KR20230149732A - Power generation device with improved output - Google Patents

Abstract

The present invention relates to a power generation device with improved output, comprising: a rotating shaft portion connected to a generator on one side and having a set length and diameter; a housing portion positioned adjacent to the generator at a distance from the generator and rotating in the same manner as the housing portion supported by the rotating shaft; a first pillar movably penetrating guide holes formed at both ends of the housing unit, and a weight rotation unit including weights provided at both ends of the first pillar; It is provided in the housing part with a gap from the weight rotating part, and has a second pillar, a third magnetic body part provided on both ends of the second pillar, and a gap with the third magnetic body part and is fixedly installed on the third quadrant side with the rotation axis as the center. It is provided with an auxiliary output enhancer including an auxiliary rotating part with a third fixed magnetic body.

Description

Power generation device with improved output {POWER GENERATION DEVICE WITH IMPROVED OUTPUT}

The present invention relates to a power generation device with improved output, and more specifically, to increase the rotational force of the rotation shaft while offsetting the force applied to the rotation shaft, and to increase the overall output by moving the weight according to rotation to form an eccentricity in the direction of rotation. It is about a power generation device that has improved.

In general, electrical energy is produced through renewable energy using natural phenomena such as hydropower, wind power, tidal power, and solar power, thermal power generation using fuel such as coal and oil, or nuclear power plant using nuclear fission.

First, in the case of thermal power generation, there is a problem that the smoke produced when heating solid fuel pollutes the air. In the case of nuclear power generation using nuclear fission, production efficiency is high, but the number is gradually decreasing due to the risk of accidents and problems with disposal of fuel rods remaining after production.

In addition, new and renewable energy has the disadvantage of causing relatively less environmental pollution compared to thermal or nuclear power generation, limited installation locations, and high installation costs.

A prior art proposed to make up for the shortcomings of such conventional methods of producing electric energy is “Non-power electric energy generation method and device” of Republic of Korea Patent No. 10-0743571 (July 23, 2007).

It generates electric energy by forming a small power generation unit with a floating pendulum that moves according to the action of gravity by the shaking naturally produced when carried without an external paid power supply, and supplies the electric energy to portable electronic devices. It is a disk-shaped device with a space inside. It consists of a floating pendulum with a formed stator and a permanent magnet installed inside the stator that rotates due to external shaking (vibration).

In addition, the floating pendulum is a spread out fan-shaped pendulum that easily moves along the center of gravity due to the action of gravity. On one side of the long arc, a convex round weight is formed to have a constant weight to add additional rotational force to the movement force of the floating pendulum. A power transmission unit is formed on the central axis of movement of the ruler. In addition, the stator forms an interior with a round shape similar to the shape of the weight so that the weight of the floating pendulum can rotate as close to three-dimensionally as possible, and provides a configuration in which a coil is installed on a core formed on the inner side of the stator.

However, in this prior art, the structure is complicated, so durability is weak, each structure is placed close to each other, so it is easily damaged, and the internal temperature rises during operation, which may cause a fire.

On the other hand, a conventional generator composed of a known rotor and a stator forms induced electromotive force and generates power through the rotation of the rotor, but a typical generator operates in a direction that reduces torque, that is, in a direction that hinders power generation. Generates back electromotive force.

Therefore, there is a loss in the power generated from the generator, and there is a problem that the generator stops operating if a force greater than the force generated by the back electromotive force is not continuously provided from the outside.

Republic of Korea Patent No. 10-0743571 (2007.07.23)

The purpose of the present invention is to provide a power generation device that improves overall output by increasing the rotational force of the rotating shaft while offsetting the force applied to the rotating shaft, and moving the weight according to rotation to form an eccentricity in the rotation direction.

A power generation device with improved output according to an embodiment of the present invention includes a rotating shaft portion connected to a generator on one side and having a set length and diameter; a housing portion positioned adjacent to the generator at a distance from the generator and rotating in the same manner as the housing portion supported by the rotating shaft; a first pillar movably penetrating guide holes formed at both ends of the housing unit, and a weight rotation unit including weights provided at both ends of the first pillar; It is provided in the housing part with a gap from the weight rotating part, and has a second pillar, a third magnetic body part provided on both ends of the second pillar, and a gap with the third magnetic body part and is fixedly installed on the third quadrant side with the rotation axis as the center. An auxiliary rotating part having a third fixed magnetic body, a rotation control part provided in the housing with a gap in the same direction as the auxiliary rotating part, and having a third pillar and a fourth magnetic body part provided at both ends of the third pillar, and an auxiliary rotation control part. An auxiliary output enhancer that is provided in the housing with a gap between the rotating part and the rotation control part in the same direction as the auxiliary rotating part, and includes an additional auxiliary rotating part including a fourth pillar and a fifth magnetic body part provided at both ends of the fourth pillar. It is provided with a rotation control unit, a rack gear formed along the longitudinal direction of the third column, a pinion gear portion that is fixedly installed and rotates in engagement with the rack gear, a connecting rod that is extended and connected to the rotation axis of the pinion gear portion and rotates, and a connecting rod of the connecting rod. It includes a first moving magnetic material formed at an end and a second moving magnetic material attached to one end of the rack gear.

