DE102010035301A1 - Rotor wing or rotor blade for power production for vertical wind-power plants or turbines, has inflow zone follows cross section of basic form of counter-rotating spiral according to principle of golden section - Google Patents

Abstract

The rotor wing or rotor blade has an inflow zone follows a cross section of basic form of a counter-rotating spiral according to the principle of a golden section. Axis parallel arrangement of rotor blades and axis of rotation, particularly a helical curvature of the rotor blades, are provided on a cylindrical outer surface.

Description

Description Vertical wind turbine with swirl rotor blades

• a) subject matter is the invention of a rotor blade ( 3 ) and its multiple arrangement (preferably 3 wings) on the rotor of a wind turbine whose axis of rotation ( 1 ) is preferably arranged vertically to the base. The wind energy is removed by means of principle of resistance or buoyancy principle from the air flow and converted into rotational energy. The rotor blade cross sections follow the design rule of the golden section or the Fibonacci number sequence. ( 9 ) This applies to the hollow area ( 4c ) as well as for the back surface ( 3d ) of the vortex red wing. The rotor blades are rotatably mounted under spring tension on the rotor carriers ( 2 ) and are automatically changed in the angle of attack during rotation by the centrifugal force. ( 3 )
• b) The wind turbine stands on a column ( 1a ) whose axis of rotation ( 1 ) is oriented vertically to the mounting plane. It can also be arranged horizontally to the mounting plane due to the design. On the column is a generator ( 1b ), which converts the rotational energy preferably into electrical or pneumatic or hydraulic energy and supplies via line connection to the consumer.
• c) At standstill ( 2 ) are the rotor blades by the at the joint ( 2c ) acting spring tension ( 2a ) in the start position. The system uses even small gusts of wind on the principle of resistance rotor. The incoming air hits the big baffle ( 3d ) also on the impact surface ( 4d ) and at the same time on the hollow surface ( 4c ). While on surface ( 3d ) and ( 4d ) results in a torque resulting from dynamic pressure, forms in the hollow surface ( 4c ) a stable vortex. Its deflection against the direction of rotation of the rotor generates a pulse in the direction of rotation, the resulting torque ( 3d ) and ( 4d ) even stronger. At the back of the vortex wing ( 3d ) the air flows along and is deflected and accelerated at the outer edge of the narrowing spiral, resulting in a negative pressure at the front of the vortex blade ( 3c ) leads. This negative pressure creates a suction, which causes an additional force vector and in turn an additional torque on the rotor axis. On the side of the rotor, which rotates counter to the wind direction, a counter-torque resulting from the dynamic pressure arises ( 6 ). The air flowing past the front edge is deflected into the inner spiral and supports the maintenance of the stable vortex. Thus, during the entire revolution, the vortex remains in the wing. However, the sum of the torques in the direction of rotation is higher than the counter-torque. This resulting torque produces an angular acceleration which, in turn, results in an increase in rotational speed. The rotor is accelerated in so-called resistance rotor operation up to the rated speed of this mode. This rated speed is dependent on the rotor dimensions.
• d) If the rotational speed exceeds the rated speed of the resistance rotor operation, the rotor blades ( 3 ) by the acting centrifugal force and voher certain spring force in dependence of the speed independently in the position buoyant runner operation pivoted outwards ( 3 ). In the speed range between the rated speed of the resistance runner operation and the rated speed of the lift rotor operation, the rotor blades change their angle of attack in proportion to the rotational speed and pivot tangentially to the rotating jacket surface. The attachment of the rotor wing joint ( 2a ) ( 2 B ) is chosen so that the line of the force vector only passes through the center of gravity when the rotor blade ( 3 ) is fully swung out. When reaching the rated speed for the lift rotor operation, the sum of the centrifugal forces, the restoring forces of the Schwenkmechnismuss and acting on the rotor blade flow forces is canceled and it sets up a stable balance ( 3 ). In addition, the position is controlled by damping elements and a stop in the joints ( 2a ) and ( 2 B ) stabilized.
