JPH09273473A - Wind power driving device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide driving force by rotating a windmill excellently by means of a weak wind. SOLUTION: A wind force driving device is constructed mainly of a wind mill 3 provided with a plurality of wind receiving parts 6, 6, 6 extending radially from the rotary shaft 2, a semicircular cover body 7 which covers the outer circumference on the reverse rotation side rotating reversely to the wind direction of the windmill 3 and can be rotated around the rotary shaft 2, an extension body extended from the cover body 7 in the wind direction, and direction blade bodies 9A, 9B which are stood slantingly in the terminal end of the extension body 8 and receives a wind so as to rotate the cover body 7 in the wind direction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wind power drive device that is rotated by wind to generate a driving force.

[0002]

2. Description of the Related Art Conventionally, there are wind power generators and the like, but these conventional wind power generators are formed in a propeller type and rotate well in strong wind conditions, but perform well in weak winds. There is a problem that it cannot rotate and a good driving force cannot be obtained.

[0003]

SUMMARY OF THE INVENTION The present invention has been devised in view of the above problems of the prior art, and an object of the present invention is not to provide a wind power drive device that can generate a good driving force even in a weak wind.
The gist of the invention is to provide a wind turbine having a plurality of wind receivers extending radially around a rotation axis, and an outer circumference of a side that rotates in a direction opposite to the wind direction of the wind turbine so as to be rotatable around the rotation axis. A substantially semi-circular cover body, an extension body for air escape extending from the cover body in a wind direction, and a cover body that is installed at an end of the extension body in an inclined shape to receive wind and receives the wind. And a directional wing body for rotating the wing in the wind direction.

[0004]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a perspective configuration diagram of a wind power drive device of this example, FIG. 2 is a vertical cross-sectional configuration diagram of FIG. 1, and FIG.
It is a cross-sectional block diagram. In the figure, the wind power drive device 1 is
A windmill 3 that receives wind to rotate on the outer periphery of a rotary shaft 2 that is provided in the vertical direction, a cover body 7 that surrounds a half-circumferential side of the windmill 3 and is rotatable around the rotary shaft 2, and this cover body. 7 is mainly formed of an extension body 8 extended from 7 and directional wings 9A and 9B erected at the end of the extension body 8,
In this example, as shown in FIG. 3, the wind turbine 3 has six arms 5, 5, 5, 5 ... Radially outward from a hexagonal base 4 fitted on the outer periphery of the rotary shaft 2. It is extended, and each of the arms 5 has a dish-shaped wind receiving part 6, 6, at the tip thereof.
6 is fixed, and the wind receiving portion 6 is formed in such a shape that the outer peripheral side is inclined outward and extends to receive the wind in a wider range.

A bearing B is externally fitted on the upper end side of the rotary shaft 2 of the wind turbine 3, and the cover body 7 is rotatably attached to the bearing B.
Therefore, the cover body 7 is rotatable in the horizontal plane about the rotary shaft 2, and the cover body 7 is formed in a substantially semi-cylindrical shape such that a cylinder is vertically cut along the central axis. In the figure, the left end side is an open edge 7a that is vertically opened, and a semicircular curved arc portion 7b is formed on the right side from the open edge 7a, and an upper surface plate 7c is formed on the upper surface of the arc portion 7b. It is provided with a bottom portion 7d on the bottom side. Inside the cover body 7, the right half of the wind turbine 3 extends along the inner peripheral surface of the cover body 7. It is mounted so that it can be rotated horizontally.

The extending body 8 extending rearward from the cover body 7 is wide on the cover body 7 side and has a pair of side surfaces 8b, 8b which are reduced toward the rear portion.
The upper surface side of b and 8b is covered with the upper surface 8a, and the bottom side is opened. Therefore, the wind entering the cover body 7 can be guided to the rear side from the extension body 8 and escaped, and the wind is favorably escaped from the rear side and the bottom side. The directional wings 9A and 9B are attached to the rear end of the extension body 8 via hinges 10 and 10 so that the inclination angle can be adjusted.
9B is provided so as to stand upright with respect to the extending body 8 in a slanting manner so as to be able to direct the cover body 7 in the wind direction by receiving wind.