Here, the weight rotating portion penetrates the first long hole in the longitudinal direction of the first pillar, and the housing portion further forms a guide rod that is fixedly installed and penetrates the first long hole in the internal space.

In addition, in the rotation control unit, as the rack gear and the pinion gear engage, the first moving magnetic body rotates to exert an attractive force on the fourth magnetic body having a polarity different from that of the first moving magnetic body, and the second moving magnetic body moves to form the second moving magnetic body. 2 A repulsive force acts with the fifth magnetic body portion having the same polarity as the moving magnetic body.

The present invention increases the rotational force of the rotating shaft even in a simple structure that reduces the weight by placing a magnetic body portion that rotates by magnetic force on one side of the rotating shaft and a rotating magnetic body with a centrifugal weight formed on the other side of the rotating shaft inside the fixed magnetic body, which is connected to one side of the rotating shaft. It has the effect of increasing the output of the generator.

The present invention has the effect of increasing the rotational force of the rotating magnetic body portion by forming the rotating shaft portion with a predetermined diameter to reduce air resistance.

The present invention consists of a housing part, a weight rotation part, an auxiliary rotation part, and a rotation control part, and moves the weight of the weight rotation part to form an eccentricity in the circumferential direction of the rotation axis part, thereby amplifying the rotation of the rotation axis part to increase output. It has an effect.

1 is a schematic diagram of a power generation device with improved output according to an embodiment of the present invention.
Figure 2 is a plan view of Figure 1.
Figure 3 is a perspective view showing a rotating magnetic body portion of a power generation device with improved output according to an embodiment of the present invention.
Figure 4 is a schematic diagram showing an example of an auxiliary output enhancer in a power generation device with improved output according to another embodiment of the present invention.
Figure 5 is a schematic diagram showing the weight movement according to the rotation of the weight rotating part applied to Figure 4.
Figure 6 is a schematic diagram showing an example of a weight rotation unit applied to Figure 4.
Figure 7 is a schematic diagram illustrating the principle that the first moving magnetic body and the second moving magnetic body move according to the movement of the rack gear according to another embodiment of the present invention and the magnetic force acts on the fourth magnetic body portion and the fifth magnetic body portion, respectively. am.
Figure 8 is a schematic diagram showing the rotation-dependent operation of the auxiliary rotation unit and rotation control unit applied to Figure 4.

The advantages and features of the present invention and methods for achieving them will become clear with reference to the embodiments described below along with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms. Only the examples are provided to make the disclosure of the present invention complete and to fully convey the scope of the invention to those skilled in the art to which the present invention pertains, and the present invention is defined by the scope of the claims. It's just that.

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

Figure 1 is a schematic diagram of a power generation device with improved output according to an embodiment of the present invention, Figure 2 is a plan view showing Figure 1 in plan, and Figure 3 is a power generation device with improved output according to an embodiment of the present invention. This is a perspective view showing the rotating magnetic body part.

As shown in FIG. 1, the power generation device 10 with improved output according to an embodiment of the present invention includes a motor 220, a rotating shaft 200, and a generator 210, and the generator 210 To improve output by including a stationary magnetic body 100 and a rotating magnetic body 300 to offset the force applied to the rotating shaft 200 by the back electromotive force or to increase the rotational force of the rotating shaft 200. Compose.

In detail, as shown in FIG. 1, the power generation device 10 with improved output according to an embodiment of the present invention has a set length where one side is connected to the generator 210 and the motor 220 is connected to the other side. A fixed magnetic body 100 in the shape of a tube surrounding the rotating shaft 200 as a central axis is formed of a rotating shaft portion 200 having a diameter and a magnetic material having magnetic force with the same polarity on one side of the generator 210, and is fixed. It includes a rotating magnetic body portion 300 formed on the rotating shaft portion 200 to amplify the rotation of the rotating shaft portion 200 by the magnetic force of the magnetic material 100.

