KR101825714B1 - A Rotor for Generator - Google Patents

Abstract

The present invention relates to a rotor for a generator which can be applied not only to non-contact type but also to contact type for all types of rotating wheels. The rotating body 30 is connected to the rotating shaft 62 of the generator 20 so that the rotational force of the rotating body 30 is transmitted to the rotating body 30, To the generator (20); An outer surface portion (32) facing the rotating locus surface; A plurality of magnet accommodating portions (33) provided on the rotating body around a circumference of the rotation axis about a radial direction; And a plurality of eddy current induction magnets (40) accommodated in the magnet accommodating portion (33) and arranged alternately in a polarity toward the locus plane to be rotated, wherein at least a part of the outer surface portion (32) 40), so that the outer surface disposed on the outer side is disposed closer to the locus plane that is rotated than the magnet (40).

Description

A Rotor for Generator}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotor for a generator, and more particularly, to a rotor for a generator that can be used both in a non-contact type and in a non-contact manner for all kinds of rotating wheels.

Eddy current refers to a swirl current flowing on a metal conductor due to an electromotive force generated when the magnetic flux changes in the metal conductor. The power loss due to the eddy current is called an eddy current, and the temperature of the metal conductor is raised by heat loss. The force generated by this eddy current is used in electric brakes in electric power meters and electric trains.

A ferromagnetic substance (ferromagnetic substance) refers to a substance that is strongly magnetized in the direction of its magnetic field when a strong magnetic field is applied from the outside, and remains magnetized even when the external magnetic field disappears. In this case, each atom of matter is like a magnet. Iron (Fe) is a typical ferromagnetic substance.

Non-magnetic material (non-magnetic substance) refers to a substance with a weak magnetic property or a material with no magnetic property at all. And includes a paramagnetic material to be described later. The relative magnetic permeability is close to 1 and is hardly affected by the magnetic field.

A paramagnetic substance is a substance that magnetizes in the direction of a magnetic field when it is placed in a magnetic field and does not magnetize when the magnetic field is removed. These include aluminum, tin, platinum, and iridium. The magnitude of magnetization is proportional to the magnitude of the surrounding magnetic field, and the degree of magnetization is expressed by the magnetic susceptibility. The magnetic susceptibility is inversely proportional to temperature, which is called Curie's Law.

Conventionally, a rotor is installed near a bicycle rim of an aluminum material, and magnets are attached to the periphery of the rotor so that the N pole and the S pole are arranged alternately. By rotating the bicycle rim, The rotor is rotated in a non-contact manner as the rim is rotated by allowing the magnet around the rotor to be attracted by the magnetic action generated by the eddy current, and the rotor around the rotor used to generate the eddy current A generator that induces a current in the coil winding is developed by using a point at which the magnet of the rotor is rotated to place a coil winding around the magnet.

However, such conventional non-contact type generators have the following problems.

First, the aluminum bicycle rim is formed by joining the elongated rim members by bending the circular rim members, so that the joints in the rim making process are made of ferromagnetic iron, There is a problem that the phenomenon of sticking and dropping on the draw is repeated. This damages both the magnet and the rim, disrupts the uniform rotation speed of the rotor, sharply reduces the power generation efficiency, and causes a problem such as a large noise.

Second, such conventional non-contact type generators can not be used for rims made of ferromagnetic material. This is because the magnets installed around the rotor are attracted to the rim in order to induce eddy currents.

Third, such conventional non-contact type generators can not be used for rims made of non-metallic carbon. This is because there is no eddy current in the carbon rim.

Fourth, in order to induce an eddy current, an electromotive force is induced through a magnet attached to a rotor, and a braking force due to a load current is applied by driving a load. Thus, a slip phenomenon The speed of the rim can not keep up with the speed of the rim).

