DE102007057077A1 - Rotor for use as e.g. ship rotor, has annular rotor blade, where blade position is changed between two of vertices with maximum distance from uplift position into down position - Google Patents

Abstract

The rotor (3) has an annular rotor blade (2) having a blade profile (22) in cross-section and formed as a hollow profile. A polygon (1) with vertices is formed as rhombus, and is inscribed to the blade that is formed as pneumatically supported membrane construction. The profile is made of plastic/metal, where blade position (21) is changed between two of the vertices with a maximum distance from an uplift position into a down position so that an aero- and hydro-dynamically generated force pair of suction- and pressure forces with an offset torque acts on a rotational axis (30).

Description

The The invention relates to a rotor for converting the in a flow contained kinetic energy in a rotary motion as a flow converter or vice versa for converting a rotational movement into a flow as a flow generator and in particular a fan and an aircraft or ship rotor. The rotor has one of the circular ring deviating, annular rotor blade, the cross-section of a wing profile with a wing nose and a wing trailing edge. The annular Rotor blade is a polygon with a given number of vertices inscribed. The wing profile is with its wing nose aligned to the flow and alternates between two Corner points with maximum distance to each other at least once the Wing position from a buoyancy position to an output position, so that when the rotor flows parallel to the axis of rotation an aero- and hydrodynamically generated pair of forces and compressive forces with an offset moment on the axis of rotation acts.

State of the art:

The EP 0 854 981 B1 shows a wind turbine with a horizontal axis of rotation and an annular rotor, which serves as a pressure ring for zugbeangespuchte, wing-shaped spokes. The proposal to develop the annular rotor itself to an aero- or hydrodynamically active element is not anticipated here. Known wind and water turbines with a horizontal axis of rotation have radially arranged rotor blades with an aero- or hydrodynamically effective wing cross section, which is aligned with a broad side to the flow. The rotor blades are connected as cantilevers with the rotor head on one side. Although the rotor diameter has been continuously increased in recent decades, this type with a rotor diameter of approximately 130 m achieves a construction-related limit. At this size, the rotor blades are subjected to extreme loads, are prone to vibrations, and cause whipping noises as the rotor blades pass through the mast. Propellers for watercraft and aircraft, as well as fans cut through a liquid or gaseous medium in the manner of a screw for the production of thrust or wind. In ship propellers, the problem of cavitation occurs. A helicopter rotor shows a radial rotor blade assembly.

outgoing from the illustrated prior art, the invention is the Task is based, a rotor with an annular rotor blade and aero- and hydrodynamically effective wing profiling in the case of a flow converter as high-speed from the flow is set in rotation and in the case a driven flow generator, a flow generated. An annular rotor blade, which by means of a Number of aero- and hydrodynamic spokes with the axis of rotation connected, not only is characterized by an elevated Efficiency at a given rotor diameter, but has better running properties and less wear. The design of a spoke wheel allows in particular in wind turbines new, previously unrealisable plant sizes with a two to three times as large rotor diameter as usual. Thus, the invention makes a contribution for further and increased development of wind power as an ecologically harmless source of energy. What the area concerning flow generators, a new ground is in which the thrust in contrast to the screw action alone the aerodynamic and hydrodynamic effect of wing profiling an annular rotor blade results.

• – Ersatz herkömmlicher, radial angeordneter, biegebeanspruchter Rotorblätter durch ein vorwiegend druckbeanspruchtes, ringförmiges Rotorblatt
• – Vorwiegende Zugbeanspruchung der vorgespannten radialen Speichen
• – Stabile Konstruktion mit einer mehrfachen, räumlichen Unterstützung des ringförmigen Rotors und einer zweifachen Lagerung der radialen Speichen
• – Einfache Montage durch Elementierung der Konstruktion
• – Die Speichenradkonstruktion ermöglicht Rotordurchmesser größer 300 m
• – Verstetigung der Rotationsbewegung durch eine günstige Massenverteilung
• – Gute Anlaufeigenschaften bei leichter Strömung
• – Selbsttätige Ausrichtung zur Anströmung
• – Kombination herkömmlicher radialer Rotorblätter mit einem ringförmigen Rotorblatt
• – Erhöhung der aero- bzw. hydrodynamisch wirksamen Oberfläche
• – Leiser Rotorlauf, Schlaggeräusche und niederfrequente Schwingungen treten nicht auf.
• – Große Variationsbreite von der Ellipse bis zum Vieleck
• – Extremer Leichtbau
• – Vergleichsweise günstige Beanspruchung der Drehlager
• – Vergleichsweise höhere elektrische Leistung bei gleichem Rotordurchmesser