Referring to Figures 1 and 2, the stationary magnetic body 100 is formed as a tube having magnetic force with the same polarity on the inside.

This fixed magnetic body 100 has a shape that surrounds the rotating shaft portion 200 around the central axis. In one embodiment, the fixed magnetic materials 100 are arranged in a cylindrical shape facing each other and spaced apart from each other, and can be formed with magnetic forces of the same polarity.

In addition, the fixed magnetic body 100 produces kinetic energy and may further include a cover C surrounding the outer surface.

Here, the cover body C is closed at both ends and may be shaped like a cylindrical or square box surrounding the stationary magnetic body 100.

In addition, the cover body C may have a hole penetrating the portion where the rotating shaft 200 is located, and a bearing may be formed along the inner peripheral surface of the hole.

Referring to Figures 1 and 2, one side of the rotating shaft unit 200 is connected to the generator 210 and is located on the central axis of the stationary magnetic body 100, and the motor 220 is connected to the other side.

In particular, the rotation shaft portion 200 is formed as a lightweight shaft with a preset length and diameter, thereby saving initial energy consumption for rotation. Also, when applying a general rotation speed even during continuous rotation, a rotation speed with a higher rotation force can be obtained compared to a shaft with a wider diameter and a heavier weight.

In addition, the rotating shaft portion 200 serves to generate induced electromotive force inside the generator 210, and it is desirable to install a winding on one side.

Meanwhile, the generator 210 is generally formed of a rotor including a permanent magnet or an electromagnet and a stator including a winding in which induced electromotive force is generated when the rotor rotates.

In addition, the generator 210 is shown to be smaller than the diameter of the fixed magnetic body 100 in the drawings of the specification, but may be formed to have the same diameter as the fixed magnetic body 100. And it is preferable that it is formed surrounded by the cover body (C).

Here, the rotor is on one side of the rotating shaft 200, and induced electromotive force can be obtained from the generator 210 by the rotational force of the rotating shaft 200.

For this purpose, a rotating magnetic body portion 300, which will be described later, is formed on the rotating shaft portion 200.

The motor 220 is connected to the other side of the rotation shaft 200 and serves to rotate the rotation shaft 200 in one direction.

At this time, the motor 220 receives external power to provide rotational force, and when the rotational force of the rotating shaft portion 200 is increased by the rotating magnetic body portion 300, the external power is temporarily stopped or the rotational force is reduced. It may further include a control unit.

Referring to FIGS. 2 and 3 , the rotating magnetic body portion 300 is formed on the rotating shaft portion 200 to amplify (increase) the rotation of the rotating shaft portion 200 by the magnetic force of the stationary magnetic material 100.

To this end, the rotating magnetic body unit 300 further includes a magnetic body unit 310 and a centrifugal weight 320.

The magnetic body portion 310 is formed of a magnetic material of the same polarity as the fixed magnetic body 100 on one side of the rotating shaft portion 200 in the longitudinal direction.

In particular, the magnetic body portion 310 extends in the longitudinal direction and is located adjacent to the inside of the fixed magnetic body 100, so that a pushing force is applied by magnetic forces of the same polarity. For this reason, when a force of 1 is applied to the rotation of the rotation shaft 200 according to the operation of the motor 220, the rotational force may be increased to a force of 2.

The centrifugal weight 320 is formed on the other side of the rotating shaft 200 in the longitudinal direction and serves to generate centrifugal force in response to the rotation of the rotating shaft 200.

In particular, the centrifugal weight 320 is preferably formed to have a weight equal to or heavier than the magnetic body portion 310 to form an eccentricity in the circumferential direction of the rotation direction to reduce air resistance of the magnetic body portion 310.

This centrifugal weight 320 is positioned facing the magnetic body portion 310 with the rotation shaft portion 200 in between, and extends in the longitudinal direction to be located adjacent to the inside of the stationary magnetic body 100.

In addition, the centrifugal weight 320 serves to further increase the rotational force of the magnetic body portion 310 through centrifugal force generated by the rotation of the rotation shaft portion 200.

In addition, in the power generation device 10 with improved output according to an embodiment of the present invention, the rotating magnetic body portion 300 further includes a first connection portion 311 and a second connection portion 321 as shown in FIG. 3. It can be included.

The first connection part 311 extends from one side in the longitudinal direction of the rotation shaft part 200 and connects the magnetic body part 310.

