KR101188058B1 - Blade structure having pivots for savonius wind generator - Google Patents

Abstract

PURPOSE: A savonius blade structure is provided to block wind pressure as wind passes through a blade placed at an opposite position to a vertical shaft. CONSTITUTION: A savonius blade structure comprises a vertical shaft, a plurality of blades, and a plurality of pivot pillars. The vertical shaft is formed at the center of a place between circular upper and lower plates. The plurality of blades is radially formed around the vertical shaft, and comprises a circular arc shape. The plurality of pivot pillars is adjacently connected to the blades, and vertically formed to the vertical shaft. The blades are connected to the pivot pillars by an elastic unit, and the pivot pillar adjacent to the blade functions as a stopper.

Description

Savonius blade structure {Blade structure having pivots for Savonius wind generator}

The present invention relates to a savonius blade structure for wind power generation.

The present invention relates to a savonius blade structure, and is used in an apparatus for generating electricity using wind power. Wind power can be converted into useful energy using its kinetic energy, which is generally a turbine or a windmill, and is classified into a horizontal axis or a vertical axis system according to the type of shaft that transmits the rotational force of the turbine to the generator.

Savonius turbines belong to the vertical axis system, and the wings generally have an s-shape as a whole, and the parts of the wing that do not generate rotation are relatively resistant to wind, so the rotation speed is relatively slow, but the rotating wing area is large. There is an advantage of generating a large torque by receiving the wind in front. In addition, there is an advantage that the generation efficiency is relatively good even at low wind speed and low air volume.

The typical form of a vertical small wind generator is to place two half pipes in opposite directions so that when one side is subjected to maximum drag, the other half pipe portion is subjected to minimum drag. And savonius rotors having torque characteristics.

In the conventional savonius rotor, a half-pipe type has recently been proposed a number of techniques using a spiral savonius shape in consideration of noise and vibration. 6 shows the wing shape of a typical savonius rotor.

The present invention is equipped with a plurality of panels for the conventional half-pipe Savonius wind power generation to the plurality of pivot pivot panel of the surface subjected to the maximum drag to maintain the shape and at the same time, the maximum torque, The area that receives the least drag is characterized by the fact that the pivot panel is opened, that is, the wind can pass through, thereby maximizing the rotational force generated.

The differentiation from the prior art will be described as follows. In the case of the conventional savonius rotor, the technology has been developed from a half-pipe shape to a spiral savonius shape in consideration of noise and vibration through simple processing, but by embodying the openable and openable savonius blade shape in the present invention. Power characteristics can be expected to improve by 20 to 30 percent and are expected to be widely used in small wind generators.

In the present invention, by installing a plurality of blade mounting structure used in the wind turbine having a savonius structure on the pivot pillar, an object of the present invention to maximize the rotational force.

The problem solving means of the present invention is as follows.

That is, in the savonius blade structure for wind power generation,

A vertical axis 300 formed at the center of the space between the circular upper and lower plates;

A plurality of blades formed in a radial direction about the vertical axis;

A plurality of pivot columns on which the blades are mounted;

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The blade is coupled by a pivoting column and elastic means so that the blades at the position receiving the maximum wind pressure (arranged concave with respect to the wind direction) are closed and at the same time the blades at the opposite positions (convex with respect to the vertical axis) Array) is characterized in that it is formed to open about the pivot pillar.

 The elastic means is a spring, one side of the spring is mounted to the pivot pillar and the other end is mounted to the blade surface, characterized in that the blade is rotated about the pivot pillar by a predetermined angle from the neutral position by the wind pressure.

In addition, the pivot pillars are interconnected by the link 900, characterized in that the pivot pillars of one side are rotated to form a body with respect to the vertical axis.

The blade structure of the present invention may be widely applied to a general wind blade.

That is, the vertical axis 300;

A plurality of blades formed in a radial direction about the vertical axis;

A plurality of pivot columns on which the blades are mounted;

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The blade is coupled by a pivoting column and elastic means so that the blades at the position receiving the maximum wind pressure (arranged concave with respect to the wind direction) are closed, and at the same time the blades at the opposite positions with respect to the vertical axis (convex with respect to the wind direction). Arrangement) is widely applicable to the wind turbine blade in a form formed to be open about the pivot pillar.

