JP4668673B2 - Wind rotating device - Google Patents

Description

The present invention relates to a rotating device using wind power, and more particularly to a wind power rotating device that can be connected to a generator to be a wind power generator, or can be connected to a stirrer to be a wind power agitating device. Is.

A wind power generator is known as a typical example of what uses wind power generated in nature.

The wind turbine generator is configured to generate power by driving a generator using a wind turbine as a wind turbine rotating with wind power, and various types of wind turbines have been proposed. ing.

Among them, as compared with the propeller-type windmill, it is small and has excellent rotational efficiency.
Cross-flow type windmills have been proposed.

FIGS. 7 (a) and 7 (b) show an example of a cross-flow type wind turbine. A plurality of blades 5 extending in the vertical direction are arranged at a required interval in the circumferential direction, and the upper and lower ends of each blade 5 are vertically rotated. The rotating part 1 is formed by attaching and fixing to a pair of upper and lower rotating plates 3 and 4 having a central part fixed to both upper and lower ends of the shaft 2. Further, a plurality of guide vanes 9 extending in the vertical direction are arranged outside the rotating portion 1 at a predetermined interval in the circumferential direction, and the upper and lower ends of each guide vane 9 are arranged at the peripheral portions of the pair of upper and lower fixed plates 7 and 8. It is set as the structure provided with the fixing | fixed part 6 attached and fixed to. As a result, when wind from a certain direction is guided to the rotating unit 1 by the guide vane 9, the wind hits the blades 5 of the rotating unit 1, and further in the space portion closed by the upper and lower rotating plates 3 and 4. The rotating unit 1 is rotated by flowing along the blades 5 (see, for example, Patent Document 1).

According to the cross flow type wind turbine shown in FIGS. 7A and 7B, the wind guided by the guide vanes 9 of the fixed portion 6 hits the blades 5 of the inner rotating portion 1 and further flows along the blades 5. Rotating part 1
Since the rotation speed of the rotary unit 1 can be increased, the outer side is a fixed guide vane 9, so that when the wind speed is constant, the wind taken into the rotary unit 1 is guided by the guide vane 9. Therefore, the rotational speed of the rotating unit 1 is limited, and a high rotational speed cannot be expected. Therefore, even when a generator is connected to the vertical rotating shaft 2 of the rotating unit 1 and this wind turbine is used as a drive source of the generator, a high power value cannot be expected.

Conventionally, a wind turbine used for wind power generation or the like that can increase the number of rotations of the rotating shaft has been proposed.

FIGS. 8A and 8B show an example thereof, which is a wind turbine composed of an inner turbine rotor 10 and an outer turbine rotor 11. That is, the inner turbine rotor 10 fixes a plurality of turbine blades 12 extending in the vertical direction between a pair of rotating plates 3 and 4 whose central portions are fixed to the upper end portion and the lower end portion of the vertical rotating shaft 2. The vertical rotary shaft 2 rotates integrally with each turbine blade 12 and the upper and lower rotary plates 3 and 4. Outer turbine rotor 11
Is rotated by the receiving members 13 and 14 provided at the upper end and the lower end of the vertical rotating shaft 2 of the inner turbine rotor 10 and outside the rotating plates 3 and 4 of the inner turbine rotor 10. Center portions of the rotating plates 15 and 16 having a diameter larger than those of the plates 3 and 4 are rotatably mounted via bearings 17, and a plurality of sheets extending in the vertical direction are provided around the upper and lower rotating plates 15 and 16. The turbine blade 18 is fixed so that the turbine blade 18 and the rotating plates 15 and 16 can freely rotate around the vertical rotating shaft 2. Further, each turbine blade 12 of the inner turbine rotor 10 and each turbine blade 18 of the outer turbine rotor 11 are both formed so that the cross section of the blade surface is curved from the outside to the inside. .

