KR20230168529A - Magnetic power generation device using repulsive force of magnetic field - Google Patents

Abstract

The present invention includes a left coil member provided with a left magnet for power generation; A right coil member configured at a position opposite to the left coil member, configured to have a configuration corresponding to that of the left coil member, and including a right magnet for power generation having a polarity opposite to that of the left magnet for power generation; a connection magnet whose both ends are respectively connected to the left coil member and the right coil member; A magnetic coupling portion in which a lower power generation magnet having opposite poles to the left power generation magnet and the power generation right magnet and an upper power generation magnet having the same pole as the power generation left magnet and the power generation right magnet are coupled, respectively, A power generation main body formed between magnetic coupling parts and including a through hole through which the magnetic force lines pass; and a driving means for operating the rotation shaft and the lifting guide; an induced current generator including a; and a frame portion that supports the lowering and rotating operations of the induced current generator.

Description

Magnetic power generation device using repulsive force of magnetic field}

The present invention relates to a magnetic power generation device using the repulsive force of a magnetic field. More specifically, the present invention relates to a magnetic power generation device that repeatedly blocks or passes magnetic force lines generated from a magnet while repeatedly raising and lowering and rotating, thereby generating an induced current and simultaneously generating counter power. This relates to a magnetic power generation device that utilizes the repulsive force of a magnetic field to minimize current and prevent excessive heat generation from lowering the efficiency of the power generation device.

In general, a power generation device using a permanent magnet generates an electromagnetic pole in a direction opposite to that of the existing permanent magnet due to an induced current flowing in the generator winding, thereby generating a counter electromotive force in the direction of reducing the torque of the generator. This back electromotive force causes a loss in the power generated from the generator, and a force stronger than the force generated by the back electromotive force must be continuously provided from the outside.

In other words, in the case of a power generation device using a permanent magnet, current is automatically generated due to the rotation of the rotor, but since more current must be input than the electricity generated at this time, the input current increases unnecessarily, resulting in high current consumption. There is a problem in that the efficiency of the power generation device decreases as excessive heat is generated.

Accordingly, Republic of Korea Patent No. 10-0940182 includes a magnet 10 configured to have N-pole and S-pole around a core around which a coil is wound; an N-pole core (20) and an S-pole core (30) in which coils having the N and S pole polarities are wound, respectively; It is configured to include a blocking member 40 formed at a portion where the magnetic force line between the N-pole core 20 and the S-pole core 30 passes, and blocks and opens the magnetic field by the blocking member 40. A magnetic force line switch-type generator that generates power using a permanent magnet and a blocking member that generates induced electricity by changing the magnetic field through repetitive motion has been published.

In particular, the blocking member 40 is composed of a rod-shaped magnetic material that is opposed up, down, left, and right, and reciprocates the rod-shaped magnetic material to change the magnetic field through repeated movements of blocking and opening the magnetic field to generate induced electricity. It consists of a shim 20 wound with an N-pole coil formed in series with an N-pole magnet 22 on the left, and a shim 30 wound with an S-pole coil formed in series with an S-pole magnet 32 on the right. ) is located and then the rod-shaped magnetic material is formed between them. When the S pole is formed on the left and the N pole is formed on the right, the magnetic field is opened and electricity flows. Conversely, when the N pole is placed on the left and the S pole is formed on the right, the magnetic field is opened and electricity flows. When configured, the magnetic field is blocked so that electricity does not flow.

However, according to the above-mentioned prior art document, the rod-shaped magnetic material, that is, the magnets each formed in the blocking member 40, enter between the N-pole core 20 and the S-pole core 30 in order to block the magnetic field. In this case, the magnetic field is not formed evenly due to different magnetic fields between each of the shims 20, 30 and the magnets comprised in the blocking member 40, and the flow toward the magnet located on the upper part of the blocking member 40 This caused a problem in that the blocking effect of the magnetic field was significantly reduced.

The background or prior art described herein is only intended to help understand the technical significance of the present invention, and does not mean technology that is widely known in the technical field to which this invention belongs before the application of the present invention.

Republic of Korea Patent No. 10-0940182

In order to solve this problem, the present invention was created based on the above-mentioned background technology. It is disposed in the magnetic force line passing portion formed between the N and S poles and operates to raise and lower and rotate by a certain angle in the forward and backward directions. The purpose is to provide a magnetic power generation device using the repulsive force of a magnetic field that can maximize the power generation efficiency of the magnetic power generation device by repeatedly blocking or passing the magnetic force lines of the N and S poles.

