JP2020191705A - Magnetic induction power generator - Google Patents

Abstract

To provide a magnetic induction power generator that is formed of a magnetic induction structure, a power generation structure, and a circulation circuit structure.SOLUTION: A magnetic induction power generator 10 is formed of a magnetic induction structure 20, a power generation structure 30, and a circulation circuit structure 40. In the magnetic induction structure 20, a magnetic induction rotary panel 26 is disposed between magnetic induction stationary panels 21 that are vertically opposed to each other, and a rotary rotor shaft 31 having a plurality of permanent magnets 24, 25 embedded in an end thereof is formed so as to be extended downward in the center axis of the magnetic induction rotary panel 26. In the power generation structure 30, the end of rotary rotor shaft 31 with the embedded permanent magnets 24, 25 is inserted in a power generation ring 34. The circulation circuit structure 40 is formed of a collector 41, a distributor 42, a secondary battery 43, an inverter converter 44, and a pressure adjustor 45. Power generated by the magnetic induction structure 20 and the power generation structure 30 is output to the outside by the circulation circuit structure 40, and is used for power feeding to an electric magnet 23 disposed in the power generator 10 itself.SELECTED DRAWING: Figure 2

Description

The present invention relates to a magnetic induction generator, and more specifically, an electromagnet composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure, and the generated power is output to the outside and arranged in the generator itself. It relates to a magnetic induction generator that can be used to energize a power source.

In the conventional magnetic induction generator, the electric power generated by the magnetic induction structure and the power generation structure can be output to the outside by the circuit structure, but a part of the electric power is not used for the generator itself.

As a specific example of a conventional magnetic induction generator, an "automatic power generation system using a magnet similar to the liner principle" using a magnet similar to the linear principle that enhances the efficiency of rotational strength (see Patent Document 1). Has been proposed and has become a known technique.

Specifically, 16 generators are arranged on the inner diameter side of the rotating ring having a drive source, a rotating magnet similar to the principle of liner is arranged on the outer diameter side, and rod-shaped fixed magnets are arranged in a circular shape at equal intervals on the fixing ring. The rotating magnets are arranged at equal intervals, but a gap of 2 to 3 mm is provided between the rotating magnets and the adjacent rotating magnets, and a gap is also formed between the rotating magnets and the rod-shaped fixed magnets. This is a proposal for a magnetic induction generator in which 3 of the generators are used as a drive source for a motor and the amount of power generated from 13 units can be freely used.

However, the above proposal has a problem that it is difficult to handle because a large number of contact brushes are installed around the rotor that rotates at high speed, so that a voltage drop due to frictional heat loss is likely to occur.

In addition, an efficient "coilless magnet generator" (see Patent Document 2) that can improve the low voltage, which is a drawback of the underlying unipolar induction generator, and extract electrical energy directly from the magnet, has been proposed. It is a known technology.

Specifically, the rotor, which is the magnet of the unipolar generator, is divided and stratified into multiple layers, and it is fixed to the rotating shaft as a disk using an insulator, and similar objects are placed coaxially, and the inner polarity repels. The material composition of each split magnet is the same as that of the split magnet, and the split magnet is rotated while maintaining an appropriate press pressure on the week edge surface of the split magnet. The polarity of each connection is equipped with a rotating brush installed so as to repel both the side-by-side and weekly installation, and the connection of the side-by-side split magnets connects the central parts of the magnets that are diagonal to each other. This is a proposal of a magnetic induction generator capable of increasing the voltage and reducing the reverse torque by utilizing the magnetic field action inside the magnet by configuring the generator as described above.

However, the above proposal has a problem that the central axis of the rotating brush is bearing-fixed by mechanical means, so that the friction coefficient becomes larger than the electromagnetic induction performance due to the linear structure at least.

The applicant paid attention to the above-mentioned conventionally proposed magnetic induction generators, and thought that the generated power could not only be output to the outside by the circuit structure but also could be used for the generator itself. Below, the power generated by the magnetic induction structure and the power generation structure can be used to energize the electromagnets arranged in the generator itself by the circulation circuit structure, and the remainder can be output to the outside at low cost and maintenance. A simple magnetic induction generator has been developed, leading to the proposal of the "magnetic induction generator" according to the present invention.

Japanese Unexamined Patent Publication No. 2011-4580 Japanese Unexamined Patent Publication No. 2003-47226

In view of the above circumstances, the present invention is composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure, and outputs the generated power to the outside and energizes an electromagnet arranged in the generator itself. An object of the present invention is to provide a magnetic induction generator that can be used.

