JP3181315U - Wind power generator - Google Patents

Abstract

A wind power generator that quickly responds to changes in wind direction is provided.
An impeller 250 is installed between an upper flat plate 253 and a lower flat plate 252 having a central portion fixed to a central shaft 230, and is disposed between the upper flat plate 253 and the lower flat plate 252 and extends radially from the central shaft 230. And a plurality of blades 260. When receiving the wind, the impeller 250 rotates horizontally and rotates the central shaft 230. The cylinder 212 has the upper end of the central shaft 230 inserted in the lower opening. The cylinder 212 is rotatable about the central axis 230 as the center of rotation. The wind direction adjusting unit having the L-shaped wind receiving plate 281 rotates the tube 212 according to the wind direction. The cover 270 includes a semicircular top plate 271 fixed to the lower part of the side surface of the cylinder 212 and a side plate 272 fixed to the outer periphery of the top plate 271. The cover 270 covers half of the outer periphery of the impeller 250 without contacting the impeller 250. The generator 150 generates power when the central shaft 230 rotates.
[Selection] Figure 1

Description

  The present invention relates to a wind turbine generator that operates regardless of wind direction.

Patent Document 1 discloses a wind power generator that operates independently of the wind direction and can quickly respond to changes in the wind direction.
In the wind turbine generator described in Patent Document 1, a horizontal rotating plate is fixed to a rotation driving shaft (center axis) of a generator extending vertically, and a plurality of rotating blades are vertically arranged along the outer periphery of the horizontal rotating plate. It is erected. When the rotating blade receives wind, the rotating blade rotates the horizontal rotating plate while rotating according to the wind direction. When the horizontal rotating plate rotates, the rotation drive shaft rotates and the generator generates electricity.

JP 2006-52669 A

However, the wind power generator described in Patent Document 1 has a complicated mechanism that quickly responds to changes in the wind direction and rotates the rotating blades according to the wind direction.
An object of the present invention is to provide a wind turbine generator having a simple mechanism for quickly responding to a change in wind direction.

In order to solve the above problems, the wind power generator of the present invention is
A central axis extending vertically;
A plurality of blades that are disposed between the upper plate and the lower plate, the center plate of which is fixed to the center axis, and between the upper plate and the lower plate, extend radially from the center axis and are equiangularly spaced An impeller that rotates horizontally when receiving wind and rotates the central axis;
A cylinder having an opening on the lower side, the upper end of the central axis being inserted into the opening, and being rotatable about the central axis as a center of rotation;
A wind direction adjusting unit that rotates the cylinder according to the wind direction;
A cover having a semicircular top plate fixed to the lower part of the side surface of the cylinder and a side plate fixed to the outer periphery of the top plate, and covering a half of the outer periphery of the impeller without contacting the impeller When,
A generator for generating electricity when the central shaft rotates;
It is characterized by providing.

Preferably, the wind power generator of the present invention is
The wind direction adjusting portion includes an L-shaped wind receiving plate attached to the cylinder,
The wind receiving plate rotates the cylinder according to the wind;
It is characterized by that.

Preferably, the wind power generator of the present invention is
The wind direction adjusting unit is
A first gear for rotating the cylinder;
A second gear meshing with the first gear;
A motor for driving the second gear;
When receiving the wind, an anemometer that faces the direction of the wind,
A rotation angle sensor for detecting an angular displacement of the anemometer;
A control unit for controlling the motor according to the angular displacement detected by the rotation angle sensor and rotating the cylinder;
It is characterized by providing.

  According to the present invention, a mechanism for quickly responding to a change in wind direction can be simplified.

It is a front view which shows an example of the structure of the wind power generator which concerns on the 1st Embodiment of this invention. It is a figure which shows an example of the structure of the flame | frame of a wind power generator. FIG. 2 is a cross-sectional view taken along line AA in FIG. 1 and shows an example of a structure of a blade and a cover side surface. It is a BB sectional view of Drawing 1, and shows an example of the relation between a cover and an impeller. It is a figure which shows an example of the angle which the semicircle opening of a top plate and a wind-receiving plate make. It is a top view of a wind power generator and shows an example of a relationship between a wind receiving plate and a cover. It is CC sectional view taken on the line of FIG. 1, and shows an example of the structure of a generator drive part. It is a front view which shows an example of the structure of the wind power generator which concerns on the 2nd Embodiment of this invention. It is the DD sectional view taken on the line of FIG.

  Hereinafter, a wind power generator according to an embodiment of the present invention will be described in detail with reference to the drawings. In all the drawings for explaining the embodiments, common constituent elements are denoted by the same reference numerals, and repeated explanation is omitted.