That is, when wind blows from the front end side of the cover body 7, the wind hits the directional wings 9A and 9B, so that the cover body 7 is automatically oriented in the wind direction around the rotary shaft 2. Thus, the wind is blown from the front end side of the cover body 7 in the longitudinal direction along the open edge 7a. The wind blown in this way abuts on the wind receiving portion 6 of the wind turbine 3 exposed on the left side of the cover body 7, and the wind receiving portion 6 is given a rotational force in the clockwise direction by the wind, whereby the rotating shaft 2 is rotated. It is rotated. That is, the exposed side of the wind turbine 3 receives the wind from the wind receiving portion 6 and rotates clockwise, and the right half, which is the side that rotates in the direction opposite to the flow direction of the wind, is covered by the cover body 7. No wind is received at the part, and the force of the wind acting in the direction opposite to the clockwise direction is well prevented by the cover body 7. Therefore, the force of the counterclockwise direction is not received, and the windmill 3 receives the weak wind. However, it can rotate clockwise satisfactorily.

After the wind turbine 3 is rotated clockwise by the wind that blows backward on the left side of the cover body 7, the wind is satisfactorily released rearward along the extension body 8. When the wind direction changes, the directional wings 9
A and 9B receive the pressing force of the wind to rotate the cover body 7 in the wind direction around the rotation shaft 2 so that the cover body 2 is always moved so that the wind direction and the open edge 7a of the cover body 7 are coaxial. Operates in the direction of the wind.

Further, in this example, an arc-shaped opening / closing cover 20 is provided on the inner peripheral side of the cover body 7 so as to be openable / closable, and a fulcrum bar 16 is erected on the top surface of the opening / closing cover 20 on the tip side. The wire 13 is connected to the fulcrum rod 16. The wire 13 is provided with the pulley 15 and the directional wings 9A, 9 provided on the upper surface 8a.
The tip of the weight 12 is connected to the weight 12 via a pulley 14 provided on the upper surface of the central portion of B.
It is arranged so that it can move up and down in the guide tube 11 fixed vertically between B.

The front side of the wire 13 passes through a pulley 17 provided at the front end of the upper surface portion 7c of the cover body 7 and sails 18
The sail 18 is provided so as to be movable in the front-rear direction on a rail 19 arranged in the front-rear direction along the open edge 7a of the cover body 7. Therefore, when the wind is weak, the weight of the weight 12 is greater, and the sail 18 is stopped at the front end side of the cover body 7. In this state, the open / close cover 20 is housed inside the cover body 7. In this state, the left half surface of the cover body 7 is in an open state, and the wind turbine 3 is rotated by receiving a favorable wind.

During strong winds such as typhoons, the wind blows from the front to move the sail 18 to the rear side by the wind pressure, that is, when the wind pressure exceeds the weight of the weight 12, the sail 18 is railed. The fulcrum rod 16 moves to the rear side along 19 and is pulled to the front side via the wire 13 at this time.
Is closed to the front side. Therefore, when the wind is strong, the open area on the left side of the cover body 7 is narrowed by the open / close cover 20, and when the sail 18 moves to the rear end of the rail 19, the open / close cover 20 moves completely to the front end side of the cover body 7. The wind turbine 3 is closed in this state.
Since the entire outer circumference is covered with the cover body 7 and the open / close cover 20, the windmill 3 is not hit by the wind, and damage to the windmill can be effectively prevented.

As described above, the wind turbine 3 can be favorably prevented from being damaged in a strong wind, and normally, the cover body 7 is directed to the front side on the side where the wind blows to ensure the wind receiving portion of the wind turbine 3 even in a weak wind. 6
The wind turbine 3 can be rotated by receiving it. For example, as shown in FIG. 2, if the rotating shaft 2 is extended downward and connected to the generator 23, the generator 23 can be rotated even in a weak wind. It can generate electricity and can function as a good wind power generator.