Wind power generator having a blade structure of the present invention to receive the wind pressure of the blowing wind as it is to be used as it is in the rotational force and at the same time the wind passes through the blade in the opposite position relative to the vertical axis, wind pressure generation is impeded by the rotational force It can exert the function to stop.

1 is a blade mounting structure according to a preferred embodiment of the present invention,
Figure 2 is a view showing a state in which the blade is open when the wind in the situation of Figure 1,
3 and 4 is a view showing the mounting state of the blade and the pivot column,
5 is a schematic representation of the principles of the invention;
6 shows a prior art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the scope of the present invention is not limited to the following examples, and the rights extend to the invention equivalent to the scope of the invention as grasped from the claims.

6 shows a conventional savonius rotor 10 structure. In the drawing, the rotor (or turbine) 20 is rotated about the vertical axis 30, and the vertical axis 30 is coupled to the support plate 40. The lower power generation unit 50 briefly illustrates a portion where power is generated as the blade 20 rotates. The blade 20 is composed of a first blade 220 that receives the wind to the front to generate a rotational force in the direction of the wind and a second blade 24 that rotates in the opposite direction to the direction of the wind.

The vertical axis of rotation is fixedly coupled to the left and right ends of the first and second blades and is perpendicular to the direction of the ground and the wind, and receives the rotational force generated by the rotation of the blade and transmits the rotational force to one end of the shaft.

In the prior art, the blade opposite to the blade (the blade concave to the wind direction) that receives the wind direction to the maximum, rather than to act to reduce the rotation force adversely affects the performance of the wind generator.

Therefore, in the present invention, the blade portion for reducing the rotational force to pass through the wind to increase the rotational force to the maximum is the subject of the technical idea.

Figures 1 and 2 show the structure of the blade of the present invention, respectively, Figure 1 shows the closed state of the blade (if there is no wind), Figure 2 from the front of the ground to the back The blades 750, 760, 770, 780 on the right side are opened by wind pressure when the wind blows.

In the state where several blades are in contact with the pivot column, it is preferable to have an arc shape when viewed from above to receive a wind pressure.

In FIG. 1 and FIG. 2, since the power generation unit 50 in FIG. 6 is generally used, only the main components are shown for convenience. Hereinafter, the blade structure and the coupling structure of the present invention will be described.

As shown in the related art of FIG. 6, the vertical vertical axis 300 is mounted at a position connecting the center of the lower plate to the center of the upper plate in the space between the upper and lower plates 400 and 410, and the blades rotate while the power is generated. The upper plate hole 401 is briefly illustrated as where the vertical axis 300 is coupled.

As described above, the blade of the present invention, unlike the prior art Figure 6 blades 710, 720, 730, 740, 750, 760, 770, 780 is coupled to one side of the pivot pillars. At this time, the blades are connected to the pivot columns by using a predetermined elastic means, which is normally closed by the elastic force of the elastic means (812a, 812b, 812c) so that it is opened by wind pressure only when the wind blows. For sake.

In FIG. 2, the various blades on the right side of the vertical axis 300 are opened by the wind pressure, and A, B, C, and D show directions in which the blades are opened by the wind pressure. The opening blades are in a convex position protruding with respect to the wind direction (right blades in FIG. 5). Blades that are not open are located concave with respect to the wind direction (left blades in FIG. 5).

On the other hand, when the blades are opened in the B and C direction, the springs are tensioned and compressed in the neutral state, respectively, to be restored to their original state, but are opened by the wind pressure.

The wind pressure can be expressed as 1/2 * air density * (square value of the wind speed), and the torque due to the wind pressure is larger than the torque due to the spring force, so that the blade is opened as shown in FIG. In consideration of the outside air velocity, the constant of the spring (elastic means) and the position where the elastic means are mounted should be determined.

Blades positioned on the left side of the vertical axis of FIG. 2 are closed. In this case, the blade 720 denotes the pivot panel 610 as a stopper, and the blade 730 refers to the pivot panel 630 as the stopper. In the blade 740, the vertical axis 300 serves as a stopper.

The pivot columns 610, 620, 630, 640, 650, 660 are symmetrically opposed to each other about the vertical axis 300, and the ends of the respective pivot columns are connected to each other by the link 900 by the link 900. The opposite pivot pillars may be rotated at the same time while facing each other at an angle of 180 degrees about 300.

