KR20120131827A - A duplicated airfoil for a small wind turbine blade and a vertical wind turbine power system using this blade - Google Patents

Abstract

PURPOSE: An airfoil blade for a wind power generator and a windmill with the same are provided with a reduced manufacturing cost as the materials of an air pressure generating member are light and more easily shaped than a blade camber. CONSTITUTION: An airfoil blade(100) for a wind power generator comprises a blade camber(110) and an air pressure generating member(120). The blade camber comprises a streamlined part(111) and an attachment part(112). The attachment part is extended from one end of the streamlined part. The attachment part is bent toward the other side of the streamlined part, and provides a space for attaching one side of the air pressure generating member. The air pressure generating member is more easily formed than the blade camber, and made of light bi-materials. One side of the air pressure generating member is fitted into the inside of the attachment part.

Description

A duplicated airfoil for a small wind turbine blade and a vertical wind turbine power system using this blade}

The present invention relates to blades used in wind power generators, and more particularly to air blade blades for wind generators manufactured in airfoil structure using different materials. In addition, the present invention also relates to a vertical windmill structure having the blade blade as described above.

Wind generators are divided into horizontal and vertical type according to the installation shape of the blade. In regions where the wind direction is not constant, the vertical wind generator is advantageous in that it is easier to start and has lower noise characteristics than the horizontal wind generator. Vertical wind generators are easy to install on windmill structures, so they can be installed on rooftops or reservoirs.

Airfoil refers to the cross-sectional shape of a wing or blade and is used to scientifically define a specific section of a lifting surface, such as the wing of a fixed wing aircraft or the blade of a helicopter. have. In order to fly an aircraft that is heavier than air, an aerodynamic effect, i.e. a large lift and a small drag, is required, so that the airfoil is generally rounded and sharpened to have a streamlined shape to increase lift. Consists of. Therefore, in the case of aircraft, the airfoil is optimally designed to obtain the maximum lift according to the flight speed range.

On the other hand, in the case of the wind generator, since the change in the relative angle of attack of the blade section that rotates with respect to the wind direction is very severe, the airfoil structure that can obtain the maximum force of the direction vector component for rotating the blade from the generated aerodynamic load component It is preferable.

Therefore, Korean Patent No. 0611371 discloses a vertical wind generator having a plurality of blades manufactured to receive more force in the direction of rotation by making curved surfaces formed in the same direction. However, the blade of this technology has a limit in increasing the efficiency of wind power because only the curved structure has no airfoil structure.

In addition, Korean Patent No. 0904850 discloses a vertical wind generator having a plurality of blades having a airfoil structure. On the other hand, the airfoil blade is rotated as the lifting force is formed after the air pressure is formed on the surface of the blade by the wind direction. Therefore, the airfoil blade will have a different rotational force depending on the shape of the curved surface of the site where air pressure is generated. That is, in the blade blade for a wind generator, the shape of the air pressure generating part is one of the important factors.

By the way, the blade blade of Korean Patent No. 0904850 is configured to have an integral structure made of one material. When airfoil blades are made of one material in this way, it is not only difficult to manufacture but also expensive to manufacture because it has to have an overall streamlined shape and integrally molded in consideration of the curved surface of the air pressure generating part. There is this.

On the other hand, the airfoil blades for the wind generator is important to light weight to configure the weight lightly. By the way, when manufacturing a blade blade integrally with one material as in the Republic of Korea Patent No. 0904850, even if a light composite material is used, there is a limit in weight reduction.

Therefore, the present invention has been made in order to solve the problems of the prior art as described above, the air pressure generating member attached to one side of the blade camber and the blade camber having a streamline shape as a whole to have a airfoil structure composed of different materials. The air pressure generating member is easy to form than the material of the blade camber, and by using a light material, it is easy to manufacture and the manufacturing cost is low as well as to provide a lightweight blade for the wind generator and a windmill structure having the same. There is this.

The airfoil blade for a wind generator of the present invention comprises a blade camber (blade camber) having a streamlined shape as a whole by processing the thin plate to have a airfoil structure, and an air pressure generating member attached to one side of the blade camber to generate air pressure The blade camber is a streamlined portion having a streamlined curved surface, and is formed to extend from one end of the streamlined portion and is bent to extend toward the other end of the streamlined portion to provide space for attaching one side of the air pressure generating member to the inside. And a airfoil structure when the end portion of the streamlined portion and the attachment portion is virtually connected, and the air pressure generating member is made of a heterogeneous material which is easier to mold and lighter than the material of the blade camber, and has a airfoil structure itself. Its one side is characterized in that it has a form fitted to the inside of the attachment portion.