The following objects are achieved by a flow converter according to the invention as a wind or water turbine:

• - Replacement of conventional, radially arranged, bending-stressed rotor blades by a predominantly pressure-loaded, annular rotor blade
• - Predominant tensile stress of the prestressed radial spokes
• - Stable construction with multiple, spatial support of the annular rotor and a double storage of the radial spokes
• - Easy installation through elemental design
• - The spoke wheel design allows rotor diameter greater than 300 m
• - Consolidation of the rotational movement by a favorable mass distribution
• - Good start-up properties with light flow
• - Automatic alignment to the flow
• - Combination of conventional radial rotor blades with an annular rotor blade
• - Increasing the aero- or hydrodynamically effective surface
• - Lighter rotor running, impact noise and low-frequency vibrations do not occur.
• - Large variation width from the ellipse to the polygon
• - Extremely lightweight
• - Comparatively cheap stress on the pivot bearing
• - Comparatively higher electrical power at the same rotor diameter

• – Geringer Rotationswiderstand
• – Große Laufruhe
• – Erhöhung des Schubs durch Kombination von Schraubenblatt und ringförmigem Rotorblatt
• – Günstige Beanspruchung der Propellerwelle und der Lager
• – Bei einem Ventilator, Erzeugung eines Luftstroms ausschließlich durch die aerodynamische Wirkung der Flügelprofile des ringförmigen Rotors
• – Große aero- und hydrodynamisch wirksame Oberfläche
• – Einfache Konstruktion
• – Kombination mehrerer aero- und hydrodynamischer Effekte
• – Große Variationsbreite vom Dreieck bis zum Vieleck

An inventive flow generator is distinguished from known solutions by the following advantages:

• - Low rotational resistance
• - Great smoothness
• - Increase of the thrust by combination of screw blade and annular rotor blade
• - Cheap use of the propeller shaft and bearings
• - For a fan, generating an air flow solely through the aerodynamic effect of the airfoils of the annular rotor
• - Large aerodynamic and hydrodynamic surface
• - Simple construction
• - Combination of several aerodynamic and hydrodynamic effects
• - Large variation width from the triangle to the polygon

Aerodynamics, hydrodynamics:

The Operating principle of an annular rotor blade leaves itself with a symmetrical wing profile, with an asymmetrical wing Wing profile or even by a profile arrangement achieve with wing effect.

at an annular rotor blade with a symmetrical wing profile becomes the periodic change of suction and compression forces by a continuously changing wing pitch (pitch) achieved. The special advantage of this design variant lies in a streamlined, harmonious transition between the input and output generating profile sections, wherein Both the profile nose and the profile trailing edge a periodically show swinging course.

at The use of adjustable profile flaps is recommended to just train the sides of a polygon. By means of profiled flaps can the couple of forces from suction and pressure forces comparatively easy to produce. The transition between The individual profile sections here is not so harmonious and increases the rotational resistance.

at The use of asymmetric wing profiles is the Forces of forces of suction and compression by inversion the wing vault made. At the seams the individual profile sections can streamlined transitional surfaces be designed. The combination of a pipe and a flow guide as a winged system leads to a very simple and therefore economical solution for a flow converter.

at an equilateral triangle and at a square that changes Wing profile between two adjacent corners with maximum distance from each other once from a buoyancy in an output position. For polygonal polygons, such as pentagon, hexagon etc., takes place the periodic change of the wing profile from the lift to the driven position on each polygon side between two adjacent vertices. A special case is one Rhombus with convex curved sides. It allows the Formation of an elliptical rotor blade. Again, this changes Wing profile between the corners with maximum distance each other once from the buoyancy to an output position.

at a driven rotor can on the wing top and on the wing base alone with the help of a flexible Fin, which is clamped at the rear wing edge, a flow can be generated. During rotation, the Wing profiling of the rotor on the outside of the ring and on the inside of the ring periodically changing pressure forces with increased flow velocity at the wing surface, resulting in a thrust.

