JP2016194262A - Wind power generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wind power generation system which reduces a rotational road to enable a low wind speed starting with a simple structure and enables improvement of a power generation amount.SOLUTION: A wind power generation system includes: a main shaft 1 erected in a vertical direction; a wind mill attached to the main shaft; and a power generation device 3 provided at a lower portion of the main shaft 1. The power generation device 3 includes: a rotor 30 attached to the lower portion of the main shaft 1 and in which permanent magnets are arranged so that the pluralities alternately differ in a circumferential direction; and a stator 40 having yokes 42 surrounding the rotor 30 and coils 43 wound around the yokes 42. The wind power generation system floats the main shaft 1 with a magnetic attraction force between the rotor 30 and the yokes 42.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a wind power generation system including a main shaft erected in a vertical direction, a windmill attached to the main shaft, and a power generation device provided at a lower portion of the main shaft.

  Conventionally, as this type of wind power generation system, as shown in Patent Document 1 below, a wind turbine generator is provided with a magnetic bearing in which permanent magnets are arranged on the upper and lower ends of a main shaft and permanent magnets facing these are provided in a bearing portion. It has been known.

JP 2001-132617 A

  However, in the conventional wind power generation system, the contact resistance can be eliminated by the non-contact magnetic bearing and the power generation efficiency can be improved. However, in addition to the magnetic bearing, it is necessary to separately configure the power generation device, and the device configuration is complicated. There was a problem of becoming.

  In particular, a vertical type small wind power generator is a business form that increases the amount of power generation by making it possible to install a plurality of units with a simple configuration. However, the fact that the device configuration is complicated and the cost per unit is high is a big business. It becomes an obstacle.

  Therefore, the present invention provides a wind power generation system capable of reducing the rotational load with a simple configuration, enabling low wind speed startup, and improving the amount of power generation.

In order to achieve the above object, a wind power generation system according to a first aspect of the present invention includes a main shaft erected in a vertical direction, a wind turbine attached to the main shaft, and a power generation device provided at a lower portion of the main shaft. In the power generation system,
The power generator is
A rotor attached to the lower part of the main shaft and having permanent magnets arranged so that the polarities are alternately different in the circumferential direction;
A stator having a plurality of yokes surrounding the rotor and a coil wound around the yokes;
The main shaft is levitated by a magnetic attraction force between the rotor and the yoke.

  According to the wind power generation system of the first aspect of the present invention, the main shaft can be floated by the magnetic attraction effect of the power generation device by configuring the power generation device by the rotor having the permanent magnet and the stator having the yoke facing the rotor. .

  Thereby, it is not necessary to separately provide a magnetic bearing, the rotational load can be reduced with a simple configuration, and the low wind speed can be started, and the power generation amount can be improved.

The wind power generation system of the second invention is the first invention,
The outer peripheral surface of the rotor has a tapered shape with the diameter expanded from the upper part to the lower part,
The inner peripheral surface of the yoke has a tapered shape whose diameter is expanded from the upper part to the lower part corresponding to the outer peripheral surface of the rotor,
In addition to a horizontal component, a vertical component is generated as a magnetic attractive force between the rotor and the yoke.

  According to the wind power generation system of the second invention, in the stator having the rotor having the permanent magnets and the yoke facing the rotor, the magnetic attraction force is in the horizontal direction between the rotor and the yoke. The taper shape has a diameter that increases from the top to the bottom and the taper shape that expands from the top to the bottom with the inner peripheral surface of the yoke corresponding to the outer peripheral surface of the rotor. A magnetic attraction force obliquely upward can be generated.

  As a result, even when the gravity applied to the main shaft increases, it is not necessary to separately provide a magnetic bearing, and the rotational load can be reduced with a simple configuration to enable low wind speed startup and the power generation amount can be improved.

The wind power generation system of the third invention is the first or second invention,
A rotor-side auxiliary permanent magnet provided at a lower portion of the rotor;
A stator side auxiliary permanent magnet provided on the stator and disposed opposite to the auxiliary permanent magnet in a reverse polarity;
The rotor side auxiliary permanent magnet and the stator side auxiliary permanent magnet assist the floating of the main shaft.

  According to the wind power generation system of the third invention, even when the gravity applied to the main shaft increases, the main shaft moves upward due to the repulsive force of the rotor side auxiliary permanent magnet and the stator side auxiliary permanent magnet provided at the lower end of the main shaft. Pushed up.

  As a result, even when the gravity applied to the main shaft increases, it is not necessary to separately provide a magnetic bearing, and the rotational load can be reduced with a simple configuration to enable low wind speed startup and the power generation amount can be improved.

The whole block diagram which shows the structure of a wind power generation system. Explanatory sectional drawing which shows the structure of the electric power generating apparatus of the wind power generation system of FIG. FIG. 3 is an explanatory cross-sectional view illustrating another configuration of the power generation device of FIG. 2.