In order to solve the above problems, the present invention is a magnetic induction generator composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure, and an electromagnet guide rail provided around in a circular shape and the electromagnet guide rail thereof. Two induction electromagnets arranged at 180 ° intervals on the inner center circle, and a magnetic induction fixing plate formed of an insulating material in which the two induction electromagnets are arranged face each other vertically, and the magnetic induction fixing plates facing each other vertically. In the middle of the above, a plurality of orbital rotating permanent magnets that rotate and move on the orbit of the electromagnet guide rail without contact are provided in an endless circle or in a circular shape, and at intervals of 72 ° on the inner center circle. A magnetic induction rotating disk formed of an insulating material in which five rotating induction fixed permanent magnets are arranged on the upper and lower surfaces are arranged, and integrally molded with the insulating material below the central axis of the magnetic induction rotation disk. At the same time, a rotating rotor shaft in which a plurality of permanent magnets are embedded at the tip is extended, and a hole through which the rotating rotor shaft can be inserted is provided in the center of the magnetic induction fixing plate arranged below, and a power generation structure is formed. Is formed by inserting the tip of a rotating rotor shaft in which a permanent magnet is embedded into a power generation ring in which a power generation coil is inserted and a ring shape is formed. The circulation circuit structure collects the output magnetically induced current. A collector and a distributor that distributes the magnetically induced current, a secondary battery that stores the magnetically induced current, an electromagnet converter that converts the output magnetically induced current, and overcurrent, overcharge, and overdischarge. It is composed of a pressure regulator to prevent, and the power generated by the magnetic induction structure and the power generation structure is output to the outside by the circulation circuit structure, and the means used to energize the electromagnets arranged in the generator itself. take.

Further, according to the present invention, in the magnetic induction rotary disk, a means can be adopted in which the rotation induction fixed permanent magnet on the lower surface is arranged at a position shifted by 36 ° with respect to the rotation induction fixed permanent magnet arranged on the upper surface. ..

Further, in the present invention, in the magnetic induction fixing plate, the induction electromagnet of the lower magnetic induction fixing plate is arranged at a position shifted by 90 ° with respect to the induction electromagnet arranged in the upper magnetic induction fixing plate. You can take measures.

Furthermore, in the present invention, the magnetic poles of the induction electromagnets arranged on the magnetic induction fixing plate are N poles toward the magnetic induction rotation plate side, and the rotation induction fixed permanent magnets arranged on the magnetic induction rotation plate. The magnetic pole of the magnet can be an S pole toward the rotation traveling direction and an N pole toward the opposite side of the rotation traveling direction.

Furthermore, in the present invention, the magnetic poles of the induction electromagnets arranged on the magnetic induction fixing plate are N poles toward the rotation traveling direction side of the magnetic induction rotation plate and S poles toward the side opposite to the rotation traveling direction. The magnetic poles of the rotation-induction fixed permanent magnets arranged on the magnetic-induction rotation plate may be N poles toward the magnetic induction-fixing plate side.

Furthermore, the present invention may adopt a means in which a magnetic shield material is embedded in the middle of the magnetic induction rotating disk.

Furthermore, the present invention may adopt means in which the distributor is provided with a breaker having an earth leakage breaker function.

Further, the present invention may adopt a means in which the secondary battery is provided with at least one connection terminal for power transmission or power reception.

According to the magnetic induction generator according to the present invention, a stable and compact structure can be obtained because a magnetic levitation effect due to non-contact is obtained by providing a magnetic induction structure with a magnetic induction fixing plate that sandwiches a magnetic induction rotating disk vertically. Therefore, it has an excellent effect of making it possible to provide a magnetic induction generator having low rotational resistance.

Further, according to the magnetic induction generator according to the present invention, the generated power can be output to the outside by the circulation circuit structure and can be used to energize the electromagnet arranged in the generator itself, which is inexpensive and maintenance-friendly. It has excellent effects such as being able to provide an easy magnetic induction generator.

Further, the magnetic induction generator according to the present invention has an excellent effect that the generation of magnetic mystery of the current output to the outside can be suppressed by the circulation circuit structure.

Furthermore, according to the magnetic induction generator according to the present invention, by adopting a means provided with a breaker having an earth leakage breaker function, it can be deployed in various environments such as a power plant, a ship, and an automobile. In addition to this, by adopting a vibration-sensing type that shuts off the earth leakage when the breaker senses shaking, it is possible to minimize accidents caused by a large earthquake or the like.

Further, according to the magnetic induction generator according to the present invention, the secondary battery is provided with at least one connection terminal for power transmission or power input having an ON / OFF function. It has excellent effects such as starting a magnetic induction generator according to the state of electricity storage, supplying electric power to the outside, and easily receiving the necessary electric power at the time of initial start-up.

It is a schematic explanatory drawing which shows the embodiment of the magnetic induction generator which concerns on this invention. It is sectional drawing which shows the embodiment of the magnetic induction generator which concerns on this invention. It is explanatory drawing which shows the correlation of the induction electromagnet and the rotation induction fixed permanent magnet in the magnetic induction generator which concerns on this invention.