The rotor as a whole:

For the connection of the annular rotor blade with a hub or with the axis of rotation spokes are provided, which are conventional in a ship rotor conventional propeller blades and a wind turbine. Rotor blades exist or are designed as aero- and hydrodynamically effective spokes. They transmit the respective offset moment caused by one polygon side to the rotation axis. In a ship's rotor, the thrust gained from the propeller blade and the annular rotor adds up. at a wind turbine, the spokes are themselves designed as aerodynamically effective wing profiles and are transverse to the flow, with its wing nose is arranged in the direction of rotation.

in the Under the invention, the spokes are proposed as ropes or form as flat profiles. The aerodynamic effect is by means of a two-part, aerodynamically and hydrodynamically effective Profile shell obtained as an aluminum extruded profile or as Plastic profile attached to the rope or on the flat profile becomes. With a windmill, a lightweight construction is important. Glass fiber reinforced plastic and carbon fiber reinforced Plastic are suitable materials for lightweight construction the annular rotor and the spokes up to a wheel diameter of 160 m. An inventive wind turbine can but be made much larger with a diameter of over 300 m. Such a big one Wheels are suitable for off-shore use and have a mast with pile foundation. At a big one Pinwheel is significant that it is at different temperatures and under varying aerodynamic load only within narrower Tolerances deformed. To ensure this, it is proposed connect each spoke with plate or coil springs to the hub. To transmit the torque, the cross over Spokes like a bicycle. For big wheels can within the tensioned spoke system between Pressure ring and hub additional coupling rods between the V-shaped spread spokes with stiffening bandages be provided. Ideally, the generator is in the wheel hub arranged.

Size, Wind turbines according to the invention can prefers along the existing traffic routes, such as highways and Railroad tracks are installed to the surrounding unverbaute To protect the landscape. By means of a spatially branched Substructure, on which a rotatable fork touches, can the wind turbines just above the traffic routes to be ordered.

little one Windmills with diameters of 3-12 m are suitable for a decentralized power supply of individual households. Here the spokes themselves can be made aerodynamically shaped Consist of metal profiles.

A special form of lightweight construction represents a pneumatic construction in which the wing contour of an annular Rotor blades made of a high-strength, filled with compressed air Membrane is formed. Such a pinwheel appears especially Economical, suitable for self-construction and can folded in a compact form to be shipped. After the same Prin zip is also proposed a fan whose pneumatic supported, annular rotor blade manifold Opportunities for an attractive design allows.

Control:

A particularly advantageous property of an inventive Wind or water turbine consists in the fact that they are aligns itself to the flow and only for that a hinge is needed. At a wind turbine is the control of the rotor speed of importance. The under the Invention proposed wing flap control triggers this task and can be done pneumatically or hydraulically.

Further advantageous details and design options The invention will become apparent from the drawings. The in the figures illustrated embodiments show a selection the numerous and arbitrarily combinable advantageous possibilities for the aerodynamic and hydrodynamic design of an inventive Flow converter and flow generator. In favor of a better readability was on the scale Representation of the relationships of the individual components to each other waived.

