KR20180135147A - Dual type vertical axis wind turbine - Google Patents

Abstract

The present invention relates to a vertical axis wind turbine converting a wind power to a rotational energy, in which one side blade of the vertical axis wind turbine is rotating in a mutually overlapped and engaged manner for reducing a reverse rotational force. According to the present invention, one pair of rotation axes vertically installed with a number of blades in the rotation axis at constant intervals are vertically installed so as to be freely rotatable in a lower portion stand, wherein a blade installed in each rotation axis rotates in a mutually overlapped and engaged direction. The rotational force of the rotation axis rotates a driving axis through a bevel gear, and a generator is driven by the rotational force of the driving axis.

Description

DUAL TYPE VERTICAL AXIS WIND TURBINE

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vertical-axis windmill for converting wind power into rotational energy, in which one blade of a vertical-axis windmill installed opposite to each other is rotated in an overlapping manner.

Unlimited, no-cost clean energy source Wind power generation equipment using wind can be divided into horizontal and vertical power generation depending on the installation state of blades to convert wind into rotational energy. Horizontal power generation using propeller type blade Since the blade for vertical axis power generation is connected to the vertically installed rotary shaft and is rotated while the three blades are installed on one rotary shaft, the blade pushed by the wind force obtains the rotational force for rotating the rotary shaft, The blade rotating in the opposite direction is subjected to a semi-rotational force which interferes with the rotation of the rotation shaft.

That is, as shown in FIG. 1, in a state where three blades 2 are installed at equal intervals on the vertical rotary shaft 1, the blade 2, which rotates in a direction to be pushed by the wind when the wind blows from the front, The blade 2a rotating in the direction reverse to the wind is subjected to the half-rotational force, so that the blade 2 pushed by the wind rotates the rotary shaft 1 by the rotational force of the wind, The rotation of the rotary shaft 1 is interrupted by the half-rotational force.

In vertical power generation like this, when the blade rotates in the wind direction, it obtains the rotational force. When the blade rotates in the opposite direction to the wind, it receives the half-rotational force. Therefore, when both the left and right blades are exposed in the wind direction, It is difficult to increase the efficiency of generating wind power using wind.

Korea Utility Model Registration 20-0382517 (Registered on April 13, 2005) Korean Patent Publication No. 10-2009-0103380 (published on October 10, 2009) Korean Patent Publication No. 10-2010-0065222 (published on June 16, 2010) Korean Patent Publication No. 10-2010-0077361 (published on July 8, 2010)

In the present invention, the blades for wind power generation are rotated by the wind while being coupled to the vertical rotation axis. In this case, the blades rotating in the same direction as the wind will obtain the turning force, but the blades rotating in the direction opposite to the wind In order to solve the problem that it is not easy to increase the efficiency of wind power generation due to receiving the half-rotational force, a pair of rotating shafts provided with three blades in the vertical direction are provided at regular intervals, So that the half-rotation force can be greatly reduced by allowing the blades to receive the half-rotation force in a superimposed state.

The present invention is characterized in that a pair of rotary shafts, each having three blades vertically arranged at regular intervals on an axis of rotation, are vertically rotatably mounted on a lower stand so that the blades installed on the respective rotary shafts are rotated in the direction of overlapping with each other, Is transmitted to the drive shaft through the bevel gear and drives the generator by the rotational force of the drive shaft so that the two blades overlap each other and rotate in the direction of receiving less counter-rotational force to increase the power generation efficiency .

The blades of the present invention form a certain space between the rotating shaft and the wind so that the wind blowing in the direction of the rotating shaft does not help generate the rotating force of the blades but interferes with the blades so that they are discharged through the space between the rotating shaft and the blades Do not act as a rotational force.

In the present invention, in a wind power generation system in which a blade is vertically erected on a rotary shaft, two rotary shafts on which blades are installed are installed close to each other, and the blades are rotated in the direction of overlapping with each other, By reducing the rotational force to increase the power generation efficiency, the overlapped blade lowers the pressure as the rotation is performed, so that the blade receives less anti-rotational force, while the central wind pushes the outer blade to push the outer blade, Thereby increasing the rotational power and increasing the power generation efficiency.