The wind turbine configured in this way is configured such that when the wind hits the turbine blade 18 of the outer turbine rotor 11 from one side, the outer turbine rotor 11 rotates freely around the vertical rotation shaft 2. Is passed through the outer turbine rotor 11 and hits the turbine blade 12 of the inner turbine rotor 10 to the opposite side so that the inner turbine rotor 10 rotates and the vertical rotating shaft 2 can be rotated (for example, patents). Reference 2).

JP 2003-120501 A JP 2000-337244 A

In Patent Document 2, the rotational speed when the inner turbine rotor 10 in which the rotating plates 3 and 4 with the turbine blades 12 are fixed to the vertical rotating shaft 2 is rotated independently, and the turbine blade 18 on the vertical rotating shaft 2 is disclosed. The rotational speed when the outer turbine rotor 11 having the attached rotating plates 15 and 16 rotatably attached via the bearing 17 is rotated alone, and the inner turbine when the inner turbine rotor 10 and the outer turbine rotor 11 are combined. The rotational speed of the rotor 10 and the rotational speed of the outer turbine rotor 11 are described, and the outer turbine rotor 11 that freely rotates is combined with the inner turbine rotor 10 as compared with the rotational speed of the inner turbine rotor 10 alone. It is described that the rotational speed of the inner turbine rotor 10 increases.

Incidentally, the present inventor made a double structure by creating an inner windmill portion that is fixed to the vertical rotation shaft and rotates the vertical rotation shaft, and an outer windmill portion that can freely rotate around the vertical rotation shaft. When the number of blades in the inner wind turbine section and the number of blades in the outer wind turbine section are the same, and when the number of blades in the inner wind turbine section and the number of blades in the outer wind turbine section are different, While changing the wind speed with no load on the shaft, rotating alone as the inner wind turbine part, rotating alone as the outer wind turbine part, or rotating with the inner wind turbine part and outer wind turbine part combined The same results as those described in Patent Document 2 have also been confirmed from the results of the experiments performed. That is, when the number of blades of the inner wind turbine unit and the outer wind turbine unit is the same, and when the number of blades of the outer wind turbine unit is smaller than the number of blades of the inner wind turbine unit, the inner wind turbine unit rotates independently. It has been confirmed that the rotational speed of the inner wind turbine portion when the outer wind turbine portion is combined is increased as compared with the rotational speed at that time.

The cause is considered to be that the rotation speed of the inner windmill portion is increased by the wind taken in from the outer windmill portion and the rotational speed is increased.

However, the present inventor conducted further experiments, and in the configuration in which the inner wind turbine unit and the outer wind turbine unit were combined, a load such as a generator was attached to the vertical rotating shaft rotated by the inner wind turbine unit, and the wind speed was 10 to 12 m. An experiment was carried out to operate under / sec. As a result, the number of rotations of the inner wind turbine part to which the load is applied is greatly reduced from the number of rotations at the time of no load, and conversely, when the load is applied, the number of rotations of the inner wind turbine part is lower than that of the outer wind turbine part. was gotten.

Patent Document 2 does not describe the rotational speed of the inner turbine rotor when a load is attached to the vertical rotating shaft and the inner turbine rotor and the outer turbine rotor are rotated.

Accordingly, the present invention provides a cross-flow type windmill disposed inside and outside, and the inside windmill portion is fixed to the vertical rotation shaft so that it can rotate integrally with the vertical rotation shaft. It is intended to increase the number of rotations of the inner windmill portion that falls when a load is applied to the shaft.

In order to solve the above-mentioned problems, the present invention is configured such that a plurality of blades extending in the vertical direction are arranged at a required interval in the circumferential direction between a pair of upper and lower rotary plates and can rotate integrally with a vertical rotation shaft. A plurality of blades extending in the vertical direction are arranged at a required interval in the circumferential direction between a certain inner rotating portion and a pair of upper and lower rotating plates arranged on the outer sides of the upper rotating plate and the lower rotating plate of the inner rotating portion. In the state where the outer rotating portion is provided and the rotational speed of the inner rotating portion is higher than the outer rotating portion between the outer peripheral portion of the vertical rotating shaft of the inner rotating portion and the outer rotating portion, the inner rotation is performed. And the outer rotating part are rotated without interfering with each other, and the rotational speed of the inner rotating part is lowered and the rotational speed of the outer rotating part is higher than the rotational speed of the inner rotating part. The rotational force of the outer rotating part is A clutch to its partner vertical rotation axis of the rotating portion is interposed, in a state where the rotational speed of the inner rotating portion is lower than the rotational speed of the outer rotating portion when the inner rotating portion of the rotation force of the outer rotating portion by the clutch It has the structure which can be urged | biased by rotation of this.