• e) In buoyancy runner mode, the swirl rotor blades in combination operate as hydrofoils and as swirl vanes. The mode of action in this mode is as follows. The surfaces ( 3d ) and ( 4d ) act as hydrofoils and generate by the incoming air, a force component, the rotor blade in the direction ( 3c ) ( 4c ) or counterclockwise drives. In addition, the inflowing air generates in arc segment ( 3c ) ( 4c ) in turn generates a stable vortex which, by its deflection, generates a pulse in the direction of rotation of the rotor. At the back of the swirl vane the air flows along and is also swirled at the outer edge of the narrowing spiral, resulting in a negative pressure at the front of the swirl vane. This negative pressure creates a suction, which causes an additional force vector and in turn an additional torque on the rotor axis. The special wing cross-section results in an optimized inflow, outflow and outflow behavior of the air at the rotor blade, which results in a high energy yield from the air flow. Due to the wing shape, the noise is very low even at high speeds compared to the horizontal wind turbines.
• f) From wind speeds> 16 m / s and strong gusts, a stagnation at the wings leads to strong turbulence within the Rotor. Furthermore, the vortex formation within the vertebrae is no longer stable and there is no further angular acceleration of the rotor. This results in an independent storm protection for the Wibelfügelrotor.
• g) When falling below the rated speed for Auftriebsläufer- and Wirbelflügelbetrieb results in a rotational speed proportional backward pivoting of the rotor blade in the resistance runner mode. Below the rated speed of the resistance rotor operation, the wind turbine operates entirely in the resistance rotor mode with pivoted rotor blades.
• h) The vortex rotor blade is applicable for vertical wind turbines of dimensions of 50 cm height and 30 cm rotor diameter (model plants) up to 16 m height and 10 m diameter. The number of rotor rotors makes sense physically and economically. Due to these proportions, outputs of approx. 50 W to 30 kW can be displayed.
• i) The swing-wing principle can also be replaced by a rigid swirl rotor blade system to simplify the design and reduce lower-speed performance. Thus, the resistance-runner mode is eliminated and the rotor always operates in wing-swirl-wing operation. This design simplification makes sense for systems below the 3 kW power class. Resulting dimensions: less than 4 m wing length and 3.5 m rotor diameter.
• j) The shape of the rotor is according to the principle of the golden Sprirale or golden section ( 5 ) developed. The proportions follow the Fibonacci number sequence. The swirl vane cross-section is constructed of two spiral segments that are pressed together to form an almost swirl-free inflow of the air into the inner spiral shape of the rotor blade via the outer spiral shape. After entering the air, a stable vortex forms whose deflection causes the impulse to propel the rotor blades ( 4 ). With additional Leitspiralflächen within the Wirbelrotorblügels this effect can be further optimized. He is modeled on the Spriral forms formed in nature as they are in 6 and 7 can be seen.
• k) There are openings on the faces of the vortex rotor blades ( 5a . 5b ), which allow the outflow of air. In order to keep the turbulences as low as possible, this outlet opening for a pressure equalization and the resulting core vortex can emerge in the axial direction to the vortex rotor blades.
• l) A wind turbine with a vertical axis and this swirling wing shape can be used in windy areas which are not always covered by wind. It already uses small gusts of wind to convert the wind energy into rotational energy. In contrast to the classic horizontal wind turbines with so-called three-wingers, the rotor does not have to be turned into the wind.

