KR20230158363A - Power Generation Device With Magnetic Force - Google Patents

Abstract

A power generation device using magnetic force is coupled to a rotating shaft, the outer surface of the rotating shaft, and has a radial cross-sectional shape centered on the axis of the rotating shaft. The outline is a rotating body that forms a wave-shaped cross-sectional shape along the circumferential direction, and the waveform of the rotating body. A rotor that has a cross-sectional shape of a wave opposite to the cross-sectional shape and includes a fixture disposed on the outside of the rotating body, an external stator fixed to the rotating shaft and formed to rotate, and an internal rotor rotatably coupled to the rotating shaft, and It includes a magnet section including a plurality of magnets arranged so that mutual repulsive force is applied to cross sections opposing the rotating body and the fixed body, and applies power generated from the internal rotor to the fixed body according to the rotation of the rotating shaft.

Description

Power Generation Device With Magnetic Force}

The present invention relates to a power generation device using magnetic force, and more specifically, to a power generation device using magnetic force that induces power generation by rotating a shaft with magnetic force.

In order to generate power, while rotating the rotating shaft, one of the cores with magnets and wires wound on them is fixed to the rotating shaft, and then electricity is induced. Power generation facilities such as power plants generate power by rotating a rotating shaft using steam. Fossil fuels are mainly needed to create steam, but now that we are faced with carbon emissions regulations to reduce global warming, there is a challenge to achieve high-efficiency power generation with minimal fuel input. For this purpose, a power generation device was developed that places magnets on a fixed body and a rotating body and uses the repulsive force of the magnets to rotate the rotating shaft to induce power generation.

However, power generation devices that use the repulsive force of magnets have a problem in that efficient power generation is not achieved because the direction in which the repulsive force acts is toward the center of the rotation axis.

Therefore, the purpose of the present invention is to provide a power generation device using magnetic power that can generate power by efficiently providing rotational force.

A power generation device using magnetic force according to the present invention to achieve the above object includes a rotating shaft; A rotating body coupled to the outer surface of the rotating shaft and having a radial cross-sectional shape centered on the axis of the rotating shaft, the outline of which forms a wave-shaped cross-sectional shape along the circumferential direction; a fixture having a wave-shaped cross-sectional shape opposite to the wave-shaped cross-sectional shape of the rotating body and disposed outside the rotating body; a rotor including an external stator fixed to the rotation shaft and configured to rotate, and an internal rotor rotatably coupled to the rotation shaft; and a magnet portion including a plurality of magnets disposed so that mutual repulsive force is applied to cross sections opposing the rotating body and the fixed body, wherein power generated from the internal rotor as the rotating shaft rotates is transferred to the fixed body. Authorize. By arranging the outer cross-sectional shapes of the rotating body and the stationary body to form a waveform and opposing each other, the repulsive force of the magnets acts in the rotation direction of the rotating body, so power generation efficiency can be improved. When the power generated from the internal rotor is applied to the stationary body, the power generation efficiency can be improved. The static magnetic force becomes strong, causing the rotating body to rotate at high speed, and the rotation of the rotating body generates more induced current in the stationary coil, thereby generating power.

Here, it is preferable that the magnet part includes at least one of a permanent magnet and an electromagnet because power generation can be generated using the permanent magnet and the electromagnet.

In addition, it is preferable that the magnet part is made of a directional magnet that outputs directional magnetic force because the repulsive force of the magnets can be concentrated in the rotation direction of the rotating body.

Here, the cross-sectional shape of the rotating body has a plurality of inclined extension surfaces obliquely extending in the rotation direction of the rotating body with respect to the outward line connecting the axis line of the rotating shaft to the outer surface, and the cross-sectional shape of the fixed body is: It has a plurality of opposing inclined surfaces formed to face the plurality of inclined extension surfaces, and the plurality of magnets are arranged on the plurality of inclined extension surfaces and the plurality of opposing inclined surfaces so that the same magnetic force is output in mutual directions. The cross-sectional shape of the rotating body and the stationary body is formed so that a directional repulsive force can act in the direction of rotation, and the magnet can be placed, which is preferable.

In addition, if the plurality of opposing inclined surfaces are formed to be more inclined in the rotation direction of the rotating body than the plurality of inclined extension surfaces, the repulsive force of the opposing magnets is applied inward rather than outward, so that the rotation of the rotating shaft can be performed more efficiently. do.

According to the present invention, the outer cross-sectional shapes of the rotating body and the stationary body are arranged to face each other in a waveform, so that the repulsive force of the magnets acts in the rotation direction of the rotating body, so power generation efficiency can be improved, and the power generated in the internal rotor is fixed. When applied as a sieve, the magnetic force of the stationary body becomes strong, causing the rotating body to rotate at high speed, and the rotation of the rotating body generates more induced current in the fixed coil body, which has the effect of generating power.

In addition, the repulsive force of the directional magnet is applied along the rotation direction of the rotating body, thereby significantly improving power generation efficiency.