Furthermore, in the above-described configuration, the blades of the inner rotating part and the outer rotating part have a blade shape in cross section, and the mounting angle to the rotating plate is 20 with respect to the radially extending line.
-30 degrees or a pair of upper and lower rotating plates of the outer rotating portion is used as a rotating plate having a taper in the peripheral portion.

According to the wind power rotating apparatus of the present invention, the following excellent effects can be obtained.
(1) An inner rotating portion in which a plurality of blades extending in the vertical direction are disposed at a required interval in the circumferential direction between a pair of upper and lower rotating plates and can rotate integrally with a vertical rotating shaft, and the inner rotation A plurality of blades extending in the vertical direction between a pair of upper and lower rotary plates disposed on the outer sides of the upper rotary plate and the lower rotary plate, and having an outer rotary unit arranged at a predetermined interval in the circumferential direction, and the inner side The inner rotating portion and the outer rotating portion interfere with each other in a state where the rotational speed of the inner rotating portion is higher than the rotating speed of the outer rotating portion between the outer peripheral surface of the vertical rotating shaft of the rotating portion and the outer rotating portion. If the rotational speed of the inner rotating part is reduced and the rotational speed of the outer rotating part is higher than the rotating speed of the inner rotating part, the rotational force of the outer rotating part is reduced. Transmitted to the vertical rotation axis of the inner rotating part. As is interposed clutch to, and so the rotational force of the outer rotating part can urging the rotation of the inner rotary part by the inner rotating portion rpm when is in a state of lowered than the rotational speed of the outer rotating part said clutch because it is assumed to have a configuration, by connecting a generator and an agitator in a vertical axis of rotation, when driving them by the wind, down the rotational speed of the vertical rotary shaft and the inner rotating part of the integral inner rotation When the rotational speed of the outer rotating part becomes higher than the rotational speed of the part, a clutch is interposed to allow the rotational force of the outer rotating part to be transmitted to the vertical rotating shaft of the inner rotating part, and the rotational speed of the inner rotating part Is lower than the rotational speed of the outer rotating part, the clutch can bias the rotational force of the outer rotating part to the rotation of the inner rotating part, and the rotational speed of the lowered inner rotating part can be increased. , Power generation It is possible to increase the output to and agitator.
(2) In particular, between the outer peripheral surface and the outer rotating part of the vertical shaft of the inner rotating section, the rotation of the outer rotating portion when the rotation speed of the outer rotating portion than the rotational speed of the inner rotary part is in a high state by force is a structure in which a clutch is interposed to so that is transmitted to the vertical shaft of the inner rotating section, to impart a rotational torque to the inner rotating part via a vertical shaft by an outer rotating part with a simple structure be able to.
(3) In addition, the blade of the inner rotating part and the blade of the outer rotating part have a blade shape in cross section, and the mounting angle to the rotating plate is 20 to 30 degrees with respect to the radially extending line. As a result, on the side where the wind acts, the wind can be collected and taken in by the collect effect, and on the side where the wind on the other side escapes, it can be spread and flowed by the diffuser effect, and efficiently The rotating part can be rotated, and furthermore, lift is generated at each blade by the mounting angle, and the overall rotational force can be increased by the generated lift. (4) By making the pair of upper and lower rotating plates of the outer rotating part have a taper in the peripheral part, it is possible to smoothly take in the wind to the outer rotating part, and more air flows Can be generated.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

