KR101815067B1 - Apparatus for generating by wind power - Google Patents

Abstract

The present invention relates to a wind power generation apparatus generating rotary power from working of strong rotary moment to stably perform power generation even if when the wind speed is low. According to the present invention, the apparatus comprises: a horizontally instead of rotary shaft unit; an eccentric weight module disposed around the rotary shaft part at uniform intervals; a plurality of eccentric weight working chambers with a configuration installing a blade around the eccentric weight module and sectioned inside the eccentric weight module; weight water stored in the eccentric weight working chamber to flow to inner and outer ends of the eccentric weight working chamber; and a configuration collecting the weight water flowing to the outer end of the eccentric weight working chamber in a downward rotational direction of the eccentric weight module and collecting the weight water flowing to the inner end of the eccentric weight working chamber in an upper rotation direction of the opposite side. Accordingly, the rotational power is able to be generated by a weight deviation due to movement of the center of gravity of the eccentric weight module.

Description

[0001] APPARATUS FOR GENERATING BY WIND POWER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wind power generator, and more particularly, to a wind power generator capable of generating stable power by generating a rotational power by a strong rotation moment action even when the wind speed is weak.

Generally, a wind power generator is a device that generates electric power by generating mechanical energy by wind force and then converting it into electric energy. Wind energy due to wind is infinite and clean, so it is recognized as an alternative energy.

As a new alternative energy generation device, the wind power generation device has a sufficient possibility. However, it is difficult to move the blades when the wind speed is variable instantaneously and the wind speed is weak (for example, about 2 to 6 m / sec) There is a problem in that the efficiency of power generation is remarkably low.

To solve such a problem, Korean Patent Registration No. 10-1206701 discloses a wind turbine generator capable of generating wind at low wind speed. Such a wind turbine generator has an airfoil type wind capturer that generates an overlapping area based on the center shaft and generates lift force on a drag blade fixed and arranged in the same rotation direction so that wind drag and lift can be used at the same time, And accelerated the output coefficient so that wind power can be generated even in a small wind.

However, since the conventional wind power generation apparatus including the above-described prior art for generating power even at low wind speed is capable of increasing the rotational power of the blades by focusing the wind mainly by the shape and arrangement of the blades, When the wind speed is changed to 2 / sec or less, the rotation of the blades is rapidly lowered and the power generation efficiency is lowered. In addition, in the case of a strong wind such as a typhoon, the blades are excessively rotated to cause damage or breakdown of the blades, It is.

KR 10-0828234 KR 10-1206701 KR 10-1239077 (Patent Literature 0004) KR 10-2011-0002745

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide an apparatus and a method for controlling weight eccentricity, The center of gravity of the weight eccentricity module is moved in the downward rotational direction of the weight eccentricity module and the gravity water is collected at the inner end of the weight eccentricity module in the opposite upward direction, The present invention provides a wind turbine generator capable of generating stable power by generating a rotary power by a strong rotation moment action due to a weight deviation caused by a weight deviation caused by the weight deviation caused by the weight deviation caused by the weight deviation.

The present invention relates to an apparatus and a method for assembling a weight eccentric module, which comprises a rotating shaft portion horizontally installed, a weight eccentricity module disposed at equal intervals around the rotary shaft portion, and blades disposed around the weight eccentricity module, A plurality of weighted eccentric operation chambers partitioned by the weight eccentric operation chambers and capable of flowing into the inner and outer ends of the weight eccentric operation chambers by being inserted into the weight eccentric operation chambers, And the weight of the water is collected by the inner end of the weight eccentric operation chamber in the direction of the opposite upward rotation, so that the water is collected by the weight deviation due to the movement of the center of gravity of the weight eccentric module And a wind power generation device capable of generating a rotational power.

Wherein the weight eccentric module is arranged such that at least two weight eccentric action chambers are laminated outwardly.

The weight eccentric action chamber is provided with first and second water collecting parts on the inside and outside of the water passage so that the weight water flows through the water passage and the first inside collecting part is deflected toward the backward direction of rotation of the weight eccentric module And the second outer collecting part is formed with a second extending space part which can be deflected toward the forward direction of rotation of the weight eccentricity module.

The first and second water collecting parts are formed by bending the inner and outer sides of the water passage at a predetermined angle. The first and second water collecting parts are formed in a plurality of weight eccentric chambers, And the final inward end of the second pockets is formed adjacent to the weight eccentric action chamber.

And a concave air collecting space is formed around the weight eccentricity module.

The present invention is characterized in that a wind power generating rotating force is generated by a wind that hits against a blade, and is partitioned in the inside of a weight eccentric module which is equidistantly arranged around the rotary shaft part, A means for generating a weight deviation according to the rotational direction of the weight eccentric module by means of the eccentric operation chamber, and a means for generating a rotational power by a strong rotation moment action even when the wind speed is weak and preventing excessive rotation The power generation efficiency can be greatly improved and stable power generation can be achieved.

