KR101335556B1 - The generator with high efficiency - Google Patents

Abstract

The present invention relates to a high-efficiency generator. The high-efficiency generator of the present invention comprises a case; a first rotor which has an armature, passes through inside the case to rotate, and receives power from a motor for rotation; a second rotor which has a field magnet, surrounds the first rotor to rotate with regard to the first rotor, receives the power of the first rotor from a power transfer member, and makes electromagnetic induction by interaction and reaction with the first rotor; and the power transfer member which is connected to the first rotor and the second rotor, passes through inside the case to rotate, and transfers the power of a motor transferred to the first rotor to the second rotor. The present invention provides a high-efficiency generator with excellent power generation efficiency using even less power than conventional energy by having a stable sine wave as the first rotor and the second rotor are rotated in the same direction, wherein the rotation speed of the first rotor having an armature for increasing energy conversion efficiency increases by lowering the resistance of the rotor is defferent from the rotation speed of the second rotor having a field magnet, and increasing rotational inertia through the changed reaction of repulsion and gravitation which plays a role as a resistor between the first rotor and the second rotor.

Description

{GENERATOR WITH HIGH EFFICIENCY}

The present invention relates to a high-efficiency generator, and more particularly, in order to lower the resistance of the rotor to increase energy conversion efficiency, the first rotor having the armature and the second rotor having the field are the same with respect to the rotational speed. It rotates in the direction to have a stable sine wave, and increases the rotational inertia through the reaction of changing repulsive force and attraction force acting as a resistance between the first rotor and the second rotor. It is about an excellent high efficiency generator.

In general, a generator is a device that generates electrical energy by consuming mechanical energy.

Most of such generators are rotating machines, and there are revolving field type and rotating electric machine type.

Rotating field magnets are generators whose conductors are stationary and magnets rotate. Rotating armatures are the opposite.
These generators are a principle of obtaining electricity by generating electromagnetic induction with each other by selecting and rotating any one selected from a conductor or a magnet as a rotor and fixing one not selected as a stator.
For example, Korean Patent Publication No. 10-1141658 discloses a high efficiency generator having a rotation field type.

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However, a generator using electromagnetic induction as described above has an energy conversion efficiency, which is a ratio of output energy to input energy consumed by induction electricity (voltage and current) generated to interfere with the rotational motion of the rotor (repulsion and attraction). Only 35% of the energy conversion efficiency has been a problem.

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The present invention is to solve the above problems, in order to lower the resistance of the rotor to increase the energy conversion efficiency, both the first rotor having an armature and the second rotor having a field in the same direction with the difference in the rotational speed Rotational inertia through stable reactions and stable reaction force between the first and second rotors and the reaction of changing repulsive force and attraction force as the resistance between the first and second rotors. To provide a high efficiency generator.

In addition, it is to provide a high-efficiency generator with low cost and simple structure, excellent durability and economy.

High efficiency generator of the present invention for achieving the above object is a case; A first rotor having an armature and installed to rotate through the inside of the case and rotated by receiving power from a motor; It has a field and is installed to be wrapped around the first rotor to rotate relative to the first rotor to generate electromagnetic induction by interacting with the first rotor due to the rotational movement received from the power transmission member the power of the first rotor. A second rotor for causing; A power transmission member connected to the first rotor and the second rotor and installed to rotate through the inside of the case to transmit power of a motor transmitted to the first rotor to the second rotor; .

The first rotor, the first gear is fixed to the first axis of rotation, one end of the first axis of rotation, the armature wound around the conductor is installed to penetrate the first axis of rotation at a predetermined distance from the first gear Preferably, a plurality of brushes are installed to penetrate the first rotary shaft at a predetermined distance from the armature, and have a plurality of slip rings.

The second rotor may be a field having a second rotation shaft, a second gear fixed to one end of the second rotation shaft, and a magnet fixed to the second rotation shaft at a predetermined distance from the second gear. It is preferable to make.

The power transmission member may include a third gear that is fixed to the third rotation shaft, one end of the third rotation shaft, and a third gear that is fixed to the third rotation shaft at a predetermined distance from the third gear. It is preferable to consist of four gears.

According to the present invention, the first rotor having an armature and the second rotor having a field are rotated in the same direction with a difference in rotational speed in order to increase the energy conversion efficiency by lowering the resistance of the rotor. In addition to having a sine wave, by increasing the rotational inertia through the reaction of the changing repulsive force and attraction force acting as a resistance between the first rotor, the second rotor, there is an excellent power generation efficiency with less power energy than conventional.

In addition, the price is low and the structure is simple, so there is an effect of excellent durability and economy.

1 is a perspective view of a high efficiency generator of the present invention.
2 is a plan sectional view of the high efficiency generator of the present invention.
3 is a detailed view of a first rotor of the high efficiency generator of the present invention.
4 is a side cross-sectional view of the high efficiency generator of the present invention.
5 is a process chart of one cycle (rotation) of the second rotor of the high-efficiency generator of the present invention.