  With reference to FIG. 1, the wind power generation system of this embodiment is demonstrated. The wind power generation system includes a main shaft 1 erected in the vertical direction via a frame X, a windmill 2 attached to the main shaft 1, and a power generation device 3 provided at a lower portion of the main shaft 1.

  The main shaft 1 is rotatably supported via a bearing Y between the main shaft 1 and rotates corresponding to the rotation of the windmill 2.

  The windmill 2 includes a pair of blades 21 and 21 extending in the vertical direction, and support arms 22 and 22 that are connected to the main shaft 1 and support the blades 21 and 21.

  As shown in FIG. 2, the power generation device 3 includes a rotor 30 attached to the lower portion of the main shaft 1 and a stator 40 provided so as to surround the rotor 30.

  The rotor 30 includes a rotating body 31 attached to a rotating shaft 1 ′ connected to the main shaft 1 via the joint portion 10, and a plurality of rotors arranged radially so that polarities are different in the circumferential direction on the outer peripheral surface of the rotating body 31. The permanent magnet 32 is provided.

  The stator 40 includes a plurality of yokes 42 supported on the inner surface of the housing 41 and a coil 43 wound around the yokes 42.

  The casing 41 is supported on the upper surface 3 ′ of the casing of the main body of the power generation device 3 via an adjustment screw 41 a so as to be adjustable in the vertical direction. A guide (anti-vibration rubber) 41b is attached to the abutting portion between the upper surface 3 'of the casing and the casing 41.

  The yoke 42 faces the permanent magnet 32 of the rotor 30 and surrounds the rotor 30 from the outer periphery. Note that the outer end portions of the yoke 42 may be connected to each other to form an annular shape.

  Thus, when the rotor 30 is inserted into the stator 40, the rotor 30 is positioned at the center position (center direction and vertical direction) of the yoke 42 as shown in FIG. 2 by the magnetic attractive force between the permanent magnet 32 of the rotor 30 and the yoke 42 facing the rotor 30. At the center position).

  The central position can be adjusted by adjusting an adjustment screw 41 a between the casing 41 and the upper surface 3 ′ of the casing of the power generation device 3 main body, and the vertical position of the main shaft 1 can be adjusted via the rotor 30. Can be adjusted.

  The coil 43 is wound around the yoke 42, and an alternating induced current is generated by a change in magnetic flux in the yoke 42 due to the rotation of the rotor 30.

  The rotor 30 and the stator 40 are provided with a rotor side auxiliary permanent magnet 34 and a stator side auxiliary permanent magnet 44, respectively, as necessary.

  The rotor-side auxiliary permanent magnet 34 is attached downward to the lower portion of the rotor 30, and the stator-side auxiliary permanent magnet 44 is disposed on the bottom surface 40 ′ of the stator 40 so as to face the rotor-side auxiliary permanent magnet 34 in the opposite polarity.

  Thus, the repulsion of the rotor side auxiliary permanent magnet 34 and the stator side auxiliary permanent magnet 44 when the rotor 30 and the main shaft 1 are not sufficiently lifted by the magnetic repulsion force between the permanent magnet 32 of the rotor 30 and the opposing yoke 42. The rotor 30 can be lifted upward by force and lifted.

  The stator-side auxiliary permanent magnet 44 is supported on the bottom surface 40 ′ of the stator 40 via an adjustment screw 44 a so as to be adjustable in the vertical direction. Therefore, by adjusting the gap between the rotor-side auxiliary permanent magnet 34 and the stator-side auxiliary permanent magnet 44, the repulsive force that pushes the rotor 30 upward can be adjusted.

  According to the wind power generation system configured as described above, when the wind rotates by receiving the blades 21 and 21, the rotation of the main shaft 1 is performed via the support arms 22 and 22.

  At this time, the main shaft 1 is provided with a magnetic attraction force between the rotor 30 provided at the lower part via the rotating shaft 1 ′ and the yoke 42 (when the rotor side auxiliary permanent magnet 34 and the stator side auxiliary permanent magnet 44 are provided. Can be brought into a floating state by the repulsive force between them.

  Thus, by making the main shaft 1 float, the bearing load of the bearing Y which is the bearing portion of the main shaft 1 can be reduced, and the rotational load can be greatly reduced to enable low-speed activation.

  Furthermore, the bearing load applied to the bearing Y can adjust the gap between the housing 41 and the upper surface 3 ′ of the casing of the main body of the power generation device 3 by the adjusting screw 41 a (see the arrow in the figure).

  In addition, when the rotor-side auxiliary permanent magnet 34 and the stator-side auxiliary permanent magnet 44 are provided, the gap between the rotor-side auxiliary permanent magnet 34 and the stator-side auxiliary permanent magnet 44 can be adjusted by the adjusting screw 44a. The bearing load on the bearing Y can be adjusted (see the arrow in the figure).