The magnetic induction generator 10 according to the present invention is composed of a magnetic induction structure 20, a power generation structure 30, and a circulation circuit structure 40, and the magnetic induction structure 20 is an electromagnet guide rail 22 provided around in a circular shape. And the magnetic induction fixing plate 21 formed of the insulating material in which the two induction electromagnets 23 arranged at 180 ° intervals on the inner center circle are opposed to each other, and are opposed to each other. A plurality of orbital rotating permanent magnets 25 that rotate and move on the orbit of the electromagnet guide rail 22 in a non-contact manner are provided in the middle of the magnetic induction fixing plate 21 so as to be scattered in an endless circumference or in a circular shape. A magnetic induction rotary disk 26 formed of an insulating material in which five rotation induction fixed permanent magnets 24 arranged at intervals of 72 ° on a central circle are arranged on the upper and lower surfaces is arranged, and the center of the magnetic induction rotation disk 26 is arranged. A rotating rotor shaft 31 integrally molded with an insulating material and having a plurality of permanent magnets 32 embedded in the tip thereof is extended below the shaft, and the rotating rotor shaft 31 is located at the center of the magnetic induction fixing plate 21 arranged below. The power generation structure 30 is formed in a power generation ring 34 in which the tip of a rotary rotor shaft 31 in which a permanent magnet 32 is embedded is formed in a ring shape and a power generation coil 35 is inserted. The circulation circuit structure 40 is composed of a collector 41 that collects the output magnetically induced current, a distributor 42 that distributes the magnetically induced current, and a magnet that is inserted into the power generation ring 34. It is composed of a secondary battery 43 for storing the induced current, an inverter converter 44 for converting the output magnetic induced current, and a pressure regulator 45 for preventing overcurrent, overcharging, and overdischarging. The electric power generated by the power generation structure 30 is output to the outside by the circulation circuit structure 40, and the most characteristic feature is that the means used for energizing the electromagnets arranged in the generator itself is adopted.
Hereinafter, embodiments of the magnetic induction generator 10 according to the present invention will be described with reference to the drawings.

The magnetic induction generator 10 according to the present invention is not limited to the examples described below, and is within the range of the technical idea of the present invention, that is, the range of shapes, dimensions, and the like capable of exhibiting the same effects. It can be changed as appropriate within.

FIG. 1 is a schematic explanatory view showing an embodiment of a magnetic induction generator according to the present invention.
FIG. 2 is a cross-sectional explanatory view showing an embodiment of the magnetic induction generator according to the present invention.
The magnetic induction generator 10 according to the present embodiment is composed of a magnetic induction structure 20, a power generation structure 30, and a circulation circuit structure 40, and the electric power generated by the magnetic induction structure 20 and the power generation structure 30 is circulated. A means used for energizing an electromagnet arranged in the generator itself while being output to the outside by the circuit structure 40 is adopted.

The magnetic induction structure 20 is formed of an insulating material in which an electromagnet guide rail 22 arranged in a circular shape and two induction electromagnets 23 arranged at 180 ° intervals on the inner central circle thereof are arranged. A magnetic induction fixing plate 21 is faced up and down, and an orbital rotating permanent magnet 25 that rotates and moves on the orbit of the electromagnet guide rail 22 without contact is provided in the middle of the magnetic induction fixing plate 21 facing up and down. A magnetic induction rotating disk 26 formed of an insulating material such as ceramic having five rotation induction fixed permanent magnets 24 arranged on the inner center circle at intervals of 72 ° is arranged on the upper and lower surfaces, and the magnetic induction rotation is performed. Below the central axis of the board 26, a rotating rotor shaft 31 integrally molded with an insulating material such as ceramic and having a plurality of permanent magnets 32 embedded in the tip thereof is extended, and the center of the magnetic induction fixing board 21 arranged below. Is provided with a punched hole 33 through which the rotating rotor shaft 31 can be inserted.

The magnetic induction fixing plate 21 is formed of an insulating material such as a disk-shaped ceramic, and has an ON / OFF function in which two circular concave electromagnet guide rails 22 and two are arranged at 180 ° intervals on the inner central circle thereof. The induction electromagnet 23 having the above is disposed.

The electromagnet guide rail 22 is an electromagnet that generates a magnetic force when energized, is formed in a circular concave shape, and is provided around the inner outer peripheral portion of the magnetic induction fixing plate 21 facing up and down in a circular shape. The cross-sectional shape has a horseshoe-shaped concave shape because it does not deviate from the orbit by the orbital rotating permanent magnet 25. By facing the electromagnet guide rails 22 vertically to generate a magnetic field by energization, the repulsive force of the orbital rotating permanent magnet 25 causes a non-contact floating state.

The induction electromagnet 23 is an electromagnet that generates a magnetic force when energized, and two are arranged at 180 ° intervals on the center circle inside the electromagnet guide rail 22 inside the upper and lower magnetic induction fixing plates 21. By generating a magnetic field by energization, the attraction and repulsion are repeated due to the relationship with the rotation induction fixed permanent magnet 24. At this time, it is conceivable that the positional relationship between the induction electromagnet 23 arranged on the upper magnetic induction fixing plate 21 and the induction electromagnet 23 arranged on the upper magnetic induction fixing plate 21 is shifted, and the position is downward with respect to the upper side. Is preferably shifted by 90 °. This is because, according to this aspect, repeated attraction and repulsion in relation to the rotation induction fixed permanent magnet 24 described later contributes to reliable and efficient rotation when rotating the magnetic induction rotation disk 26.

A punch hole 33 is provided in the lower magnetic induction fixing plate 21. The punched hole 33 allows the rotary rotor shaft 31, which will be described later, to be inserted through the hole 33, and is provided at the center of the lower magnetic induction fixing plate 21.

The magnetic induction rotating disk 26 is arranged in the middle of the magnetic induction fixing plate 21 facing up and down, and is provided with an orbital rotating permanent magnet 25 that rotates and moves on the orbit of the electromagnet guide rail 22 without contact. At the same time, five rotation-guided fixed permanent magnets 24 arranged at intervals of 72 ° on the inner center circle are arranged on the upper and lower surfaces, respectively, and are formed of an insulating material such as ceramic. Further, a rotary rotor shaft 31 is stretched and formed below the central shaft of the magnetic induction rotary disc 26.