The Figures show:

1 a ship's rotor in isometric overview

2 the ship's rotor 1 in the view

3 the cross section through the annular ship rotor after 1

4 a water turbine in an isometric overview

5 the water turbine after 4 in the view

6 a wind turbine in view

7 the cross section through a buoyancy generating ring segment of the wind turbine after 6

8th the cross section through an output generating ring segment of the wind turbine after 6

9 a wind turbine with elliptical rotor blade in view

10 the cross section through a buoyancy generating segment of the annular rotor blade of the wind turbine after 9

11 the cross section through an output generating segment of the annular rotor blade of the wind turbine after 9

12 a pentagonal rotor in the isometric overview

13 the cross section of the annular rotor after 12

14 a hexagonal annular rotor in view

15 the cross section through the annular rotor after 14

16 the view of a flow converter with concentrically arranged, annular rotor blades

17 the cross section through the flow converter after 16

18 a water turbine with an octagonal annular rotor in the isometric overview

19 the cross section through a pneumatically supported, annular rotor blade

20 a wind turbine with an octagonal ring-shaped rotor in an isometric overview

21 the cross section through a spoke of a wind turbine according to the invention

22 the cross section through a spoke of a wind turbine according to the invention

23 the cross section through a spoke of a wind turbine according to the invention

1 shows a ship's rotor ( 320 ) with an annular rotor blade ( 2 ), which is characterized by a symmetrical wing profile ( 22 ) is formed. Spokes ( 33 ), which act as propeller blades ( 335 ) are formed, act with the annular rotor blade ( 2 ) and transmit the thrust to the rotor shaft ( 321 ). The hydrodynamic effect of the annular rotor blade ( 2 ) is determined by its deviating from the circular shape polygon shape. An equilateral triangle ( 13 ) is the annular rotor blade ( 2 ) and has convex sides ( 110 ) and rounded corners ( 12 ) on. On each polygon side ( 10 ) changes the symmetrical wing profile ( 22 ) regularly by a lift division ( 210 ) in an output position ( 211 ). The resulting suction ( I ) and compressive forces ( II ) cause on the rotor shaft ( 321 ) an offset moment. At its wing surfaces, the annular rotor blade ( 2 ) a flow which is related to the total thrust of the ship's rotor ( 320 ) contributes.

2 shows the downstream side of the ship propeller ( 320 ) to 1 in the view. The wing trailing edge ( 24 ) changes on each polygon page ( 10 ) of the triangle ( 13 ) from the outside to the inside of the annular rotor blade ( 2 ). This is done by changing the sash position ( 21 ) of a buoyancy position ( 210 ) in an output position ( 211 ) via a continuously changing wing pitch. The ship propeller ( 320 ) generates a part of the thrust force through the as propeller blades ( 335 ) trained spokes ( 33 ). A significant proportion of the thrust provides the annular rotor blade ( 3 ) by the pressure and suction forces ( I . II ) generated flow.

3 shows the cross section (aa) through the annular rotor blade ( 2 ) to 2 , in an uplifting position ( 210 ) of the symmetrical wing profile ( 22 ). The change of the sash position ( 21 ) of the buoyancy position ( 210 ) in the stripping position ( 211 ) is represented by the dashed lines.

In 4 that a water turbine ( 310 ) in an isometric overview, the annular rotor blade ( 2 ) periodically from a buoyancy position ( 210 ) in an output position ( 211 ) over the circumference of a quadrilateral ( 14 ). Thrust generating spokes ( 33 ) connect the annular rotor blade ( 2 ) with one at the base ( 316 ) via a rotary joint ( 315 ) rotatably mounted mast ( 314 ). The generator ( 312 ) is from a coaxial to the rotation axis ( 30 ) arranged generator shaft ( 313 ). The flow converter ( 31 ) aligns itself independently with the flow (s).

5 shows the periodic change of suction and compression forces ( I . II ) on the course of the wing trailing edge ( 24 ) of the wing profile ( 22 ). The annular rotor blade ( 2 ) is a square ( 14 ) inscribed. Convex pages ( 110 ) and rounded corners ( 12 ) support the hydrodynamic effect of the annular rotor blade ( 2 ). Each polygon page ( 10 ) shows a buoyancy position ( 210 ) and an output position ( 211 ) by continuously changing the wing pitch ( 21 ).

