JP2000083366A - Magnetic permanent power equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To strengthen power by obtaining a drive force in one direction due to repulsion- attraction by means of the magnetic action of an outer magnet and a fixed inner magnet and then adding it to the total drive force. SOLUTION: In the case of cylindrical equipment, N-pole and S-pole of a permanent magnet 1 is divided by a grooved pit and fixed to parallel cylindrical types, the inner magnet 2 is made of many permanent magnets arranged vertically around a shaft 7 as a center with the polarity created by a homogeneous pole in a shape of an embedded ring, a cylindrical type fixed inner magnet 3 having a thick wall at the inner side comprises permanent magnets with divided N-pole and S-pole and is arranged and fixed at the bottom portion of the equipment. Also, the inner magnet 2 supported by bearings at the top and bottom of the equipment is set freely rotatable, a movable core 28 is planted among the permanent magnets of the outer magnet 1 and fixed inner magnet 3, and multi-pole coils 29 is wound around it. An inner magnetic core 10 of a generator provided in an upper portion of the shaft 7 clamps a pipe-shaped steel pipe at the inner side, and excitation coil 11 of the generator is wound is the outer peripheral space. Then, the projections conforming with the number of poles of the inner magnetic core 10 of the generator are provided with the laminated cores of power generating core 8, a power generating coil 9 is wound, and the current is converted into DC via diodes and transmitted to the excitation coil 11. In this way, power can be strengthened.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a permanent power source that uses no repulsion and attraction of a permanent magnet as a power source and consumes no material.

[0002]

2. Description of the Related Art All existing power sources except for hydropower, wind power, solar power and the like are subject to resource consumption, and there is no permanent power without physical consumption.

[0003]

In order to convert the static magnetism of a permanent magnet into motive power, the magnetic action must be gathered in one direction. Height is required, a step is provided, a new ramp is made, many balls are placed on each ramp, and the overall transfer weight is the same as lifting the top ball with a step, and the specific direction is not visible Was.

[0004]

Referring to the schematic diagram of FIG. 1, a large number of two permanent magnets are arranged side by side in the horizontal direction and face in a gap with a 2-1 sliding plate fixedly arranged in one direction. One plate-shaped permanent magnet is a plate-like structure in which the N pole and S pole are divided by groove piles, and is fixed in parallel in the sliding direction. In order to reduce the magnetic resistance associated with one magnet of the sliding plate facing the strong magnetic field when passing through the one plate-shaped permanent magnet, the plate-shaped magnet is formed into a 1-1 oblique shape to assist self-propelling. Further, a 28-pole iron core is implanted between one plate-shaped magnets, a 29-pole coil is mounted on the core, and an alternating voltage is applied to the magnet to attract by suction and repel and transfer in the sliding direction by 28.
The switching of the polarity to the magnetic field of the shifting core is performed in a timely manner so that the power is increased by adding to the total driving force as propulsion except for the magnetic resistance.

[0005]

FIG. 2 is an exploded view of the apparatus. FIG. 2 is an exploded view of a cylindrical apparatus. One thick permanent magnet N pole / S pole is divided into grooves on the inner arc surface and fixed in a parallel cylindrical form. 2 The inner magnet is a ring-like shape in which the polarity of a large number of permanent magnets is embedded in one pole in the vertical direction centering on 7 axes.
The inner magnet, which is made up of permanent magnets with divided poles and is fixed at the bottom of the machine, is supported by upper and lower bearings. The magnetic core in the generator 10 provided with a 28-pole core between the permanent magnets, a 29-pole coil mounted on the upper part of the 7-axis, and a pipe-shaped iron tube inside the shape of both hands combined with scissors, and a peripheral space around the core To 1
1 Excitation coil for power generation, 12 laminated cores of 8 power generation cores that proliferate to 12 commutators, and 10 Rectifications corresponding to the number of internal magnetic poles of the power generation. Rectified to direct current via diode and send to 11 excitation coil, 9
The power is sent directly from the generator coil to the 29-transfer coil to enhance the power. FIG. 3 is a partial cutaway view of the combination, showing 14
The output adjustment knob 20 is a power outlet for pushing and incorporating the power generation internal magnet of the bearing 10. FIG. 4 is a schematic structural diagram showing 1 outer magnet, 2 ring-shaped inner magnet, 3 fixed inner magnet 28, shifting core 29.
Is a transfer coil.