In addition, the present invention minimizes the current consumption that occurs when driving the power generation device by minimizing the back electromotive current generated when driving the power generation device, and solves the conventional problem of lowering the efficiency of the power generation device due to excessive heat generation. The purpose is to provide a magnetic power generation device using the repulsion force of the magnetic field.

However, the purpose of the present invention is not limited to this, and of course, even if not explicitly mentioned, purposes or effects that can be understood from the means of solving the problem or the embodiment are also included.

According to one embodiment of the present invention for achieving this problem, a left coil member provided with a left magnet for power generation; It is configured at a position opposite to the left coil member, but is configured to have a configuration corresponding to the configuration of the left coil member, and includes a right magnet for power generation that generates a magnetic force line having a polarity opposite to that of the left magnet for power generation. Right coil member; A magnetic force line passing portion formed between the left magnet for power generation and the right magnet for power generation; a connection magnet whose both ends are respectively connected to the first and second conductive panels and has the same polarity as the left magnet for power generation and the right magnet for power generation; An induced current generator configured in the magnetic force line passing portion and generating an induced current by changing the magnetic field of the left magnet for power generation or the right magnet for power generation through a descending and rotating operation; and a frame portion that supports the lowering and rotating operations of the induced current generator.

According to one embodiment of the present invention, the left coil member includes a first eddy current prevention member that blocks eddy currents and improves the magnetic flux density of the induced current, and a first coil configured to surround the outer peripheral surface of the first eddy current prevention member. And, a first insulating member each coupled to the upper and lower ends of the first eddy current prevention member, a first conductive panel inserted in close contact with the penetrating central portion of the first eddy current prevention member, and the first eddy current prevention member. It is inserted into one side of the upper part and is configured to be connected to the first conductive panel, has the same polarity as the polarity of the first conductive panel, and includes a left magnet for power generation that generates a magnetic field of the corresponding polarity to form a magnetic field. do.

According to one embodiment of the present invention, the induced current generator includes a rotating shaft rotatably coupled to the frame and including a rotation guide with a coupling shaft formed in the central portion; a rotary flange having a coupling groove in which the coupling shaft is coupled and a sealing flange for sealing the rotary guide; a lifting guide coupled to the lower part of the rotating flange; A magnetic coupling portion in which a lower power generation magnet having opposite poles to the left power generation magnet and the power generation right magnet and an upper power generation magnet having the same pole as the power generation left magnet and the power generation right magnet are coupled, respectively, A power generation main body formed between magnetic coupling parts and including a through hole through which the magnetic force lines pass; and a driving means for operating the rotation shaft and the lifting guide.

According to one embodiment of the present invention, the power generation body includes a guide inclined portion that guides the magnetic force line to move toward the magnet coupling portion to which the lower power generation magnet is coupled, and moves the magnetic force line toward the lower power generation magnet and the upper power generation magnet. It is characterized in that a movement guide unit is further configured to guide the user to do so.

According to one embodiment of the present invention, the power generation main body is connected to the elevating guide to be disposed in the magnetic force line passage portion and blocks the magnetic force line passing through the magnetic force line passage portion by lifting and lowering operation and rotating operation, or guides the magnetic force line passing through the magnetic force line passage portion. It is characterized by generating an electric current.

According to one embodiment of the present invention, the lower power generation magnet, the upper power generation magnet, and the through hole are configured to have the same arc and curvature.

According to this embodiment of the present invention, the magnetic force line passing portion formed between the N-pole core and the S-pole core is disposed, and the N-pole core and the S-pole core are rotated by a certain angle in the forward and backward directions. It has the effect of maximizing the power generation efficiency of a magnetic power generation device by repeatedly blocking or passing the magnetic force lines of the core.

In addition, according to an embodiment of the present invention, by minimizing the back electromotive current generated when driving the power generation device, the current consumption that occurs when driving the power generation device is minimized, and the efficiency of the power generation device is lowered due to excessive heat generation. It has the effect of solving problems.

However, the purpose of the present invention is not limited to this, and of course, even if not explicitly mentioned, purposes or effects that can be understood from the means of solving the problem or the embodiment are also included.

In addition, the various and beneficial advantages and effects of the present invention are not limited to the above-described content, and may be more easily understood in the process of explaining specific embodiments of the present invention.