Fifth, since a current is induced by using a magnet attached to the rotor in order to induce an eddy current, a magnet attached to the rotor must be disposed close to the rim, and this acts as a spatial limitation, The cores used to do so will not be available. In other words, the core can not be installed due to the spatial restriction around the rotor, and therefore, the magnet formed by the magnet attached to the rotor does not have a core, and thus is largely lost in the air. Further, according to the eddy current principle, almost no eddy current is generated when the rim rotates at a low speed, and the rotational speed of the rotor itself is greatly reduced. If the power generation efficiency is extremely low, the electromotive force can not be induced at low speed.

Japanese Patent Application Laid-Open No. 10-2014-0062463 Patent Registration No. 10-1320295 Patent Registration No. 10-1471392 Japanese Patent Application Laid-Open No. 10-2014-0028427

SUMMARY OF THE INVENTION It is an object of the present invention to provide a rotating body for a generator which can be used for all kinds of rotating wheels and has a sufficient power generation efficiency.

The rotary body (30) includes a rotary shaft (62) of the generator (20) and a rotary shaft (62) of the generator (20) A rotary shaft connecting part 31 connected to the rotary shaft 30 to transmit the rotational force of the rotary shaft 30 to the generator 20; An outer surface portion (32) facing the rotating locus surface; A plurality of magnet accommodating portions (33) provided on the rotating body around a circumference of the rotation axis about a radial direction; And a plurality of eddy current induction magnets (40) accommodated in the magnet accommodating portion (33) and arranged alternately in a polarity toward the locus plane to be rotated, wherein at least a part of the outer surface portion (32) 40 so that the outer surface disposed outside is positioned closer to the locus plane of rotation than the magnet.

The rotation shaft connecting portion 31 may be made of a material harder than the outer surface portion 32.

The outer surface portion 32 may be an elastic material absorbing impact and having a frictional force.

The rotary shaft connecting portion 31 and the outer surface portion 32 may have a concave / convex engaging portion 323 engaged with each other.

And the outer surface portion 32 may cover the magnet 40.

The magnet accommodating portion 33 is provided at least at the rotary shaft connecting portion 31 so that rotational force applied to the magnet can be transmitted to the generator 20 through the rotary shaft connecting portion 31.

The magnet accommodating portion 33 is formed so as to be connected to the outer surface portion 32 from the rotation shaft connecting portion 31. The magnet accommodating portion 33 is formed in a shape that the magnet 40 is accommodated in the magnet accommodating portion 33, The rotation of the outer surface portion 31 and the rotation of the outer surface portion 32 can be constrained to each other.

The portion of the outer surface portion 32 facing the locus plane may be inclined downward toward the outer side with respect to the rotation axis in the upper surface 322.

The portion of the outer surface portion 32 facing the locus plane may be inclined inward from the side surface 321 toward the upper portion.

According to the present invention, it is possible to efficiently generate electric power by using a rotating body applicable to any kind of rotating wheel.

That is, in the case of a wheel made of a ferromagnetic material, the rotating body can be rotated by the attraction force of the magnet. In the case of a wheel made of a paramagnetic body, the rotating body can be rotated using eddy currents generated in the paramagnetic body. In the case of wheels that are not energized or energized, it is possible to rotate the rotating body in a semi-contact manner, so that it can be installed on all rotating wheels, as well as bicycle wheels of iron rims, aluminum rims and carbon rims Do.

Further, according to the present invention, it is possible to solve the problem caused by the rim desorption phenomenon of the magnet generated when the aluminum rim is used.

According to the present invention, it is possible to prevent the generator, which is connected to the rotating body, from interfering with the wire spoke of the wheel due to the shape of the inclined surface of the rotating body, and the positional relationship between the rotating shaft of the rotating body and the rotating shaft of the rotating wheel , Vertical, etc.) can be freely set.

Further, according to the present invention, since the rotating body has high impact absorption rate, abrasion resistance and rolling friction coefficient, it can be used both in noncontact type, semi-contact type and contact type, and has a high rigidity center body, There is an advantage.