6 shows a wind turbine according to the invention ( 311 ), whose annular rotor blade ( 2 ) a square ( 14 ), with convex sides ( 110 ) and rounded corners ( 12 ). The polygon pages ( 10 ) are produced by asymmetric wing profiles ( 23 ) whose wing arching on each side of the square ( 14 ) changes from the rotor blade outer side to the rotor blade inner side, whereby suction and pressure forces ( I . II ) be generated. Each polygon page ( 10 ) of the annular rotor blade ( 2 ) thus causes a pair of forces, the offset with the axis of rotation of the wind turbine ( 311 ) and therefore causes a torque. About spokes ( 33 ) is the rotor blade ( 2 ) with the hub ( 35 ) connected.

7 shows the cross section (bb) of a buoyancy generating side segment ( 10 ) with an asymmetrical wing profile ( 23 ).

8th shows the cross section (cc) of an output-generating side segment ( 10 ) with an asymmetrical wing profile ( 23 ).

9 shows a wind turbine ( 311 ) with an annular rotor blade ( 2 ), the elliptical shape of which is inscribed in the rotor blade ( 140 ) is determined. This changes an asymmetric wing profile ( 23 ) between the two vertices with maximum spacing of the rhombus ( 140 ) once from a buoyancy position ( 210 ) in an output position ( 211 ). Each of the four segments of the annular rotor blade ( 2 ) causes one with offset on the axis of rotation ( 30 ), resulting air force from suction ( I ) and compressive forces ( II ). Two spokes ( 33 ), which are asymmetrical spoke wing profiles ( 331 ) are formed, connect the ring-shaped rotor blade ( 2 ) with a fork ( 36 ), which in turn via a rotary joint ( 315 ) with a mast ( 314 ).

10 shows in cross-section (dd) a buoyancy ( 210 ) generating ring segment with an asymmetric wing profile ( 23 ). With his wing nose ( 20 ) is the wing profile ( 23 ) aligned with the flow (s).

11 shows the wing profile in cross section (ee) 10 in an output position ( 211 ). The sash position of the four segments of the elliptical rotor blade ( 2 ) causes an automatic alignment of the wind turbine ( 311 ) to the flow (s).

12 shows an annular rotor blade ( 2 ), the pentagon ( 15 ) is trained. At flow (s) arises at the axis of rotation ( 30 ) a torque caused by a profile arrangement with wing action ( 25 ) via a windward hollow profile ( 250 ) with leeward flow control surface ( 251 ). Each polygon page ( 10 ) is divided into two sections, each one at the axis of rotation ( 30 ) effective pair of forces of suction and compression forces ( I . II ) cause. The advantage of the profile arrangement ( 25 ) consists in its simplicity. A corresponding rotor can be inexpensively manufactured for rotors up to 30 m in diameter with the simplest means.

13 shows the cross section through the in 12 described profile arrangement with wing effect ( 25 ) from a windward hollow profile ( 250 ) as wing nose ( 20 ) and a leeward flow control surface ( 251 ) as wing trailing edge ( 24 ).

14 shows the flow-away view of an annular rotor blade ( 2 ), which as a hexagon ( 16 ) is trained. The rotor blade ( 2 ) is part of one around the axis of rotation ( 30 ) rotating flow generator ( 32 ) and shows in cross section (dd) after 15 a symmetrical wing profile ( 22 ) with an elastic fin ( 27 ). In the case of a ship's rotor ( 320 ) creates a rhythmic oscillation on the elastic fin during rotation ( 27 ), which generates a thrust. Thereby flexible rods ( 270 ) with a connecting membrane ( 271 ) together. Alternating on the outside and inside of the annular rotor blade ( 3 ) he witnessed suction and pressure forces ( I . II ) cause the flow (s) and the thrust of the ship's rotor ( 320 )

15 shows the cross section (dd) through the annular rotor blade ( 2 ) to 14 , The dashed lines in 14 and 15 describe the area in which the annular rotor blade presses and pulls during rotation, thereby generating a flow (s) on its curved wing sides.