At this time, a configuration in which the magnetic shield material 26a is embedded in the middle of the magnetic induction rotary disk 26 can be adopted. The magnetic shield material 26a is for blocking magnetic force, and is formed of, for example, nickel, permalloy, sendust, silicon steel, or the like. By embedding the magnetic shield material 26a, the rotation induction fixed permanent magnets 24 arranged on the magnetic induction rotation disk 26 function as independent magnetic force bodies without affecting each other on the upper surface side and the lower surface side. obtain.

The orbital rotation permanent magnet 25 has an endless circumferential shape at positions facing the electromagnet guide rail 22 above and below the magnetic induction turntable 26 so as to rotate and move on the inner orbit of the horseshoe-shaped recess of the electromagnet guide rail 22 without contact. Alternatively, a plurality of circular shapes are provided scattered on the circumference.

The rotation induction fixed permanent magnets 24 are arranged on a central circle inside the orbital rotation permanent magnets 25, and five rotation induction fixed permanent magnets 24 are arranged on one side of the magnetic induction rotation disk 26 at intervals of 72 °. When arranged on both sides, 10 rotation-guided fixed permanent magnets 24 are arranged. At this time, it is conceivable that the positional relationship between the rotation induction fixed permanent magnet 24 arranged on the upper side of the magnetic induction rotation disc 26 and the rotation induction fixed permanent magnet 24 arranged on the lower side is shifted with respect to the upper side. A mode in which the lower side is shifted by 36 ° is preferable. This is because, according to this aspect, repeated attraction and repulsion in relation to the induction electromagnet 23 contributes to reliable and efficient rotation when rotating the magnetic induction rotating disk 26.

The rotary rotor shaft 31 is stretched below the central shaft of the magnetic induction rotary disc 26, integrally molded with an insulating material such as ceramic, and is formed by embedding a plurality of permanent magnets 32 at the tip.

The permanent magnet 32 is divided into a plurality of pieces and embedded on the circumference of the rotating rotor shaft 31, and has a feature of maintaining the properties of a magnet for a relatively long period of time without receiving a magnetic field or an electric current from the outside. .. As an example, alnico magnets, ferrite magnets, neodymium magnets and the like are used.

The power generation structure 30 adopts a means for generating power by inserting the tip of the rotary rotor shaft 31 in which the permanent magnet 32 is embedded into the power generation ring 34. That is, when the tip of the rotary rotor shaft 31 in which the permanent magnet 32 is embedded rotates in the power generation ring 34, an induced electromotive current (magnetic induced current) is generated in the power generation coil 35 inserted in the power generation ring 34. ..

The power generation ring 34 is made of an insulating material such as ceramic, and is formed in a ring shape (annular ring) through which the tip of the rotating rotor shaft 31 can be inserted in the center. One or a plurality of through holes are formed radially from the center of the power generation ring 34, and a power generation coil 35 in which a conductive steel wire (copper wire) is wound in a coil shape is inserted in the through holes. It is fitted. At this time, the cross-sectional area of the power generation ring 34, the diameter of the through hole, the diameter of the power generation coil 35, and the number of turns are not particularly limited, and are appropriately within the best range in consideration of the current collection efficiency while considering the electric resistance and the like. It can be decided.

It should be noted that the shape of the through hole formed in the power generation ring 34 can be tapered inward. At this time, the shape of the power generation coil 35 to be inserted also forms a tapered shape that gradually expands inward according to the shape of the through hole. By adopting such an embodiment, it is expected that the amount of power generation of the induced electromotive current (magnetic induced current) will be increased due to the relationship of the generated magnetic force.

The circulation circuit structure 40 is a circuit structure for outputting the generated electric power to the outside and using a part of the electric power for power transmission to the electromagnet arranged in the generator. The collector 41 and the distributor 42 , A secondary battery 43, an inverter converter 44, and a pressure regulator 45.

The collector 41 is a device provided for collecting the magnetically induced current generated and output by the power generation structure 30.

The distributor 42 is a device provided for distributing the magnetic induced current collected in the collector 41 to a plurality of currents so that the ratio of the voltage and the current is not disturbed, and is provided as a distribution destination for an external output and a generator. There is one for its own electromagnet.

The secondary battery 43 is provided to store the magnetically induced current, and is also called a storage battery (rechargeable battery). The secondary battery 43 stores the generated magnetically induced current and outputs it to the outside when necessary or for the initial operation of the generator. It is for use. There is no limitation on the specific structure of the secondary battery 43, and it is sufficient to use a conventional one.

The inverter converter 44 is a device for converting the output magnetically induced current into a useful current as appropriate. For example, a conversion circuit between direct current and alternating current, or alternating current having a different frequency from direct current or alternating current is generated (inverse conversion). It is a power supply circuit or a device that has that circuit. It is also called an inverse conversion circuit or an inverse conversion device, and is a device that can obtain an energy saving effect by combining it with a control device. By providing such an inverter converter 44, it is possible to supply the required type of electric power.