The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

FIG. 1 is a perspective view showing a state where a generator, to which a rotating body is applied, is installed close to or in contact with a rim of a bicycle according to an embodiment of the present invention;
2 is an exploded perspective view of a rotating body, which is one embodiment of the present invention,
Fig. 3 is a partial oblique view of a generator to which the rotating body of the present invention is applied,
4 is a side view of a generator to which a rotating body is applied,
Fig. 5 is a sectional view taken along the line AA of Fig. 4,
6 and 7 are exploded perspective views of a rotating body according to another embodiment of the present invention,
8 is a side view of a rotating body, which is another embodiment of the present invention.
9 is a side view of a generator to which a rotating body is applied, and FIG.
10 and 11 are modifications of the rotor of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

FIG. 1 is a perspective view showing a state in which a generator, to which a rotating body is applied, is installed close to or in contact with a rim of a bicycle, FIG. 2 is an exploded perspective view of a rotating body according to an embodiment of the present invention, FIG. 4 is a side view of a generator to which a rotating body is applied, and FIG. 5 is a sectional view taken along the line AA of FIG. 4. FIG.

[Installation style and position of the generator according to one embodiment of the rotating body]

The generator 20 to which the rotating body of FIG. 2 is applied according to an embodiment of the present invention is installed on the bicycle frame so as to be close to or in contact with the rim 10 of the rotating bicycle wheel, for example, as shown in FIG. That is, the generator is fixed on the bicycle frame, and the rim 10 of the bicycle wheel rotates in a state of being in proximity to the rotating body 30 of the generator 20 or in contact with the rotating body when the bicycle wheel rotates. The upper portion of the generator 20 shown in the drawing is an embodiment of the rotor 30 to be described later.

The rotating shaft connected to the rotating body 30 of the illustrated embodiment is substantially perpendicular to the axis of the bicycle wheel. That is, the circumferential direction of rotation of the side surface of the rotating body and the circumferential direction of rotation of the side surface of the rim facing the rotating body coincide with each other.

[Structure and rotation principle of rotating body]

It is the portion of the rotating body 30 of the generator 20 which is in close proximity to or in contact with the rim 10 of the bicycle wheel. Referring to FIG. 2, as one embodiment of the present invention, the rotating body 30 has a truncated cone structure. That is, the portion of the outer surface 32 of the rotating body 30, which faces the locus plane of the rim, is inclined inward toward the upper side from the side surface 321.

The reason for forming the truncated cone, that is, the trapezoidal shape of the rotating body is to cope with the shape in which the rim of the bicycle wheel becomes gradually narrower toward the hub, which is the center of the wheel. That is, as the rim of the wheel is inclined, the side surface of the rotating body facing the rim is inclined so as to correspond to the inclination of the rim, so that the generator 20 provided at the lower portion of the rotating body is installed far from the wire spoke of the bicycle wheel (See FIG. 4).

However, the shape of the rotating body is not necessarily limited thereto, and it may have a cylindrical shape, a polygonal columnar shape, or a polygonal prism shape depending on the shape of the rim and the method of storing the magnet.

The outer surface portion 32 of the rotating body 30 installed close to the rim of the bicycle wheel is made of a synthetic resin material and is made of a material having a good shock absorbing ratio and a high abrasion resistance and a high rolling friction coefficient . Materials such as tires may be applicable. Silicon series may also be used, although the hardness is weak.