16 shows the view of a water turbine ( 310 ) or wind turbine ( 311 ). The annular rotor blade ( 2 ) inscribed polygon ( 1 ) is a heptagon ( 17 ) with even sides ( 100 ). Extended wing flaps ( 26 ), highlighted by thick black lines cause a rotation of the rotor ( 3 ) clockwise. By a concentric arrangement ( 100 ) of the annular rotor blades ( 2 ), the kinetic energy contained in the flow (s) is used very well. Particularly advantageous is a nozzle effect between the concentrically arranged rotor blades ( 2 ).

17 shows a schematic section through the flow converter ( 31 ) to 16 , The wing flaps ( 26 ) are shown here in the basic position, the z. B. is taken in a storm. Three annular rotor blades ( 2 ) with symmetrical wing profile ( 22 ) are in concentric arrangement ( 300 ) around the axis of rotation ( 30 ) grouped. They also show a concave arrangement for better utilization of the flow (s). The generator shaft ( 313 ) drives a generator ( 312 ) and is via a rotary joint ( 315 ) with a mast ( 314 ) connected. The flow converter ( 31 ) automatically aligns with the flow (s).

18 shows a water turbine according to the invention ( 310 ), whose annular rotor blade ( 2 ) as an octagon ( 18 ) is trained. The at the axis of rotation ( 30 ) effective torque from suction and pressure forces ( I . II ) is characterized by a symmetrical wing profile ( 22 ) with adjustable flap ( 26 ) causes. Hydraulically also a torque causing spokes ( 33 ) with an asymmetrical wing profile ( 331 ) connect to the hub ( 35 ) ago. By means of a swivel joint ( 315 ) at the base ( 316 ) the water turbine ( 310 ) automatically to the flow (s). The water turbine is made of hollow sections ( 28 ) made of metal ( 281 ) built up. The wing flaps ( 26 ) have a hydraulic control ( 261 ).

19 shows the cross section through an inventive annular rotor blade profile ( 3 ), which in its geometry is built up in 18 equivalent. However, the sectional view shows the symmetrical wing profile ( 22 ) and the adjustable wing flap ( 26 ) as a pneumatically supported membrane construction ( 282 ). According to this design, an ultralight rotor with an annular rotor blade ( 2 ) and can be used in addition to the energy production for decorative and promotional purposes.

20 shows a large wind turbine according to the invention ( 311 ). The annular rotor blade ( 2 ) is an octagon ( 18 ) and is provided with a plurality of crossed spokes ( 33 ) with the hub ( 35 ), the generator ( 312 ), connected. The training of the spokes ( 33 ) is in the 21 . 22 and 23 described in more detail. They are each via a spring element ( 34 ) connected in the form of a plate spring or coil spring to the hub, so that their biasing force is kept constant under different temperature and operating conditions. The supporting structure of the wind turbine ( 311 ) consists of a fork ( 36 ), whose legs have an oval, with the narrow side to the flow (s) aligned cross-section. A mast widening conically to the base ( 314 ) takes over a swivel joint ( 315 ) the fork ( 36 ) on. Each polygon page ( 10 ) creates a suction force ( I ) or a compressive force ( II ). About the circumference of the annular rotor blade ( 3 ) so periodically changing pairs of forces arise from suction and compression forces ( I . II ), each having a torque at the axis of rotation ( 30 ) cause. Due to the feathering position of the symmetrical wing profiles ( 22 ) the wind turbine ( 311 ) automatically to the flow (s). With the help of the wing flaps ( 26 ), the rotor speed of the wind turbine can be controlled in the simplest way. In storm, the wheel is stopped. By an inverted position of the wing flaps ( 26 ), the direction of rotation can be changed. By means of the spokes ( 33 ), the annular rotor blade ( 2 ) kept spatially. Such a wind turbine can have a diameter greater than 300 m. With the achievable electrical power, the use of wind energy comes in new, previously unrealizable dimensions. Because the spokes ( 33 ) also generate a torque, the overall system is very effective.

21 shows the cross section of a possible embodiment of the spokes ( 33 ) the in 20 described wind turbine ( 311 ). The asymmetrically designed spoke wing profile ( 331 ) shows a two-part spoke shell ( 334 ) made of extruded aluminum sections, which are attached to the rope by means of screws (not shown) 332 ) are clamped.