1 is a diagram schematically showing a magnetic power generation device according to the prior art;
Figure 2 is a diagram showing a magnetic power generation device using the repulsion force of a magnetic field according to an embodiment of the present invention;
Figure 3 is a cross-sectional view showing the left and right coil members of a magnetic power generation device using the repulsion force of a magnetic field according to an embodiment of the present invention;
Figure 4 is a perspective view showing an induced current generator of a magnetic power generation device using the repulsion force of a magnetic field according to an embodiment of the present invention;
Figures 5 and 6 are front and side views showing an induced current generator according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. First, when adding reference signs to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even if they are shown in different drawings. Additionally, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

In addition, terms such as “include,” “comprise,” or “have” described below mean that the corresponding component may be included, unless specifically stated to the contrary, and thus do not exclude other components. Rather, it should be construed as being able to further include other components, and all terms, including technical or scientific terms, are generally used by those skilled in the art to which the present invention pertains, unless otherwise defined. It has the same meaning as understood. Additionally, when describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, sequence, or order of the component is not limited by the term. When a component is described as being “connected,” “coupled,” or “connected” to another component, that component may be directly connected or connected to that other component, but there is another component between each component. It will be understood that elements may be “connected,” “combined,” or “connected.”

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

As shown, the magnetic power generation device using the repulsion force of the magnetic field of the present invention is

A left coil member 100 that generates N-pole magnetic force lines, a right coil member 200 configured at a position opposite the left coil member 100 and generating S-pole magnetic force lines, and the left and right coils. The members 100 and 200 are connected to each other to be made of magnetic materials having N-pole and S-pole, and a connection magnet 400 is provided to prevent the operation of the induced current generator 300 from being interrupted by back electromotive force when driven. , It is configured between the left and right coil members 100 and 200, and as the lifting and rotating operation occurs, the magnetic force lines generated from the left coil member 100 and the right coil member 200 pass or are blocked, thereby responding to changes in the magnetic field. It is configured to include an induced current generator 300 that generates an induced current.

The left coil member 100 is composed of a magnetic material with N polarity, and is a first eddy current prevention member 110 that blocks eddy currents generated when driving the induced current generator 300 and improves the magnetic flux density of the induced current. ), a first coil 120 of a conductive component configured to surround the outer peripheral surface of the first eddy current prevention member 110, and a first insulating member each coupled to the upper and lower ends of the first eddy current prevention member 110 ( 130), a first conductive panel 140 that is inserted in close contact with the penetrating central portion of the first eddy current prevention member 110, and a first conductive panel (140) that is inserted into one upper side of the first eddy current prevention member 110. A left magnet for power generation (150) that is configured to be connected to the first conductive panel (140), has the same polarity as the polarity of the connection magnet (400) transmitted to the first conductive panel (140), and generates a magnetic field of the corresponding polarity to form a magnetic field. It consists of

The first eddy current prevention member 110 may be made of a ferrite-based material, and preferably may be configured in the form of a hollow shaft member processed from an electromagnetic steel sheet made of the ferrite-based material.

The first coil 120 is made of a normal magnetic field coil and is configured to surround the outer peripheral surface of the first eddy current prevention member 110, and is preferably used for power generation connected to the upper end of the first eddy current prevention member 110. It is disposed between the left magnet 150 and the connection magnet 400 connected to the lower end of the first eddy current prevention member 110 and is configured to generate electromotive force when the induced current generator 300 is driven.

The first insulating member 130 is made of a non-conductive material, is coupled to the upper and lower ends of the first eddy current prevention member 110, and uses electrical energy generated from the left magnet 150 and the connection magnet 400 for power generation. It blocks discharge to the outside of the left coil member 100.

This first insulating member 130 is configured to contact all of the first eddy current prevention member 110, the first conductive panel 140, and the left magnet 150 for power generation.

In addition, the first insulating member 130 is configured to be mounted on the bottom frame 510 of the frame portion 500, which will be described later, when coupled to the lower end of the first eddy current prevention member 110.

The first conductive panel 140 is made of a metallic conductor component, is inserted into the central part penetrating the first eddy current prevention member 110, and includes a left magnet 150 for power generation inserted into the first eddy current prevention member 110, and The connecting magnets 400 are connected so that the polarity of the connecting magnet 400 and the polarity of the left magnet 150 for power generation have the same polarity.

