JP5561837B2 - Rotational force propulsion device for wind turbine for wind power generation - Google Patents

Description

The present invention relates to a wind turbine for wind power generation, and more particularly to a rotational force propulsion device for a wind turbine for vertical axis wind power generation.

  Conventionally, various proposals have been made regarding the structure of wind turbines for wind power generation, in particular, vertical axis wind turbines for wind power generation.

  Among such a wide variety of proposals, there is a conventional vertical axis type wind turbine for wind power generation using so-called straight blades.

  However, in the wind turbine using this straight blade, the wind from the blade tip is missed, and so-called blade tip stall is caused.

  Therefore, in order to eliminate the blade tip stall, there has been proposed a blade in which the upper and lower blade tips are curved inward, that is, toward the rotating shaft member.

  With this wing, wind can be collected relatively efficiently, and the wind turbine can be swept backwards, so that the rotational speed of the windmill can be significantly increased as compared with the prior art.

  Next, in the conventional vertical axis type windmill, generally, 4 to 5 blades and a plurality of blades are used, and the blade width is relatively narrow, and the length of the blade in the longitudinal direction is elongated. Wing windmills were common in the past.

  However, if the number of blades is two or more, the air resistance increases with the acceleration of the rotational force, and conversely, the number of rotations of the windmill does not increase.

  Further, when the number of blades is two or more, there is a problem that the torque that each blade gives to the rotating shaft of the rotating shaft member is small, so that it is likely to stall when a load of the wind power generator is applied.

  Therefore, in recent vertical axis type wind turbines, the number of blades should be reduced as much as possible, and if possible, it should be a pair, that is, two blades. Proposals have been made to draw lift by spreading.

  As a result, the torque is increased, the rotation speed can be increased to the optimum, and the wind power can be extracted to the maximum. There was also an effect that wind noise could be reduced due to the long blade length.

  The wind turbine starts rotating at a wind speed of about 1.5 m / s and generates power when the wind speed exceeds 2.5 m / s, although it varies depending on the structure of the wind power generator, the size of the blades, the number of stages, and the like.

JP 2004-108330 A

  However, in the conventional wind power generator, that is, the vertical axis type wind turbine for wind power generation, for example, it is difficult to start the rotation of the wind turbine with a slight wind of about 0.3 m / s. If there is no wind of more than s, sufficient windmill rotation cannot be obtained.

  Therefore, for example, there is a problem in the installation condition that the vertical axis wind turbine for wind power generation cannot be adopted mainly in a place where wind is weak, such as in the city center.

Thus, the present invention was devised by adding further thought and improvement to the various proposals that have been made so far, and in a vertical axis wind turbine, for example, a wind speed of about 0.3 m / s. Even if it is, it aims at providing the rotational force propulsion apparatus of the windmill for vertical axis | shafts which can fully start a windmill rotation. In other words, it is possible to start the rotation of the blades even with a light wind of around 0.3 m / s, and a sufficient rotational moment can be obtained, and the windmill can be rotated with high power generation efficiency in a wider range of wind speed than before. And it aims at providing the rotational force propulsion apparatus of the windmill for wind power generation which can also endure a strong wind.

The rotational force propulsion device for a wind turbine for wind power generation according to the present invention is:
A vertical shaft type windmill having a rotating shaft member installed vertically, a supporting member having one end connected to the rotating shaft member, and a blade attached to the other end of the supporting member. ,
A pair of the wings are provided so as to be arranged at symmetrical positions with the rotary shaft member as a symmetrical axis,
The support member protrudes in a horizontal direction from the rotary shaft member, and rises at the same gradient as the first support member for connecting the pair of blades arranged in the vertical direction and the rotary shaft member, respectively. Or a second support member that protrudes downward and connects the pair of blades and the rotary shaft member,
The first support member and the second support member are formed in a general fish shape excluding the tail fin portion so that the longitudinal cross-sectional shape does not receive wind resistance in the traveling direction, and from the tail portion. Has a rotational force promoting member in the form of a substantially square sheet,
When the wind turbine in the non-winding state does not rotate, the attached rotational force promoting member hangs down due to its own weight and increases the area to receive wind, and after the wind turbine starts rotating, it is horizontally shelved from the tail. The structure that reduces the area that receives wind,
It is characterized by
Or
The rotational force promoting members are attached to the pair of first support members,
It is characterized by
Or
The rotational force promoting member is attached to the pair of first support member and second support member,
It is characterized by
Or
The size and shape of the rotational force promoting member can be changed to a size and shape capable of propelling the rotational force of the wind turbine in consideration of the wind condition at the installation location of the wind turbine for wind power generation.
It is characterized by
Or
The installation position of the rotational force promoting member can be changed to an installation position that can promote the rotational force of the windmill in consideration of the wind condition at the installation location of the wind turbine for wind power generation, suitable for the wind condition,
It is characterized by
Or
The sheet-like rotational force promoting member is formed in a structure in which the area that receives wind is large in a windless or low wind speed state, and after windmill rotation, the area that receives wind is small.
It is characterized by this.

