DE10056767A1 - Wind power system has air channel for rectifying, compressing and focused transporting of wind flowing onto or around building to rotor - Google Patents

Abstract

The system has at least one rotor and a drive element connected to its driven shaft. At least one rotor (2) is mounted on the building, integrated into the facade or roof surface, with a vertical axis and air conducting facade elements (3,3a) on one or both sides forming an air channel (5,5a) with the roof or wall (6) for rectifying, compressing and focused transport of wind flowing onto or around the building to the rotor.

Description

The invention relates to a wind turbine on a Building is attached and comprises at least one rotor, whose output shaft is connected to a drive element is.

Wind turbines are the kinetic energy of the wind using facilities. The kinetic energy of a wind turbine or rotor or a wind turbine in the axis direction horizon valley or vertical to the axis flowing wind converted into kinetic energy by transferring on a drive element, for example a generator, in usable energy is converted.

In addition to wind turbines or wind turbines with regard to the Wind flow through the horizontal axis are also rotors with a vertical axis, for example Darrieus or Savo nius rotors, known, although cheaper herge can be provided, but their efficiency is significant less than that of the horizontal axis wind turbines is. The well-known and frequently used in practice Wind turbines with horizontal wind turbines are different on the other hand, disadvantageous in that the strong vibration against the wind turbine blades to premature materia lead to fatigue and cause considerable noise chen. In addition, put on specially built elaborate structures at high altitude wind turbines a change that is significantly disruptive of the location and landscape.

Among other things, to avoid the latter in some cases it has already been used several times, for example in  DE 30 06 612, proposed the horizontal wind turbo to be attached to or on a conventional building. But there are also known solutions of this type further the problem of the disturbance of the townscape and the Noise pollution caused by on or on the building Wind turbines as well as the insufficient usable from such wind turbines Energy.

The invention is therefore based on the object to train a wind turbine attached to a building that the external appearance of the building does not affect is pregnant and even at comparatively low Wind speeds with a high specific power compared to the known wind turbines for buildings efficiency is achieved.

According to the invention the task with a Features of claim 1 trained wind power plant solved.

In other words, the basic idea of the invention is in that in the facade and / or the roof of a building of the rotors with vertical to the wind flow direction Axis, for example Savonius and / or Darrieus rotors, are integrated, on the long sides essentially arranged parallel to the wall or roof surface of the building Nete air duct facade elements are provided, which flow on or around the building with high acceleration pick up the wind and in the between the wall or Roof surface and the facade element formed air duct rectify, condense and channel accordingly feed the corresponding rotor, its rotary motion to an on drive unit, for example a generator for energy generation, is transmitted. The orientation or axis position arranged parallel to the respective wall or roof surface  Rotors can travel from vertical to horizontal chen. The facade elements are parallel with a plurality lel to the rotor axis, between each other Air gaps populated by louvers. The aerodyna Mix-shaped slats are aligned so that the Air gaps diagonally inwards, that is, to the longitudinal side ten of the rotor are directed. So about a be any height or width of a building or roof suitable rotors with the specially designed facade The design elements fit well into the building surface. On the other hand, they are due to the groove acceleration of the wind on the building surfaces and its compression and channeling with the help of specifically designed facade elements capable of a large part of the wind effectively in Be motion energy and with the help of a attached to the rotors closed generator to convert into electrical energy. In annual average in European coastal areas from a height of 25 m it is quite common for wind speeds speeds of 6 m / s can therefore up to 80% of the energy a high-rise building may be covered.

From the dependent claims and the following description Exercise of an exemplary embodiment result further features and advantageous developments of the Er making.

An exemplary embodiment is shown in greater detail on the basis of the drawing explained. Show it:

Fig. 1 is a schematic view of the present invention integrated in a building facade individual wind turbine in a horizontal section;

Fig. 2 is a detailed representation of the aerodynamically shaped lamellae of a facade element;

3 is a perspective view of a rotor with a vertical axis of rotation and articulated on both sides on the longitudinal sides of facade elements. and

Fig. 4 is a graphical representation of the energy conversion to be expected in two effective turbines per year at different wind speeds and facade heights.

In Fig. 1, the vertical Ge building wall of a cross-sectionally oval high building is designated by reference numeral 6 . A Sa vonius rotor 2 is attached parallel to the building wall 6 , the blades of which partially engage in a recess 11 in the building wall 6 . The Savonius rotor 2 is opposite the recess 11 of the Ge building wall 6 partially covered with a cover plate 10 , between the respective longitudinal edge and the facade 6 on one side a narrow air inlet slot 9 and on the opposite side a wide air inlet slot 9 a is formed , In the area of larger air entry slot 9 a is due to the arranged here Savonius rotor 2, an air baffle plate 7, the opposite to the slit 9 offset in this case wind supply to the Savonius rotor 2 and the air inlet passage slot 9 corresponding slit width sten to ensu. In the case of the arrangement of a Darrieus rotor, the use of the air baffle according to the exemplary embodiment according to FIG. 1 is not necessary due to the fact that the design and function of a Savoniust turbine differ.