As shown in the figure, the magnet accommodating portion 33 is formed at an equal interval in the radial direction around the rotating body having a shape extending in the radial direction around the rotation axis. The magnet accommodating portion 33 accommodates the eddy current induction magnet 40, respectively. A plurality of eddy current induction magnets 40 are accommodated in the magnet accommodating portion 33 so that the magnets are alternately arranged in the direction in which the magnets face the outside of the rotating body. When the N pole and S pole are arranged alternately, the eddy current is generated in the rim so that the rotating body can rotate well. The magnet may be a neodymium magnet, and the number of the magnet may be about 6 to about 20 by examining various factors such as an installation environment. The eddy current induction magnet 40 may be inserted into the magnet accommodating portion 33 after the rotation body is manufactured or may be integrally inserted into the magnet accommodating portion 33 by an insert injection method. The magnet accommodating portion 33 and the eddy current induction magnet 40 are formed in an angular structure as shown in FIG. When the magnet accommodating portion 33 and the eddy current inducing magnet 40 are manufactured in an asymmetric shape as in the case of the trapezoidal column as shown in the drawing, the eddy current induction magnet 40 is hollow in the magnet accommodating portion 33 The phenomenon can be prevented. In other words, in order to obtain the most efficient rotational force through the induction of eddy current, the polarity direction of the magnet once oriented must maintain its state continuously.

At least a portion of the rotation center portion of the outer surface portion (32) is fitted with a hard rotary shaft connection portion (31). To this end, a coupling portion 323 having a shape corresponding to the rotation axis connection portion 31 is formed at the center of the outer surface portion 32. The outer surface of the rotating shaft connecting portion 31 and the inner surface of the engaging portion 323 are each provided with concavities and convexities to prevent the outer surface portion 32 of the rotating body 30 and the rotating shaft connecting portion 31 from being idle. That is, the outer surface of the rotating shaft connecting portion 31 and the inner surface of the engaging portion 323 of the rotating body, which is one embodiment of the present invention, make the rotation between the outer surface portion 32 and the rotating shaft connecting portion 31 constrained to each other. Further, in the present invention, a rigid rotating shaft connecting portion 31 is disposed relatively to the rotating center of the rotating body to support the rotation of the relatively soft rotating body, and the above-mentioned concave and convex shape doubles the supporting force. That is, the concavo-convex shape described above has a function of supporting the relatively soft outer surface portion 32 as well as a function of transmitting the rotational force. The rotary shaft connecting portion 31 is connected to the rotary shaft 62 of the generator 20 to transmit the rotational force of the rotary body 30 to the generator 20. In the case of constructing a rigid rotating shaft connection portion at the center of the rotating body rather than when all of the rotating body is made of a soft material, the factor of rotation of the rotating body can be greatly reduced even if the rotating body is elastically deformed. In addition, when the hard rotary shaft connecting portion 31 is inserted into the center of the rotating body, the relatively soft outer surface portion 32 becomes tighter so that the eddy current induction magnet 40 inserted in the rotating body 30 is fixed more firmly .

A shaft receiving groove 311 in which a rotating shaft 62 to be described later is formed is formed at the rotation center of the rotation shaft connecting portion 31. Therefore, when the rotating body rotates, the rotating shaft moves integrally and rotates. It goes without saying that the rotating body 30 rotates about the rotating shaft 62 as a matter of course.

According to the present invention, when the rim material of the bicycle wheel is made of ferromagnetic material, attraction is exerted between the eddy current induction magnet 40 of the rotating body 30 and the rim 10, and as the rim rotates, The eddy current induction magnet is pulled by the attraction force and the rotating body 30 is also rotated to induce rotation of the rotating body. The rotating body may come into contact with the rim by the attraction force of the eddy current induction magnet 40 in the rotating body 30. However, even in such a case, the outer surface portion 32 constituting the surface of the rotating body may have abrasion resistance and rolling frictional force Is made of a large material so that it can rotate well together with the rotation of the rim. Therefore, in the case of the generator and rotor structure of the present invention, the generator can be used in non-contact type and / or contact type in the rim made of iron. This is because the energy loss is small as a noncontact type due to the use of the attraction force of the magnet, and even when the surface of the rotating body touches the surface of the rim due to the attraction of the magnet, it is semi-contact type not strong contact, Much less. That is, the work force method can be applied in parallel with the semi-contact method. According to the attraction method, the distance between the rotating body and the rim can be 1 to 10 mm.