Next, referring to FIG. 4, FIG. 1, FIG. 2 and FIG.
The wind-powered driving device 1 shown in 1 is installed in the upper part of the hull 21. That is, in FIG. 4, the wind turbine drive device 1 is fixed to the upper portion of the hull 21, and the wind turbine 3 in the wind turbine drive device 1 is rotated to drive the rotary shaft 2.
The generator 2 is decelerated through a gear box 22 provided on the hull 21 and is connected to the generator 23 through a shaft or the like.
3 can be driven well, and the generator 23 may be provided with a switching clutch 24 or the like so that the rotational driving force of the rotary shaft 2 is transmitted to the screw 25 of the ship. With this configuration, for example, by mounting the wind power drive device 1 on a yacht-type leisure ship, the rotating shaft 2 can be driven well even in a weak wind, and the rotational force of the screw 25 can be obtained by this. With this, the hull 21 can be propelled, and unlike the conventional yacht, it is not necessary to operate a mast or a sail, and it can be a leisure ship that is extremely easy to operate.
By stopping the engine installed separately, it is possible to favorably propel the ship by wind force.

By attaching the wind power drive device 1 to a catamaran as shown in FIG. 5, a more stable leisure ship can be obtained, and a connecting member 26 is provided between the right hull 21A and the left hull 21B. The wind power drive device 1 is mounted on the connecting member 26.
If a screw (not shown) is connected to the lower end of the rotary shaft 2 of the wind power drive device 1, the screw can be rotated well by the wind power drive device 1 and the catamaran can be propelled. It will be possible to provide extremely innovative leisure ships.

[0015]

The wind power drive device of the present invention includes a wind turbine having a plurality of wind receiving portions extending radially around the rotary shaft, and the rotary shaft covering the outer periphery of the wind turbine rotating in the direction opposite to the wind direction. A substantially semicircular cover body rotatably provided as a center, an extension body for air escape extending in the wind direction from the cover body, and an inclined body standing at the end of the extension body. By providing a directional wing body for rotating the cover body in the wind direction by receiving the wind, the cover body is automatically oriented in the wind blowing direction via the directional wing body according to the wind direction. It is possible to surely receive the wind on the wind receiving part of the wind turbine, and it is possible to rotate the wind turbine satisfactorily even with a weak wind, and since the force received in the opposite direction from the wind is prevented by the cover body, The wind force can be converted into a rotating force with a 100% windmill, and the rotating shaft If by connecting the generator in light winds it becomes capable of satisfactorily generator. Further, there is an effect that this wind power driving device is attached to a leisure ship, and the screw is rotated by the driving force of the rotating shaft to obtain a novel leisure ship.

[Brief description of drawings]

FIG. 1 is a perspective configuration diagram of a wind power drive device.

FIG. 2 is a vertical cross-sectional configuration diagram of FIG.

FIG. 3 is a cross-sectional configuration diagram of FIG.

FIG. 4 is a schematic configuration diagram in which a wind power drive device is attached to a ship.

FIG. 5 is a perspective view showing a state in which the wind power drive device is attached to a catamaran.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Wind power drive device 2 Rotating shaft 3 Wind turbine 5 Arm 6 Wind receiving part 7 Cover body 7a Open edge 8 Extension body 9A, 9B direction wing body 11 Guide cylinder 12 Weight 13 Wire 14, 15, 17 Pulley 16 Pull point bar 18 Sail 19 Rail 20 Open / close cover 21, 21A, 21B Hull 22 Gear box 23 Generator 24 Switching clutch 25 Screw

Claims (1)

[Claims] 1. A wind turbine having a plurality of wind receiving portions extending radially around a rotation shaft, and a wind turbine provided so as to be rotatable about the rotation shaft by covering an outer circumference of a side of the wind turbine that rotates in a direction opposite to a wind direction. A substantially semi-circular cover body, an extension body for wind escape extending in the wind direction from the cover body, and the cover formed by standing upright at the end of the extension body to receive the wind. A wind force drive device, comprising: a directional wing body for rotating the body in a wind direction.