The high-efficiency generator of the present invention has a mechanism such that both the first rotor with the armature and the second rotor with the field are rotatable in the same direction with a difference in rotation speed in order to increase the energy conversion efficiency by lowering the resistance of the rotor. Formed academically, the rotational inertia is increased through the reaction of changing repulsive force and attraction force acting as a resistance between the first and second rotors, thereby improving the power generation efficiency with less power energy than before.

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

1 is a perspective view of a high efficiency generator of the present invention, FIG. 2 is a sectional plan view of the high efficiency generator of the present invention, FIG. 3 is a detailed view of the first rotor of the high efficiency generator of the present invention, and FIG. 4 is a side sectional view of the high efficiency generator of the present invention. 5 is a diagram showing a process of one cycle (rotation) of the second rotor of the high-efficiency generator of the present invention.

1 to 5, the high efficiency generator of the present invention comprises a case 10, the first rotor 20, the second rotor 30, the power transmission member 40.

The case 10 is made of a structure having an empty space therein, preferably made of a non-conductive material.

The first rotor 20 has an armature 21 and is installed to rotate through the inside of the case 10.

At this time, the first rotor 20 is rotated by receiving power from the motor A to obtain power from the outside,

The first rotor 20 includes an armature 21, a first rotating shaft 23, a first gear 25, and a brush 27.

The armature 21 is a cylindrical shape in which the wire 21a is wound, the mass of which will be described later, is heavier than the field, and interacts with the magnet 31a of the second rotor 30 to generate electromagnetic induction. The generated electrical energy is output to the outside through the wire.

In this case, the amount of electrical energy varies depending on the number and thickness of the wound wire 21a.

The first rotating shaft 23 is installed to rotate through the inside of the case 10 in a circular rod shape having a length.

The first gear 25 is fixedly installed at one end of the first rotation shaft 23, and is installed to penetrate the first rotation shaft 23 so as to be rotatable along the first rotation shaft 23.

A plurality of brushes 27 are installed to penetrate and be fixed to the first rotation shaft 23 at a predetermined distance from the armature 21, and are rotatably installed along the first rotation shaft 23.

The brushes 27 have a plurality of slip rings 27a and are installed to be connected to the conductive wires 21a so that when the armature 21 rotates along the first rotational shaft 23, the conductive wires 21a also rotate together. This prevents twisting of the conductive wire 21a.

The second rotor 30 has a field 31 and is installed to surround the first rotor 20 so as to rotate about the first rotor 20.

That is, the second rotor 30 is installed to be engaged with the fourth gear 55 of the power transmission member 40, which will be described later, and receives the rotational kinetic energy of the fourth gear 55 to receive the first rotor 20. And rotates together with the first rotor 20 to generate electromagnetic induction.

At this time, the second rotor 30 has a rotation ratio of 4 (first rotor): 1 (second rotor) relative to the first rotor 20.

The second rotor 30 includes a field 31, a second rotating shaft 33, and a second gear 35.

The field 31 has a cylindrical shape having arc-shaped magnets 31a having two different magnetic poles at left and right ends thereof, and is lighter in mass than the armature 21.

In this case, the magnets 31a are preferably permanent magnets.

The second rotating shaft 33 is installed in a circular rod shape having an empty length to surround the first rotating shaft 23 and rotatably installed with respect to the first rotating shaft 23.

The second gear 35 is fixed to one end of the second rotary shaft 33, is installed to penetrate the second rotary shaft 33 is rotatably installed along the second rotary shaft 33, which will be described later In order to be engaged with the fourth gear 55 of the power transmission member 40.

At this time, it is preferable that the second gear 35 has a larger diameter than the first gear 25.

The power transmission member 40 is connected to the first rotor 20 and the second rotor 30, but is installed to rotate through the inside of the case 10 to be transmitted to the first rotor 20. Installed to transmit the power of the motor A to the second rotor (30).

The power transmission member 40 includes a third rotation shaft 43, a third gear 45, and a fourth gear 55.

The third rotation shaft 43 is installed to rotate through the inside of the case 10 in a circular rod shape having a length.

The third gear 45 is fixedly engaged with the first gear 25 at one end of the third rotation shaft 43 and rotates together with the first gear 25 that is rotated by receiving power from the motor A.

The fourth gear 55 penetrates the third rotation shaft 43 at a predetermined distance from the third gear 45 and is fixedly engaged with the second gear 35 to rotate by being powered by the motor A. FIG. The rotational kinetic energy is transmitted to the second gear 35 by being rotated together with the first gear 25.

Looking at such a method of operation of the present invention,

When the first rotor 20 starts to rotate rapidly by the motor A, the first rotor 20 is rotated a second time through the power transmission member 40 installed to be connected to the first rotor 20 and the second rotor 30. The electron 30 rotates slowly in the same direction with a time difference from the first rotor 20, and the rotation ratio at this time is 4 (first rotor): 1 (second rotor).

Looking at the above power transmission process in more detail,

The first gear 25 directly connected to the first rotating shaft 23 is rotated by the motor A to rotate the armature 21 wound around the conductive wire 21a in a clockwise direction, and the first gear 25 The third gear and the fourth gear directly engaged with the third rotary shaft start to rotate counterclockwise in the reverse direction of the first rotary shaft, and the second gear meshed with the fourth gear in the clockwise direction opposite to the third rotary shaft. The rotation is performed, and the second rotation shaft directly connected to the second gear, the field having a magnet, and the brushes are started to rotate in the same direction as the first rotation shaft with a difference in rotation speed.