On the other hand, when the rim material of the bicycle wheel is made of aluminum, the magnetic flux of the eddy current induction magnet 40 of the rotating body 30 induces an eddy current on the surface of the rim 10 as the rim rotates, The rotating body 30 also rotates in a noncontact manner as the rim 10 rotates by pulling the magnet 40 for inducing eddy current by acting as a magnetic force again. At this time, there may occur a case where the eddy current induction magnet (40) in the rotating body (30) collides against the rim because a ferromagnetic substance is present at one portion (joint portion) along the circumference of the rim (10) Since the outer surface portion 32 of the rotating body 30 covers the magnet 40 in the state in which the rotating body 30 is accommodated in the rotating body 30, The side 321 of the part 32 hits the rim and receives the rotational force of the rim, so that the rotational force of the rotating body is not lost. As a result, the problems occurring in the above-described conventional non-contact type generator are solved at once. Therefore, in the case of the generator and rotor structure of the present invention, the generator can be used in a non-contact manner to a rim made of a paramagnetic material such as aluminum. Since this is a non-contact type, energy loss is much less than conventional full contact generators. With the eddy current method, the distance between the rotating body and the rim can be set to 1 to 10 mm.

In addition, when the rim material of the bicycle wheel is made of a material such as carbon in which no eddy current is induced, the outer side surface 32 side 321 of the rotating body 30 is rotated in a semi-contact state with the side surface of the rim. At this time, the upper portion of the side surface 321 of the rotating body 30 is provided so as to be in contact with the lower side surface of the rim. Therefore, in the generator and rotor structure of the present invention, since the generator can be used semi-contactly with a rim made of a material such as carbon which is not a ferromagnetic material or a paramagnetic material, It is possible to rotate the rotating body in a semi-contact or non-contact manner.

[Structure of generator]

Next, the generator 20 of the present invention will be described in detail with reference to FIGS. 3 to 5. FIG.

A rotating shaft (62) fixed to the center of the rotating body (30) extends to the generator (20). The generator 20 includes a case 70 fixed to a frame or the like of a bicycle and a core 66 fixed inside the case 70. [ For example, the case 70 may have a cylindrical shape, and the core in the case may have a cylindrical shape on the outer surface as shown in FIG. A coil 68 is wound around the core 66.

Since the generator is driven on the basis of the rotational kinetic energy interlocked by the bicycle, it is necessary to achieve high output with small size and light weight.

The core 66 may have a diameter of about 20 to 50 mm, and the coil bundle may have about 2 to 12 coil bundles. The height of the core is about 20 to 50 mm.

The diameter of the coil 68 is about 0.15 to 0.4 mm. These cases, cores and coils are fixed.

A rotating shaft 62 is disposed in a space surrounded by the core 66 and the coil 68 and rotates. As shown in the figure, the power generating magnet 62 is formed on the rotary shaft 62 and rotates together with the rotation of the rotary shaft. The power generation magnet 62 can be a neodymium magnet, and the number of magnet poles can be set from 2 to 8 poles.

The shape of the generator can consist of single-phase or three-phase depending on the number of magnetic poles and the number of coil bundles.

According to the present invention, since the magnets (40) provided in the rotating body and the magnets (64) provided in the rotating shaft (62) for inducing the electromotive force are separately provided in order to induce eddy currents, Since a coil can be installed, a magnetic path is formed, so that the power generation efficiency is superior to that of a conventional non-contact generator.

[Another embodiment of the rotating body]

FIG. 8 is a side view of a rotating body, which is another embodiment of the present invention. FIG. 9 is a perspective view of a generator according to another embodiment of the present invention, Side view, and Figs. 10 and 11 are modifications of the rotating body of the present invention, respectively.