The left magnet for power generation (150) is inserted into the upper part of the first eddy current prevention member (110) and connected to the connection magnet (400) by the first conductive panel (140), with the polarity and polarity of the left side of the connection magnet (400) By generating magnetic force lines of the same polarity, the magnetic force lines are blocked or passed through the induced current generator 300 through the lifting and rotating operations of the induced current generator 300.

Meanwhile, the right coil member 200 also has the same configuration as the left coil member 100 described above, and preferably includes the second eddy current prevention member 210, the second coil 220, and the second insulating member 230. , It may be composed of a second conductive panel 240 and a right magnet 250 for power generation, and has a magnetic force opposite to the left magnet 150 for power generation.

That is, when the left magnet 150 for power generation generates magnetic force lines of the N pole, the right magnet 250 for power generation generates magnetic force lines of the S pole.

The induced current generator 300 is mounted on the support frame 520 of the frame portion 500 and is configured to enable both lifting and rotating operations, and includes the left magnet 150 for power generation and the right magnet for power generation ( It is configured to be located in the magnetic force line passing portion 160 formed between the magnetic force line passing portion 160 and blocks the magnetic force line from passing through the magnetic force line passing portion 160 or generates an induced current while allowing the magnetic force line to pass through, the rotating shaft 310, It is comprised of a rotation guide 320, a rotation flange 330, a lifting guide 340, a power generation body 350, a magnet frame 360, and a driving means 370.

Both ends of the rotation shaft 310 are rotatably coupled to the support frame 520 of the flange portion 500, and are configured to rotate the power generation body 350 in both directions by a certain angle.

At this time, one end of the rotation shaft 310 is coupled to one side of the support frame 520, a driving means 370 for rotating the rotation shaft 310 is coupled, and the rotation shaft 310 is coupled to the other side of the support frame 520. The other end of is coupled, and the drive support portion 372 that supports the rotation operation is coupled.

Here, the drive support unit 372 may be made of a typical bearing assembly, but is not limited thereto.

Additionally, the driving means 370 may be configured as a rotation motor that performs a two-way rotation operation, but is not limited thereto.

The rotation guide 320 is coupled to the outer peripheral surface of the rotation shaft 310 and is configured to rotate when the rotation shaft 310 rotates. It has the function of transmitting the rotational force of the rotation shaft 310 to the rotation flange 330. By performing this, a coupling shaft 322 is formed that is coupled to the rotating flange 330 forward and backward.

The rotation flange 330 is open at the top and is configured to be coupled to the rotation guide 320 to enable rotation, and receives rotational force from the rotation guide 320 to rotate the power generation main body 350 and at the same time, this power generation main body ( A lifting guide 340 is mounted on the lower part to enable the lifting operation of 350).

At this time, it is preferable that the rotation flange 330 further includes a coupling groove into which the coupling shaft 322 is inserted and fixed, and the rotational operation of the rotation guide 320 is performed due to the coupling method of the coupling shaft 322 and the coupling groove. The rotation flange 330 is also configured to rotate in the same direction.

In addition, a sealing flange 332 may be further formed on the upper part of the rotation flange 330 to seal the open upper part and prevent the rotation guide 320 from being separated from the rotation flange 330.

In addition, the rotating flange 330 is configured to be electrically connected to the driving means 370, so that the lifting guide 340 is lifted and lowered depending on whether the driving means 370 is driven or power is supplied. do.

The lifting guide 340 may be composed of a normal cylinder member or an actuator, and allows the power generation body 350 to enter the magnetic force line passage portion 160 or deviate from the magnetic force line passage portion 160 to move the power generation body 350 to the left and right sides. It is a component that blocks and allows the magnetic force lines generated through the right coil members 100 and 200 to pass.

At this time, the lifting guide 340 may be configured to control the lifting height according to the polarity of the power generation magnets 302 and 304 formed in the power generation main body 350, and the driving control of the lifting guide 340 It would be preferable to be controlled through a control unit that controls whether or not the driving means 370 is driven.

The power generation body 350 is connected to the lifting rod of the lifting guide 340 and is lifted up and down to a certain height according to the operation of the lifting guide 340, blocking the magnetic force line passing through the magnetic force line passing part 160 or continuing. It is configured to generate an induced current while passing through it, and as the rotating operation of the rotating shaft 310 is performed, the amount of magnetic passage is increased and the magnetic field is changed, thereby further improving the generation efficiency of the induced current. Perform.

This power generation body 350 has a lifting rod 342 coupled to the upper center, and a magnetic coupling portion 354 on which the power generation magnets 302 and 304 are mounted is formed in the lower center.