The windmill structure of the present invention is a plurality of wind turbine blade blades configured as described above, the shaft is connected to the lower portion of the power generator for producing electrical energy using the wind, and fixed to the upper and lower portion of the shaft and a plurality of wind power It characterized in that it comprises a plurality of support members for supporting the blade blade for the generator up and down.

The present invention consists of a blade camber having a streamlined shape and an air pressure generating member attached to one side of the blade camber in a heterogeneous material so as to have an airfoil structure. Since it is easy to manufacture, there is an advantage that the manufacturing cost is low as well as light weight.

1 is an exploded perspective view showing the configuration of the airfoil blade blades according to an embodiment of the present invention,
2 and 3 is a front view and a rear view of the air blade blade shown in Figure 1 is coupled,
4 is a cross-sectional view taken along the line AA of the airfoil blade shown in FIG.
5 is an exploded perspective view showing the configuration of the windmill structure having a blade blade for a wind generator according to the present invention,
6 is a perspective view of the combination of the windmill structure shown in FIG.
7 is a perspective view of the support member shown in FIG.
8 is a perspective view of the bracket shown in FIG. 5,
9 is a perspective view of the upper cap shown in FIG.
10 is a perspective view of the lower cap shown in Figure 5,
FIG. 11 is a perspective view of the connector shown in FIG. 5. FIG.

In the following, with reference to the accompanying drawings, preferred embodiments of a wind turbine blade blade and a windmill structure having the same according to the present invention will be described in detail.

First, the airfoil blade for a wind generator according to this embodiment will be described. In the drawings, Figure 1 is an exploded perspective view showing the configuration of the airfoil blade blades according to an embodiment of the present invention, Figures 2 and 3 are a front view of the airfoil blade shown in Figure 1 coupled and 4 is a cross-sectional view taken along the line AA of the blade blade shown in FIG. 2.

1 to 4, the airfoil blade 100 for a wind generator according to this embodiment has a blade camber 110 and a blade camber 110 having a streamline shape as a whole to have a airfoil structure. Attached to one side of the air pressure generating member 120 for generating an air pressure.

The blade camber 110 is bent to have a streamlined shape as a whole. For example, thin aluminum sheets may be sheet metalized to have a airfoil structure. That is, the blade camber 110 is formed by extending from one end of the streamlined portion 111 and the streamlined portion 111 having a streamlined curved surface, and is bent to extend toward the other end of the streamlined portion 111. It is composed of an attachment portion 112 that provides a space for attaching one side of the air pressure generating member 120. The blade camber 110 is manufactured to be integral, and is configured to have a airfoil structure when the ends of the streamline portion 111 and the attachment portion 112 are virtually connected.

The air pressure generating member 120 is composed of a different material different from the blade camber 110, but is formed of a material that is easier to form and lighter than the material of the blade camber 110. For example, the air pressure generating member 120 of this embodiment may be made of styrofoam or plastic. The air pressure generating member 120 itself has a airfoil structure, one side thereof is fitted to the inside of the attachment portion (112). In addition, the air pressure generating member 120 is configured to have a width length smaller than the streamlined portion 111 of the blade camber 110. Therefore, the air pressure generating member 120 is attached to only one side of the inner side portion of the streamlined portion 111, the one side is attached and coupled to the inside of the attachment portion 112.

The airfoil blade 100 for the wind generator of this embodiment is to produce a blade camber 110 and the air pressure generating member 120 of a different material, the blade camber 110 is made of airfoil structure by sheet metal processing a thin aluminum sheet. The air pressure generating member 120 may be made of styrofoam or plastic, which is easier to form and lighter than the material of the blade camber 110, and then attached and integrated. That is, in manufacturing the airfoil blade for the wind power generator, the air pressure generating portion that requires a precise curved surface is injection-molded with styrofoam or plastic, which is easy to form, to manufacture the air pressure generating member 120, and then, by sheet metal processing or the like. Since it can be attached to the blade camber 110, which is simply manufactured, and integrated, the fabrication can be made easily and at low cost. In addition, as the air pressure generating member 120 is made of styrofoam or plastic, which is a light material, it is possible to reduce the weight of the airfoil blade 100 for a wind generator.

Hereinafter, a windmill structure having a blade blade for a wind generator configured as described above will be described. 5 is an exploded perspective view showing the configuration of the windmill structure having a blade blade for a wind generator according to the present invention, Figure 6 is a combined perspective view of the windmill structure shown in Figure 5, Figures 7 to 11 5 is a perspective view of the supporting member, the bracket, the upper cap, the lower cap or the connector shown in FIG. 5.