1 is a perspective view of a conventional vertical axis windmill
2 is a front view of the blade of a conventional vertical axis windmill
3 is a perspective view of a vertical axis wind turbine installed state of the present invention
4 is a perspective view of a vertical axis windmill
5 is a front view of a vertical axis wind turbine according to the present invention
Fig. 6 is a plan view showing the rotating state of the vertical axis windmill
7 is a plan view showing the rotation state of the blade of the present invention
Fig. 8 is a front view of a recessed portion showing a vertical axis windmill fixed state of the present invention

The present invention is characterized in that a pair of rotary shafts provided with three blades at equal intervals on a vertically installed rotary shaft are provided adjacently to each other so that the blades are rotated while being overlapped with each other and at the same time, The rotational force is generated by rotating the one drive shaft by using the bevel gear so as to generate power by the rotational force of the drive shaft.

Since the blades located near the rotation axis have the same wind pressure as the blades located at a long distance, the distance traveled by the rotation of the rotation axis is short. Therefore, the energy generated from the blades near the rotation axis is transmitted to the rotary shaft and the blades The present invention provides a space between the rotating shaft and the blade so that the airflow can flow without obstructing the flow of air at a place where energy is little generated. do.

The rotation axis of the present invention is set to be rotated on the lower stand, the blades are fixed to the rotation axis at a predetermined interval, and the distance between the rotation axes is set to be similar to the width of the blades, but the blades installed on the rotation axis are rotated to be overlapped with each other The rotational force of the rotary shaft is transmitted to the drive shaft through the bevel gear, and is transmitted to the generator to generate electric power.

In the present invention, when the wind is blown, the blades installed on the pair of rotary shafts are rotated by the influence of the wind, but the outer blades rotating in the direction of the wind are rotated, and the inner blades rotating in the direction opposite to the wind Since the blades are rotated counterclockwise while the inner blades are rotated in a state of overlapping with each other, one blade that rotates from the inner side is subjected to a half-rotational force, but the rotating blade is forced to receive less anti- The power generation efficiency can be increased.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention is characterized in that the blades 20 and 20a are fixed to the rotary shaft 10a installed vertically in four directions and the rotary shaft 10 and the rotary shaft 10a are fixed to the lower stand 30 by means of thrust bearings 11 The blades 20 and 20a are provided with a square frame by means of a pipe or the like and then the inside of the blades 20 and 20a is covered with a cloth like fabric. The space 25 is formed at a predetermined distance from the rotor 10 and 10a so that the wind can pass through the space 25 between the rotary shaft 10 and the blades 20 and 20a. do.

In the present invention, the two rotary shafts 10 and 10a are installed on one lower stand 30 so that the blades 20 and 20a are spaced apart from each other by overlapping the rotary shafts 10 and 10a. And the rotational force transmitted to the drive shaft 50 is transmitted to the known generator through the pulley 51 and the belt 52. The rotational force transmitted to the drive shaft 50 is transmitted to the drive shaft 50 via the bevel gears 40, To be delivered to wind power generation.

In the present invention, the blades (20) and (20a) installed outward with respect to the pair of rotary shafts (10) and (10a) when the wind is blown in front of the drawing receive the maximum wind force in the unfolded state, The blades 21 and 21a are subjected to wind force only in substantially one blade area so that the blades 20 and 20a are rotated while being pushed backward and the blades 21 and 21a 21a are rotated in the direction opposite to the wind.

The rotary shaft 10a of the present invention connects two rows of wire ropes 60 via bearings 10 and 12a on the upper side and the wire rope 60 is connected to a concrete pole support 70 70a so as to rotate in a stable state when the wind is blown to rotate the rotary shaft 10 (10a).

When the rotary shaft 10a of the present invention is rotated by the blades 20 and 20a the rotational force of the rotary shaft 10a is transmitted to the drive shaft 50 through the bevel gears 40 and 40a The bevel gears 40 and 40a are used to transmit the rotational force of the two rotating shafts 10 and 10 to the one driving shaft 50.

The rotational force of the drive shaft 50 is transmitted through the pulley 51 and the belt 52 to the generator after being accelerated by a booster (not shown), thereby generating wind power.

When the wind is blown in the direction shown in the drawing, the blade 20 (20a) coupled to the outside of the rotating shaft 10 (10a) is rotated while being pushed in the wind direction, and the rotating shaft 10 The blades 21 and 21a located between the blades 20 and 20a are rotated in the direction reverse to the wind so that the blades 21 and 21a are rotated counterclockwise when the blades 20 and 20a obtain rotational force. .