FIG. 1 is a front view showing an example of the structure of a wind turbine generator 1 according to the first embodiment of the present invention. FIG. 2 shows an example of the frame structure of the wind turbine generator 1.
The frame of the wind turbine generator 1 has a structure in which an annular lower frame member 10, an intermediate frame member 20, and an upper frame member 30 are connected by four rectangular pillars 40 extending vertically. Inside the ring of the lower frame member 10, two parallel square bars 11, 12 and two parallel square bars 13, 14 intersect, and the lower panel 110 and the bearing are in the center where they intersect. 111 is attached. Even inside the ring of the upper frame member 30, the two parallel square bars 31, 32 and the two parallel square bars 33, 34 intersect with each other, and the upper panel 210 and the bearing are in the center where these intersect. 211 is attached. An intermediate panel 120 is fixed between the lower frame member 10 and the intermediate frame member 20 on the two opposing quadrangular columns 40.
The frame of the wind power generator 1 is installed on the ground 400, for example. The grounding portions 41 of the four quadrangular columns 40 are in contact with the ground 400.

As shown in FIG. 1, two generators 150 are arranged between the lower frame member 10 and the middle frame member 20, and an impeller 250 is arranged between the middle frame member 20 and the upper frame member 30. Has been. The two generators 150 are attached to the middle panel 120 fixed to the two quadrangular columns 40.
The impeller 250 rotates horizontally when receiving wind. This rotation is transmitted to the two generators 150, and the generators 150 generate power.

A bearing 211 fixed to the upper frame member 30 holds the cylinder 212 rotatably. The cross section of the tube 212 is circular. The cylinder 212 has an opening on the lower side, and a bearing 213 is provided in the opening.
A central axis 230 extends vertically from the lower panel 110 at the center of the lower frame member 10 to the inside of the tube 212. An upper part and a lower part of the central shaft 230 are rotatably held by a bearing 213 and a bearing 111.
The impeller 250 includes a lower flat plate 252, an upper flat plate 253, and eight blades 260 installed therebetween. Center portions of the lower flat plate 252 and the upper flat plate 253 are fixed to the central shaft 230. As shown in FIG. 3, the blades 260 extend radially from the central axis 230 and are arranged at equiangular intervals. The impeller 250 can rotate with the central shaft 230 as the center of rotation.
The lower flat plate 252 and the upper flat plate 253 are flat plates having a circular or octagonal outer periphery. Further, the number of blades 260 is not limited to eight, and an appropriate number can be installed.

As described above, the cylinder 212 is rotatably held by the bearing 211 fixed to the upper frame member 30, and the upper end portion of the central shaft 230 is inserted into the bearing 213 of the opening portion. For this reason, the cylinder 212 can also rotate around the central axis 230 with the central axis 230 as the center of rotation.
A top plate 271 of the cover 270 is fixed to the lower part of the side surface of the tube 212. The cover 270 includes a top plate 271 and a side plate 272. The top plate 271 has a semicircular shape with a central angle of 180 °, and a side plate 272 is fixed to the outer periphery thereof. The radius of the top plate 271 is larger than the radius of the lower flat plate 252 and the upper flat plate 253. As shown in FIGS. 3 and 4, the side plate 272 and the top plate 271 of the cover 270 cover half of the outer periphery of the impeller 250 without contacting the impeller 250. The cover 270 blocks the wind and prevents half of the impeller 250 from being hit by the wind.

As shown in FIG. 1, a shaft 280 is fixed to the ceiling of the tube 212. An L-shaped wind receiving plate 281 is attached to the shaft 280. As shown in FIG. 5, the angle formed by the semicircular cut opening of the top plate 271 and the wind receiving plate 281 is a.
The wind receiving plate 281 rotates in accordance with the direction of the wind. The tube 212 and the cover 270 also rotate with the wind receiving plate 281. On the other hand, a force for rotating the cover 270 in a direction opposite to the rotation direction of the wind receiving plate 281 by the wind acts. When the wind direction is constant, as shown in FIG. 6, the wind receiving plate 281 and the cover 270 are stationary in a state where the force received by the wind receiving plate 281 and the force rotating the cover 270 are balanced. Therefore, the position of the cover 270 can be controlled by the wind receiving plate 281 according to the direction of the wind.
Serrations or splines are processed at the lower end of the shaft 280 and the upper part of the tube 212, and the angle a can be changed. For example, the angle a may be determined so that the semicircular cut of the top plate 271 is parallel to the wind flow when the wind of the average wind speed is blowing in the place where the wind power generator 1 is installed.
The wind receiving plate 281 is an example of a wind direction adjusting unit that rotates the cover 270 according to the wind direction.