Here, the power generation magnets 302 and 304 are composed of a lower power generation magnet 302 formed in the lower part of the magnetic coupling part 354 and an upper power generation magnet 304 formed in the upper part of the magnetic coupling part 354. The lower power generation magnet 302 and the upper power generation magnet 340 are composed of magnets with different polarities at the front and rear parts of the power generation main body 350, respectively.

The lower power generation magnet 302 is configured to have a magnet having an S pole disposed at the front of the power generation body 350, and a magnet having an N pole is disposed at the rear of the power generation body 350.

That is, the lower power generation magnet 302 has magnets of opposite polarity to the left power generation magnet 150 of the left coil member 100 and the right power generation magnet 250 of the right coil member 200, so that they are different from each other. It is configured to generate an induced current using the repulsive force of the magnetic field generated from a polarized magnet.

The upper power generation magnet 304 is configured so that a magnet having a polarity opposite to that of the lower power generation magnet 302 is disposed at the front and rear parts of the power generation main body 350. That is, a magnet having an N pole is arranged in the front part of the power generation body 350, and a magnet having an S pole is arranged in the rear part of the power generation main body 350.

The upper power generation magnet 304 and the lower power generation magnet 302 are magnets of the same polarity as the left power generation magnet 150 of the left coil member 100 and the right power generation magnet 250 of the right coil member 200. It is arranged so that an induced current is generated using changes in the magnetic field generated from magnets of the same polarity.

Meanwhile, the power generation magnets 302 and 304 of the present invention are configured to have a predetermined arc and have different curvatures.

However, it is not limited to this, and the curvature of the power generation magnets (302, 304) may all be configured to have the same diameter. In this case, the through hole 352 is also the same as the power generation magnets (302, 304). It can be configured to have arcs and curvatures.

In addition, the power generation body 350 of the present invention is formed on both sides of the magnetic coupling portion 354 with a passage hole 352 through which the magnetic force lines generated from the left coil member 100 or the right coil member 200 pass.

Here, the passing hole 352 is formed between the lower power generation magnet 302 and the upper power generation magnet 304, and when the lifting and lowering guide 340 operates, the left coil member 100 or the right coil member 200 ) is configured to allow the magnetic force lines generated from the lower power generation magnet 302 or the upper power generation magnet 304 to pass after being blocked.

That is, during the lowering operation by the lifting guide 340, the magnetic force lines generated from the left coil member 100 or the right coil member 200 are blocked by the lower power generation magnet 302, and then through the through hole 352. It is configured to pass through, and then, as the lowering operation of the lifting guide 340 is performed, it is blocked by the upper power generation magnet 304, and then passes again through the passing hole 352 to generate an induced current. It is composed.

When the lowering operation of the power generation body 350 is performed by driving the lifting guide 340, the lower power generation magnet 302 formed at the front lower part generates power of the left coil member 100 and the right coil member 200. It is configured to be located on the same axis as the left magnet (150) for power generation and the right magnet (250) for power generation.

In addition, the power generation body 350 is rotated by a certain angle in one direction by the driving means 370 to maximize the repulsive force of the magnetic field, and the end of the lower power generation magnet 302 and the left power magnet 150 and When the center of the right magnet 250 for power generation is located on the coaxial line, the lifting guide 340 moves down and places the center on the coaxial line with the passage hole 352, and then the driving means 370 is driven. It causes rotation and allows magnetic force lines to pass at the same time.

Likewise, when the end of the passing hole 352 and the center of the left magnet 150 for power generation and the right magnet 250 for power generation are located on the same axis by repeated rotation operation, the lifting guide 340 As the further lowering operation is performed, the center of the left magnet for power generation (150) and the right magnet for power generation (250) are positioned on the same axis as the upper magnet for power generation (304), and then rotated by driving the driving means (370). It is structured to make it happen.

That is, the present invention is configured to generate induced current by repeating the process of blocking or passing magnetic force lines while repeating the raising and lowering operation and rotation operation of the power generation magnets 302 and 304.

Meanwhile, the power generation main body 350 is formed at the lower end, and when the lowering operation is performed by driving the lifting guide 340, there is contact with the magnetic force line generated from the left coil member 100 or the right coil member 200. A guide inclined portion 356 may be further configured to guide the magnetic force line to move toward the magnet coupling portion 354 to which the lower power generation magnet 302 is coupled.