That is, the pivot pillars are interconnected by the link 900 so that the pivot pillars on one side may be rotated to form a body with respect to the vertical axis. Of course, the number of the pivot pillars can be added or subtracted.

In addition, although the shape of the blade is shown in a flat plate shape, it is formed in an arc shape having a curvature (cross section is an arc shape), when looking at the four blades on one side of the vertical axis 300 as a whole (when viewed from above) It is preferable to form a shape of. That is, it is preferable to be formed like the shape of one blade of Figure 6 showing the prior art.

In more detail, the coupling structure of the pivot column and the blade will be described.

3, the blade 750 is mounted on the side of the pivot pillar 640, the elastic means 812a is mounted on one side of the central portion of the pivot pillar. When the wind does not blow, the elastic means is pulled and fixed in one direction by the elastic force of the elastic means, and when the wind blows, it is opened by the wind pressure as shown in FIG. 2.

The end of the elastic means has a structure fixed to the spring fixing means 735, the edge of the blade 750 is coupled with the blade fixing means 642a, 642b. The blade fixing means is mounted to surround the outer circumference of the pivot column 640.

Although the blade fixing means 642a and the blade 750 are preferably coupled by a plurality of riveting means 737, various fastening means may be used without being limited to rivets.

In FIG. 4, two blades 720 and 730 are mounted on the pivot column 620 of the pivot columns of FIG. 2.

The pivot column 620 and blades 720 and 730 of FIG. 4 are structurally identical to the other pivot columns 650 and blades 760 and 770 of FIG. 2.

As shown in FIG. 2, the two blades 720 and 730 are centered around the pivot column 620, and open in a v-shape when the wind pressure is applied to pass through the wind.

The structure of FIG. 4 differs from FIG. 3 in that two blades are mounted on one pivot column. Therefore, two elastic means 812b and 812c are mounted around the pivot pillar, and two blade fixing means 642c, 642d, 642e, and 642f are coupled to and fixed with the blades 720 and 730, respectively.

The end of the elastic means is fixed to one side of the blade face takes the same structure as in the case of FIG.

5 is a view summarizing the structure and the principle of operation of the present invention, the wind direction is set from the bottom up, it is a view observed from the top of FIG.

As described above, when the wind blows, the blades on the left side receive the maximum wind pressure based on the vertical axis to generate the rotational force (clockwise), and the blades on the right side have the spring force less than the wind pressure so that the blades open about the pivot column. So as not to reduce the rotational force.

400: top plate 401: top hole
410: lower plate
610, 620, 630, 640, 650, 660: first to sixth pivot column
710,720,730,740,750,760,770,780: first to eighth blades
812a, 812b, 812c: elastic means

Claims (5)

In the savonius blade structure for wind power generation,
A vertical axis 300 formed at the center of the space between the circular upper and lower plates;
A plurality of blades formed in a radial direction about the vertical axis and having an arc shape when viewed from above;
A plurality of pivot columns adjacent and coupled to the blades and formed parallel to the vertical axis; Including,
The blade is coupled by the pivot column and the elastic means, the blades in the position receiving the maximum wind pressure (arranged in the wind direction), the pivot pillar adjacent to the blade serves as a stopper, the blade is closed,
At the same time, the blades (arranged convexly with respect to the wind direction) of the opposite positions with respect to the vertical axis are formed so that the elastic means are displaced and opened about the pivot column by wind pressure, and the elastic means is a spring, and one side of the spring is At the same time as being mounted to the pivot column, the other end is mounted to the blade surface, so that the blade is rotated and opened about the pivot column by a predetermined angle from the neutral position by the wind pressure,
Normally, the blades are closed by the elastic force of the elastic means 812a, 812b, 812c and are opened by the wind pressure only when the wind blows, but the blades that are opened are in a convexly protruding position with respect to the wind direction. The non-opening blades are characterized by being concave in the wind direction. When the blades are opened, the springs are tensioned and compressed in the neutral state and restored to their original state, but are opened by the wind pressure greater than the spring force. The blade which is opened by the wind is opened automatically while forming a v shape with the pivot pillar 620 as the center, and is characterized in that it passes through without receiving a fluid resistance.
The pivot columns are connected to each other by a link 900 so that the pivot columns on one side may be rotated to form a body based on a vertical axis.
Savonius blade structure.

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