1 is a perspective view showing a configuration of a wind power generator according to the present invention;
2 is a cross-sectional view showing a configuration of a wind power generator according to the present invention;
3 is a partially cutaway perspective view showing a configuration of a weight eccentricity module in a wind turbine generator according to the present invention.
4 is a cross-sectional view illustrating a configuration of a weight eccentricity module in a wind power generator according to the present invention.
5 is a cross-sectional exemplary view showing an operating state of a wind power generator according to the present invention;
6 is a front view showing a state in which the wind power generator according to the present invention is installed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The wind turbine generator of the present invention comprises a rotary shaft portion 10 horizontally installed to transmit rotational power to a generator and a plurality of weight eccentric operation chambers 30 And the blade 40 is installed around the weight eccentricity module 20, as shown in FIG.

Needless to say, the blade 40 may be integrally installed around the weight eccentricity module 20 or may be attached to various parts of the blade 40 by varying the shape and size of the blade 40.

The weight eccentricity module 20 includes at least two or more weight eccentric action chambers 30 stacked outwardly. In the figure, four weight eccentric action chambers 30 are disposed in a single weight eccentricity module 20 And the plurality of weight eccentric operation chambers 30 in the weight eccentricity module 20 in which the rotational directions are at the same position are configured so that the respective weight numbers 50 flow in the same manner, The module 20 is allowed to perform a strong center-of-gravity movement.

A plurality of weight eccentric operation chambers 30 are provided in the weight eccentricity module 20 and the weight water 50 is introduced into the weight eccentric operation chambers 30 so that the inner ends of the weight eccentric operation chambers 30 So that the weighted water 50 can flow through the outer end.

In the downward rotation direction of the weight eccentricity module 20, the weight water 50 is collected by the outer end of the weight eccentric operation chamber 30 and is collected in the counterclockwise rotation direction, And the weight of the weight 50 is collected and collected at the inner end of the weight eccentricity module 20, so that a rotational power can be generated by a strong rotation moment of the weight eccentricity module due to the weight deviation due to the center of gravity of the weight eccentricity module 20 .

The weight water 50 is made of water or oil and is not frozen even at a low temperature so that the weight water 50 can flow into the weight eccentric operation chamber 30 through a single injection port And the weight water 50 flows through the inner and outer ends of the weight eccentric operation chamber 30 to fill the weight of the weight eccentric action chamber 30. [

The weight eccentricity module 20 has a configuration in which a plurality of weight eccentric action chambers 30 are partitioned and first and second collecting portions 31 and 32 are provided on the inside and outside of the water passage 35 The weight water 50 is deflected toward the rear of the weight eccentricity module 20 in the rotation direction of the weight accumulation module 20 and the water is collected through the water passage 35, And the outer second reservoir portion 32 is provided with a first extended space portion 31a for allowing the weight number 50 to be deflected and collected in front of the rotational direction of the weight eccentricity module 20 Respectively.

The first and second extended space portions 31a and 32a of the first and second collectors 31 and 32 are formed to be deflected rearward or forward with respect to the rotating direction of the weight eccentricity module 20, The weight eccentric action due to the flow of the water in the weight eccentric operation chamber 30 can be performed according to the rotational position of the eccentric module 20. [

The first and second pockets 31 and 32 of the weight eccentric operation chamber 30 provided in the pivoting module 20 are provided in the same volume so that the water collecting capacity due to the flow of the weight 50 is the same So that the center of gravity can be smoothly moved to the inner and outer ends of the water channel 35.

The first and second collectors 31 and 32 are formed by bending the inside and the outside of the water passage 35 at a predetermined angle and are formed in a plurality of weight eccentric operation chambers 30 The final inner end (31-1) of the second puddle part (32) formed in the weight eccentric action chamber (30) formed of a plurality of the second side weight decuding modules (20) So that the interconnecting portions of the respective weight eccentric modules 20 are formed in a stable and connected state without being separated from each other.

In addition, as described above, the air trapping space portion 38 formed concavely on the outer side of the interconnecting portion of the weight eccentricity module 20 is provided so that the air trapping space portion 38 can easily collect the air of the blade 40 .

An embodiment of the wind turbine generator according to the present invention will now be described in detail.

The wind turbine generator according to the present invention includes means for generating a rotational force by a wind which hits a blade 40 provided at regular intervals around a weight eccentricity module 20 which is horizontally rotated around a horizontal rotary shaft portion 10 and rotated in a vertical direction As shown in FIG.