1 to 4 show an embodiment of the present invention, and a fixed frame 20 having a planar shape in a triangular shape as shown by a broken line in FIG. 2 at the upper and lower ends of a rotating shaft 19 arranged in a vertical direction.
And the upper fixing frame 20 is attached to a cap-shaped bearing case 22, and the bearing case 22 is attached to the outer surface of the vertical rotating shaft 19 via a bearing 23. It is attached so that the fixed frame 20 and the vertical rotation shaft 19 can rotate relative to each other. On the other hand, the lower fixed frame 21 is attached to the lower bearing case 24, and the bearing case 24 is attached to the vertical rotating shaft 19 via the bearing 23 so that the lower fixed frame 21 and the vertical rotating shaft 19 can rotate relatively. The upper bearing 23 is configured to press the inner race 23 a from above by a presser plate 25 fixed to the upper end surface of the vertical rotating shaft 19, and the lower bearing 23 is expanded in diameter to the outer peripheral portion of the vertical rotating shaft 19. The inner race 23 a is received by the receiving portion 26 provided in this manner, and the outer race 23 b is received from below by the bearing cap 27 attached to the bearing case 24.

The upper fixed frame 20 and the lower fixed frame 21 attached to the vertical rotating shaft 19 as described above are connected to each other at the upper and lower ends with a rod 28 extending in the vertical direction to form an integral structure.

Between the upper fixed frame 20 and the lower fixed frame 21, an inner windmill portion 29 as an inner rotating portion and an outer windmill portion 30 as an outer rotating portion are disposed concentrically, and the inner windmill portion 2.
9 rotates integrally with the vertical rotation shaft 19, and the outer wind turbine unit 30 freely rotates around the vertical rotation shaft 19 during reverse rotation and applies rotational force to the vertical rotation shaft 19 during normal rotation. Allow energization.

More specifically, the inner windmill portion 29 rotates with the inner windmill portion bosses 31a and 31b fixed to the upper end portion and the lower end portion of the vertical rotating shaft 19, respectively, as shown in FIG. Plates 32 and 33 are attached, and between the upper rotating plate 32 and the lower rotating plate 33, as shown in FIG. 4, the one end side is bent and the other end side is bent so as to be almost linear, and the wing shape is obtained. A plurality of blades 34 having the required length are arranged in the circumferential direction (showing the case of eight in FIG. 2), and the mounting angle (elevation angle) θ1 is set to 20 to 30 degrees, preferably 22 to 24 degrees, And each blade 3
The upper end of each blade 34 is connected to the upper rotary plate 32 so that one end side of the curved surface 4 is on the outer side.
Further, the lower end of each blade 34 is attached to the upper surface of the lower rotary plate 33 so that the rotary plates 32 and 33 and each blade 34 can be rotated together with the vertical rotary shaft 19 in an integrated structure.

The outer wind turbine unit 30 includes an upper rotary plate 35 and a lower rotary plate 36 on the outer sides of the upper rotary plate 32 and the lower rotary plate 33 of the inner wind turbine unit 29, and the upper and lower rotary plates 35. 36, a ring-shaped clutch case 37 is attached to the center of each of the inner and outer windmills 29 by rotation of the outer windmill 30 between each clutch case 37 and the outer peripheral surface of the vertical rotating shaft 19. A one-way clutch 38 is interposed as a mechanism for speeding up. Furthermore, the upper and lower rotating plates 35 and 36
In between, a plurality of blades 39 (six cases are shown in the figure) having a cross-sectional shape similar to the blades 34 of the inner windmill portion 29 are arranged, and the attachment angle θ2 of each blade 39 is set. The upper and lower rotary plates 35 are set at the same angle as the mounting angle θ1 of each blade 34 of the inner windmill 29.
The configuration is attached to 36. The reason why the mounting angle of the blades 34 and 39 is set to 20 to 30 degrees is that the effect of generating lift cannot be maximized when the angle is 20 degrees or less and 30 degrees or more.

