DE102009038076A1 - Rotor element for flow around a fluid and rotor - Google Patents

Abstract

A rotor element (10) for the flow around a fluid and for a rotor (20) is disclosed. It comprises a rotor blade (12), which has two side surfaces, and a flow guide surface (14) assigned to the rotor blade (12), the wake of which at least partially influences the flow onto one of the side surfaces of the rotor blade (12).

Description

The The invention relates to a rotor element for flowing around a fluid with the Features of the preamble of claim 1. Furthermore, the Invention a rotor having the features of the preamble of the claim 9th

Wind turbines and wind turbines have rotors equipped with aerodynamically optimized rotor blades are so that the kinetic energy of the wind with one possible high efficiency can be used. Mostly rotors are for such Power plants with a substantially horizontal axis of rotation designed, have at least two adjustable rotor blades and generate a torque on a shaft over a Transmission is used to drive an electric generator. Dependent of the size, in particular height, and the length the rotor blades There are different performance classes. The design is based on this all wind turbines on the Betz formula; only about 59% of the energy can bypass the wind be removed, otherwise the wind is slowed down too much or the Wind is pouring evasive around the windmill.

task the present invention is to provide a high utilization of the flow energy, especially wind energy.

These The object is achieved by a Rotor element solved with the features of claim 1. advantageous Further developments of the invention are characterized in the dependent claims.

According to the invention a rotor element for flow around by a fluid, in particular by air, and for a rotor a rotor blade, the two side surfaces and a flow guide element associated with the rotor blade. Here is the flow guide a flow guide whose wake or wake flow at least partially the flow, in particular the pressure distribution and / or the velocity field, on one of the side surfaces of the rotor blade influenced.

Of the Caster acts directly or indirectly on the rotor blade. The caster is in particular laminar or turbulence-free or vortex-free. The inflow on the side surface or the flow around of the rotor blade is in particular laminar or turbulence-free or wirbelfrei. In other words, at least in part, the flow conditions changed by the rotor blade compared to the situation without flow guide. The Influencing can be location-dependent his or a spatial Have distribution. The influence can be in a speed increase, in a speed direction change, or in a generation of pressure differences or pressure gradients exist, which acts on the rotor blade. In particular, at least a portion of the rotor blade lie downstream of the flow guide. In other words, the wake can be at least partially on the rotor blade to meet.

through the flow guide becomes in a surprise and advantageously the flow of the rotor blade in such a way changed that in comparison to the situation without flow guide to a stronger force effect of the flow the rotor blade results. In particular, additional flow can be directed to the rotor blade become. Quantitatively, the force effect by varying different Parameters, such as the size, the Shape and the distance of the rotor blade and the flow guide to each other optimized. The flow guide can Also referred to as fluid flow control system, in particular air flow control system become.

in the Rotor element according to the invention can be a long distance measurement along the flow guide a longitudinal axis extend the rotor blade and / or the flow guide can within a shadow projection along a direction of a surface vector, in particular the averaged area vector or total area vector, (vertical shadow projection) of the rotor blade lie. The flow guide can two convex side surfaces and / or an elliptical Have cross-section (perpendicular to the long distance measurement). The one side surface of the rotor blade may be concave and / or the other side surface of the Rotor blade be convex. The flow guide surface may be the concave side surface of the Rotor blade opposite. In different versions the flow guide can in particular substantially perpendicular or parallel to the concave side surface of the Rotor blade can be arranged. In a further development is the Angle between the rotor blade and the flow guide adjustable.

In preferred embodiments the rotor element according to the invention the rotor blade and the flow guide are fixed spaced apart and / or together in fixed relative position to each other movable.

Concrete can the rotor blade and the flow guide with each other connected by struts or taken together on a rotor base be. The rotor blade may in particular be a drive rotor blade or to be a generator rotor blade.