From Fig. 1 and 2 it can also be seen that on the longitudinal edges of the cover plate 10 of the Savonius rotor 2 , an air guide facade element 3 , 3 a is pivotally articulated about a Drehge 8 . At its opposite end the pivot 8, the air guide Fassadenele element 3, 3 a between two stops 4 a and 4 a fix it to the facade 6 stop plate 4 b held. The slants 1 , 1 a of the two air-guiding facade elements 3 , 3 a, each oriented obliquely in the direction of the Savonius rotor 2 , that is to say oppositely oriented to one another, are aerodynamically shaped for optimal wind supply via the slots formed between the slats 1 , 1 a and in limited circumference pivoted about its longitudinal axis. The aerodynamic profiling of the slats 3 can best be seen from FIG. 2. The opposite oblique arrangement of the slats 1 in the two Luftleit-Fassadenele elements 3 , 3 a is again clear from Fig. 3.

According to Fig. 1 of the wind hits due to the wind direction or formed on the surfaces of buildings flow direction of the air guide facade elements 3, 3 a, so that the air flow mainly through the slots between the lamellae 1 of the left in the drawing air guide facades elements 3 occurs. The free end of the air guide Fassa denelements 3 is located at the upper stop 4 a to the stop plate 4 and forms with the building wall 6 a gradually narrowing towards the Savonius rotor 2 air channel 5 , 5 a, in which the air flow channeled, rectified and is gradually compressed due to the lamella formation and the possibly decreasing cross section of the air duct 5 and thus directly impinges the rotor blades with high kinetic energy. The mounted on the other side of the Savonius rotor 2 air guiding facade element 3 a is pressed by the action of wind on the lower stop 4 b ge. A connected to the Savonius rotor 2 generator (not shown) converts the kinetic energy generated by the wind power of the rotor into electrical energy. When changed wind direction, the air routing facade element 3 applies to the building wall, while the air channel 5 opens a brin supply due to its pivoting on. The channeled and compressed air in the guide channel 5 , 5 a is in this case directed over the air guide plate 7 onto the rotor blades in order to set the Savo nius rotor 2 in a rotational movement. Corresponding to the different wind directions, however, several turbines including the associated air-guiding facade elements are preferably distributed in the main wind direction on the building wall in such a way that at four turbines provided on the circumference of the building, at least two are involved in the conversion of wind energy into electrical energy. In the case of a wind flow incident perpendicularly to the building wall, a turbine operates without a flow component from the corresponding air duct 5 or 5 a. In this case, the largest share of energy is generated by the turbines laterally offset on the building.

The invention is of course not based on the here Embodiment described for exemplary explanation tion of the principle of the invention limited.

Instead of the Savonius rotors specified above, other turbines with a vertical axis, for example Darrieus rotors, can also be used. Due to the different functioning of the Darrieus rotors, the arrangement of the air baffle 7 is not necessary in this case.

Preferably, a plurality of rotors or rotor segments connected to one another with the associated air-guiding facade elements are arranged one after the other, that is to say one below the other or next to one another, in order to increase the wind force effect. The design of the air-guiding facade elements can change, for example with regard to the gap width between the lamellae 1 , 1 a, over the height of the rotor arrangement in such a way that a uniform force effect is exerted on the rotor blades in spite of the greater wind strength. Equally, a combination of Savonius and Darrieus rotors in the same axis or the arrangement of at least one Savonius rotor as a drive rotor for an adjacent Darrieus rotor is also conceivable.

The preferred building shape in horizontal cross-section for attaching the rotors with the associated barrel The elements on the building wall are round or oval. Basically, however, their arrangement is also suitable conceivable roof areas.

To calculate the energy conversion, the force exerted on the rotors is first calculated from the pressure balance according to Bernoulli for incompressible media and the rate of mass conservation between the channel inlet and outlet

P _A = ρ _ISA /2.C ² + P _ISA - ρ _ISA /2.C _A

determined where
P _A air pressure at the duct outlet
ρ _ISA ambient air density
P _ISA air pressure at duct entrance
c undisturbed wind speed
c _A flow velocity at the channel outlet
is.

The torque of a turbine passed on to the generator results from taking into account the aerodynamically active area of the rotors

M = t _K .F.η _T .n _J ,

in which
t _K depth of the channel opening
F force on the rotors
η _T efficiency
η _J Number of rotor revolutions per year
is.

