KR20120128851A - Vertical axis windpower generation of H-rotor - Google Patents

Abstract

PURPOSE: An H-rotor vertical shaft wind power generation is provided to obtain the various output of wind power generation as a plurality of small auxiliary blades is connected to main blades, respectively. CONSTITUTION: An H-rotor vertical shaft wind power generation comprises main blades(11) and auxiliary blades(13). The main blades comprise blade wings(12,14) on both sides around a rotary shaft(15). Airfoil blades are arranged in the blade wings, respectively. The auxiliary blades respectively comprise blades wings on both sides around the rotary shaft. One airfoil blade is arranged in the blade wings. The main blades are longer than the auxiliary blades. The main blades and auxiliary blades are placed around the rotary shaft. The length of the auxiliary blade is the 40~60% of the length of the main blade.

Description

H vertical rotor wind power generation {Vertical axis windpower generation of H-rotor}

The present invention relates to vertical axis wind power generation, and more specifically, to each of the two long blade wings (main wings) arranged in combination of a plurality of small blades instead of a single large blade, In order to recover lost torque in stall area, two small blade blades (auxiliary blades) are installed with small blades. will be.

Wind power is to generate electricity by transmitting rotational force generated by rotating blades or propellers to the generator using wind, and it is divided into horizontal wind power generation and vertical wind power generation according to the direction in which the blades or propellers are installed. Although the generation efficiency is relatively high, the structure of the rotor is complicated because the direction of the rotor must be changed according to the direction of the wind and the device must be connected to the generator by installing a device that converts the horizontal rotational power into the vertical rotational power. The blade is installed along the longitudinal direction of, and the structure is simple because it is composed of a generator that generates electric power by receiving the rotational force of the rotating shaft.

In order to obtain the desired output required by vertical wind power generation, the blade width must be increased or the height, that is, the length of the blade, should be increased. The longer the blade, the more inconvenient the installation work and the longer the blade length, Difficulties in producing non-eccentric rotating shafts and structural weakness of the vertical shaft blades, which cause severe vibrations due to high eccentricity during rotation, damages the structure of the wind turbine and stops power generation. There is a serious problem that causes them to fall or fall, causing further danger and damage.

In addition, the smaller the number of blades, the higher the number of revolutions of the blades, the higher the output of wind power generation.To increase the number of revolutions, the TSR (Tip Speed Ratio) is the ratio of the speed of the blade end divided by the wind speed. In order to have an optimal TSR, the number of blades should basically be small. In wind power generation, a generator consisting of two blades has a TSR of 6, a generator having three blades has a TSR of 5, and a generator having four blades has a TSR of about 3, and the type and design of an airfoil Depending on the 25 ~ 30% will be added.

H-rotor with two blades is the most efficient in vertical wind power generation, but the reason why the three blades are the most produced is that the three blades are structurally stable and according to design, the TSR is 6? It can be increased to 7, and the two blades (H-rotor) have a solid ratio (solidity, circumference at blade rotation / (chord length × blade arm number)}) Because of this, it is difficult to manufacture, and if the two blades are positioned diagonally to the left and right in front of the airflow, the rotational force will not be lost or rotated during rotation. This phenomenon occurs when the blade blade is positioned in the direction of the blade. Because.

A stall is a phenomenon in which the flow of airflow flowing through the surface of the blade is separated from the upper surface of the blade, causing the lift to decrease and the drag force to increase, causing the engine to stop rotating without stopping. It is a phenomenon that can not be maintained, which is caused when the angle of attack of the blade is above a certain limit, or when a strong shock wave is generated on the surface of the blade, the downstream flow drops and the stalling phenomenon occurs. Too little blade rotates at low speed, and the lower the speed, the larger the angle of attack, so there is a high risk of stalling. When stall occurs, not only the wind power efficiency decreases, but also the blade is severely damaged.

The present invention has been made to solve the above problems, and an object of the present invention is to combine a plurality of small blades instead of a single large blade in each of two long blade blades (main wings) The installation enables wind power of various outputs and disperses vibrations generated during blade rotation. It is structurally stable and has two short blade blades (auxiliary wings) to recover lost torque in stall area. In order to provide H-row rotor vertical axis wind power generation by combining two small blades, main blade and auxiliary blade.

H rotor vertical axis wind power generation according to the present invention for solving the above problems, the blade wing (wing) is installed on both sides around the rotation axis, respectively, 2 to 7 airfoil blades (array) are arranged on each blade wing Main wing; Blade blades are respectively provided on both sides of the rotation shaft, and each blade blade includes auxiliary blades in which one airfoil blade is arranged, and the length of the main blade is longer than the length of the auxiliary blade. And the auxiliary wings are arranged in a vertical direction with respect to the rotation axis.

Preferably, the length of the auxiliary wings is 40-60% of the length of the main wings, and each blade arranged on the main wings has an angle between the rotational center axis of the rotation angle blade and the line connecting the leading edge of each blade. Are arranged to be the same.