FIG. 5 is a schematic diagram of the circuit.
Power is sent to the 11 excitation coil through a diode, but changes in the rotational speed of the power and the load of the power to be taken out cause instability of the electromotive force. Therefore, the strength of the 11 excitation coil is controlled through a 31 transistor zener diode or the like and within a certain limit. Output stability.

FIG. 6 shows a disk-shaped device for reducing the size of the device, which is provided with one permanent magnet divided into N and S poles.
The inner surface of the fixed disk is attached in parallel to the surface of the disk, and 28 poles are implanted between the magnets. 29 poles are installed. The polarity of the permanent magnet is set to one pole, the pole faces are exposed on both sides of the board, and a large number of them are buried radially, and they are embedded in a flat disc shape. One external magnet is sandwiched by a gap. Is a powerful small power that is housed in a device together with a power generation mechanism, 21 is an output adjustment knob 20, and a power outlet 19 is a speed reducer.

FIG. 7 and FIG. 8 show that a large number of two internal magnets are molded and integrated in order to mass-produce the magnets. 7 is a cylindrical ring shape, FIG. 8 is a combination of flat plate shapes, and FIG.
Reverse-fixed type, in which permanent magnets having N and S poles divided on the rotating disk surface of the inner magnet are fixed in parallel on the disk surface, and a large number of permanent magnets are radially arranged on one outer magnetic disk surface with one of the poles turned out. The same can be adopted for the cylindrical type, and the structure is determined structurally.

FIG. 10 shows various types of high-frequency members corresponding to the number of magnets having two internal magnets and a high frequency member made of laminated steel plates having high speed and mass productivity by, for example, ferrite molding sintering, corresponding to the increase in the number of internal magnets and the speed. The iron core is a molded product.

[0010]

The power unit of the present invention has a wide variety of uses from small to large, and its driving force will be improved in the future and will be expensive. For example, a rare magnet or a superconducting magnetic power unit will be available. It has been suggested that the facilities respond appropriately in terms of function and price, and the effect of permanent power without consuming fuel and polluting the atmosphere is great.

[Brief description of the drawings]

FIG. 1 is a basic principle diagram of the present invention.

FIG. 2 is an exploded perspective partial cutaway view of the device.

FIG. 3 is a partially cutaway view of a combination of devices.

FIG. 4 is a schematic diagram of the apparatus.

FIG. 5 Circuit summary diagram

[Fig. 6] Disc-type compact powerful device

Fig. 7 Integration of cylindrical magnet

FIG. 8: Disc-shaped magnet integrated combination

FIG. 9: Reverse fixed type structure

Fig. 10 Transfer iron core ferrite molding

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 fixed magnet, outer magnet 1-1 oblique shape 2 inner magnet 3 fixed inner magnet 7 main shaft 8 generator laminated core 9 power generation coil 10 power generation internal magnet 11 power generation excitation coil 12 commutator 13 device body 14 bearing 20 power take Exit 21 Output adjustment knob 28 Transfer iron core Molding various 29 Transfer coil 30 Rectifier diode 31 Adjustment transistor

Claims (4)

[Claims] An air gap is formed by an axis in a space between an external magnet in which permanent magnets divided into N and S poles are arranged side by side on the inner surface of the device and a fixed internal magnet formed by dividing N and S poles in the center of the device. The internal magnet that is driven to rotate is a ring-shaped ring in which a large number of permanent magnets are vertically arranged and fixed in a cylindrical shape. The magnetic permanent magnet generates a unidirectional driving force by repulsion and attraction by the magnetic action of the external magnet and the fixed internal magnet. Power plant. 2. A disk-type internal magnet in which permanent magnets obtained by dividing N and S poles are arranged in parallel with the inner surface of the device disk and driven to face an external magnet fixed to the inner surface of the device disk. A permanent magnetic power unit with a structure in which a large number of radial magnets are fixed radially and an external magnet sandwiches them across a gap. 3. A plurality of permanent magnets according to claim 1 arranged in one pole and an external magnet fixed to the inner surface of the apparatus and permanent magnets divided into N poles and S poles are provided in a rotation drive unit. Magnetic permanent power unit with inverted structure 4. A pole-changing core is stood and planted between the parallel external magnets according to claim 1 and claim 2 and between the magnets of the rotary drive part according to claim 3, and a pole-changing coil is mounted thereon. A magnetic permanent power unit that reinforces the power by adding the voltage to the overall driving force as a propulsion force except for the reluctance when transferring and changing the polarity of the magnetic field with the facing magnet