초록 ▼

The present invention relates to a wind power installation (1) for generation of electrical power by means of ambient air, having a flow channel (3) through which the ambient air is passed by an air flow being formed, with the flow channel (3) having an outer casing (6) delimiting it, and also havin

The present invention relates to a wind power installation (1) for generation of electrical power by means of ambient air, having a flow channel (3) through which the ambient air is passed by an air flow being formed, with the flow channel (3) having an outer casing (6) delimiting it, and also having: a first section (7) with an essentially constant cross section, into which the ambient air can be introduced, with an air acceleration device (39) being provided in the first section (7), a second tapered section (9) which is in the form of a Venturi nozzle (10), a third section (11) which follows the second section (9) and in which a rotor (60) is arranged which is caused to rotate by the air flowing through it, and whose rotation is used to generate electrical power, a fourth flared section (13) which is in the form of a Laval nozzle (12), and a fifth section (15) which has a second air acceleration device (85) used as the exhaust for the air which has been introduced into the flow channel (3).

대표청구항 ▼

1. A wind power installation for generating electric power from ambient air, with a flow channel, through which the ambient air is conducted by the formation of an air stream, wherein the flow channel comprises an external sleeve forming its boundary and also comprises: a first section with an essen

1. A wind power installation for generating electric power from ambient air, with a flow channel, through which the ambient air is conducted by the formation of an air stream, wherein the flow channel comprises an external sleeve forming its boundary and also comprises: a first section with an essentially constant cross section, into which the ambient air can be introduced, wherein an air acceleration device is provided in the first section,a second tapering section,a third section, following the second section, in which third section a rotor is installed, which is set in rotation by the through-flowing air stream and the rotation of which serves to generate electric power,a fourth enlarging section, anda fifth section, which comprises a second air acceleration device, which serves to discharge the air introduced into the flow channel. 2. A wind power installation of claim 1 characterized in that the air acceleration device of the first and/or of the fifth section of the flow channel comprises at least one fan. 3. A wind power installation of claim 1 characterized in that downstream with respect to the flow direction of the ambient air of the air acceleration device of the first and/or of the fifth section of the flow channel, a flow guide device is provided, which converts the turbulent and/or rotating air stream produced by the air acceleration device in question into a laminar flow. 4. A wind power installation of claim 3 characterized in that the flow guide device is a downstream stator. 5. A wind power installation of claim 3 characterized in that the flow guide device is a parallel-tube device. 6. A wind power installation of claim 3 characterized in that the flow guide device comprises both a downstream stator and a parallel-tube device. 7. A wind power installation of claim 3 characterized in that, downstream of the flow guide device following the air acceleration device in the first section, a tapering tubular section is provided, in which a flow cone, which tapers to a point and along which the air stream flows is provided, wherein the taper angle α of the cone is essentially 15° or less. 8. A wind power installation of claim 7 characterized in that a section of constant cross section is installed after the tapering tubular section of the flow channel. 9. A wind power installation of claim 8 wherein another flow guide device is provided in the section of constant cross section. 10. A wind power installation of claim 1 characterized in that, upstream of the air acceleration device of the first section and/or of the air acceleration device of the fifth section, an air guide device is provided to achieve a laminar air flow. 11. A wind power installation of claim 10 characterized in that a parallel-tube device is provided upstream of the air guide device of the fifth section. 12. A wind power installation of claim 1 characterized in that the flow channel narrows down in the second tapering section with an angle α of 15° or less. 13. A wind power installation of claim 1 characterized in that the flow channel expands in the fourth section downstream from the rotor at an angle β of 7° or less. 14. A wind power installation of claim 1 characterized in that the cross section of the outlet of the flow channel is larger than the cross section of the inlet of the flow channel. 15. A wind power installation of claim 14 wherein the cross section of the outlet of the flow channel is essentially twice as large as cross section of the inlet of the flow channel. 16. A wind power installation of claim 1 characterized in that, in the second section, a cone, which expands from a tip to the cross section of the hub of the rotor, is provided, the expansion angle α of which is the same as the taper angle α of the second tapering section. 17. A wind power installation of claim 1 characterized in that, the rotor includes a hub, and in the fourth section, a cone, which tapers to a tip, is provided, the outlet cross section of which is essentially the same as the cross section of the hub of the rotor, wherein the taper angle β of the cone is the same as the expansion angle β of the fourth enlarging section. 18. A wind power installation of claim 1 characterized in that, rotor includes a hub, and upstream of the fifth section, in front of the flow guide device, a cone, which expands from a tip at an angle β, is provided, the end cross section of which is essentially the same as the cross section of the hub of the flow guide device. 19. A wind power installation of claim 1 characterized in that the third section comprises a gear unit, which converts the rotation of the rotor into a rotational movement of at least one output shaft, which extends in an essentially perpendicular manner from the flow channel and serves to drive a generator. 