Here, since the two blades 21 and 21a are rotated in a state in which they are overlapped with each other, a half-rotational force is obtained when only the blade 21 rotates in the direction opposite to the wind direction, and the blade 21a, Because the pressure is reduced, the effect of the wind is minimized, and the anti-torque is received at a lower magnitude.

Therefore, even though the half-rotation force received by the blade 21 is similar to the conventional one, the blade 21a rotating along the blade 21 receives less influence of the wind as the rotation progresses and the pressure is lowered, So that the blades 21 and 21a are installed so as to overlap each other as in the present invention as compared with the case where the rotating shafts 10 and 10a are separated from each other, , Thereby improving the power generation efficiency and increasing the rotational force applied to the outer blades 20 (20a).

In the present invention, the blades 20 and 20a are rotated in the direction in which the wind is blown from the outside of the rotating shaft 10 and 10a, and the blades 21 and 21a are rotated with respect to the rotating shaft 10 Since the pressure is lowered by the first rotating blade 21, the second rotating blade 21a is forced to receive a small amount of the semi-rotary force, and the rotating shaft 10 In particular, the blades 21 (21a), which have received the half-rotational force, push the wind outward while rotating in the direction of wind blowing, and as a result, the blade (20) and (20a).

Accordingly, in the present invention, all of the blades 21 and 21a are not subjected to the half-rotational force, only the blade 21 receives the half-rotational force, and the blade 21a rotates following the blade 21, The rotational force of the rotating shaft 10 (10a) is increased.

Since there is little energy between the blades 20 and 20a and the rotary shaft 10 and 10a, the space 25 is formed to allow the wind to flow through the blades 20 and 20a.

The upper part of the rotary shaft 10a is fixed to the concrete pole supports 70a and 70a via the bearings 12 and 12a by the two wire ropes 60 so that the flow of the bearings 12 and 12a And the rotary shaft 10 (10a) can be stably rotated by firm fixing.

In the present invention, the rotational force of the two rotating shafts 10 and 10a is transmitted to one driving shaft 50, and one driving shaft 50 is rotated by the rotational force of the rotating shafts 10 and 10a rotating in different directions The bevel gears 40 and 40a are provided between the rotating shaft 10 and the driving shaft 50 so that the driving shaft 50 is rotated by the rotational force of the rotating shaft 10 The rotational force of the drive shaft 50 is increased by the accelerator not shown through the pulley 51 and the belt 52, and then the generator is driven to generate electric power.

In the present invention, two rotary shafts provided with blades are installed close to each other, and each of the blades is rotated in a direction in which the blades are engaged with each other so as to increase the power generation efficiency by reducing the anti-rotational force by the wind.

10, 10a: rotating shaft 20, 20a, 21, 21a: blade
25: Space 30: Lower Stand
40, 40a: Bevel gear 50: Drive shaft
60: Wire rope 70, 70a: Concrete pole support

Claims (3)

The rotary shaft 10 and the rotary shaft 10a are installed on the lower stand 30 such that the blades 21 and 21a can overlap each other,
The blades 20 and 20a located on the outer side of the rotary shaft 10 and 10a are rotatable in the direction of the wind while the blades 21 are rotated to overlap with each other between the rotary shaft 10 and the rotary shaft 10, (21a) is rotated in the direction reverse to the wind,
The rotational force of the rotary shaft 10a is transmitted from the drive shaft 50 to the generator through the bevel gears 40 and 40a,
Wherein the upper side of the rotary shaft (10) is connected to the wire rope (60) and supported by the concrete pole supports (70a). The blade according to claim 1, wherein the blades (21) provided between the rotating shafts (10) and (10a) are rotated in a direction reverse to the wind while being engaged with each other, 20) 20a is rotated in a wind-pushed direction. 2. The apparatus according to claim 1, wherein a space 25 is formed between the rotary shaft 10a and the blades 20a, 20b, 21a and 21a, and a lower side of the rotary shaft 10 and 10a is connected to the lower stand And the upper side is rotatably coupled to the two wire ropes (60) by bearings (12) and (12a) while being supported by the thrust bearings (11)

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