The pressure regulator 45 is a device provided to prevent overcurrent, overcharge, and overdischarge when the generated magnetic induced current is transmitted to the electromagnet in which the generator itself exists. That is, the pressure regulator 45 is provided at an intermediate portion of the distribution line between the distributor 42 and the electromagnet guide rail 22 and the induction electromagnet 23 provided on the magnetic induction fixing plate 21.

The power generation structure of the magnetic induction generator 10 according to the present embodiment having the above configuration will be described.
The magnetic induction rotation is performed by the magnetic induction structure 20 formed by arranging one magnetic induction rotation plate 26 in the middle of the two magnetic induction fixing plates 21 arranged one above the other.
Specifically, an electromagnet guide rail 22 is arranged in a circular shape inside the magnetic induction fixing plate 21 facing the top and bottom, and the magnetism arranged in the middle of the magnetic induction fixing plate 21. Orbital rotating permanent magnets 25 are arranged on both the upper and lower surfaces of the induction rotating disk 26 so as to face the electromagnet guide rail 22. When power is transmitted to the electromagnet guide rail 22, a magnetic force that repels the orbital rotating permanent magnet 25 existing at the opposite position is generated, whereby the magnetic induction rotating disk 26 is suspended in a manner sandwiched between the upper and lower magnetic induction fixing plates 21. It becomes.

Two induction electromagnets 23 are arranged on the central circle inside the electromagnet guide rail 22 at intervals of 180 ° on the magnetic induction fixing plate 21, and 72 on both the upper and lower sides of the magnetic induction rotating plate 26. Five rotation-guided fixed permanent magnets 24 are arranged at ° intervals. When a magnetic force is generated by energizing the induction electromagnet 23, the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 repeat attraction and repulsion, so that the magnetic induction rotation disk 26 starts a rotational movement. At this time, since the magnetic induction rotating plate 26 is in a floating state with respect to the upper and lower magnetic induction fixing plates 21, friction due to rotation does not occur.

Here, the correlation between the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 in the rotational operation of the magnetic induction rotation disk 26 will be described with reference to FIG. In the drawings, for convenience of explanation, the magnetic induction fixing plate 21 and the induction electromagnet 23 are drawn with broken lines, and the magnetic induction rotation plate 26 and the rotation induction fixed permanent magnet 24 are drawn with solid lines.
Two patterns are assumed for the relationship between the magnetic poles of the induction electromagnet 23 and the rotation induction fixed permanent magnet 24, and the first pattern is arranged on the magnetic induction fixing plate 21 as shown in FIG. 3A. The north pole of the induced electromagnet 23 is arranged toward the side of the magnetic induction rotating disk 26, and the S pole of the magnetic pole of the rotation induction fixed permanent magnet 24 arranged on the magnetic induction rotating disk 26 is on the rotation traveling direction side. , The north pole is arranged on the opposite side of the rotation traveling direction.

In the first pattern, when all of the two induction electromagnets 23 and the five rotation induction fixed permanent magnets 24 are in the displaced positions (positions that do not overlap), the rotation induction fixed permanent magnets 24 are on the rotation traveling direction side. The existing S pole and the N pole of the induction electromagnet 23 are attracted to each other, and the N pole existing on the opposite side of the rotation traveling direction of the rotation induction fixed permanent magnet 24 and the N pole of the induction electromagnet 23 repel each other, thereby causing magnetic induction rotation. The board 26 acts to rotate in the direction of travel.

Further, when any of the two induction electromagnets 23 and the five rotation induction fixed permanent magnets 24 are in the overlapping position, the S pole and the induction electromagnet 23 existing on the rotation traveling direction side of the rotation induction fixed permanent magnet 24 are also the same. The magnetic induction turntable 26 rotates in the direction of travel as the N poles attract each other and the N poles on the opposite side of the rotation induction fixed permanent magnet 24 and the north pole of the induction electromagnet 23 repel each other. It works as much as possible.

At this time, the relationship between the magnetic poles of the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 existing at the overlapping positions becomes a problem. That is, when the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 overlap, more specifically, when the induction electromagnet 23 and the S pole portion of the rotation induction fixed permanent magnet 24 overlap, the magnetic force relationship becomes balanced and the magnetism The problem is that the rotation of the induction turntable 26 may stop. However, the magnetic induction turntable 26 is rotating in the traveling direction in the first place, and when the two overlap each other, the bias in the traveling direction is applied, and the rotation induction fixed permanent magnet is added to the other non-overlapping induction electromagnets 23. The above-mentioned action with 24 also exists, and further, the positional relationship between the induction electromagnet 23 of the upper magnetic induction fixing plate 21 and the rotation induction fixed permanent magnet 24 on the upper surface of the magnetic induction rotation plate 26 is the lower magnetism. Since the positional relationship between the induction electromagnet 23 of the induction fixing plate 21 and the rotation induction fixed permanent magnet 24 on the lower surface of the magnetic induction rotation plate 26 is deviated, it is not assumed that both magnets overlap at the same time on both the top and bottom. Since the action of inquiry and repulsion is always working, the rotation of the magnetic induction turntable 26 never stops and continues.