Here, the first connection portion 311 is formed as a lightweight shaft with a predetermined diameter and can reduce air resistance by reducing air friction due to rotation.

The second connection portion 321 extends from the other longitudinal side of the rotating shaft portion 200 and connects the centrifugal weight 320.

Meanwhile, the power generation device 10 with improved output according to an embodiment of the present invention may further include a battery 400 as shown in FIGS. 1 and 2.

The battery 400 charges electromotive force generated from the generator 210 and may be equipped with a converter that converts rotational energy into electrical energy.

This battery 400 may further include a plurality of terminals to apply power to portable electronic devices.

Figure 4 is a schematic diagram showing an example of an auxiliary output enhancer in a power generation device with improved output according to another embodiment of the present invention. Figure 5 is a schematic diagram showing the weight movement according to the rotation of the weight rotating part applied to Figure 4. Figure 6 is a schematic diagram showing an example of a weight rotation unit applied to Figure 4. Figure 7 is a schematic diagram illustrating the principle that the first moving magnetic body and the second moving magnetic body move according to the movement of the rack gear according to another embodiment of the present invention and the magnetic force acts on the fourth magnetic body portion and the fifth magnetic body portion, respectively. am. Figure 8 is a schematic diagram showing the rotation-dependent operation of the auxiliary rotation unit and rotation control unit applied to Figure 4.

Meanwhile, referring to FIGS. 4 to 8, in another embodiment, the output device 10 with improved output according to the present invention has a structure of a fixed magnetic body and a rotating magnetic body unit configured with the rotating shaft unit 200 as the central axis, and It can be configured to further include an auxiliary output enhancer 700 adjacent to the structure of the generator 210 and spaced apart.

The auxiliary output enhancer 700 momentarily moves the weight 720 having a set weight in the rotation direction when the rotation shaft portion 200 rotates to further form eccentricity in the circumferential direction of the rotation direction. By doing so, the rotation of the rotary shaft unit 200 can be further amplified to further amplify the output of the entire power generation device.

In an embodiment for this purpose, referring to FIG. 4, in the power generation device 10 with improved output, the auxiliary output enhancer 700 is spaced apart from the generator 210, the stationary magnetic body 100, and the rotating magnetic body portion 300. It is configured at a neighboring position in the axial direction.

The auxiliary output enhancer 700 largely has a structure including a housing portion 710, a weight rotating portion (D), an auxiliary rotating portion (E), and an additional auxiliary rotating portion (G).

The housing part 710 is supported on the rotating shaft part 200 and rotates equally, and has an internal space for the provision and operation of the weight rotating part (D), the auxiliary rotating part (E), and the additional auxiliary rotating part (G), and the necessary Depending on the shape, it may take the form of a cylindrical or square box. In Figure 4, the shape of the housing portion 710 is shown as a rectangular box as an example, but it is not limited thereto.

This housing portion 710 is integrated with the rotation shaft portion 200 and has a structure that rotates together with the rotation shaft portion 200.

In addition, the weight rotating part (D) includes a first pillar 721 movably penetrating the guide hole (h) formed at both ends of the housing part 710, and a first pillar 721 provided at both ends of the first pillar 721. It has a structure including a weight 720.

This weight rotating part (D) rotates together when the housing part 710 rotates according to the rotation of the rotating shaft part 200. As the weight 720 passes from the first quadrant to the fourth quadrant, the rotating force and weight It moves by being tilted downward.

At this time, the first pillar 721 is supported by the guide hole (h) and moves along it, causing the weight 720 to be tilted to one side (see Figure 5).

As the weight 720 moves, the weight is moved and an eccentricity is formed in the circumferential direction of the rotational shaft portion 200, thereby amplifying the rotation of the rotating shaft portion.

The movement of the weight 720 moves up and down along the guide hole (h) like a piston movement.

Meanwhile, referring to FIG. 6, the weight rotating part D penetrates the first long hole 721a in the longitudinal direction of the first pillar 721 for stable movement. In addition, the housing portion 710 further forms a guide rod 711 fixedly installed while penetrating the first long hole 721a in the internal space. Of course, if necessary, a plurality of the first long hole 721a and the guide rod 711 can be formed as one set depending on the length or weight of the first pillar 721.

According to this structure of the first long hole 721a and the guide rod 711, the weight rotating part D is prevented from being separated from the housing part 710 and more stable operation is possible.

Meanwhile, the rotational amplification movement caused by the movement of the weight 720 of the weight rotation unit D inevitably requires force when the weight 720 moves from the third quadrant to the second quadrant due to gravity.