The efficiency of a continues to be included in the calculation Savonius rotors with 29% and friction losses with 10%, while all air parameters are altitude dependent and after the norms of the international standard atmosphere (ISA) be determined. The force on the rotors and the number the rotor revolutions are from the facade height, the Ka depth, wind speed and rotor diameter dependent.

The annual heating energy requirement for a high-rise building with, for example, 90,000 m ^{2 of} usable space is 5,400 MWh. With an average wind speed of 6 m / sec, which is easily achieved in all European coastal areas from a height of 25 m, two effective rotors according to the invention and corresponding facade elements can achieve energy coverage of up to 80% of the annual requirement at a certain height become.

Claims (21)

1. Wind power plant which is mounted on a building and comprises at least one rotor and a drive shaft with its From associated drive element, characterized by at least one ßenfläche at the Gebäudeau arranged, che in the facade or Dachflä integrated rotor (2) with a vertical axis, on one or both longitudinal side (s) is arranged a receiving air flow facade element ( 3 , 3 a), with the neigh disclosed roof surface or building wall ( 6 ) an air channel ( 5 , 5 a) for rectification , Compress and bundle supply of the wind flowing on or around the building to the rotor in question ( 2 ). 2. Wind turbine according to claim 1, characterized in that the air guiding facade elements ( 3 , 3 a) have a plurality of mutually parallel lamellae len ( 1 , 1 a) and the air intake slots formed between these diagonally towards the rotor ( 2 ) are aligned. 3. Wind turbine according to claim 2, characterized in that the lamellae ( 1 , 1 a) have an aerodynamic cross-sectional shape. 4. Wind power plant according to claim 2 and 3, characterized in that the lamellae ( 1 , 1 a) are attached to the air guide facade element ( 3 , 3 a) to a certain extent about their longitudinal axis. 5. Wind turbine according to one of claims 1 to 4, characterized in that the air guiding facade elements ( 3 , 3 a) are arranged substantially parallel to the building wall ( 6 ). 6. Wind power plant according to one of claims 1 to 4, characterized in that the Luftleit-Fassadenele elements ( 3 , 3 a) about a on the long sides of the rotor ( 2 ) provided swivel joint ( 8 ) are pivotally mounted in a predetermined extent , 7. Wind power plant according to one of claims 1 to 6, characterized in that the rotor ( 2 ) while leaving free air inlet slots ( 9 , 9 a) to the inter mediate of the building or roof surface and the air guide facade element ( 3 , 3 a ) formed air duct ( 5 , 5 a) is covered with a cover plate ( 10 ). 8. Wind power plant according to claim 7, characterized in that the air inlet slots ( 9 , 9 a) on the opposite longitudinal sides of the rotor ( 2 ) have a different width un. 9. Wind power plant according to claim 6 to 8, characterized in that the rotary joints ( 8 ) on the longitudinal edges of the cover plate (1 ()) are attached. 10. Wind power plant according to one of claims 1 to 9, characterized in that the rotor ( 2 ) consists of a plurality of interconnected, essentially the course of the building or roof surface adapted Ro torsegmente. 11. Wind turbine according to claim 10, characterized records that the air guiding facade elements from a individual segments are formed.   12. Wind turbine according to claim 11, characterized indicates that the fin spacing of the air control Facade elements according to the height of the arrangement is variable on the building. 13. Wind turbine according to one of claims 1 to 12, characterized in that the rotors or Rotorsegmen te are designed as Savonius rotors ( 2 ), wherein in the air duct ( 5 a) in the region of the wide air inlet slot ( 9 a) an air baffle ( 7 ) is provided to effect an exact or via the two air inlet slots ( 9 , 9 a) offset air supply to the Savo nius rotor ( 2 ). 14. Wind turbine according to one of claims 1 to 12, characterized in that the rotors or rotor segments are designed as Darrieus rotors. 15. Wind turbine according to claim 13 and 14, characterized ge indicates that a rotor from both Savonius Rotor segments as well as from Darrieus rotor segments is formed. 16. Wind turbine according to claim 15, characterized records that at least one Savonius rotor segment intended as a drive rotor for a Darrieus rotor is. 17. Wind turbine according to one of claims 1 to 17, characterized in that the cross-sectional shape of the Building is aerodynamically designed. 18. Wind turbine according to claim 17, characterized records that the building is essentially round or is elliptical.   19. Wind power plant according to one of claims 1 to 18, characterized in that a plurality of rotors ( 2 ) with air guiding facade elements ( 3 , 3 a) are arranged according to the main wind direction on the circumference of the building. 20. Wind turbine according to claim 1, characterized net that the drive element to generate a generator supply of electrical energy. 21. Wind turbine according to claim 19, characterized records that on the air guide facade elements So lar cells for additional energy generation are brought.