KR101296674B1 - root airfoil of blade for wind power generator - Google Patents

Abstract

The present invention relates to a root airfoil of a blade for a wind turbine, and more particularly, to a root airfoil of a blade for a wind turbine comprising an upper side and a lower side formed between the front side and the front side and the rear side having a space from the front side and the front side. The root airfoil is formed in a shape having an inflection point for retarding the flow peeling backwards even at a low angle of attack on the camber line connecting the center to the upper and lower surfaces in order to increase the drag ratio, thereby maintaining the flow peeling even at a low angle of attack. Special invention that increases blade stability and energy production efficiency by delaying and improving starting torque and starting blade even at low wind speed, and generating higher lifting ratio than the root airfoil shape of existing blade. to be.

Description

Root airfoil of blade for wind power generators

The present invention relates to a root airfoil of a blade for a wind turbine, and more particularly to a root airfoil of a blade for a wind turbine to generate a higher lift ratio than the existing blade to increase the stability and energy production efficiency of the blade. .

In general, a wind turbine is a device that converts kinetic energy of wind into electrical energy through blades and generators. The wind turbine is in the introduction stage in Korea, but it is commercialized for land and sea in developed countries such as Europe and the United States, and is economical and effective. Wind energy, which is a high renewable energy source, is used a lot.

Therefore, the blade for turning the wind turbine has lower utilization in low wind speed and low wind volume area because the smaller surface area is smaller for gas dynamics reasons. As it grows, it must have an appearance that accommodates the specific gas dynamics requirements involved.

Therefore, the blade 100 is composed of a root airfoil 10, which is an inner portion of the blade 100, and a tip airfoil 20, which is an outer portion of the blade 100, as shown in FIG. In order to save weight and reduce weight, the inner and outer circumferences are made of hollow polyester, epoxy resin and the like on the reinforcing fibers and are surrounded by a gas-dynamically advantageous surface.

In addition, the root airfoil of the blade should have a high rigidity to prevent the weight of the blade and sag of the outer portion, but if the root airfoil has a large thickness for high rigidity, flow peeling occurs on the surface even at a low angle of attack. Since it can cause vortex, it should be possible to suppress it as much as possible.

However, since the root airfoil of the conventional blade is mainly developed for an aircraft, there is a problem in that the wind turbine blade and operating conditions are very different, and the optimum performance design point is also different, so that a large amount of performance loss must be taken.

That is, the root airfoil of the existing blade has a problem that the flow separation occurs even at a low angle of attack.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to form a root airfoil of the blade so as to delay the flow separation even at a low angle of attack, the blade to have a higher lift ratio than conventional blades It is to provide that the efficiency and performance of the further increase.

The present invention for achieving the above object is in the root airfoil of the blade for a wind turbine comprising a top and bottom formed between the front and rear and the front and rear having a space from the front and the front, the root air The foil is characterized in that it is formed in a shape having an inflection point for increasing the drag ratio by retarding the flow peeling backwards even at a low angle of attack on the camber wire connecting the center to the upper and lower surfaces in turn.

In the present invention, the maximum lift ratio coefficient of the root airfoil is characterized in that more than 1.3 at Reynolds number 3.0E + 06.

In the present invention, the root airfoil has a thickness ratio of 30%, and the top and bottom profiles have horizontal coordinate values (x / c) corresponding to the following table so that the root airfoil having a thickness ratio of 30% has the inflection point. And a vertical coordinate value (y / c).

In the present invention, the root airfoil has a thickness ratio of 40%, so that the root airfoil having a thickness ratio of 40% has the inflection point, so that the profile of the upper and lower surfaces has a horizontal coordinate value (x / c) corresponding to the following table. And a vertical coordinate value (y / c).

As described above, the present invention allows the blade root airfoil to have one or more inflection points on the camber wire, thereby increasing rigidity, delaying flow peeling at a low angle of attack, and improving blades even at low wind speeds due to improved starting torque. I can start it.

In addition, there is an economic effect of increasing the stability and energy production efficiency of the blade by generating a higher lifting ratio than the root airfoil shape of the existing blade.

1 is a view showing a blade for a wind turbine.
2 is a view showing a root airfoil of the blade according to an embodiment of the present invention.
3 is a graph between the angle of attack and the ratio of the blade according to an embodiment of the present invention
4 is a view showing a root airfoil of the blade according to another embodiment of the present invention.
5 is a graph between the angle of attack and the steering ratio of the blade according to another embodiment of the present invention

Hereinafter, a preferred embodiment of the root airfoil of the wind turbine blade according to the present invention will be described in more detail with reference to the accompanying drawings.

Here, in all the drawings below, the components having the same functions are not repeated, using the same reference numerals, and the following terms are defined in consideration of functions in the present invention, which are inherently commonly used. It should be interpreted as meaning.

First, the root airfoil structure of the blade is summarized to explain the present invention.

As shown in FIGS. 2 and 4, a straight line connecting the front leading edge 1 and the rear leading edge 2 of the root airfoil 10 of the blade 100 is referred to as a cord 5 and the root air of the blade 100. The line connecting the center to the upper surface 3 and the lower surface 4 of the foil 10 is called camber line 7.