Of course, the rotating shaft unit 200 can rotate by receiving continuous rotational amplification force, but the weight 720 of the rotating weight unit D is inevitably affected by gravity.

In order to assist the movement of the weight rotating part (D), an auxiliary rotating part (E) and an additional auxiliary rotating part (G) are included to make it easier to rotate the weight rotating part (D) in the third quadrant by using the attraction between magnetic materials. do.

Referring to Figure 4, in one embodiment, the auxiliary rotating part (E) is provided in the housing 710 at a distance from the heavy rotating part (D). And, the auxiliary rotating part (E) has a gap between the second pillar 731, the third magnetic body part 730 provided at both ends of the second pillar 731, and the third magnetic body part 730, and the rotation axis part ( 200) and includes a third fixed magnetic body 750 fixedly installed on the third quadrant side.

At this time, the third magnetic body portion 730 and the third fixed magnetic body 750 have different polarities and exert an attractive force to attract each other.

In addition, the additional auxiliary rotating part (G) is provided in the housing part 710 between the auxiliary rotating part (E) and the rotation control part (E) with a gap in the same direction as the auxiliary rotating part (E). And, the additional auxiliary rotating part (G) includes a fourth pillar 781 and a fifth magnetic body part 780 provided at both ends of the fourth pillar 781.

Meanwhile, the auxiliary output enhancer 700 according to an embodiment of the power generation device 10 with improved output of the present invention further includes a rotation control unit (F) and an additional auxiliary rotation unit (G).

The rotation control unit (F) makes the operation of the auxiliary rotation unit (E) and the additional auxiliary rotation unit (G) more smooth, leading to stable rotational force amplification.

Referring to FIG. 4, the rotation control unit (F) is provided in the housing unit 710 at intervals in the same direction as the auxiliary rotation unit (E) and the additional auxiliary rotation unit (G).

Specifically, the rotation control unit F includes a third pillar 741 and a fourth magnetic body part 740 provided at both ends of the third pillar 741.

Meanwhile, referring to FIG. 7, the rotation control unit (F) is fixedly installed with a rack gear 742 formed along the longitudinal direction of the third pillar 741 in the housing unit 710 and rotates in engagement with the rack gear 742. a pinion gear unit 743, a connecting rod 761 extending and rotating with the second axis 744b of the pinion gear unit 743, a first moving magnetic body 760 formed at the end of the connecting rod 761, and It has a structure including a second moving magnetic body 770 attached to one end of the rack gear.

At the other end of the rack gear 742, a first bracket 790a is provided at a right angle to the longitudinal direction of the rack gear 742, so that the rack gear 742 moves in one direction and is caught by the second bracket 790b, causing the first bracket ( 790a) prevents continuous movement.

In addition, an elastic member (sp) is provided on one surface of the first bracket 790a in the direction opposite to the direction in which the rack gear 742 is arranged, so that the rack gear 742a is elastic while moving in one direction and then returns to its original position. Let it come back. The elastic member (sp) may be implemented as a spring.

The first and second pinion gears 743a and 743b rotate about one first axis 744a, and the third pinion gear 743c rotates about the second axis 744b. As the first pinion gear (743a) rotates, the second pinion gear (743b) rotates, and the third pinion gear (743c) rotates in mesh with the second pinion gear (743b). The connecting rod 761 rotates in the direction opposite to the direction in which the rack gear 742 moves according to the rotation of the third pinion gear 743c.

At this time, as the rack gear 742 and the first pinion gear 743a engage, the first moving magnetic body 760 moves to form the fifth magnetic body portion 780 and the fifth magnetic body portion 780 having the same polarity as the first moving magnetic body 760. Repulsive force acts. When the rack gear 742 returns to its original position, the first moving magnetic body 760 also returns to its original position.

The first moving magnetic body 760 moves in a rotating manner. At this time, a moving weight 745 may be attached to the upper part of the connecting rod 761 to facilitate rotation of the first moving magnetic body 760.

In addition, as the rack gear 742 and the first pinion gear 743a engage, the second moving magnetic body 770 moves to form a fourth magnetic body portion 740 having a polarity different from that of the second moving magnetic body 770. Attractive force works. When the rack gear 742 returns to its original position, the second moving magnetic body 770 also returns to its original position.

The operating structure of the auxiliary output enhancer 700 configured as described above will be described in more detail with reference to the drawings as follows.