In addition, the power generation body 350 is formed in the front and rear portions of the magnetic coupling portion 354, respectively, and the magnetic force lines of the left power generation magnet 150 and the power generation right magnet 250 are connected to the lower power generation magnet 302. and a movement guide unit 358 that guides movement toward the upper power generation magnet 304 may be further configured.

The movement guide portion 358 is formed at each end of the magnetic coupling portion 354 and is configured to form a predetermined groove, and its circumferential surface is configured to have a predetermined inclined surface so that the magnetic force lines follow the inclined surface. It will be possible to guide you to the power generation magnets (302, 304).

The driving means 370 is connected to the rotation shaft 310 and rotates the left and right coil members 100 and 200 forward and backward by a certain angle, and supplies power to enable the lifting operation of the lifting guide 340. It is a component that does.

Although this driving means 370 has been described as rotating the rotation range of the rotation shaft 310 by a certain angle, it is not limited to this, and may be configured to rotate the rotation shaft 310 by 360° under the control of the control unit. It might be possible.

At this time, of course, the left coil member 100, the right coil member 200, and the induced current generator 300 may also be composed of a plurality along the rotation radius of the driving means 370.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

100: Left coil member 110: First eddy current prevention member
120: first coil 130: first insulating member
140: First conductive panel 150: Left magnet for power generation
160: Magnetic force line passing part 200: Right coil member
210: Second eddy current prevention member 220: Second coil
230: second insulating member 240: second conductive panel
250: Right magnet for power generation 300: Induced current generator
302: Lower power generation magnet 304: Upper power generation magnet
310: rotation axis 320: rotation guide
330: Rotating flange 340: Elevating guide
350: Power generation body 360: Magnet frame
370: Drive means 400: Connection magnet
500: frame part

Claims (1)

A first eddy current prevention member that blocks eddy currents and improves the magnetic flux density of induced current, a first coil configured to surround the outer peripheral surface of the first eddy current prevention member, and each coupled to the upper and lower ends of the first eddy current prevention member. A first insulating member, a first conductive panel that is inserted in close contact with the penetrating central portion of the first eddy current prevention member, and a first conductive panel that is inserted into one upper side of the first eddy current prevention member and is connected to the first conductive panel. , a left coil member including a left magnet for power generation, which has the same polarity as the polarity of the first conductive panel and generates lines of magnetic force of the corresponding polarity to form a magnetic field;
It is configured at a position opposite to the left coil member, and includes a second eddy current prevention member, a second coil, a second insulating member, and a second conductive panel corresponding to the left coil member, and the polarity of the left magnet for power generation and A right coil member including a right magnet for power generation that generates magnetic force lines with opposite polarities;
a connection magnet whose both ends are respectively connected to the first and second conductive panels and has the same polarity as the left magnet for power generation and the right magnet for power generation;
It consists of a magnetic force line passing portion formed between the left magnet for power generation and the right magnet for power generation, and generates an induced current by changing the magnetic field of the left magnet for power generation or the right magnet for power generation through a falling and rotating operation. Current generating device; and
It includes a frame portion that supports the lowering and rotating operation of the induced current generator,
The induced current generator is,
A rotation shaft rotatably coupled to the frame and including a rotation guide with a coupling shaft formed in the central portion;
a rotary flange having a coupling groove in which the coupling shaft is coupled and a sealing flange for sealing the rotary guide;
a lifting guide coupled to the lower part of the rotating flange;
A magnetic coupling portion in which a lower power generation magnet having opposite poles to the left power generation magnet and the power generation right magnet and an upper power generation magnet having the same pole as the power generation left magnet and the power generation right magnet are coupled, respectively, A passage hole formed between the magnetic coupling portions through which the magnetic force lines pass, a guide inclined portion that guides the magnetic force lines to move toward the magnet coupling portion to which the lower power generation magnet is coupled, and the magnetic force lines are connected to the lower power generation magnet and the upper power generation magnet. It consists of a movement guide that guides movement to the side, and is connected to the elevating guide to be disposed in the magnetic force line passage portion, so that the magnetic force line passing through the magnetic force line passage portion is blocked or continues to pass through the magnetic force line passage portion through a lifting and lowering operation and a rotation operation to generate an induced current. Shiki power generation body; and
It further includes a driving means that operates the rotation shaft and the lifting guide,
A magnetic power generation device using the repulsive force of a magnetic field, characterized in that the lower power generation magnet, the upper power generation magnet, and the pass hole are configured to have the same arc and curvature.