Preferably, the main wing and the auxiliary wing is installed in pairs on the upper and lower parts of the rotation axis, the lower part of the auxiliary wing is attached to the sculpture symmetrical about the rotation axis.

Preferably, the upper and lower rotary plates are fixedly coupled to the upper and lower rotary plates, respectively, and the upper rotary plate and the lower rotary plate have a flat plate shape by chamfering the same edge, and the lower surface of the lower rotary plate. The recessed insertion groove is formed.

H rotor vertical axis wind power generation according to the present invention having the configuration features as described above, because the H-rotor (H-rotor) having two main wings, the power generation efficiency is good, the size of each of the two long main wings Since a small number of blades instead of a single large blade is combined and installed, not only is it possible to generate wind power of various outputs, but also a plurality of blades are installed to disperse the vibration generated when the blade is rotated, so it is structurally stable. In addition, by installing the auxiliary wing short in the direction perpendicular to the main wing it is possible not only to maintain the rotational force in the stall area, but also to release the main wing from the stall area.

1 is a perspective view showing the H rotor vertical axis wind power generation in accordance with the present invention.
2 is a view for explaining the rotation of the rotor in the H rotor vertical axis wind power generation.
3 is a view showing an example of a blade in which a cap is fastened to both ends of the blade in the longitudinal direction.
4 is a view showing an embodiment in which the sculpture is attached to the H rotor vertical axis wind power generation in accordance with the present invention.
Figure 5 is a view showing a rotation axis of the H rotor vertical axis wind power generation in accordance with the present invention.

According to the present invention, the H rotor vertical axis wind power generation consisting of only the main wings is stopped when two blades are positioned in the stall area in the absence of airflow (that is, the main wings are stopped in the airflow direction and the diagonal direction). In order to prevent the main wing from moving even after the airflow occurs, the H rotor is formed by installing an auxiliary wing having a shorter length than the main wing in the direction perpendicular to the main wing. It is related to the H rotor vertical axis wind power generation that combines the main wing and the auxiliary wing to help prevent, as well as to rotate the main wing.

H-rotor is a name given because the plane shape looks like an alphabet H when the blade blades are arranged on both sides of the rotation axis and the blades are arranged at the ends thereof, as shown in FIG. In the absence of airflow (ie, without wind), the two blades are stopped and positioned in the stall area, so that even if the wind blows thereafter, the main blade 11 no longer moves in the state of losing torque. This phenomenon does not occur during rotation, but this phenomenon occurs when the first air flow flowing in the diagonal direction with the main blade when the rotation is stopped in the absence of air flow occurs. Under the airflow, the drag is slightly pushed down and the auxiliary wing ② is also dragged to move forward or in the direction of the arrow indicated by ③. By repeatedly inducing backwards, the main blade 11 can escape the stall area.

H rotor 10 of the present invention has two main wings 11 and two auxiliary wings 13, the main blades 11 are respectively provided blade blades on both sides around the rotation axis (15) 2 to 7 airfoil blades 12 are arranged on each of the main wings 11. In addition, the auxiliary blades 13 are respectively provided blade blades on both sides around the rotation axis 15, each of the auxiliary blades 13, one airfoil blade shorter than the blade 12 of the main blade (11) (14) is arranged.

The length of the main wing 11 is longer than the length of the auxiliary wing 13, the main wing 11 and the auxiliary wing 13 is disposed in the vertical direction with respect to the axis of rotation (15), the auxiliary wing (13) of The length is preferably about 40 to 60% of the length of the main blade 11, and the length of the blade 12 of the main wing 11 is preferably longer than the length of the blade 14 of the auxiliary wing (13).

Each blade 12 of the main blade 11 is arranged so that the rotation angle is the same, where the rotation angle is the central axis of rotation of the blade (that is, the center of the rotation axis 15) and of each blade 12 Means the angle between the lines connecting the leading edge, the angle of rotation is about 7-10 °, but is set according to the shape of the airfoil and the required torque and rotational speed (rpm). In this case, since there is only one rotation angle, this means that a line that bisects the angle between the segments connecting two blade tips in the central axis of rotation becomes a segment connecting the center of the blade in the central axis of rotation.

If each blade 12 of the main blade 11 is arranged so that the rotation angle is the same, the front end of the blade which collides with the air flow has a plurality of places, so that the vibration generated when the air flow hits the blade end is in one place. It is not concentrated but distributed to a plurality of blade ends, which is structurally stable, and much higher rpm can be obtained at the same wind speed, thereby achieving high power.

The main wing 11 and the auxiliary wing 13 should have a larger area than the portion where the end portion is connected to the rotating shaft 15 portion (see drawing). The shape can be varied, and the main wing 11 When arranging the blades 12), it is preferable that each blade 12 is arranged so as not to overlap each other in the longitudinal direction, or in the case of overlapping, each blade 12 is arranged to overlap within 50% in the longitudinal direction. In addition, the blade tip disposed at the innermost side of the main blade 11 is located at the frontmost side in the rotational direction, and should be arranged so that the blade tips are sequentially located at the rear toward the outside. Otherwise, if the arrangement is reversed, the air flow past the blade located forward in the rotational direction affects the air flow of the blade located next, which affects the rpm and the torque.