As described above, the weight rotating part (D) constituting the auxiliary output enhancer 700 moves the weight according to the movement of the weight 720 to form an eccentricity in the circumferential direction of the rotating shaft part 200. Amplifies rotation.

And, as described above, the auxiliary rotating part (E) uses the attractive force between magnetic materials to assist the movement of the heavy rotating part (D), making it easier to rotate the heavy rotating part (D) in the third quadrant.

Referring to FIG. 8, the third magnetic body part 730b and the third fixed magnetic body 750 constituting the auxiliary rotating part E exert an attractive force that pulls each other, and the third fixed magnetic body 750 has a set thickness and width. It has the shape of an arc, has a gap in the rotation axis portion 200, and has a shape surrounding the third quadrant.

Accordingly, the third magnetic body portion 730b may rotate to the vicinity of the second quadrant without stopping due to the pulling force of the third fixed magnetic body 750 while passing through the third quadrant. Depending on its force, the weight rotation unit (D) also allows the weight 720 to pass without stopping while passing through the third quadrant.

Meanwhile, the auxiliary rotating part (E) must pass through the third quadrant provided with the third fixed magnetic body 750 and rotate to the second quadrant, and the attractive force between the third magnetic body part 730b and the third fixed magnetic body 750 It may be difficult to turn because it is strong.

The above-described embodiments of the present invention have been described with reference to the embodiments shown in the drawings to aid understanding, but these are merely illustrative, and those skilled in the art will be able to make various modifications and other equivalent embodiments therefrom. You will understand that it is possible. Therefore, the true technical protection scope of the present invention should be determined by the appended claims.

10: Power generation device with improved output
100: fixed magnetic material 100a: first fixed magnetic material
100b: second fixed magnetic body 200: rotating shaft portion
210: generator 220: motor
300: Rotating magnetic body part 310: Magnetic body part
311: first connection part 320: centrifugal weight
321: second connection part 330: first magnetic body part
340: second magnetic body portion 400: battery
700: Auxiliary output enhancer 710: Housing portion 720: Weight 730: Third magnetic body portion 740: Fourth magnetic body portion 745: Moving weight
750: Third fixed magnetic material 760: First moving magnetic material
770: second moving magnetic body 780: fifth magnetic body part
790a: 1st bracket 790b: 2nd bracket
sp: Elastic member D: Heavy rotation part E: Auxiliary rotation part F: Rotation control part
G: Additional auxiliary rotating part

Claims (3)

A rotating shaft portion connected to a generator on one side and having a set length and diameter;
a housing part positioned adjacent to the generator at a distance from the generator, supported by the rotating shaft and rotating in the same manner;
a first pillar movably penetrating guide holes formed at both ends of the housing unit, and a weight rotation unit including weights provided at both ends of the first pillar;
It is provided in the housing part and spaced apart from the weight rotating part, and includes a second pillar, a third magnetic body part provided at both ends of the second pillar, and a third quadrant spaced from the third magnetic body part and centered on the rotation axis. An auxiliary rotating part having a third fixed magnetic body fixedly installed on the side,
A rotation control unit provided at a distance in the same direction as the auxiliary rotation unit and provided in the housing unit, including a third pillar and a fourth magnetic body part provided at both ends of the third pillar;
An additional auxiliary rotating part is provided in the housing unit with a gap between the auxiliary rotating part and the rotation control part in the same direction as the auxiliary rotating part, and includes a fourth pillar and a fifth magnetic body part provided at both ends of the fourth pillar.
It is provided with an auxiliary output enhancer including,
The rotation control unit,
A rack gear formed along the longitudinal direction of the third pillar, a pinion gear portion that is fixedly installed and rotates in engagement with the rack gear, a connecting rod that is extended and connected to the rotation axis of the pinion gear portion and rotates, and a third formed at the end of the connecting rod. 1. A power generation device with improved output, comprising a moving magnetic body and a second moving magnetic body attached to one end of the rack gear.
According to paragraph 1,
The weight rotating portion penetrates the first long hole in the longitudinal direction of the first pillar,
A power generation device with improved output, characterized in that the housing portion further forms a guide rod that penetrates the first long hole and is fixedly installed in the internal space.
According to paragraph 1,
As the rack gear and the pinion gear unit engage, the first moving magnetic body rotates to exert a repulsive force with the fifth magnetic body part having the same polarity as the first moving magnetic body, and the second moving magnetic body moves to generate the second moving magnetic body. 2. A power generation device with improved output, characterized in that an attractive force acts on the fourth magnetic body portion having a polarity different from that of the moving magnetic body.

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