The maximum height of the upper surface 3 and the lower surface 4 in the vertical direction of the cord 5 is referred to as the profile maximum thickness 6 and the maximum distance from the cord 5 to the average camber line. This is called the maximum camber line (8).

On the other hand, the horizontal coordinate value (x / c) refers to the length of the cord (5) and the vertical coordinate value (y / c) refers to the thickness of the upper surface (3) and the lower surface (4) along the length of the cord (5).

3 and 5, the lift ratio (cl / cd) refers to the ratio of lift and drag, and the angle of attack (AOA) refers to the angle between the code and the blowing wind. .

In addition, the thickness ratio is defined as the thickness / code length at any position of the blade, the Reynolds number is a general dimensionless coefficient used to represent the hydrodynamic operating conditions, the maximum drag force coefficient is the drag along the angle of attack The maximum size of the rain.

The present invention according to the structure definition as described above, as shown in Figures 2 to 5, the front leading (1), the rear leading (2) formed with a space from the front leading (1), the front leading (1) and the rear leading ( 2) In the root airfoil 10 of the blade 100 for a wind turbine comprising an upper surface 3 and a lower surface 4 formed therebetween, the root airfoil 10 is the upper surface 3 and the lower surface ( 4) is formed in a shape having one or more inflection points (9) to increase the drag ratio by delaying the flow separation to the rear end (2) even at a low angle of attack on the camber line (7) connecting the center in turn.

This will be described in detail with reference to Examples.

FIG. 2 is a root airfoil 10 of the blade 100 having a thickness ratio of 30% and being within 40% of the blade 100 in the radial direction, and having the inflection point 9 above. The profile of (3) and the lower surface 4 is formed by the horizontal coordinate value (x / c) and the vertical coordinate value (y / c) corresponding to Table 1 below.

The root airfoil 10 of the blade 100 according to an embodiment of the present invention as described above has a shape in which the concave shape is changed in a curve on the camber line 7, that is, two inflection points 9. In this way, the inflection point (9) increases the drag ratio by delaying the flow separation to the trailing edge (2) even at a low angle of attack, so that the maximum drag ratio coefficient as compared to the conventional blade 100 as shown in Figure 3 Reynolds number 3.0E Achieve 1.3 or higher at +06.

4 is a root airfoil 10 of the blade 100 which is 40% of the thickness ratio according to another embodiment of the present invention and is within 40% of the blade 100 in the radial direction, so as to have the inflection point 9. The profiles of the upper surface 3 and the lower surface 4 are formed by the horizontal coordinate values x / c and the vertical coordinate values y / c corresponding to Table 2 below.

The root airfoil 10 of the blade 100 according to another embodiment of the present invention as described above has a shape in which a concave shape is changed in a curve on the camber line 7, that is, two inflection points 9. In this way, through the inflection point (9) to increase the drag ratio by delaying the flow separation to the rear (2) even at a low angle of attack, as shown in Figure 5, the maximum drag ratio coefficient compared to the conventional blade 100, Reynolds number 3.0 Achieving 1.3 or higher at E + 06.

1: before the war 2: behind the war
3: top side 4: bottom side
5: code 6: maximum thickness of profile
7: Camber Line 8: Maximum Camber Line
9: inflection point 10: root airfoil
20: tip airfoil 100: blade

Claims (5)

In the front air and the root air foil of the blade for a wind turbine comprising a top surface and a bottom surface formed between the front edge and the front edge formed with a space from the front edge,
The root airfoil is formed in a shape having an inflection point for increasing the drag ratio by delaying flow separation backwards even at a low angle of attack on the camber line connecting the center to the upper and lower surfaces in turn.
The root airfoil is the blade inner portion that is within 40% of the blade radially,
The maximum drag ratio of the root airfoil is 1.3 or more at Reynolds number 3.0E + 06,
The root airfoil has a thickness ratio of 30%, and the top and bottom profiles have horizontal coordinate values (x / c) and vertical coordinate values corresponding to the following table so that the root airfoil having a thickness ratio of 30% has the inflection point. Root air foil of the blade for a wind turbine, characterized in that formed by (y / c).

delete delete delete In the front air and the root air foil of the blade for a wind turbine comprising a top surface and a bottom surface formed between the front edge and the front edge formed with a space from the front edge,
The root airfoil is formed in a shape having an inflection point for increasing the drag ratio by delaying flow separation backwards even at a low angle of attack on the camber line connecting the center to the upper and lower surfaces in turn.
The root airfoil is the blade inner portion that is within 40% of the blade radially,
The maximum drag ratio of the root airfoil is 1.3 or more at Reynolds number 3.0E + 06,
The root airfoil has a thickness ratio of 40% and the top and bottom profiles have a horizontal coordinate value (x / c) and a vertical coordinate value corresponding to the following table so that the root airfoil having a thickness ratio of 40% has the inflection point. Root air foil of the blade for a wind turbine, characterized in that formed by (y / c).

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