5 to 11, the windmill structure according to this embodiment has a plurality of airfoil blades 100 configured as described above, and a lower portion thereof in a power generating device (not shown) for producing electrical energy using wind power. A pair of support members 300 and a plurality of airfoil blades 100, which are connected to the shaft 200 to be connected, fixed near the top and bottom of the shaft 200, and support the airfoil blades 100 vertically. A plurality of brackets 400 respectively fixed to the pair of support members 300, an upper cap 500 finishing the upper end of the upper support member 300 among the pair of support members 300, and a shaft; The lower cap 600 to finish the lower end of the 200, and is coupled to the circumference of the lower cap 600 is composed of a connector 700 for connecting to the generator.

As shown in FIG. 7, the support member 300 of this embodiment is configured to have three support portions 310 for supporting the three blade blades 100 at equal intervals. On the other hand, the support 310 has a rounded end portion so as to be in close contact with the inner surface of the blade blade 100, that is, the peripheral surface of the attachment portion 112 of the blade camber 110. In addition, the support 310 is configured to have a plurality of fastening holes 311 near the end for fastening with the bracket 400 and the screw.

As shown in FIG. 8, the bracket 400 serves as a medium for fixing the blade blade 100 to the support 310 of the support member 300, and has a bent shape in a right angle. On the other hand, the bracket 400 has a plurality of fastening holes 410 near each end for fastening with screws or the like, respectively. One side of the bracket 400 is fastened and fixed to the support 310 of the support member 300, the other side is fastened and fixed to the outer surface of the streamlined portion 111 of the blade blade 100, airfoil blade 100 To the support member 300.

Although the technical details of the airfoil blade for the wind generator and the windmill structure having the same have been described above with reference to the accompanying drawings, this is by way of example and not by way of limitation.

In addition, it is obvious that any person skilled in the art can make various modifications and imitations within the scope of the appended claims without departing from the scope of the technical idea of the present invention.

100: airfoil blade 110: blade camber
111: streamlined portion 112: attachment portion
120: air pressure generating member 200: shaft
300: support member 310: support portion
311: fastening hole 400: bracket
410: fastening hole 500: upper cap
600: lower cap 700: connector

Claims (9)

It comprises a blade camber (110) having an overall streamlined shape by processing the thin plate to have an airfoil structure, and an air pressure generating member (120) attached to one side of the blade camber (110) to generate air pressure. ,
The blade camber 110 is formed by extending from one end of the streamlined portion 111 having a streamlined curved surface and the streamlined portion 111 and extending to bend toward the other end side of the streamlined portion 111. And an attachment part 112 providing a space for attaching one side of the air pressure generating member 120 to the airfoil structure when the ends of the streamlined part 111 and the attachment part 112 are virtually connected. Has,
The pneumatic pressure generating member 120 is made of a material of a heterogeneous material that is easier to form and lighter than the material of the blade camber 110, and has a airfoil structure on its own side, one side of which is inside the attachment part 112. Air blade blade for wind power generator, characterized in that it has a form to be fitted. The method according to claim 1,
The air pressure generating member 120 is configured to have a smaller width than the streamlined portion 111, airfoil blades for a wind generator, characterized in that attached only to a portion of the inner surface of the streamlined portion (111). The method according to claim 2,
Air blade blade for a wind generator, characterized in that the blade camber 110 is made of an aluminum material. The method according to claim 3,
The air pressure generating member 120 is a blade blade for a wind generator, characterized in that consisting of styrofoam or plastic material. The blade blades 100 for a plurality of wind generators described in any one of claims 1 to 4,
The shaft 200 is connected to the lower portion of the generator for producing electrical energy using wind power, and
Is provided near the top and bottom of the shaft 200 is provided with a blade blade for the wind generator, characterized in that it comprises a plurality of support members 300 for supporting the plurality of wind blade blades 100 for the wind turbine up and down. Windmill structure. The method according to claim 5,
Windmill structure having a wind blade blade for wind generators, characterized in that it further comprises a plurality of brackets (400) for fixing the plurality of blade blades for wind generators (100) to the plurality of support members (300), respectively. The method of claim 6,
The upper cap 500 for finishing the upper end of the support member 300 of the uppermost of the plurality of support members 300, the lower cap 600 for finishing the lower end of the shaft 200, and the lower The windmill structure having a blade blade for a wind generator, characterized in that it further comprises a connector 700 coupled to the circumference of the cap 600 for connecting to the generator. The method of claim 6,
The support member 300 is configured to have a plurality of support portions 310 for supporting the plurality of blade blades 100 for wind generators at equal intervals, the support portion 310 is attached to the blade camber 110 A windmill structure having a blade blade for a wind generator, characterized in that it has a rounded end portion to be in close contact with the peripheral surface of the portion (112). The method according to claim 8,
The bracket 400 is configured to be bent at a right angle, one side is fastened and fixed to the support 310 of the support member 300, the other side is an outer surface of the streamlined portion 111 of the blade blade 100. Windmill structure having a blade blade for wind power generator, characterized in that fastened to the fixed.

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