6 to 9, the rotating body 30, which is another embodiment of the present invention, may be installed on the bicycle frame so as to be close to or in contact with the rim of the rotating bicycle wheel as shown in FIG. The rotating shaft 62 of the rotating body 30 may be arranged substantially parallel to the rotational axis of the bicycle wheel. That is, the circumferential direction of the rotation of the upper surface of the rotating body and the circumferential direction of rotation of the side surface of the rim facing the rotating body coincide with each other. In consideration of the inclination of the rim of the bicycle, the outer surface portion 32 has a downward inclined surface toward the outer side with respect to the upper surface 322.

The generator 20 to be applied to the rotating body 30, which is another embodiment of the present invention, may be a disk-shaped generator as shown in FIG. 1 to 5, such a generator 20 can be mounted anywhere that the front wheel of the bicycle or the rear wheel can be easily mounted. The disk type generator can be made compact in terms of the assembly of the generator and the rotating body by matching the standard with the relatively flat and flat rotating body 30.

Referring to FIG. 6, the rotating body 30 according to another embodiment of the present invention includes an outer surface portion 32 facing a locus plane that rotates as a rim of a bicycle wheel, and an outer surface portion 32 connected to a rotation axis 62 of the generator 20 And a rotary shaft connecting part (31) for transmitting the rotational force of the rotary body (30) to the generator (20). The rotation shaft connecting portion 31 is fastened to the outer surface portion 32 in such a manner that the outer circumferential surface thereof is fitted to the coupling portion 323 of the outer surface portion 32.

The rotary shaft connecting portion 31 is configured to transmit the rotational force of the rotating body to the generator, and is preferably made of a material harder than the outer surface portion. A shaft receiving groove 311 is formed at the center of the rotary shaft connecting portion 31 to receive the rotary shaft 62 of the generator 20. The shaft receiving groove has a part of a flat surface, and the rotating shaft 62 also has a flat portion (see FIG. 3) that engages with the rotating shaft 62 so that the rotating shaft connecting portion 31 and the rotating shaft 62 rotate integrally without loosening.

The outer surface portion 32 may be made of a material that is relatively soft compared to the rotating shaft connecting portion 31 and may be an elastic material capable of absorbing impact and a material having high frictional force such as silicone or rubber.

The magnet accommodating portion 33 is formed in the space surrounded by the outer surface portion 32 and the rotation axis connecting portion 31 as the inner space of the rotating body 30. [ A plurality of magnet accommodating portions are provided radially about the circumference of the radial direction around the rotation shaft. The eddy current induction magnet (40) accommodated in the plurality of magnet accommodating portions is alternately arranged in the polarity toward the upper surface (322) of the rotating body facing the rotating locus plane.

Since the outer surface portion 32 covers the magnet 40, the outer surface portion 32 is arranged closer to the rotating locus surface, that is, the rim, than the magnet 40. As described above, such an outer surface structure allows the rotation body to be installed and used in a non-contact attraction force method or a semi-contact manner regardless of the material of the rim of the bicycle wheel, that is, the rotating locus plane, And the shock generated when the rotating body collides with each other is absorbed and the rotational force is transmitted.

6 and 7, the magnet accommodating portion 33 is formed at least in the rotation axis connecting portion 31 in comparison with the magnet accommodating portion 33 formed on the outer surface portion 32 in the embodiment of FIG. . According to this structure, the eddy current is generated and the rotating force generated by the external force applied to the magnet can be transmitted to the generator through the rotating shaft connecting part 31 completely. The magnet accommodating portion 33 is connected to the outer surface portion 32 from the rotation shaft connecting portion 31. When the magnet is received in the magnet accommodating portion 33 connected to the rotation axis connecting portion 31 and the outer surface portion 32 of the magnet accommodating portion, the magnet rotates about the rotation axis connecting portion 31 and the outer surface portion 32, So as to restrain the rotation of the motor. This is a structure that can replace or be combined with the concavo-convex structure of the coupling portion 323 described above. This structure is particularly useful when the outer surface portion 32 of the rotating body has a semi-contact relationship with the locus plane to which rotational force is transmitted. That is, in the semi-contact type, the rotating force of the rotating locus plane is transmitted to the rotating body 30 through the outer surface portion 32, and this rotational force is transmitted to the rotating shaft connecting portion 30 through the magnet accommodating portion of the outer surface portion 32 and the magnet 40, (31) through the magnet accommodating portion of the rotor (31).