At this time, the first rotor and the second rotor is different in gear ratio of the first gear to the fourth gear in order to make a difference in the rotational speed of 4 (first rotor): 1 (second rotor) in the same direction. do.

Then, the first and second rotors are gradually reversed in the forward and backward positions with time difference, and the power consumption is reduced compared to the conventional one by reducing the repulsive force and the resistance of manpower when electricity is generated.

The process is shown in 5 (a) to 5 (h) of FIG.

The magnet N (S) pole provided in the field of the second rotor in the clockwise direction is slowly moved eight times at 45 degrees at a rotation ratio of 4 (first rotor): 1 (second rotor), and the first rotation is performed. The armature, in which the wire of one rotor is wound, is also made eight times, that is, four turns by 180 degrees.

In other words,

FIG. 5 (a) shows that the armature of the first rotor and the magnet N (S) pole of the second rotor are horizontal.

Fig. 5 (b) shows that when the armature of the first rotor moves 180 degrees, that is, half a turn, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 1/8 of a turn,

Fig. 5 (c) shows that when the armature of the first rotor moves 180 degrees, that is, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 2/8 of a turn,

Fig. 5 (d) shows that when the armature of the first rotor moves 180 degrees, that is, one and a half turns, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 3/8 of a turn. ,

5 (e) shows that when the armature of the first rotor moves 180 degrees, that is, two wheels, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 4/8 of a turn,

Fig. 5 (f) shows that when the armature of the first rotor moves 180 degrees, that is, two and a half turns, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 5/8 of a turn. ,

Fig. 5 (g) shows that when the armature of the first rotor moves 180 degrees, that is, three wheels, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 6/8 of a turn,

Fig. 5 (h) shows that when the armature of the first rotor moves 180 degrees, that is, three and a half turns, the magnet N (S) pole of the second rotor moves 45 degrees, that is, 7/8 of a turn. .

As shown in FIGS. 5 (a) to 5 (h), when the armature of the conductor wire wound during the power generation is rotated by the action of resistance by 180 degrees, the magnet N (S) provided in the field is also rotated by 45 degrees at the same time. Rotation is formed to enable the reaction (resistance according to the rotational motion of the first rotor, the second rotor) of the armature by the resistance action of the repulsive force and the attraction force has an excellent power generation efficiency with less power energy than conventional.

According to the present invention, in order to lower the resistance of the rotor to increase energy conversion efficiency, the first rotor having the armature and the second rotor having the field are all rotated in the same direction with a difference in the rotational speed to have a stable sinusoidal wave. In addition, by increasing the rotational inertia through the reaction of the changing repulsive force and the attraction force acting as a resistance between the first rotor, the second rotor provides a high efficiency generator with excellent power generation efficiency even with less power energy than conventional.

In addition, the low cost and simple structure provides a highly efficient generator with excellent durability and economy.

Case: 10
First rotor: 20
Armature: 21
Lead wire: 21a
1st axis of rotation: 23
1st gear: 25
Brush: 27
Slip ring: 27a
Second rotor: 30
Field: 31
Magnet: 31a
Second axis of rotation: 33
Second gear: 35
Power transmission member: 40
Third rotating shaft: 43
Third gear: 45
4th Gear: 55
Motor: A

Claims (4)

A case 10;
A first rotor (20) having an armature (21) and installed to be rotated through the inside of the case (10) to receive a power from a motor (A);
It has a field 31 and is wrapped around the first rotor 20 is installed to rotate about the first rotor 20 is rotated by receiving the power of the first rotor 20 from the power transmission member 40 The second rotor 30 to generate an electromagnetic induction by interacting with and reacting with the first rotor 20;
Power of the motor A connected to the first rotor 20 and the second rotor 30 and installed to penetrate the inside of the case 10 and rotated to be transmitted to the first rotor 20. A power transmission member 40 for transmitting the power to the second rotor 30; And,
The first rotor 20,
The first rotary shaft 23, the first gear 25 is fixed to one end of the first rotary shaft 23, and penetrates the first rotary shaft 23 at a predetermined distance from the first gear 25 The armature 21, which is fixedly installed, is wound around the armature 21 wound around the armature 21, and a plurality of slip rings 27a are installed to penetrate and be fixed to the first rotating shaft 23 at a predetermined distance from the armature 21. Consisting of brushes 27 with
The second rotor 30,
The second rotation shaft 33, the second gear 35 is fixed to one end of the second rotation shaft 33, the second gear 35 to be fixed to the second rotation shaft 33 at a predetermined distance from the It consists of a field 31 having magnets 31a to be installed,
The power transmission member 40,
A third gear 45 which is fixed to the third rotary shaft 43, one end of the third rotary shaft 43 and the third rotary shaft 43, and a third distance from the third gear 45 at a predetermined distance; High efficiency generator, characterized in that consisting of the fourth gear 55 is fixed to the rotating shaft 43. delete delete delete

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