Furthermore or alternatively, in the rotor element according to the invention in the longitudinal direction of the rotor blade, the distance of an edge of the flow guide surface from the side surface of the rotor blade increase monotonously.

in the Connection of the inventive idea is also a rotor with a plurality of rotor elements for flowing around a fluid, in which a rotor element according to the invention used. In other words, a rotor according to the invention with a plurality of rotor elements for flow around through a fluid at least one rotor element with features or feature combinations according to this Presentation on.

through the realized in the rotor element fluid flow control system according to the invention is an increase in the speed of the rotor possible in an advantageous manner. Quantitatively can the ratio the speed of the rotor to the flow velocity of the fluid play a role. By the arrangement in the rotor element according to the invention can disturbing Turbulence of the fluid can be reduced.

In especially for Wind turbines or wind turbines preferred embodiments the rotor according to the invention lies from the direction of rotation of the rotor or in the plane of rotation of the rotor seen the flow guide in (on the direction of rotation or the rotational movement related) slipstream of the Rotor blade.

In an advantageous development are the angular positions the drive rotor blades of the rotor and / or the flow guide around their respective Längsachsrichtungen adjustable, in particular controllable or adjustable. Preferred are drive rotor blades and flow control surfaces correlated with each other adjustable, in particular controllable or adjustable. This will be a corresponding mechanical and / or electrical device used. The drive rotor blades are used in practice for optimal use of the flow conditions, in particular the wind conditions, set.

Various embodiments the rotor according to the invention can used in various concrete applications.

A first special use is in power machines, in particular Wind power machines or wind turbines. An engine according to the invention for converting the flow energy a fluid, preferably wind energy, into another form of energy, in particular in electrical energy, has a rotor whose Rotary axis substantially in the flow direction is adjustable and the characteristics or feature combinations according to this Presentation includes. In this case, the fluid may be a gas, in particular and preferably air, or a liquid, especially and preferably water.

A second special use is in propeller drives, in particular Aircraft propeller drives, for example, a Flugzeugurburbopropellerantrieb. An inventive propeller drive for producing a propulsion in a fluid comprises at least a rotor having features or feature combinations according to this Presentation.

In a preferred embodiment the propeller drive is seen in the plane of rotation of the rotor the flow guide before the rotor blade. Advantageously, more thrust can be generated. The flow guide improved The aerodynamics in the direction of rotation of the rotor, in addition, allow more air to the rotor steered and air turbulence are reduced.

Furthermore can the rotor of the invention with respect to hydropower in a tidal engine or a Turbine can be used. The arrangement of the rotor element according to the invention can be realized with respect to wind power even in sailing ships: The sail corresponds to the rotor blade.

Further Advantages and advantageous embodiments and further developments of the invention will become apparent from the following Description with reference to the figures shown. It shows in detail:

1 an embodiment of a rotor element according to the invention, and

2 an embodiment of a wind turbine with three rotor elements according to the invention.

The 1 shows an embodiment of a rotor element according to the invention 10 , The rotor element 10 has a rotor blade 12 and a flow guide surface associated therewith 14 on. The flow control surface 14 lies a side surface 16 across from. In the embodiment shown, the side surface is 16 Concave - it has an inner arc, while the other, hidden side surface of the rotor blade 12 is convex. Furthermore, the flow guide has 14 two convex sides - it has two outer curves - and has an elliptical cross-section.

Will the rotor element according to the invention 10 a fluid flow with a fluid flow direction 18 exposed by being aligned like a sail to the fluid flow, arises in cooperation of the flow guide 14 and the rotor blade 12 a particular laminar flow field between these two parts of the rotor element 10 , Compared to the flow around the rotor blade 12 without flow control surface 14 results with flow control surface 14 a stronger force on the rotor leaf 12 , The force on the rotor blade acts substantially perpendicularly from the concealed convex side surface of the rotor blade 12 away (buoyancy).

The 2 is a schematic representation of an embodiment of a wind turbine with a rotor 20 , the three rotor elements according to the invention 10 and on a mast 22 swiveling around the figure axis of the mast 22 is attached. The rotor elements 10 are equidistant on the rotor 20 at one about an axis perpendicular to the plane of the rotor elements 10 rotatable rotor base 24 arranged. Not shown in detail drawn such an embodiment of a wind turbine also includes a shaft on which by the rotation of the rotor 20 in the direction of rotation 26 a torque acts, an electric generator for generating power and a transmission for transmitting torque from the shaft to the electric generator. Regarding the direction of rotation 26 lies the flow control surface 14 a short distance behind, especially in the slipstream of the rotor blade 12 , Seen frontally on the wind turbine, is the concave side surface of the rotor blade 12 visible, noticeable.