LIST OF REFERENCE NUMBERS

1

Drehachse

1a

Ständersäule

1b

Einbauraum für Generator oder Pumpe

2

Wirbelrotorträger

2a

Federelement mit Gelenk

2b

Dämpfungselement mit Gelenk

3

Wirbelrotorflügel

3a

Obere Abdeckung des Wirbelrotflügels

3b

Untere Abdeckung des Wirbelrotflügels

3c

Vorderkante des Wirbelrotflügels

3d

Rückwärtige Anströmzone des Wirbelrotflügels

4a

Oberes Innenprofil zur Versteifung mit Öffnung für Wirbelbildung

4b

Unteres Innenprofil zur Versteifung mit Öffnung für Wirbelbildung

4c

Hohlseite des Wirbelrotorsflügels

4d

Vordere Anströmzone des Wirbelrotflügels

5a

Obere Kernwirbelaustrittsöffnungen des Wirbelrotflügels

5b

Untere Kernwirbelaustrittsöffnungen des Wirbelrotflügels

Fig. 1 vertical vortex wing rotor with 3 individual wings column stand and axis of rotation

1

axis of rotation

1a

upright column

1b

Installation space for generator or pump

2

Vortex rotor support

2a

Spring element with joint

2 B

Damping element with joint

3

Eddy wind turbine blade

3a

Upper cover of the vortex red wing

3b

Lower cover of the vortex red wing

3c

Leading edge of the vertebral wing

3d

Backward inflow zone of the vortex rotor wing

4a

Upper inner profile for stiffening with opening for vortex formation

4b

Lower inner profile for stiffening with opening for vortex formation

4c

Hollow side of the vortex rotor blade

4d

Front inflow zone of the vortex red wing

5a

Upper core vortices of the vertebrate wing

5b

Lower core vortex openings of the vertebrate wing

2 Rotor blade arrangement in resistance runner mode of operation The spring elements are in the rest position and the employment of the swirl rotor blades results in a larger overall diameter than in the lift rotor mode of operation.

3 Top view of rotor blade arrangement in buoyancy and vortex mode The spring elements are tensioned by the centrifugal force and the swinging in of the vortex rotor blades results in a smaller total diameter than in the resistance rotor mode.

4 Longitudinal flow into the inner spiral of the vortex blade with inflow behavior and vortex formation

5 Side inflow into the inner spiral of the vortex blade with inflow and vortex formation

6 Front inflow to the outer spiral of the vortex blade with inflow and vortex formation

7 Longitudinal flow on the back wall of the outer spiral of the vortex blade with swirling and negative pressure formation on the front side

8th Side inflow to the rearward outer spiral of the vortex wing with buoyancy formation

9 Design principle "Golden spiral" / "Golden section"

Claims (8)

Rotor blades or rotor blades for generating energy for vertical wind turbines or turbines with at least one rotor blade, which operate on the principle of stable internal vortex and its generated momentum and force component. As a result of the working principle, the cross-sectional fundamental shape is constructed according to the spiral of the golden section, or follows the propions of the Fibonacci number series. Further characterized by an inflow zone whose cross-sectional basic shape follows an opposite spiral on the principle of the golden section, or whose propositions of the Fibonacci number series follows and continues directly the spiral shape. Furthermore, characterized by the axis-parallel arrangement of the rotor blade and the axis of rotation in particular the helical curvature of the rotor blades on the cylinder jacket surface about the axis of rotation. Rotor blades or rotor blades according to claim 1, characterized by the cross-sectional basic shape, which is constructed according to the principle of a general spiral, a cylindrical or an elliptical shell segment. Furthermore, characterized by an inflow zone whose cross-sectional basic shape follows an opposite general spiral, or constructed according to the principle of a cylindrical or an elliptical shell segment and directly continues the Spriralform in opposite directions. Rotor blades or rotor blades according to claim 1 to 2, whose ends or end faces are provided with core vortex outlet openings and allow the exit of the core vortex. Rotor blades or rotor blades according to claim 1 to 3, the ends of which taper and are shaped counter to the direction of rotation to the rear. Rotor blades or rotor blades according to claim 1 to 4, which can pivot by means of pivoting mechanism, speed proprionally by the acting centrifugal force independently in 2 different working positions and are secured by springs, damping elements and stop positions. Rotor blades or rotor blades according to claim 1 to 5, which are pivoted by means of controlled Schwenkmechnismus depending on the current angular position and the wind direction in the optimal yield position. Rotor blades or rotor blades according to claim 1 to 6, which had a stiffening construction whose inner bore allows the formation of the stable vortex in the interior of the wing cross-section. Rotor blades or rotor blades according to claim 1 to 7, the ratio between the rotor diameter to rotor blade length 1 to 1.6 results.

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