At this time, the wind power generator according to the present invention generates rotational power by a strong rotation moment action even when the wind speed is weak due to the center of gravity moving means provided inside the weight eccentricity module 20, as well as the rotational force by the blade 40 So that stable development can be achieved.

That is, when the power is generated in a state where the blade 40 is installed so that the weight eccentricity module 20 rotates clockwise along the horizontal rotary shaft 10 as illustrated in FIG. 5 of the present invention, In the case of the weight eccentric operation chamber 30 in which the eccentric module 20 is rotated in the downward rotational direction (3 o'clock direction), the weight 28a of the second extended space portion 32a of the outer second accumulating portion 32 In the weight eccentric operation chamber 30 at the position where the weight eccentricity module 20 is rotated in the upward rotational direction (9 o'clock direction) The rotational power can be greatly increased by the movement of the weight eccentricity in which the weight water 50 is collected in the extended space portion 31a.

This is because in the case of the weight eccentric acting chamber 30 located in the downward rotational direction (3 o'clock direction) of the weight eccentricity module 20 with respect to the rotary shaft portion 10, the outer second accumulating portion 32 While the weight of the weight eccentricity module 20 is increased by the amount of the weight of the weight of the water in the weight of the water- The center of gravity of the weight eccentricity module 20 moves in the downward rotational direction (3 o'clock direction) as compared with the upward rotation direction (9 o'clock direction) Due to the deviation, the weight eccentricity module 20 continuously generates a rotational power by applying a strong rotational moment continuously in the downward direction (3 o'clock direction).

As described above, in the wind power generator according to the present invention, the wind power generating the rotational force is generated by the wind that hits against the blade 40, and is partitioned in the interior of the weight eccentricity module 20, The weight eccentric operation chamber 30 having the eccentric action causes a weight deviation in accordance with the rotational direction of the weight eccentricity module 20, so that a strong rotational moment acts to increase the rotational force.

That is, the weight eccentric action chamber 30 located at the downward rotation direction (3 o'clock direction) of the weight eccentricity module 20 with respect to the rotary shaft portion 10 is provided with the second water collection portion 32 The weight is eccentrically operated so that the weight is continuously collected. This makes it possible to generate stable power by generating a rotational power by a strong rotation moment action even when the wind speed is low, On the other hand, when a strong wind such as a typhoon blows, it acts as a weight preventing the weight 50 from being excessively rotated by the weight 50 inside the weight eccentric operation chamber 30 inside the weight eccentricity module 20 .

Thus, according to the present invention, even when the wind speed is weak, a stable power generation can be achieved by means of generating a rotational power by a strong rotation moment action and preventing excessive rotation when strong wind is blown.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: rotary shaft part 20: weight eccentric module
30: Weight eccentric acting chambers 31, 32:
31a, 32a: first and second extension spaces 31-1:
32-1: final inner side
35: water passage 38: air trapping space part
40: Blade 50: Weight

Claims (5)

A weight eccentricity module 20 disposed equidistantly around the rotary shaft portion 10 and a blade 40 around the weight eccentricity module 20, With the installed configuration
A plurality of weight eccentric operation chambers 30 which are divided and partitioned in the weight eccentricity module 20 and a plurality of weight eccentric operation chambers 30 which are inserted into the weight eccentric operation chambers 30 and flow into inner and outer ends of the weight eccentric operation chambers 30, And the weight 50 is collected at the outer end of the weight eccentric operation chamber 30 in the downward rotational direction of the weight eccentricity module 20, In the rotating direction, the weight water 50 is collected and collected at the inner end of the weight eccentric operation chamber 30, so that a rotational power can be generated by the weight deviation due to the movement of the center of gravity of the weight eccentricity module 20 Including, but not limited to,
The weight eccentric operation chamber 30 is provided with first and second collectors 31 and 32 on the inside and the outside of the water passage 35 so that the flow of the weight water 50 through the water passage 35 A first extended space portion 31a is formed to be deflected toward the rear of the weight eccentricity module 20 in the direction of rotation of the inner first accumulator portion 31 and an outer second accumulating portion 32 is formed A second extended space portion 32a is formed for deflecting toward the forward direction of rotation of the weight eccentricity module 20,
The first and second collectors 31 and 32 are formed by bending the inside and the outside of the water passage 35 at a predetermined angle and are formed in a plurality of weight eccentric operation chambers 30 The final inner end (31-1) of the second puddle part (32) formed in the weight eccentric action chamber (30) formed of a plurality of the second side weight decuding modules (20) 32-1) are adjacent to each other.
The method according to claim 1,
Wherein the weight eccentricity module (20) is arranged such that at least two weight eccentric action chambers (30) are laminated outwardly.
delete delete The method according to claim 1,
And a concave air collecting space (38) is formed around the weight eccentricity module (20).

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