To the experimental proof of the described principle at one more drive rotor blades Windmill were at a plurality of different air flow speeds (Winds) and parameterizes with the angle of attack of the wind turbine to the flow direction performed on the wind turbine with and without associated flow control surfaces. there have shown the following quantitative dependencies: wind turbines with and reach without flow control surfaces with variation of the angle of attack at a certain angle of attack independent of the flow velocity a maximum speed. At a fixed angle and a fixed flow rate can basically by means of the flow guide the Speed can be increased. With increasing flow velocity the relative rates of increase are greater. With decreasing angle between the rotor blade and the flow guide increases the speed.

LIST OF REFERENCE NUMBERS

10

rotor member

12

rotor blade

14

flow guide

16

side surface

18

Fluid flow direction

20

rotor

22

mast

24

rotor base

26

direction of rotation

Claims (15)

Rotor element ( 10 ) to the flow around a fluid and for a rotor ( 20 ), with a rotor blade ( 12 ), which has two side surfaces, and one the rotor blade ( 12 ) associated flow guide, characterized in that the flow guide a flow guide ( 14 ), whose wake at least partially the flow on one of the side surfaces of the rotor blade ( 12 ). Rotor element ( 10 ) according to claim 1, characterized in that a long Maßstrecke the flow guide ( 14 ) along a longitudinal axis of the rotor blade ( 12 ) and / or that the flow control surface ( 14 ) within a shadow projection along a direction of a surface vector of the rotor blade ( 12 ) lies. Rotor element ( 10 ) according to claim 1 or 2, characterized in that the flow guide surface ( 14 ) has two convex side surfaces and / or an elliptical cross-section. Rotor element ( 10 ) according to one of the preceding claims, characterized in that the rotor blade ( 12 ) and the flow control surface ( 14 ) are firmly spaced from each other and / or are mutually movable in a fixed relative position to each other. Rotor element ( 10 ) according to one of the preceding claims, characterized in that the one side surface of the rotor blade ( 12 ) concave and / or the other side surface of the rotor blade ( 12 ) is convex. Rotor element ( 10 ) according to claim 5, characterized in that the flow control surface ( 14 ) of the concave side surface of the rotor blade ( 12 ) is opposite. Rotor element ( 10 ) according to one of the preceding claims, characterized in that the rotor blade ( 12 ) and the flow control surface ( 14 ) are connected together by struts or together on a rotor base ( 24 ) are included. Rotor element ( 10 ) according to one of the preceding claims, characterized in that in the longitudinal direction of the rotor blade ( 12 ) the distance of an edge of the flow guide ( 14 ) from the side surface of the rotor blade ( 12 ) increases monotonously. Rotor ( 20 ) having a plurality of rotor elements ( 10 ) to the flow around a fluid, characterized by at least one rotor element ( 10 ) according to any one of the preceding claims. Rotor ( 20 ) according to claim 9, characterized in that from the direction of rotation of the rotor ( 20 ) seen the flow control surface ( 14 ) in the lee of the rotor blade ( 12 ) lies. Rotor ( 20 ) according to claim 9 or 10, characterized in that the angular positions of the rotor blades ( 12 ) and / or the flow control surfaces ( 14 ) are adjustable, in particular controllable or controllable, about their respective longitudinal axis directions. Engine for converting the flow energy of a fluid into another form of energy, in particular into electrical energy, with a rotor ( 20 ), whose axis of rotation can be adjusted substantially in the flow direction, characterized in that the rotor ( 20 ) is a rotor according to one of claims 9 to 11. Engine according to claim 12, characterized in that that the fluid is a gas, in particular air, or a liquid, especially water, is. Propeller drive for generating a propulsion in a fluid, characterized by at least one rotor ( 20 ) according to any one of claims 9 to 11. Propeller drive according to claim 14, characterized in that in the plane of rotation of the rotor ( 20 ) seen the flow control surface ( 14 ) in front of the rotor blade ( 12 ) lies.

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