The in 22 Spoke cross-section shown also shows an asymmetric spoke wing profile ( 331 ), of two shell bodies ( 334 ) forming a supporting core in the form of a flat profile ( 333 ) surround. The shell body ( 334 ) can be made of metal or plastic.

23 shows a symmetrical spoke wing profile ( 330 ) in cross section. The load-bearing flat profile ( 333 ) of metal or composite material is of a shell body ( 334 ), which in lateral flow (s) as well as in 21 and 22 Spoke sections shown causes a torque. Reference numeral Overview polygon 1 Ring-shaped rotor blade 2 rotor 3 polygon side 10 wing leading edge 20 axis of rotation 30 Straight side 100 wing position 21 Concentric rotor blade 300 Convex side 110 lift position 210 flow converter 31 Tip corner 11 force position 211 water turbine 310 Rounded corner 12 Symmetrical wing profile 22 wind turbine 311 Equilateral triangle 13 Asymmetrical wing profile 23 generator 312 square 14 Trailing edge 24 generator shaft 313 diamond 140 Profile arrangement with wing action 25 mast 314 pentagon 15 tube profile 250 swivel 315 hexagon 16 flow guide 251 nadir 316 heptagon 17 wing flap 26 flow generator 32 octagon 18 Pneumatic control 260 ship rotor 320 Hydraulic control 261 rotor shaft 321 Elastic fin 27 spoke 33 Flexible rod 270 Symmetrical spoke wing profile 330 membrane 271 Asymmetrical spoke wing profile 331 hollow profile 28 rope 332 Plastic profile 280 low profile 333 metal profile 281 Two-piece shell body 334 Pneumatically supported membrane 282 propeller blade 335 full profile 29 spring element 34 inflow s hub 35 suction force I fork 36 thrust II

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• EP 0854981 B1 [0002]

Claims (24)