  Further, by adopting an overhang structure in which the stator 40 is provided so as to surround the rotor 30 in the horizontal direction, a bearing between the rotor 30 and the stator 40 can be omitted, and a bearing load portion can be eliminated. , The rotational load can be further reduced.

  In addition, by adopting an overhang structure in which the stator 40 is provided so as to surround the rotor 30, tolerance can be given to vibration in the longitudinal direction of the main shaft 1, and a bearing between the rotor 30 and the stator 40 can be provided. This also eliminates the need for flexible couplings, flexible shafts, and the like that are used in combination.

  As described above, according to the wind power generation system of the present embodiment, the rotational load can be reduced with a simple configuration to enable low wind speed startup, and the power generation amount can be improved.

  Next, with reference to FIG. 3, the example of a change of the electric power generation system of this embodiment is demonstrated. In addition, about the structure same as the said embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  In this case, the rotor 30 ′ provided on the rotating shaft 1 ′ has a tapered shape whose outer peripheral surface is expanded from the upper part to the lower part.

  Specifically, the rotor 30 'has a tapered shape in which the outer peripheral surface of the rotating body 31' is expanded from the upper part to the lower part, and the permanent magnet 32 'on the outer peripheral side has a different polarity in the circumferential direction on the outer peripheral surface. Are arranged radially.

  In this case, the stator 40 'has a tapered shape in which the inner peripheral surface of the yoke 42' attached to the inner surface of the housing 41 'is expanded from the upper portion to the lower portion corresponding to the outer peripheral surface of the rotor 30'. . Note that the inner peripheral surface of the yoke 42 ′ may have a step shape for the production of the yoke 42 ′.

  The casing 41 ′ is supported on the lower surface 3 ″ of the casing of the power generation device 3 main body via an adjustment screw 41 a ′ so as to be adjustable in the vertical direction. Further, a guide (anti-vibration rubber) 41b ′ is attached to a contact portion between the casing 41 ′ and the lower surface 3 ″ of the casing.

  According to the modified example of the power generation system of this embodiment, the magnetic attraction force is perpendicular to the tapered surface so as to pull up the rotor 30 ′ as compared with the embodiment in which the magnetic attraction force is in the horizontal direction between the rotor 30 and the yoke 42. It is possible to generate a magnetic attractive force that is obliquely upward (arrow in the figure).

  At this time, by adjusting the adjustment screw 41a ′ between the casing 41 ′ and the lower surface 3 ″ of the casing of the power generation device 3 main body, the center position thereof can be adjusted, and the main shaft 1 can be adjusted via the rotor 30 ′. The vertical position of can be adjusted.

  Thereby, even when the gravity applied to the main shaft 1 increases, the rotational load can be reduced with a simple configuration to enable low wind speed activation, and the power generation amount can be improved.

  In the modification of the power generation system of the present embodiment, the rotor side auxiliary permanent magnet 34 and the stator side auxiliary permanent magnet 44 may be provided supplementarily when the load applied to the main shaft 1 is large.

DESCRIPTION OF SYMBOLS 1 ... Main shaft, 1 '... Rotating shaft, 2 ... Windmill, 3 ... Electric power generation apparatus, 3', 3 "... Casing, 21 ... Blade, 22 ... Support arm, 30 ... Rotor, 31, 31 '... Rotating body, 32 , 32 '... permanent magnet, 40 ... stator, 41 ... housing, 41a, 41a', 44a ... adjusting screw, 42, 42 '... yoke, 43 ... coil, X ... frame, Y ... bearing (bearing).

Claims (3)

In a wind power generation system comprising a main shaft erected in a vertical direction, a windmill attached to the main shaft, and a power generation device provided at a lower portion of the main shaft,
The power generator is
A rotor attached to the lower part of the main shaft and having permanent magnets arranged so that the polarities are alternately different in the circumferential direction;
A stator having a plurality of yokes surrounding the rotor and a coil wound around the yokes;
A wind power generation system, wherein the main shaft is levitated by a magnetic attractive force between the rotor and the yoke. The wind power generation system according to claim 1,
The outer peripheral surface of the rotor has a tapered shape with the diameter expanded from the upper part to the lower part,
The inner peripheral surface of the yoke has a tapered shape whose diameter is expanded from the upper part to the lower part corresponding to the outer peripheral surface of the rotor,
A wind power generation system in which a vertical component is generated in addition to a horizontal component as a magnetic attractive force between the rotor and the yoke. The wind power generation system according to claim 1 or 2,
A rotor-side auxiliary permanent magnet provided at a lower portion of the rotor;
A stator side auxiliary permanent magnet provided on the stator and disposed opposite to the auxiliary permanent magnet in a reverse polarity;
A wind power generation system, wherein the rotor side auxiliary permanent magnet and the stator side auxiliary permanent magnet assist the floating of the main shaft.