As an example of the one-way clutch 38, as shown in FIG. 3, a cam surface is formed on the inner surface of the outer race 38a to store the roller 38b, and when the outer race 38a rotates in one direction, the roller 38b When the roller 38b reaches the cam surface on the inner surface of the outer race, the roller 38b acts as a wedge between the cam surface and the vertical rotation shaft 19, and when the outer race 38a rotates in the opposite direction, the roller 38b moves away from the cam surface. The outer race 38a is used so as to idle with respect to the vertical rotation shaft 19.

The outer race 38a of the one-way clutch 38 is fixed to the clutch case 37, and the outer race 38a can rotate together with the rotating plates 35 and 36. When the rotating plates 35 and 36 rotate forward, A rotational force is transmitted to the rotary shaft 19 by the wedge action.

In FIG. 1, reference numeral 40 denotes a generator as a load, which is connected to the lower end portion of the vertical rotating shaft 19 so as to be detachable. Reference numeral 41 denotes a support plate connected to the lower fixed frame 21.

As described above, in the wind turbine rotating apparatus of the present invention, each blade 39 of the outer wind turbine unit 30 has an attachment angle (elevation angle) θ2 of 20 to 30 degrees with respect to a line extending in the radial direction, as shown in FIG. Since each of the adjacent blades 39 is narrowed in a tapered shape from the outside to the inside. for that reason,
Assuming that the wind acts from the direction of arrow A in FIG. 2, the wind taken in between the adjacent blades 39 is guided to the inner wind turbine 29 by the collect effect that is collected and flowed downstream. The inner wind turbine 29 also has 20 blades 20 with respect to a line extending in the radial direction.
Since they are attached at an attachment angle (elevation angle) θ1 that is in the range of ˜30 degrees and are arranged at a required interval in the circumferential direction, the gap between adjacent blades 34 is tapered from the outside to the inside. It is squeezed. Therefore, the wind taken in by the outer windmill unit 30 is further throttled. As a result, as shown in FIG. 2, the wind taken into the outer wind turbine section 30 is squeezed and flowed inward, and further, the inner wind turbine section 29 is squeezed and flowed inward, and the direction in which the wind is taken In the opposite direction, the inner wind turbine portion 29 and the outer wind turbine portion 30 both expand from the inner side toward the outer side and the wind spreads out. The inner windmill portion 29 is further efficiently rotated by the wind force that is further narrowed down and introduced by the wind force that is caused to flow.

Further, as shown in FIG. 2, the blade 39 of the outer wind turbine section 30 and the blade 34 of the inner wind turbine section 29 are both wing-shaped in cross section, and the curved portion on one end side is located outside. Therefore, in the experiment in which the cross-sectional shape of the blade 34 or 39 is a semicircular shape, it is possible to prevent the generation of the air vortex generated on the downstream side of the blade 34 or 39. The resistance of the blades 34 and 39 when the inner and outer windmill portions 29 and 30 rotate can be reduced, and the rotational force of the inner and outer windmill portions 29 and 30 can be increased more efficiently. Further, since the blades 34 and 39 have a wing shape in cross section as described above, lift force can be generated by the air flow flowing along the blade 34 or 39, and the generated lift force can be generated by the outer wind turbine unit 30. And the rotational force of the inner wind turbine unit 29 can be applied.

Therefore, in a no-load state in which no load is applied to the vertical rotating shaft 19, both the outer wind turbine unit 30 and the inner wind turbine unit 29 rotate efficiently, and the inner wind turbine unit 29 can be rotated at a higher speed. At this time, in the one-way clutch 38 interposed between the upper and lower rotary plates 35 and 36 of the outer wind turbine unit 30 and the vertical rotary shaft 19, the rotational speed of the inner wind turbine unit 29 is higher than the rotational speed of the outer wind turbine unit 30. In other words, since the outer wind turbine portion 30 is rotating in the reverse direction relatively, the outer race 38 a of the one-way clutch 38 is idle with respect to the vertical rotation shaft 19. Therefore, the inner and outer windmills 29 and 30 are rotating without interfering with each other.