FIG. 7 is a cross-sectional view taken along the line CC of FIG. 1 and shows an example of the structure of the generator drive unit.
Two generators 150 are arranged between the lower frame member 10 and the middle frame member 20. When the central shaft 230 rotates together with the impeller 250, the generator driving unit rotates the rotors of the two generators 150 and causes the generator 150 to generate power.
The generator drive unit includes a sprocket 151, a sprocket 121, and a chain 122. A sprocket 151 is attached to the upper end of the rotor of each generator 150, and a sprocket 121 corresponding to each sprocket 151 is attached to the central shaft 230. Each sprocket 151 and the corresponding sprocket 121 are located on the same horizontal plane and are linked via a chain 122.
1 and 7 show an example in which two generators 150 are arranged. However, the present invention is not limited to this. For example, four generators may be arranged and can be installed. There is no limit to the number of units.

FIG. 8 shows an example of the structure of the wind turbine generator 2 according to the second embodiment of the present invention. 9 is a cross-sectional view taken along the line DD of FIG.
The wind turbine generator 2 is different from the wind turbine generator 1 according to the first embodiment in the configuration of the wind direction adjusting unit. The wind direction adjusting unit of the wind turbine generator 2 includes a first gear 290, a motor 291, a second gear 292, an anemometer 293, a rotation angle sensor 294, and a controller 295.
The first gear 290 is attached to the shaft 280 of the ceiling of the tube 212 and rotates the tube 212 around the shaft 280 as the center of rotation.
The motor 291, the anemometer 293, the rotation angle sensor 294, and the controller 295 are fixed to the upper frame member 30. The first gear 290 meshes with the second gear 292 driven by the motor 291.
The controller 295 includes a control panel 296 and a battery 297. Part of the electric power generated by the two generators 150 is supplied to the controller 295 and stored in the battery 297. The battery 297 is used as a power source for the motor 291, the rotation angle sensor 294, and the control panel 296.
The rotation angle sensor 294 and the cover 270 are initially set to an optimum state for the impeller 250 to efficiently rotate. When the wind vane 293 receives wind, the wind vane 293 turns to the wind direction. The rotation angle sensor 294 detects the movement (angular displacement) of the anemometer 293. The control panel 296 controls the motor 291 according to the angular displacement detected by the rotation angle sensor 294, rotates the cylinder 212 together with the first gear 290, and rotates the cover 270 to a position where the impeller 250 rotates efficiently. Let

  As described above, according to the present invention, a mechanism for quickly responding to a change in wind direction can be simplified.

DESCRIPTION OF SYMBOLS 1, 2 ... Wind power generator, 10 ... Lower frame member, 11, 12, 13, 14 ... Square rod inside ring of lower frame member, 20 ... Middle frame member, 30 ... Upper frame member, 31, 32, 33 34 ... Square rod inside ring of upper frame member, 40 ... Square pillar, 41 ... Grounding part, 110 ... Lower panel, 111 ... Bearing, 120 ... Middle panel, 121 ... Sprocket, 122 ... Chain, 150 ... Generator 151 ... Sprocket, 210 ... Upper panel, 211 ... Bearing, 212 ... Cylinder, 213 ... Bearing, 230 ... Center shaft, 250 ... Impeller, 252 ... Lower flat plate, 253 ... Upper flat plate, 260 ... Vane, 270 ... Cover, 271: Top plate, 272 ... Side plate, 280 ... Shaft, 281 ... Wind receiving plate, 290 ... First gear, 291 ... Motor, 292 ... Second gear, 293 ... Anemometer, 294 ... Rotation angle sensor, 2 5 ... controller, 296 ... control panel, 297 ... battery, 400 ... ground

Claims (3)

A central axis extending vertically;
A plurality of blades that are disposed between the upper plate and the lower plate, the center plate of which is fixed to the center axis, and between the upper plate and the lower plate, extend radially from the center axis and are equiangularly spaced An impeller that rotates horizontally when receiving wind and rotates the central axis;
A cylinder having an opening on the lower side, the upper end of the central axis being inserted into the opening, and being rotatable about the central axis as a center of rotation;
A wind direction adjusting unit that rotates the cylinder according to the wind direction;
A cover having a semicircular top plate fixed to the lower part of the side surface of the cylinder and a side plate fixed to the outer periphery of the top plate, and covering a half of the outer periphery of the impeller without contacting the impeller When,
A generator for generating electricity when the central shaft rotates;
A wind turbine generator comprising: The wind direction adjusting portion includes an L-shaped wind receiving plate attached to the cylinder,
The wind receiving plate rotates the cylinder according to the wind;
The wind power generator according to claim 1. The wind direction adjusting unit is
A first gear for rotating the cylinder;
A second gear meshing with the first gear;
A motor for driving the second gear;
When receiving the wind, an anemometer that faces the direction of the wind,
A rotation angle sensor for detecting an angular displacement of the anemometer;
A control unit for controlling the motor according to the angular displacement detected by the rotation angle sensor and rotating the cylinder;
The wind power generator according to claim 1, comprising:

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