In addition, when arranging the blades 12 of the main blades 11 in which a plurality of blades are arranged, the spacing between the rows in which the blades 12 are arranged is the length of the chord length and the blades. It is preferable to set it as about 50 to 70% of the length of the line which connects a rear end. If the spacing between rows is within 50% of the length of the demonstration, the air flow past the blade located in front of the blade affects the air flow of the blade located next, which affects rpm and torque. The effect of stacking overlaps will be reduced.

Most of the blades used in vertical wind power generation are extruded airfoil blades, which have the same shape as both ends are cut horizontally in the longitudinal direction of the blades, so that there is a problem of detachment of air flow at the ends. In order to solve such a problem, it is preferable to insert a cap (12 ') having a round shape of a plastic or die-cast outer circumferential surface at both ends of the blade 12 arranged on the main blade 11 and fasten it with a fastening means such as a bolt. However, the outer circumferential surface of the cap 12 'is shaped like a peak portion slightly moved from the tip to the rear end in the hemispherical shape (see FIG. 3). Here, the blade 14 arranged on the auxiliary wing 13 has a shorter length than the blade 12 arranged on the main blade 11, so there is no difference in effect even if the cap is not fastened.

The main wing 11 and the auxiliary wing 13 should be installed in pairs on the upper and lower parts of the rotary shaft 15. When the wind turbine is installed in the city, the aesthetics are also important, so the lower part of the auxiliary wing 13 The beautifulness of the wind power generator can be added by attaching the sculpture 20 into which the company logo, advertisement, or various designs are inserted by means of etching or coating on a disk-shaped thin plate around the rotating shaft 15 ( See FIG. 4). At this time, even if the sculpture is not in the shape of a disk, any shape may be used as long as it is a sculpture whose shape is symmetrical about the rotation axis 15 (that is, the rotation axis is the center of gravity).

The rotary shaft 15 is coupled to the upper rotary plate 152 and the lower rotary plate 153 to the top and bottom of the shaft 151, respectively, and blade blades (or blades) to the upper rotary plate 152 and the lower rotary plate 153, respectively The part connected to the blade) is fixedly coupled to the fastening means through the fastener 154, wherein the upper rotary plate 152 and the lower rotary plate 153 has a disk shape and is positioned in pairs at the top and the bottom of the blade wings. In order to accurately fit, it is preferable to form the flattened chamfer 155 by D-cutting the same edge portion of the rotating plate. The chamfer 155 may be one or more, but as shown in FIG. 5, it is preferable to form the chamfer 155 in three places, and the chamfer 155 is not only convenient at the time of processing but also H. It is also very useful for centering to prevent eccentricity during rotor rotation.

The generator 16 is coupled to the lower portion of the lower rotating plate 153 of the rotating shaft 15. In order to facilitate coupling between the generator 16 and the lower rotating plate 153, a concave shape is formed on the lower surface of the lower rotating plate 153. It is preferable to form the coupling groove 156 to correspond to the convex portion formed on the top of the generator 16. Reference numeral 157 denotes a center hole.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: H rotor 11: the main wing
12, 14: blade 13: auxiliary wing
15: shaft 151: shaft
152: upper rotating plate 153: lower rotating plate
154: fastener 155: chamfer
156: coupling groove 157: center hole
16: generator
20: sculpture

Claims (6)

Main blades each having blade wings installed on both sides of the rotation axis, and 2-7 airfoil blades arranged on each blade wing;
Auxiliary wings which are respectively provided on the blade blades on both sides around the axis of rotation, one airfoil blade is arranged on each blade blade;
It is configured to include, the length of the main blade is longer than the length of the auxiliary wing, the main blade and the auxiliary wing is characterized in that the vertical axis of the rotor rotor disposed on each other in the vertical direction.
The method of claim 1,
H auxiliary rotor vertical axis wind power generation, characterized in that the length of the auxiliary wing is 40 ~ 60% of the main wing.
The method of claim 1,
Each of the blades arranged on the main wing is a vertical angle of the rotor rotor, characterized in that the angle of rotation between the angle of rotation between the rotation axis of the blade and the line connecting the leading edge of each blade?
The method of claim 1,
The main blade and the auxiliary wing is installed in pairs on the upper and lower parts of the rotary shaft, the lower rotor vertical axis wind power generation, characterized in that the sculpture is attached to the weight symmetrical about the rotation axis.
The method of claim 1,
The rotary shaft, the upper rotary plate and the lower rotary plate is fixedly coupled to the upper and lower, respectively, the upper rotary plate and the lower rotary plate is a flat plate shape by chamfering (D-cutting) the same edge portion, the lower surface of the lower rotary plate H rotor vertical axis wind power generation, characterized in that the concave coupling groove is formed.
The method of claim 1,
H rotor vertical axis wind power generation, characterized in that the cap (cap) of the outer circumferential surface is fastened to both ends of the blades arranged on the main wing.

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