1 is an exemplary diagram of a power generation device using magnetic force according to the present invention.
Figure 2 is an exemplary diagram of the rotating body and fixed body of the power generation device using magnetic force of Figure 1.
Figure 3 is an exemplary diagram of a deformable rotating body and a fixed body.

Hereinafter, a power generation device 1 using magnetic force according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is an exemplary diagram of a power generation device 1 using magnetic force according to the present invention.

The configuration of the power generation device 1 using magnetic force will be described with reference to FIG. 1.

The power generation device (1) using magnetic force includes a rotating shaft (10), a rotating body (20), a fixture (30), a magnet portion (40), a rotor (50), an external stator (60), and an internal stator (70). Includes.

The rotating shaft 10 may include a car shaft, a rotating shaft for power generation, etc.

The rotating body 20 is coupled to the outer surface of the rotating shaft 10 and has a radial cross-sectional shape centered on the axis of the rotating shaft 10, and the outline forms a wave-shaped cross-sectional shape along the circumferential direction. The rotating body 20 may be provided in a sawtooth shape or in a rotating knife shape. The rotating body 20 includes a rotating body 21 and an inclined extension surface 22.

The rotating body 21 is a part connected to the rotating shaft 10 and is the central area of the cross-sectional shape of the rotating body 20.

The inclined extension surface 22 is formed to extend obliquely in the rotation direction of the rotating body 21 with respect to an outward line connecting the axis of the rotating shaft 10 to the outer surface. The inclined extension surface 22 is formed to protrude from an outer area of the rotating body 21 and extends at an inclined angle in the rotation direction of the rotating body 21 to form a plane. A plurality of inclined extension surfaces 22 are formed along the circumferential direction of the rotating body 21.

The fixture 30 has a wave-shaped cross-sectional shape that is opposite to the wave-shaped cross-sectional shape of the rotating body 20, and is disposed on the outside of the rotating body 20 when the rotating body 20 is rotated on the inside. The fixture 30 includes a fixture body 31 and an opposing inclined surface 32.

The fixed body 31 is formed so that it can be supported by another external device.

The opposing inclined surface 32 is formed on the inside of the fixed body 31 to face the plurality of inclined extension surfaces 22. The opposing inclined surface 32 is formed as a depression from an inner region of the fixed body 31 and extends at an inclined angle in the rotation direction of the fixed body 31 to form a plane opposing the inclined extension surface 22. A plurality of opposing inclined surfaces 32 are formed along the inner circumferential direction of the fixed body 31.

Here, the plurality of opposing inclined surfaces 22 may be formed to be more inclined at least in the rotation direction of the rotating body 20 than the plurality of inclined extension surfaces 32.

A plurality of magnet units 40 are provided, and are disposed on a plurality of inclined extension surfaces 22 and a plurality of opposing inclined surfaces 32 so that the same magnetic force is output in mutual directions, so that a mutual repulsive force is applied. The magnet portion 40 may be provided with either a permanent magnet or an electromagnet, but is made of a directional magnet that outputs directional magnetic force.

The rotor 50 is fixed to and rotates on the rotation shaft 10 and may be made of a plurality of inward-facing magnets.

The external stator 60 and the internal rotor 70 are fixedly supported by an external device, etc., and are composed of a fixed coil body that is arranged to face each other in accordance with the arrangement of a plurality of internal magnets.

The rotation of the inward-facing magnet of the rotor 50 generates an induced current in the fixed coils of the external stator 60 and the internal stator 70, thereby generating power.

FIG. 2 is an exemplary diagram of the rotating body 20 and the fixed body 30 of the power generation device 1 using magnetic force of FIG. 1.

As shown in FIG. 2, the internal fixture 30 has a sawtooth or rotating knife shape with an outer cross-section that is car-shaped, and the spacing becomes close along the clockwise direction with respect to the inner surface of the rotating body 20. The section that moves away has a repetitive shape. In addition, as a result, magnets having the same N-pole magnetic force are disposed on the outside of the stationary body 30 and the inside of the rotating body 20, so that rotation occurs in a counterclockwise direction due to mutual repulsion.

For example, when the magnet part is made of an electromagnet or a permanent magnet stationary coil, when power is applied to the electromagnet or a permanent magnet stationary coil, the magnetic force of the stationary body 30 becomes strong, causing the rotating body 20 to rotate at high speed and the rotating body 20 ), an induced current is generated in the fixed coil due to the rotation of the coil, thereby generating power. Some of the power generated in this way is supplied to the electromagnet or permanent magnet fixed coil, and some can be withdrawn outside the electromagnet and stored in a storage battery, etc., or transferred to the outside through a wire.