However, as shown in FIG. 1, when the generator 40 is connected to the vertical rotating shaft 19, the rotational speed of the inner windmill portion 29 is significantly reduced, and conversely, the rotational speed of the outer windmill portion 30 is decreased. As described above, it has been confirmed by the inventors' experiments. According to the experiment results of the present inventor, when the wind speed is 10 to 12 m / sec, the rotational speed of the inner windmill portion 29 when there is a load decreases to less than half of the rotational speed of the outer windmill portion 30. 30 rpm is 139rp
When m, the result is that the rotational speed of the inner wind turbine portion 29 is 55 rpm.

In the embodiment of the present invention shown in FIGS. 1 to 4, a one-way clutch 38 is interposed between the outer wind turbine unit 30 and the vertical rotating shaft 19, and the vertical rotating shaft 19 is rotated by the rotational force of the outer wind turbine unit 30. Since the rotational force is energized, when the rotational speed of the inner windmill portion 29 decreases due to the load and the rotational speed of the outer windmill portion 30 is higher than the rotational speed of the inner windmill portion 29, the outer windmill portion The state where 30 rotates around the vertical rotation shaft 19, that is, the outer wind turbine unit 30 is rotated forward with respect to the vertical rotation shaft 19. In such a state, the roller 38b inside the outer race 38a of the one-way clutch 38 is sandwiched between the cam surface and the vertical rotation shaft 19 to act as a wedge, and the rotational force of the outer wind turbine unit 30 is applied to the vertical rotation shaft 19. Will be communicated. As a result, the vertical rotating shaft 19 is rotated by the rotational force of the outer wind turbine unit 30, and the inner wind turbine unit 29 integrated with the vertical rotating shaft 19 is increased in speed and rotated.

Therefore, when the generator 40 is connected to the vertical rotating shaft 19 as shown in FIG. 1 and used as a wind power generator, the capacity of the generator 40 can be increased.

Next, as another embodiment of the present invention, FIG. 5 shows an outline when the apparatus of the present invention is used as a device other than a wind power generator, for example, a wind agitator.

That is, like the one shown in FIG. 1, the inner windmill portion 29 fixed to the vertical rotating shaft 19,
A structure having an outer windmill portion 30 attached to the vertical rotation shaft 19 via a one-way clutch 38 that drives the vertical rotation shaft 19 when rotating around the vertical rotation shaft 19 in only one direction. A large number of stirring blades 4 on the stirring shaft 43 at the lower end of the vertical rotation shaft 19.
4 is connected, the rotation of the vertical rotation shaft 19 is transmitted to the stirring shaft 43, and the stirrer 42 is rotated. Other configurations are the same as those shown in FIG. 1, and the same components are denoted by the same reference numerals.

According to this embodiment, by installing the apparatus of the present invention where water is stored for a long time, such as a reservoir, and by immersing the stirrer 42 in water, the natural force of wind power can be obtained. The water can be stirred by using the water, and the water quality can be managed without using electric power or the like.

FIG. 6 shows still another embodiment of the present invention, in which the upper and lower rotating plates 35 and 36 of the outer wind turbine unit 30 in the same configuration as that shown in FIGS. Instead, rotating plates 45 and 46 having a taper on the outer peripheral portion are used.

That is, as the upper rotating plate of the outer wind turbine unit 30, the upper rotating plate 45 having a taper on the lower surface of the peripheral portion is used, and as the lower rotating plate, the lower rotating plate 46 having a taper on the upper surface of the peripheral portion. The blade 39 is disposed between the tapered surface 47 of the upper rotating plate 45 and the tapered surface 47 of the lower rotating plate 46 so that the upper and lower ends of the blade 39 are fixed to the tapered surface 47. It is a thing. Other configurations are the same as those shown in FIG. 1, and the same components are denoted by the same reference numerals.