If it is the rotational force propulsion device of the wind turbine for wind power generation according to the present invention,
For example, even if the wind speed is around 0.3 m / s in a weak wind place such as in the city center, the windmill rotation can be sufficiently started, and the windmill can be rotated efficiently in a wider range of wind speed than before. Therefore, it has an excellent effect of having good power generation efficiency and withstanding strong winds.

It is explanatory drawing which shows the external appearance of the rotational force propulsion apparatus of the windmill for wind power generation concerning this invention. It is explanatory drawing (1) explaining operation | movement of the rotational force propulsion apparatus of the windmill for wind power generation. It is explanatory drawing (2) explaining operation | movement of the rotational force propulsion apparatus of the windmill for wind power generation. It is explanatory drawing (3) explaining operation | movement of the rotational force propulsion apparatus of the windmill for wind power generation.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the wind power generator for a wind turbine according to the present invention includes a rotating shaft member 1 erected vertically, and a first support member 2 a having one end connected to the rotating shaft member 1, It is used for a vertical axis type wind turbine 4 having a second support member 2b and a blade 3 attached to the other end of the first support member 2a and the second support member 2b.

A pair of blades 3, 3 attached to the vertical axis wind turbine 4 are provided so as to be arranged at symmetrical positions with the rotary shaft member 1 as a symmetrical axis.

  Here, it is said that the length of the blade 3 in the longitudinal direction, that is, the blade length is generally appropriate to a length substantially equal to the rotation radius. For example, if the rotation radius is 3 meters, a plurality of blades 3, it is appropriate that the total length in the longitudinal direction is 3 meters.

  Therefore, if the wings 3 are a pair, that is, two wings 3, the length of one wing 3 in the longitudinal direction is 1.5 meters.

  The wings 3... May be a pair, that is, not two but two or more, such as four or five. In the case where the length in the direction is 0.75 m and five, it is appropriate that the length in the longitudinal direction of each wing 3 is configured to be 0.6 m.

  Next, the first support member 2a protrudes in the horizontal direction from the rotary shaft member 1, is arranged in the vertical direction, and has a pair of blades 3 with the tip side inner side surfaces 5 and 5 facing the rotary shaft portion 1 side. The blades 3 and 3 and the rotary shaft member 1 are connected to each other.

  The second support members 2b and 2b protrude upward or downward at the same gradient from the connection portion where the rotary shaft member 1 and the first support member 2a are connected, and rotate with the pair of blades 3 and 3 The shaft member 1 is connected to each other.

  Here, the angle of the gradient is not limited in any way, but as can be understood from FIG. 1, an upward gradient angle and a downward gradient angle of about 45 degrees are preferable.

  The first support member 2a and the second support member 2b have cross-sectional shapes such as the shape of a fish excluding the tail fin portion in the traveling direction, as can be understood from FIG. It is preferable that the shape is such that it does not receive the resistance of the wind 8 as much as possible in the traveling direction.

  And the rotational force acceleration | stimulation member 6 which makes | forms the substantially square sheet shape comprised so that shelves may be pulled back from the tail part 7 used as the rear-end part of the width direction of the supporting member 2 is attached.

  Here, the configuration of the rotational force promoting member 6 is not limited in any way, and the wind turbine rotates with a structure in which the area for receiving the wind 8 is large in a no wind or low wind speed state (a state where the wind 8 is not blowing too much). It is preferable to form the structure in which the area for receiving the wind 8 is reduced after the discharge.

  For example, as shown in FIG. 1, when there is no wind, it is in a state where it hangs down due to its own weight, so that the area receiving the wind 8 is increased, and the windmill starts to rotate. After that, it is possible to construct a structure in which the tails 7 are horizontally laid from the tail part 7 to the rear side so that the area receiving the wind 8 is reduced and the resistance of the wind 8 is reduced.

  Here, depending on the material of the rotational force promoting member 6, when the wind does not hang down in the no wind state, that is, when the wind is not in the wind area, the area receiving the wind 8 does not increase, or the low wind speed, In the case where the shelves are pulled immediately even in a light wind state and the area receiving the wind 8 does not increase, a small weight is attached to the lower end portion side of the rotational force promoting member 6, so that no wind or low wind speed state (not so much wind) It is conceivable to form a structure in which the area that receives the wind 8 becomes large in a state where the wind 8 is not blown, and a structure in which the area that receives the wind 8 becomes small after the windmill starts rotating.

  Although it is about the material of the rotational force acceleration | stimulation member 6, this is not limited at all, What is necessary is just the material which can be comprised in a sheet form. However, durability is also required to some extent, and when it is configured in a sheet shape, for example, it may be configured with a resin member. If it is a resin-made member, there is no possibility of being damaged even in rainy weather, and there is no possibility of being relatively torn even by a strong wind.

  Furthermore, what is necessary is just to comprise in a sheet form and it is not limited about the magnitude | size and shape of the sheet form.

These sheet-like size and shape is made shall be determined in accordance with the actual wind conditions in the region to be installed.