When electricity is applied from the internal rotor 70 to the electromagnet or permanent magnet stationary coil due to the rotational force of the rotating body 20 and the fixed body 30, the magnetic force of the fixed body 30 becomes strong and the rotating body 20 ) is rotated at high speed, and an induced current is generated in the external stator 60 and the internal regulator 70 of the fixed coil body due to the rotation of the rotating body 20, thereby generating power. The power generated in the internal stator 70 is applied to the stationary body 30, which is an electromagnet or a permanent magnet stationary coil, and the power generated in the external stator 60 is drawn to the outside and stored in a storage battery, etc. or transmitted to the outside through a wire.

Figure 3 is an exemplary diagram of a deformable rotating body 20 and a fixed body 30.

The inclined extension surface 22 of the rotating body 20 and the opposing inclined surface 32 of the fixed body 30 are arranged to face each other. In the area of the inclined extension surface 22 of the rotating body 20 and the opposing inclined surface 32 of the fixed body 30, directional magnets 40 and 41 are arranged in opposing directions, and repulsive force is output in opposing directions. . As a result, the rotating body 20 disposed on the outside rotates clockwise. The positions of the rotating body 20 and the fixed body 30 may be changed.

When the fixture 30 is on the outside and the rotation 20 is on the inside, A1 and A2 may be parallel, but A1 may be inclined more to the right than A2. This has the same meaning as saying that the angle of R2 is larger than that of R1. As a result, an inward repulsive force is formed close to the axis of the inner rotating body, so the rotational efficiency of the rotating body can be improved.

Modifiable embodiments other than the above embodiments will be described.

In the above embodiment, the directional magnets are disposed one by one on the inclined extension surface 22 of the rotating body 20 and the opposing inclined surface 32 of the fixture 30, but the directional magnets are disposed on the inclined extending surface 22 of the rotating body 20. A plurality of them may be arranged to face each other on the opposing inclined surface 32 of the fixture 30 (22).

The number of directional magnets arranged opposite to each other may be arranged to be inclined in the direction of rotation as it increases along the direction of rotation. For example, on the left side of the inclined extension surface, a directional magnet is placed perpendicular to the inclined extension surface, that is, the directional magnet is arranged at a left angle of 90 degrees with the inclined surface, and the directional magnet on the right is placed at a left angle of 93 degrees with the inclined surface, Then, the directional magnet on the right can be placed at a left angle of 95 degrees with the inclined surface. This allows the repulsive force to efficiently rotate the rotating body.

When the rotating body is placed on the inside and the fixture is placed on the outside, the central area of the cross section of the rotating body may be made of a heavy material that increases the rotating inertial force.

In the power generation device 1 using magnetic force, the outer cross-sectional shapes of the rotating body 20 and the stationary body 30 are arranged to face each other in a waveform, so that the repulsive force of the magnets acts in the rotation direction of the rotating body 20. Therefore, power generation efficiency can be improved. In addition, power generation efficiency is significantly improved by allowing the repulsive force of the directional magnet to be applied along the rotation direction of the rotating body 20.

1: Power generation device using magnetic power
10: rotation axis
20: rotating body 21: rotating body
22: Inclined extension surface
30: fixture 31: fixture body
32: Opposite slope
40: Magnet portion 41: Directional magnet
50: rotor
60: external stator 70: internal stator

Claims (5)

In a power generation device using magnetic power,
axis of rotation;
A rotating body coupled to the outer surface of the rotating shaft and having a radial cross-sectional shape centered on the axis of the rotating shaft, the outline of which forms a wave-shaped cross-sectional shape along the circumferential direction;
a fixture having a wave-shaped cross-sectional shape opposite to the wave-shaped cross-sectional shape of the rotating body and disposed outside the rotating body;
a rotor including an external stator fixed to the rotation shaft and configured to rotate, and an internal rotor rotatably coupled to the rotation shaft; and
A magnet unit including a plurality of magnets disposed so that mutual repulsive force is applied to cross sections opposing the rotating body and the stationary body,
A power generation device using magnetic force, characterized in that the power generated by the internal rotor is applied to the fixture according to the rotation of the rotation shaft.
According to claim 1,
The magnet part,
A power generation device using magnetic force, characterized in that it includes at least one of a permanent magnet and an electromagnet.
According to claim 1,
The magnet part,
A power generation device using magnetic force, characterized in that it consists of a directional magnet that outputs directional magnetic force.
According to claim 1,
The cross-sectional shape of the rotating body has a plurality of inclined extension surfaces extending obliquely in the direction of rotation of the rotating body with respect to an outward line connecting the axis of the rotating shaft to the outer surface,
The cross-sectional shape of the fixture has a plurality of opposing inclined surfaces formed to face the plurality of inclined extension surfaces,
A power generation device using magnetic force, wherein the plurality of magnets are disposed on the plurality of inclined extension surfaces and the plurality of opposing inclined surfaces so that the same magnetic force is output in mutual directions.
According to clause 4,
A power generation device using magnetic force, wherein the plurality of opposing inclined surfaces are formed to be more inclined at least in the rotation direction of the rotating body than the plurality of inclined extending surfaces.