DE102014005220B4 - Impeller with spar, wing profiles and rotation axis - Google Patents

Abstract

Impeller with spar (1), wing profiles (3, 4) and rotation axis (2), wherein the hub for the axis of rotation in the middle of the spar (1) and the wing profiles (3, 4) perpendicular to the axis of rotation (2) on both sides , with approximately equal distances, one above another and rectified on the spar (1) are arranged, and wherein the vertices of the wing profiles (3, 4) can span any geometric surfaces, characterized in that the wing profiles (3, 4) flat plates, blades, Circular arc profiles, hydrofoils and similar structures may be, with their aerodynamic angle of attack on one side of the spar (1) and the one hand clamped surface upwards and on the other side of the spar (1) and the other side clamped surface facing down, and after these positions, the impeller rotates in one direction and with reversal of the angle of attack, the impeller rotates in the opposite direction, the effect of the flow on the wing elrad can be controlled with the change in the angle of attack.

Description

The invention relates to an impeller with spar, wing profiles and axis of rotation, wherein the hub for the axis of rotation in the middle of the spar and the wing profiles perpendicular to the axis of rotation, on both sides, with approximately equal distances one above the other and rectified are arranged on the spar and the vertices of the wing profiles span any geometric surfaces.

The DE 168 711 A shows a section of a windmill wing with adjustable shutters.

Flow and centrifugal machinery, including windmill blades, pumps, fans, turbines, propellers, propellers and, last but not least, wind turbines. Striking feature are the more or less large hubs for radial recording of the long blades, which can be 100 m and longer. This creates structures that are increasingly open to public discussion because of the effects on nature, the environment and land use.

Although common flow and centrifugal machines often have hubs with a large diameter, which are less noticeable because they are housed in housings or structures. Here, at most, the great expense in the production is perceived as a disadvantage.

The object of the invention is to seek a better design for flow and centrifugal machines in general, which avoids the known disadvantages. For mere refinement of structures can only bring some small progress.

With regard to the wind energy plant, for example, a compression at the inflow surface would not only lead to smaller structures, but also less favorable locations could be used first or even at all.

In the current flow and centrifugal machines with a star-shaped radial arrangement of the airfoils, only a fraction of the possible circular area can be impinged or reached by the fluid particles. Because with the star-shaped radial arrangement of the airfoils, the rotary cavity must remain partially empty or is not used by the flow.

It must also be assumed that in such a star-shaped arrangement of the airfoils can be optimal flow conditions between two airfoils only at a radius distance. Outside this radius distance, the flow is more or less disturbed.

On the other hand, if the wing profiles are parallel to one another, they are flowed through in the optimum manner over the entire wing length and the entire rotational cavity is utilized, and the distance between the wing profiles can then be set to a favorable distance. It stands to reason that with the parallel arrangement of the airfoils not only the inflow surface is compressed, but the area of the vanes can be increased by a multiple value.

In one embodiment, wing profiles with a total length of sixty meters could be accommodated in a right-angled inflow area of approximately two times two-square meters (2 × 2.6 m). By comparison, only four meters of wing length would have been possible with a three-bladed, radial arrangement.

Even with the acceptance of unfavorable aerodynamic flow, a positive result remains. As a benefit, increase in power or reduction of the structures can be derived.

Although from the literature level just grid of blades known (Dubbel, paperback for mechanical engineering, 14th edition under a paddle 1.4.1.). Wing profiles or blades are not used in this arrangement in machines, because when flowing through a fluid only a linear movement. At most, such an arrangement will investigate or illustrate fundamental theoretical experimental relationships.

The generation of work, however, requires the change of the peripheral speed. Only the conception according to the invention generates a rotational movement and thus the change of the peripheral speed.

The invention alone provides new structures in flow and centrifugal machines. This is reflected not only in less material and lower manufacturing costs, but also in smaller loads for nature and the environment.

Description of the figure

In the 1 an impeller with rectangular clamping and rectangular inflow in the view and the section AA and BB is shown.

The surface for the flow is spanned by two rectangular surfaces. The impeller has a spar ( 1 ) with hub and axis of rotation ( 2 ), as well as the wing profiles ( 3 ) with upwardly (positively) directed angle of attack and the wing profiles ( 4 ) with downward (negative) directed angle of attack to the horizontal. If the impeller flows from the view side, the impeller rotates clockwise.

Claims (8)

Impeller with bar ( 1 ), Wing profiles ( 3 . 4 ) and rotation axis ( 2 ), wherein the hub for the axis of rotation in the middle of the spar ( 1 ) and the wing profiles ( 3 . 4 ) at right angles to the axis of rotation ( 2 ) on both sides, at approximately equal intervals, one above the other and rectified on the spar ( 1 ) are arranged, and wherein the vertices of the wing profiles ( 3 . 4 ) can span any geometric surfaces, characterized in that the wing profiles ( 3 . 4 ) flat plates, blades, circular arc profiles, airfoils and similar structures, wherein their aerodynamic angle of attack on one side of the spar ( 1 ) and on the one hand spanned surface upwards and on the other side of the spar ( 1 ) and the other hand, the surface is spanned downwards, and after these positions, the impeller rotates in one direction and with the reversal of the angle of attack, the impeller rotates in the opposite direction, the effect of the flow are controlled on the impeller with the change in the angle of attack can. An impeller according to claim 1, characterized in that the spar is a straight support to both sides at right angles to the axis of rotation and functional parts and structures for adjustment of the wing profiles contains or may contain. Impeller according to one of claims 1 to 2, characterized in that the impeller in the orientation of the axis of rotation of the horizontal to the vertical can be operated arbitrarily. Impeller according to one of claims 1 to 3, characterized in that an impeller is also meant when only two airfoils are arranged on the sides of the spar and a propeller circular surface in the sense of the so-called jet theory arises and this as in propellers, propellers, water turbines, wind turbines and other flow or centrifugal machines acts. Impeller according to one of claims 1 to 4, characterized in that there is more than one spar for receiving wing profiles. Impeller according to one of claims 1 to 5, characterized in that different blade profiles form the impeller. Impeller according to one of claims 1 to 6, characterized in that the impeller is freewheeling or by a housing and the housing is designed for aerodynamic functions. Impeller according to one of claims 1 to 7, characterized in that the impeller is formed in several stages, of guide and wheels, the guide wheels may be fixed or revolving.

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