The second pattern regarding the relationship between the magnetic poles of the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 is that the magnetic poles of the induction electromagnet 23 arranged on the magnetic induction fixing plate 21 are magnetic as shown in FIG. 3 (b). The magnetic induction fixing plate 21 has an N pole on the rotation traveling direction side of the induction rotating plate 26 and an S pole on the opposite side of the rotation traveling direction, and the magnetic poles of the rotation induction fixed permanent magnets 24 arranged on the magnetic induction rotating plate 26. It is a mode in which the north pole is arranged toward the side of the magnet.

In the second pattern, when all of the two induction electromagnets 23 and the five rotation induction fixed permanent magnets 24 are in the displaced positions (positions that do not overlap), the magnetic induction in the induction electromagnet 23 of the magnetic induction fixing plate 21 The S pole existing on the opposite side of the rotation traveling direction of the rotating disk 26 and the N pole of the rotating induction fixed permanent magnet 24 are attracted to each other, and are present in the rotation traveling direction of the magnetic induction rotating disk 26 in the induction electromagnet 23 of the magnetic induction fixing plate 21. When the N pole and the N pole of the rotation induction fixed permanent magnet 24 repel each other, the magnetic induction rotation disk 26 acts to rotate in the traveling direction.

Further, when any of the two induction electromagnets 23 and the five rotation induction fixed permanent magnets 24 are in the overlapping position, the rotation traveling direction of the magnetic induction rotation plate 26 in the induction electromagnet 23 of the magnetic induction fixing plate 21 is the same. The S pole existing on the opposite side and the N pole of the rotation induction fixed permanent magnet 24 are attracted to each other, and the N pole existing in the rotation traveling direction of the magnetic induction rotation plate 26 in the induction electromagnet 23 of the magnetic induction fixing plate 21 and the rotation induction fixed permanent magnet. When the N poles of the 24 repel each other, the magnetic induction rotating disk 26 acts to rotate in the traveling direction.

Regarding the relationship between the magnetic poles when the induction electromagnet 23 and the rotation induction fixed permanent magnet 24 are present at the overlapping positions, the magnetic induction rotation disk 26 never stops and continues to rotate without any problem. It is the same as one pattern.

A rotary rotor shaft 31 in which a plurality of permanent magnets 32 are embedded at the tip is extended below the central axis of the magnetic induction rotary disk 26, and when the magnetic induction rotary disk 26 rotates, the rotary rotor shaft 31 also interlocks with the rotation rotor shaft 31. Rotate. Since the tip of the rotary rotor shaft 31 is inserted into the power generation ring 34, the permanent magnet 32 rotates in the power generation ring 34 due to the rotation of the rotary rotor shaft 31, and is inserted into the power generation ring 34. An induced electromotive force (magnetic induced current) is generated in the power generation coil 35.

The generated induced electromotive current (magnetic induced current) is distributed by the distributor 42 via the collector 41. The distribution ratio is appropriately determined in consideration of the electric power required by the generator. For example, the distribution ratio is 1: 1: 8, and 10% of the current is magnetically induced and fixed above. The current flows to the electromagnet guide rail 22 and the induction electromagnet 23 arranged on the panel 21, and 10% of the current flows to the electromagnet guide rail 22 and the induction electromagnet 23 arranged on the lower magnetic induction fixing plate 21, and remains. It is conceivable that 80% of the current flows to the secondary battery 43 and is stored.

The electric power stored in the secondary battery 43 is converted into an optimum mode such as direct current or alternating current via the inverter converter 44, and is output to the outside.

In general, the flow of generated electricity (transmission mode) will be briefly described as follows.
The electricity generated by the power generation structure 30 in which the tip of the rotary rotor shaft 31 in which the permanent magnet 32 is embedded is inserted into the power generation ring 34 is from the collector 41 to the distributor 42 and from the distributor 42 to the secondary battery 43 or the pressure regulator. 45, the flow is from the secondary battery 43 to the inverter converter 44, from the pressure regulator 45 to the electromagnet guide rail 22 and the induction electromagnet 23, and from the inverter converter 44 to the external electromechanical equipment.

The magnetic induction generator 10 according to the present embodiment configured as described above is composed of a magnetic induction structure 20, a power generation structure 30, and a circulation circuit structure 40, and is further generated by the magnetic induction structure 20 and the power generation structure 30. The electric power is output to the outside, and the circulation circuit structure 40 makes it possible to provide the magnetic induction generator 10 that can be used to energize the electromagnets arranged in the generator itself.

The magnetic induction generator 10 according to the present embodiment can adopt a means in which the distributor 42 is provided with a breaker 46 having an earth leakage breaker function. There is no limitation on the specific structure of the breaker 46, and it is sufficient to adopt a conventional method.
At this time, it is more preferable to adopt a vibration-sensing type for the breaker 46, which shuts off the earth leakage when the shaking is detected.

The magnetic induction generator 10 of the embodiment of the present invention adopting the above means is provided with a breaker 46 having an earth leakage breaker function, so that it can be used in various environments such as a power plant, a ship, and an automobile. In addition to being able to be deployed, it is also effective as a blocking function when it gets wet with water, and by adopting a vibration-sensing type that shuts off earth leakage when the breaker 46 senses shaking, accidents and disasters due to large earthquakes etc. can be prevented. It provides a magnetic induction generator 10 which can be suppressed to the minimum.

The magnetic induction generator 10 according to the present embodiment can adopt a means in which the secondary battery 43 is provided with at least one connection terminal 47 for power transmission or power reception.