6 and 7 illustrate that the magnet 40 illustrated in the other embodiment of the present invention is in the form of a tiny cylinder, but the shape of the magnet is not limited thereto. 10 and 11, the rotation shaft connecting part 31 of the present invention may have various modifications. Here, the shape of the magnet is rectangular, and the magnet accommodating part 33 is disposed radially with respect to the rotation axis 10), and can be arranged in the form of a whirlpool around the rotation axis (see FIG. 11). 10 and 11, the outer surface portion 32 may be covered with a cover. The shape and material of the shaft receiving groove 311 can be variously modified as shown in Fig. 10 (harder ring is inserted) and Fig. 11 (concave and convex).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It is apparent that various combinations of various modifications and embodiments can be made. Although the embodiments of the present invention have been described in detail above, the effects of the present invention are not explicitly described and described, but it is needless to say that the effects that can be predicted by the configurations should also be recognized.

10: rim
20: generator
30: rotating body
31:
311: Axle accommodating groove
32: outer surface portion
321: Side
322: upper surface
323:
33: Magnet accommodating portion
40: Magnet for induction of eddy current
62:
64: Power generating magnet
66: Core
68: Coil
70: Case

Claims (9)

A rotary body (30) for a generator, which is provided in contact with or near to a rotating locus plane,
The rotating body (30)
A rotary shaft connecting portion 31 connected to the rotary shaft 62 of the generator 20 to transmit the rotational force of the rotary body 30 to the generator 20;
An outer surface portion (32) facing the rotating locus surface;
A plurality of magnet accommodating portions (33) provided on the rotating body around a circumference of the rotation axis about a radial direction; And
And a plurality of eddy current induction magnets (40) accommodated in the magnet accommodating portion (33) and arranged alternately in a polarity toward the locus plane to be rotated,
At least a part of the outer surface portion 32 is disposed on the outer side of the magnet 40 so that the outer surface portion disposed on the outer side is disposed closer to the locus plane of rotation than the magnet 40,
A rotational force applied to at least one of the outer surface portion 32 and the magnet 40 is transmitted to the generator 20 through the rotary shaft connecting portion 31,
Wherein the outer surface portion (32) is an elastic material that absorbs impact and has a frictional force.

The method according to claim 1,
Wherein the rotation shaft connecting portion (31) is made of a material harder than the outer surface portion (32).
delete The method according to claim 1,
Wherein the rotation shaft connecting portion (31) and the outer surface portion (32) are provided with engaging portions (323) of concave and convex engageable with each other.
The method according to claim 1,
And the outer surface portion (32) covers the magnet (40).
The method according to claim 1,
Wherein the magnet accommodating part (33) is provided at least at the rotation shaft connecting part (31), so that rotational force applied to the magnet is transmitted to the generator (20) through the rotation shaft connecting part (31).
The method of claim 6,
The magnet accommodating portion 33 is formed so as to be connected to the outer surface portion 32 from the rotation shaft connecting portion 31. The magnet accommodating portion 33 is formed in a state in which the magnet 40 is accommodated in the magnet accommodating portion 33, (31) and the outer surface portion (32) are constrained to each other.
The method according to claim 1,
Wherein a portion of the outer surface portion (32) facing the locus plane is inclined downward toward the outer side with respect to the rotation axis at an upper surface (322).
The method according to claim 1,
Wherein a portion of the outer surface portion (32) facing the locus plane is inclined inward toward the upper side from the side surface (321).

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