Rotor ( 3 ) for converting the kinetic energy contained in a flow into a rotary motion as a flow converter ( 31 ) or vice versa for converting a rotational movement into a flow as a flow generator ( 32 ) and in particular as a fan, aircraft or ship rotor ( 320 ), which rotor ( 3 ) a rotation axis ( 30 ) and a deviating from the circular ring shape, annular rotor blade ( 2 ), which in cross-section a wing profile ( 22 . 23 . 25 ) with a wing nose ( 20 ) and a wing trailing edge ( 24 ), characterized in that the annular rotor blade ( 2 ) a polygon ( 1 ) is inscribed with a predetermined number of vertices and the wing nose ( 20 ) is directed to the flow (s), wherein the sash position ( 21 ) between two corner points at maximum distance from each other at least once from a buoyancy position ( 210 ) in an output position ( 211 ) changes, so that when the flow (s) of the rotor ( 3 ) parallel to the axis of rotation ( 30 ) an aero- and hydrodynamically generated force pair of suction ( I ) and compressive forces ( II ) with an offset moment on the axis of rotation ( 30 ) acts. Rotor according to claim 1, characterized in that the wing position ( 21 ) between two adjacent vertices of a polygon ( 1 ) regularly from a buoyancy position ( 210 ) in an output position ( 211 ) changes. Rotor according to claim 1, characterized in that a polygon side ( 10 ) as a straight side ( 100 ) or as a convex side ( 110 ) and the polygon ( 1 ) pointy corners ( 11 ) or rounded corners ( 12 ) Has. Rotor according to claim 1, characterized in that the polygon ( 1 ) an equilateral triangle ( 13 ) or a square ( 14 ) or a rhombus ( 140 ) or a pentagon ( 15 ) or a hexagon ( 16 ) or a heptagon ( 17 ) or an octagon ( 18 ) or a polygon. Rotor according to claim 1, characterized in that the polygon ( 1 ) as a rhombus ( 140 ) with convex sides ( 110 ) is formed and the annular rotor blade ( 2 ) has an elliptical shape. Rotor according to claim 1, characterized in that the force pair of suction ( I ) and compressive forces ( II ) of a symmetrical wing profile ( 22 ) whose wing position ( 21 ) between two vertices of the polygon ( 1 ) of a buoyancy position ( 210 ) in an output position ( 211 ) changes, whereby the wing pitch changes continuously. Rotor according to claim 1, characterized in that the force pair of suction ( I ) and compressive forces ( II ) with a symmetrical wing profile ( 22 ) by means of an adjustable flap ( 26 ) is effected. Rotor according to claim 1, characterized in that the force pair of suction ( I ) and compressive forces ( II ) of an asymmetric wing profile ( 23 ), whose wing vault between two vertices of a polygon ( 1 ) from the outside to the inside of an annular rotor blade ( 2 ) changes. Rotor according to claim 1, characterized in that the force pair of suction ( I ) and compressive forces ( II ) of a profile arrangement with wing action ( 25 ) is caused, in which a flowed hollow profile cross section ( 250 ) with a flow guide ( 251 ) cooperates. Rotor according to claim 1, characterized in that the force pair of suction ( I ) and compressive forces ( II ) with a symmetrical wing profile ( 22 ) and asymmetric wing profile ( 23 ) at the trailing edge of the wing ( 24 ) by means of an elastic fin ( 27 ) of flexible rods ( 270 ) and a connecting membrane ( 271 ) is effected. Rotor according to claim 1, characterized in that a wing profile ( 22 . 23 ) as a hollow profile ( 28 ) or as a full profile ( 29 ) is formed and made of plastic ( 280 ) or metal ( 281 ) consists. Rotor according to claim 1, characterized in that the annular rotor blade ( 2 ) as a pneumatically supported membrane construction ( 282 ) is formed and can be folded together for transport. Rotor according to claim 1, characterized in that in the case of a wing profile ( 22 . 23 ) the rotor rotation number by means of a wing flap ( 26 ) with pneumatic or hydraulic control ( 260 . 261 ) is controlled. Rotor according to claim 1, characterized in that a plurality of annular rotor blades ( 2 ) in a concentric arrangement ( 300 ) about the axis of rotation ( 30 ) are arranged and by means of spokes ( 33 ) are interconnected. Rotor according to claim 1, characterized in that two or more concentrically arranged annular rotor blades ( 2 ) and are arranged in a plane or staggered, so that the rotor ( 3 ) has a concave or convex shape. Rotor according to claim 1, characterized in that an annular rotor blade ( 2 ) by means of a number of spokes ( 33 ) and a hub ( 35 ) with the axis of rotation ( 30 ) connected is. Rotor according to claim 1, characterized in that a spoke ( 33 ) as a symmetrical spoke wing profile ( 330 ) or as an asymmetrical spoke wing profile ( 331 ) is trained. Rotor according to claim 1, characterized in that a spoke wing profile ( 330 . 331 ) from a spoke shell ( 334 ), with a rope ( 332 ) or with a flat profile ( 333 ) connected is. Rotor according to claim 1, characterized in that the spokes ( 33 ) and with the hub ( 35 ) via a spring element ( 34 ) are connected in the form of a plate spring or a coil spring. Rotor according to claim 1, characterized in that a flow converter ( 31 ) via a rotary joint ( 315 ) with a mast ( 314 ) and automatically aligns with the flow (s). Rotor according to claim 1, characterized in that the axis of rotation ( 30 ) of a flow converter ( 31 ) as generator shaft ( 313 ) a generator ( 312 ) drives. Rotor according to claim 1, characterized in that the hub ( 35 ) of a flow converter ( 31 ) a generator ( 312 ) and by means of fork ( 36 ) and swivel joint ( 315 ) with the mast ( 314 ) connected is. Rotor according to claim 1, characterized in that a flow generator ( 32 ) as a ship propeller ( 320 ) by means of a propeller shaft ( 321 ) is driven, wherein the connecting element ( 33 ) as a propeller blade ( 335 ) is trained. Rotor according to claim 1, characterized in that both the annular rotor blade ( 2 ) as well as the connecting elements ( 33 ) at flow (s) a torque at the axis of rotation ( 30 ) cause.