According to this embodiment, the tapered surface 47 is formed around the upper and lower rotating plates 45 and 46 of the outer wind turbine unit 30, and the upper and lower rotating plates 45 and 46 are rotated up and down by the tapered surface 47. The peripheral part of the plates 45 and 46 can be formed as a funnel-shaped wind guide surface. Thereby, it becomes possible to take in more wind, and the rotation of the outer windmill part 30 and the inner windmill part 29 can be promoted.

The present invention is not limited to the above embodiment. For example, as the number of blades 34 and 39 of the inner windmill portion 29 and the outer windmill portion 30, the blade 3 of the inner windmill portion 29 is used.
4 shows the case where the number of blades 39 of the outer wind turbine unit 30 is six, but the outer wind turbine unit 30 is shown as six.
8 blades 39, or the blades 3 of the inner and outer windmills 29 and 30
The number of 4 and 39 may be other than the above, and the case where the one-way clutch 38 is provided between the outer wind turbine unit 30 and the vertical rotating shaft 19 is shown, but any one having the same function can be used. However, it should be understood that various changes can be made without departing from the spirit of the present invention.

It is a partially cutaway side view showing an outline of an embodiment of the present invention. FIG. 2 is a cut plan view from the II-II direction in FIG. 1. It is an expanded sectional view which shows the connection relationship with a vertical rotating shaft, a fixed frame, an outer side windmill part, and an inner side windmill part. It is a perspective view of the braid | blade currently used for the internal and external windmill parts. It is a partially cutaway side view showing an outline of another embodiment of the present invention. It is a partially cutaway side view which shows other form of implementation of this invention. An example of the crossflow type windmill proposed conventionally is shown, (A) is a perspective view of the whole, and (B) is a perspective view of an inner rotating part. FIG. 1 shows a conventionally proposed wind turbine, in which (a) is a cut side view, and (b) is a cut plan view of (a).

Explanation of symbols

19 Vertical Rotating Shaft 20 Upper Fixed Frame 21 Lower Fixed Frame 29 Inner Windmill (Inner Rotating Unit)
30 Outside windmill (outside rotating part)
32 Upper rotating plate 33 Lower rotating plate 34 Blade 35 Upper rotating plate 36 Lower rotating plate 38 One way clutch 39 Blade 40 Generator 42 Stirrer 45 Upper rotating plate 46 Lower rotating plate 47 Tapered surface

Claims (3)

An inner rotating portion in which a plurality of blades extending in the vertical direction are arranged at a required interval in the circumferential direction between a pair of upper and lower rotating plates and can rotate integrally with a vertical rotating shaft, and an upper portion of the inner rotating portion An outer rotating portion in which a plurality of blades extending in the vertical direction are arranged at a predetermined interval in the circumferential direction between a pair of upper and lower rotating plates disposed on the outer sides of the rotating plate and the lower rotating plate , and the inner rotating portion Between the outer peripheral surface of the vertical rotating shaft and the outer rotating portion, the inner rotating portion and the outer rotating portion rotate without interfering with each other when the rotating speed of the inner rotating portion is higher than the rotating speed of the outer rotating portion. When the rotational speed of the inner rotating portion decreases and the rotational speed of the outer rotating portion is higher than the rotating speed of the inner rotating portion, the rotational force of the outer rotating portion is increased to the inner rotating portion. To be transmitted to the vertical rotation axis of The clutch is interposed, the structure rotating speed of the inner rotating section which is to be urged rotational force of the outer rotating part by becomes in a state of lowered than the rotational speed of the outer rotating portion the clutch to the rotation of the inner rotary part A wind power rotating apparatus comprising: The blade and the outer rotating part blades of the inner rotating part, No cross-sectional shape and having a blade shape, placement and claim 1 Symbol was 20-30 degrees the mounting angle of the rotary plate with respect to a line extending radially Wind rotating device. The wind power rotating apparatus according to claim 1 or 2 , wherein the pair of upper and lower rotating plates of the outer rotating portion is a rotating plate having a taper at a peripheral portion.

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