In the magnetic induction generator 10 of the embodiment of the present invention that employs the above means, the secondary battery 43 is provided with a connection terminal 47 for power transmission, so that external electricity is supplied according to the storage state of the secondary battery 43. It is possible to connect and use machinery and equipment. It is also possible to use the electric power stored in the secondary battery 43 as the initial starting electric power of the magnetic induction generator 10 itself.

Further, since the secondary battery 43 is provided with a connection terminal 47 for power input, when power cannot be stored due to deterioration of the secondary battery 43 or the like, power is input from external power via the connection terminal 47. Therefore, it is possible to replace a part of the functions of the secondary battery 43.

It is also possible to provide the connection terminal 47 not only for power transmission and for power reception but also for both.
Further, it is conceivable that the connection terminal 47 is provided with an ON / OFF function. That is, it is an embodiment in which the usage state of the wiring is switched by the ON / OFF function while the wiring is connected to the connection terminal 47.

The magnetic induction generator according to the present invention is composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure. Further, the electric power generated by the magnetic induction structure and the power generation structure is output to the outside and the circulation circuit. Since the structure makes it possible to energize the electromagnets arranged in the generator itself, it is possible to provide a magnetic induction generator that is inexpensive and easy to maintain. Therefore, it is considered that the industrial applicability of the "magnetic induction generator" according to the present invention is extremely large.

10 Magnetic induction generator 20 Magnetic induction structure 21 Magnetic induction fixing plate 22 Electromagnet guide rail 23 Induction electromagnet 24 Rotational induction fixed permanent magnet 25 Orbital rotating permanent magnet 26 Magnetic induction rotating plate 26a Magnetic shield material 30 Power generation structure 31 Rotating rotor shaft 32 Permanent Magnet 33 Drill hole 34 Power generation ring 35 Power generation coil 40 Circulation circuit structure 41 Collector 42 Distributor 43 Secondary battery 44 Inverter converter 45 Pressure regulator 46 Breaker 47 Connection terminal

In order to solve the above problems, the present invention is a magnetic induction generator composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure, and an electromagnet guide rail provided around in a circular shape and the electromagnet guide rail thereof. Two induction electromagnets arranged at 180 ° intervals on the inner center circle, and a magnetic induction fixing plate formed of an insulating material in which the two induction electromagnets are arranged are opposed to each other vertically, and the magnetic induction fixing plates facing each other are opposed to each other. In the middle of the above, a plurality of orbital rotating permanent magnets that rotate and move on the orbit of the electromagnet guide rail without contact are provided in an endless circle or in a circular shape, and at intervals of 72 ° on the inner center circle. A magnetic induction rotating disk formed of an insulating material in which five rotating induction fixed permanent magnets are arranged on the upper and lower surfaces are arranged, and integrally molded with the insulating material below the central axis of the magnetic induction rotation disk. At the same time, a rotating rotor shaft with a plurality of permanent magnets embedded in the tip is extended, and a hole through which the rotating rotor shaft can be inserted is provided in the center of the magnetic induction fixing plate arranged below, and a power generation structure is formed. Is formed by inserting the tip of a rotating rotor shaft in which a permanent magnet is embedded into a power generation ring in which a power generation coil is inserted and a ring shape is formed. The circulation circuit structure collects the output magnetically induced current. A collector / distributor, a distributor that distributes the magnetically induced current, a secondary battery that stores the magnetically induced current and is equipped with a connection terminal for incoming power, and an inverter converter that converts the output magnetically induced current. It is composed of a pressure regulator that prevents overcurrent, overcharge, and overdischarge, and the power generated by the magnetic induction structure and power generation structure is output to the outside by the circulation circuit structure and distributed to the generator itself. Take the means used to energize the electromagnet.

Further, the present invention may adopt a means in which the secondary battery is provided with at least one connection terminal for power transmission.

The magnetic induction generator 10 according to the present invention is composed of a magnetic induction structure 20, a power generation structure 30, and a circulation circuit structure 40, and the magnetic induction structure 20 is an electromagnet guide rail 22 provided around in a circular shape. And the magnetic induction fixing plate 21 formed of the insulating material in which the two induction electromagnets 23 arranged at 180 ° intervals on the inner center circle are opposed to each other, and are opposed to each other. A plurality of orbital rotating permanent magnets 25 that rotate and move on the orbit of the electromagnet guide rail 22 in a non-contact manner are provided in the middle of the magnetic induction fixing plate 21 so as to be scattered in an endless circumference or in a circular shape. A magnetic induction rotary disk 26 formed of an insulating material in which five rotation induction fixed permanent magnets 24 arranged at intervals of 72 ° on a central circle are arranged on the upper and lower surfaces is arranged, and the center of the magnetic induction rotation disk 26 is arranged. A rotating rotor shaft 31 integrally molded with an insulating material and having a plurality of permanent magnets 32 embedded in the tip thereof is extended below the shaft, and the rotating rotor shaft 31 is located at the center of the magnetic induction fixing plate 21 arranged below. The power generation structure 30 is formed in a power generation ring 34 in which the tip of a rotary rotor shaft 31 in which a permanent magnet 32 is embedded is formed in a ring shape and a power generation coil 35 is inserted. The circulation circuit structure 40 is composed of a collector 41 that collects the output magnetically induced current, a distributor 42 that distributes the magnetically induced current, and a magnet that is inserted into the power generation ring 34. A secondary battery 43 that stores an induced current and is equipped with a connection terminal 47 for receiving electricity, an electromagnet converter 44 that converts the output magnetic induced current, and a pressure regulator that prevents overcurrent, overcharge, and overdischarge. The electric power generated by the magnetic induction structure 20 and the power generation structure 30 is output to the outside by the circulation circuit structure 40 and is used to energize the electromagnets arranged in the generator itself. The biggest feature is that the means are taken.
Hereinafter, embodiments of the magnetic induction generator 10 according to the present invention will be described with reference to the drawings.

