indentations can homogeneous or not homogeneous on the surface of the buoyancy and / or resistance runner be distributed.

In As a rule, the wind energy converter has other components, such as, for example a mast, which is preferably also provided with indentations is to reduce its air resistance, for example.

The indentations according to the invention can in the material of the buoyancy and / or resistance runner imprinted become. Furthermore, you can the indentations, for example, also by painting, or by other chemical and / or physical processes, such as Laser ablation or anodizing or the like, in the surface of the Buoyancy and / or resistance rotor be introduced. The indentations are preferably part of a Foil or sheathing, which is then applied to the buoyancy and / or resistance rotor, preferably glued. This bond is preferably reversible, so that the sheathing and / or foil after a certain time can be exchanged.

In the event that the buoyancy and / or resistance rotor is a rotor blade, the indentations are arranged in relation to the flow direction, preferably in the rear area thereof. Furthermore, the indentations preferably extend evenly or unevenly from the rear rotor blade edge in the direction of the front rotor blade edge. In a further preferred embodiment of the present invention, only the top or bottom of the rotor blade is provided with depressions and / or the indentations on the top or bottom of the rotor blade are different which differ in their number of dimensions and / or shape.

For example it is conceivable that the indentations from the rotor blade leading edge increase or decrease in dimension to the trailing edge of the sheet.

If, for example, a hemisphere of a cup cross anemometer is held with its round side in a horizontal flow, the part of the flow that has to take the detour around the hemisphere must accelerate. Due to the increase in speed, a negative pressure will form on their right and left side. Since pressure can be assumed to be proportional to force in this case, it follows that the same force acts on both sides. The resulting force in this hemisphere in a horizontal flow is therefore zero. But if you now place a hemisphere in a horizontal flow, the right outer surface of which is formed with depressions ( 6 ), the flow will follow the profile on the right side longer than on the left side due to the boundary layer created. The vortex wake is reduced. There is also an air flow velocity difference between the left and right sides of the hemisphere. The resulting pressure difference creates a buoyancy or suction that can be used to generate rotation and support.

Here a significantly higher speed (approx. 15%) could already be demonstrated in the test setup with a wind force of only 6 m / s. Furthermore, both outer sides of the hemisphere can be formed with depressions ( 8th ). By placing the recess differently in terms of shape, depth, number and extent of the right versus the left side of a hemisphere, the horizontal and vertical extent of the boundary layer can be influenced in a targeted manner from the right or left side and thus generate a speed difference in the air flow. The resulting pressure difference in turn creates a buoyancy or suction.

The energy converter according to the invention has the advantage that a combined buoyancy and resistance runners can be made. This increases the efficiency of resistance runners, which are provided with the indentations, since both the air resistance as well as the buoyancy is used to generate energy. Furthermore has the energy converter according to the invention the advantage that the formation of vortices is considerably reduced and thus the efficiency is increased. With a combined lift and resistance rotor, whose Rotor the surface structure according to the invention a laminar air flow is not absolutely necessary, what a low height of the wind turbine. In the case of wind energy converters with lift rotors, the technique according to the invention is also applicable. Existing systems can be covered with foils, varnishes or glazes that have the desired surface texture have, subsequently converted become.

In the following the invention based on the 1 to 8th explained. These explanations are only examples and do not limit the general inventive concept.

1 shows the wells in two views,

2 shows further designs of the wells in two views,

3 shows a flow profile around an air-flowed body,

4 shows the aerodynamic effects of the recesses,

5 also shows the influence of the boundary layer by the depressions,

6 - 8th each show a shell anemometer with the indentations.

1 shows the indentations in two views. In the present case, the indentations are circular and offset from one another.

2 shows a further embodiment of the surface with the indentations. In the present case, the indentations have a different shape and size.

3 shows the flow profile in the flow around an aerodynamic body with the indentations according to the invention. Near the surface of the buoyancy and / or resistance rotor, the flow velocity of the air is almost zero. From there, the flow rate increases to the upper end of the boundary layer. The targeted introduction of turbulence into the boundary layer influences its expansion, so that a flow profile is generated within the boundary layer which differs from a flow profile without indentations. If one manipulates the boundary layer of the air-circulating profile by means of depressions and the turbulence brought about by it in such a way that the boundary layer of one side of the profile differs in its extent from the boundary layer on the other side of the profile, flow velocity profiles are generated, which also differ in their Ausdeh Differentiate between which, according to the Bernoulli equation, there is a pressure difference between the two sides of the profile, which causes suction or buoyancy. In 3 In particular, the air flow velocity profile is shown in the case of different expansion of the boundary layer in the case of an aerodynamic body provided with a depression on both sides. V _g is the uniform velocity; V the speed, the size of which is symbolized by the length of the arrows.

4 shows the effect of depressions on the top of an air-flow profile. Due to the indentations, the air follows the profile of a body longer than without depressions, so that a lower pressure is established on the top than on the bottom. Furthermore, the illustration shows that the formation of vortices on the upper side is considerably reduced.

5 shows different depressions on the top and bottom. The indentations on the underside reduce the extent of the boundary layer, but do not completely suppress the formation of vortices. Here, too, a lower pressure occurs on the upper side than on the lower side, which leads to a buoyancy or suction and thus to a higher efficiency of the energy conversion. Furthermore, the indentations reduce the air resistance of the aerodynamic profile.

6 to 8th show a shell anemometer with indentations on the air-flow side. The indentations each ensure different flow conditions on the two half sides of the resistance rotor, which each causes suction and thus a higher efficiency of the cup anemometer. At the same inflow velocity, the shell anemometers are positioned accordingly 6 - 8th higher rotational speeds than with shell anemometers without indentations.

Claims (12)

Wind energy converter with buoyancy and / or resistance rotors, characterized in that at least 25% of the surface of a rotor, as the buoyancy and / or resistance rotor is formed, has indentations with which turbulence can be generated, which enter energy into the boundary layer surrounding the rotor. Wind energy converter according to claim 1, characterized in that the indentations have a circular, oval and / or polygonal cross section exhibit. Wind energy converter according to claim 2, characterized in that the indentations are even and / or deep uneven radius have, whose center lies outside the surface. Wind energy converter according to one of the preceding Expectations, characterized in that the depressions differ in depth are. Wind energy converter according to one of the preceding Expectations, characterized in that the wells are arranged with an offset are. Wind energy converter according to one of the preceding Expectations, characterized in that a surface is shaped differently Has depressions. Wind energy converter according to one of the preceding Expectations, characterized in that the depressions on the surface are not are distributed homogeneously. Wind energy converter according to one of the preceding Expectations, characterized in that it has other components in addition to the rotor has, which are at least partially provided with indentations. Wind energy converter according to one of the preceding Expectations, characterized in that the indentations on a film and / or Sheathing are arranged, which are preferably reversible on the Buoyancy and / or Resistance runners can be attached is. Wind energy converter according to one of the preceding Expectations, characterized in that it has rotor blades and that the Indentations related to the flow direction in the rear Area are arranged. Wind energy converter according to one of claims 1-8, characterized characterized that he is a resistance rotor based on the cup anemometer principle and that only half the shell has indentations. Use of indentations on the surface of Buoyancy and / or resistance runners to generate buoyancy, suction and / or to reduce the formation of vortices.