20. A wind power installation of claim 19 characterized in that the gear unit comprises a housing, in which a shaft is supported, wherein one end of the shaft is connected outside the housing to a rotor, while the other end is connected to a takeoff shaft offset by 90°, and in that the housing of the gear unit is supported in a bearing device, which comprises bearing plates, which are connected to the external sleeve of the flow channel. 21. A wind power installation of claim 1 characterized in that the rotor is supported on a shaft, which is connected nonrotatably to the bearing device; in that the rotor comprises an external tubular section, which forms a part of the external sleeve of the flow channel, wherein the external tubular section comprises a gear rim, which serves to transmit the rotation of the rotor by way of a gear unit to a generator. 22. A wind power installation of claim 21 characterized in that, to transmit the rotational movement of the rotor, a plurality of pinions are distributed uniformly around the circumference are provided, each of which is connected to a drive shaft, each drive shaft being connected to a generator. 23. A wind power installation of claim 1 characterized in that the rotor is mounted on a shaft, which is connected nonrotatably to a bearing device, and in that the rotor comprises an external section, which drives the rotor and/or the armature of a generator. 24. A wind power installation of claim 1 characterized in that it is arranged in a stand, which is supported rotatably. 25. A wind power installation of claim 24 characterized in that it comprises a bottom wall, a roof, and a plurality of posts, wherein the first to the fifth sections of the flow channel are arranged essentially between the outermost posts. 26. A wind power installation of claim 25 characterized in that the wind power installation is arranged a certain distance away from the bottom wall. 27. A wind power installation of claim 24 characterized in that an additional tapering section is provided on an air stream inlet side. 28. A wind power installation of claim 24 characterized in that an additional enlarging section is provided on an discharge side. 29. A wind power installation of claim 24 characterized in that the rotatable stand comprises a rotatable buoyancy unit which floats in a liquid. 30. A wind power installation of claim 29 characterized in that the liquid is held in a circular basin, in which the buoyancy unit is arranged. 31. A wind power installation of claim 29 characterized in that a king pin projects downward from a bottom plate of the buoyancy unit and is rotatably supported in a bearing, which is formed in a bearing block. 32. A wind power installation of claim 31 characterized in that a circumferential bearing is arranged above the level of the liquid between a side wall of the buoyancy unit and the basin. 33. A wind power installation of claim 1 characterized in that it is arranged vertically. 34. A wind power installation of claim 33 characterized in that an air feed device is provided at the upper inlet of the wind power installation. 35. A wind power installation of claim 34 characterized in that said air feed device is preferably semicircular in design. 36. A wind power installation of claim 33 characterized in that a flow deflection device, which comprises a flow channel, which deflects the outflowing air stream from the vertical direction into an essentially horizontal direction, is provided on the outlet side. 37. A wind power installation of claim 36 characterized in that the flow channel is arranged in a deflector body, around which the ambient air flows. 38. A wind power installation of claim 36 characterized in that the flow channel expands in the flow direction and preferably comprises an additional air acceleration device. 39. A wind power installation of claim 36 characterized in that downstream of the flow channel with respect to the direction of flow, several baffle plates are arranged. 40. A wind power installation of claim 39 characterized in that said baffle plates project beyond the cross section of the flow channel. 41. A wind power installation of claim 33 characterized in that a sail, which serves to keep the installation oriented in the optimal flow direction of the ambient air, is attached to the wind power installation. 42. A wind power installation system for generating electric power from ambient air of claim 1, characterized in that several wind power installations are arranged on top of or next to each other. 43. A wind power installation system of claim 42 characterized in that it comprises a stand, in which the wind power installations, which are arranged on top of or next to each other, are rotatably supported. 44. A method for generating electric power from ambient air, preferably ambient air which has been put in motion, which comprises the following steps: introducing ambient air into a first section of a flow channel,accelerating the air stream by means of an acceleration device, which is installed in the first section of the flow channel,further accelerating the air stream in a second tapering section of the flow channel by means of a constriction in the flow channel,conducting the air stream through a third section of the flow channel and the driving of a rotor in this section,discharging the air stream into a fourth enlarging section of the flow channel,renewedly accelerating the air stream in a fifth section of the flow channel, anddischarging the air stream into the environment, wherein both kinetic energy and heat energy are extracted from the air stream during its passage through the flow channel. 45. A method of claim 44 characterized in that, upstream of the acceleration device of the first and/or of the fifth section of the flow channel, the inflowing air is aligned as a laminar flow. 46. A method of claim 44 characterized in that the air stream is accelerated in the first and second sections of the flow channel so that it reaches a predetermined velocity by the time it enters the third section of the flow channel. 47. A method of claim 44 characterized in that a negative pressure is generated in the fourth enlarging section by the fifth section. 48. A method of claim 44 characterized in that, at the beginning of the power generation process, the acceleration devices are driven by external energy, and after a stable power production state has been reached, they are supplied with the generated power.