The secondary battery 43 is provided to store the magnetically induced current, and is also called a storage battery (rechargeable battery). The secondary battery 43 stores the generated magnetically induced current and outputs it to the outside when necessary or for the initial operation of the generator. It is intended for use, and is provided with a connection terminal 47 for receiving power to receive power from external power. The electric power stored in the secondary battery 43 by receiving electric power from an external electric power via the connection terminal 47 can be used as the initial starting electric power of the magnetic induction generator 10 itself . There is no limitation on the specific structure of the secondary battery 43, and it is sufficient to use a conventional one.

The magnetic induction generator 10 according to the present embodiment can adopt a means in which the secondary battery 43 is provided with at least one or more connection terminals 47 for power transmission in addition to the one for power reception.

Further, it is conceivable that the connection terminal 47 is provided with an ON / OFF function. That is, it is an embodiment in which the usage state of the wiring is switched by the ON / OFF function while the wiring is connected to the connection terminal 47.

Claims (8)

It is a magnetic induction generator composed of a magnetic induction structure, a power generation structure, and a circulation circuit structure.
The magnetic induction structure is magnetic formed by an insulating material in which an electromagnet guide rail provided around a circle and two inductive electromagnets arranged at 180 ° intervals on a central circle inside the guide rail are arranged. The induction fixing plate is opposed to the top and bottom, and in the middle of the magnetic induction fixing plate facing the top and bottom, an orbital rotating permanent magnet that rotates and moves on the orbit of the electromagnet guide rail without contact is formed in an endless circumference or a circular shape. A magnetic induction rotating disk formed of an insulating material in which five rotation induction fixed permanent magnets arranged at 72 ° intervals on the inner center circle are arranged on the upper and lower surfaces is arranged. Then, below the central axis of the magnetic induction rotary disk, a rotary rotor shaft integrally molded with an insulating material and having a plurality of permanent magnets embedded in the tip thereof is extended, and the center of the magnetic induction fixing plate arranged below. Is provided with a hole through which the rotating rotor shaft can be inserted.
The power generation structure is formed by inserting the tip of the rotary rotor shaft in which a permanent magnet is embedded into a power generation ring formed in a ring shape and in which a power generation coil is inserted.
The circulation circuit structure converts the output magnetic induced current into a collector / distributor that collects the output magnetic induced current, a distributor that distributes the magnetic induced current, a secondary battery that stores the magnetic induced current, and the output magnetic induced current. It consists of an inverter converter and a pressure regulator that prevents overcurrent, overcharge, and overdischarge.
The magnetic induction power generation is characterized in that the electric power generated by the magnetic induction structure and the power generation structure is output to the outside by the circulation circuit structure and is used for energizing an electromagnet arranged in the generator itself. Machine. The first aspect of the magnetic induction rotary disk, wherein the rotation induction fixed permanent magnet on the lower surface is arranged at a position shifted by 36 ° with respect to the rotation induction fixed permanent magnet arranged on the upper surface. Magnetic induction generator. The claim is characterized in that, in the magnetic induction fixing plate, the induction electromagnet of the lower magnetic induction fixing plate is arranged at a position shifted by 90 ° with respect to the induction electromagnet arranged on the upper magnetic induction fixing plate. Item 2. The magnetic induction generator according to item 1 or 2. The magnetic poles of the induction electromagnets arranged on the magnetic induction fixing plate are N poles toward the magnetic induction rotation plate side, and the magnetic poles of the rotation induction fixed permanent magnets arranged on the magnetic induction rotation plate are on the rotation traveling direction side. The magnetic induction generator according to any one of claims 1 to 3, wherein the magnetic induction generator has an S pole toward the surface and an N pole toward the side opposite to the direction of traveling of rotation. The magnetic poles of the induction electromagnets arranged on the magnetic induction fixing plate are N poles toward the rotation traveling direction side of the magnetic induction rotation plate and S poles toward the opposite side of the rotation traveling direction. The magnetic induction generator according to any one of claims 1 to 3, wherein the magnetic poles of the arranged rotation induction fixed permanent magnets are N poles toward the magnetic induction fixing plate side. The magnetic induction generator according to any one of claims 1 to 5, wherein a magnetic shield material is embedded in the middle of the magnetic induction rotating disk. The magnetic induction generator according to any one of claims 1 to 6, wherein the distributor is provided with a breaker having an earth leakage breaker function. The magnetic induction generator according to any one of claims 1 to 7, wherein the secondary battery is provided with at least one connection terminal for power transmission or power reception.