  The attachment of the rotational force promoting member 6 according to the present invention will be described with reference to FIG. 1. First, in the pair of first support members 2a and 2a, the first support members 2a and 2a are in a state of being brought closer to the distal end side to form rectangular shapes. The sheet-like rotational force promoting members 6 and 6 are attached. If the wind condition is relatively good, the first support members 2a, 2a may be mounted close to the base end side, but if the wind condition is not good and you want to start rotation even in a light wind condition, The first support members 2a and 2a are attached relatively close to the tip end side.

  As an example of this attachment method, the front end surface of the sheet-like rotational force promoting member 6 is connected to the tail portion 7 which becomes the rear end portion in the width direction of the first support member 2a. 4, for example, when the first support member 2 a is divided into two parts in the horizontal direction and joined, the front end surface of the rotational force promoting member 6 having the sheet shape is sandwiched. It is conceivable to install with.

  Further, when the first support member 2a is not divided into two parts, it is conceivable to use an adhesive and attach and attach the distal end surface of the rotational force promoting member 6 to the outer peripheral surface in the vicinity of the tail portion 7. It is done.

  Incidentally, each of the second support members 2b... Is attached with a rotational force promoting member 6.

  Therefore, the attachment method is the same as that attached to the first support member 2a.

  In the present embodiment, a total of six rotational force promoting members 6 are attached.

  Note that the number and size of the rotational force promoting members 6 to be attached and the attachment position with respect to the support member 2 are not limited at all. What is necessary is just to determine in consideration of the wind condition of the area where the vertical axis type windmill 4 is attached.

  In addition, regarding the attachment method of the rotational force promotion member 6, the structure which can be continuously adjusted to the longitudinal direction position of the 1st support member 2a or the 2nd support member 2b about the attachment position can also be employ | adopted. With such a configuration, it is possible to start rotation of the vertical axis wind turbine 4 in accordance with the wind conditions at the installation location.

  In the above, when the rotation of the vertical axis wind turbine 4 according to the present invention is started, as described above, the rotation is usually started from the wind speed of about 1.5 m / s. However, in this embodiment, for example, the wind speed is 0 Even if the wind is around 3 m / s, the windmill rotation can be fully started.

  That is, even with a slight wind speed of about 0.3 m / s, the rotational force promoting member 6 can start the rotation of the blades 3.

  It is also conceivable to attach the rotational force promoting members 6 and 6 to both tip portions of the pair of blades 3 and 3.

  If comprised in this way, the vertical-axis type windmill 4 will receive the ascending current of the wind 8 in the rotational force promotion member 6, and the vertical-axis type windmill 4 can be rotated lightly only with the ascending current 8 of the wind. . In addition, during rainy weather, rain resistance is received by the rotational force promoting members 6 and 6 attached to both ends of the pair of wings 3 and 3, mainly the lower rotational force promoting member 6. 4 can be rotated lightly.

  Therefore, it is possible to rotate the windmill with high power generation efficiency in a wide range of wind speeds including a wind speed range of light wind than usual.

As a result, the power generation efficiency is good, the structure can withstand strong winds, and has sufficient durability.

DESCRIPTION OF SYMBOLS 1 Rotation shaft member 2a 1st support member 2b 2nd support member 3 Wing | blade 4 Vertical axis type windmill 5 Inner side surface of wing | blade 6 Rotational force acceleration | stimulation member 7 Tail 8 Wind

Claims (5)

A vertical shaft type windmill having a rotating shaft member installed vertically, a supporting member having one end connected to the rotating shaft member, and a blade attached to the other end of the supporting member. ,
A pair of the wings are provided so as to be arranged at symmetrical positions with the rotary shaft member as a symmetrical axis,
The support member protrudes in a horizontal direction from the rotary shaft member, and rises at the same gradient as the first support member for connecting the pair of blades arranged in the vertical direction and the rotary shaft member, respectively. Or a second support member that protrudes downward and connects the pair of blades and the rotary shaft member,
The first support member and the second support member are formed in a general fish shape excluding the tail fin portion so that the longitudinal cross-sectional shape does not receive wind resistance in the traveling direction, and from the tail portion. Has a rotational force promoting member in the form of a substantially square sheet,
When the wind turbine in the non-winding state does not rotate, the attached rotational force promoting member hangs down due to its own weight and increases the area to receive wind, and after the wind turbine starts rotating, it is horizontally shelved from the tail. The structure that reduces the area that receives wind,
A rotational power propulsion device for a wind turbine for wind power generation.
The rotational force promoting members are attached to the pair of first support members,
The rotational force propulsion device for a wind turbine for wind power generation according to claim 1.
The rotational force promoting member is attached to the pair of first support member and second support member,
The rotational force propulsion device for a wind turbine for wind power generation according to claim 1.
The size and shape of the rotational force promoting member can be changed to a size and shape capable of propelling the rotational force of the wind turbine in consideration of the wind condition at the installation location of the wind turbine for wind power generation.
The wind power generation wind turbine propulsion device according to claim 1, 2, or 3, characterized by the above.
The installation position of the rotational force promoting member can be changed to an installation position that can promote the rotational force of the windmill in consideration of the wind condition at the installation location of the wind turbine for wind power generation, suitable for the wind condition,
The wind power generator wind power propulsion device according to claim 1, 2, 3, or 4.

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