KR20100099675A - Magnetic control magnetic motorizing device - Google Patents

Abstract

PURPOSE: A magnetic controlled power device is provided to generate a driving force through a rotation shaft by controlling the repulsion of magnets. CONSTITUTION: A circular fixing plate(A) is inserted into connecting pivots(2-1). Oil-hydraulic circuits(5,5-1) are connected to moving bearings which is mounted on fixed magnets. A permanent magnet is installed at the circular rim of the fixed magnets. The movement bearing is mounted in the fixed magnet. The permanent magnet is mounted in rotator magnets(3,3-1). The fixed magnet is inserted into the rotator magnet. The rotator magnet is inserted into the connecting pivot.

Description

Magnetically controlled magnetic motorizing device {omitted}

The present invention relates to a magnetic force control apparatus and method for generating a magnetic force by combining a permanent magnet and a permanent magnet to control the magnetic force.

Conventionally required power is easily obtained and used in the rotation operation of the electric motor, the electric energy is supplied to the operation of the electric motor, this electricity is supplied with electricity generated by hydro, fossil fuel, nuclear fuel and the like.

Recently, as carbon dioxide emission suppression and energy saving are required to prevent global warming, an energy saving method has been proposed to generate electricity by using permanent magnets and electromagnets in a rotating device.

For example, in the Japanese patent application of the magnetic rotating device (Public Publication No. 2006-246605 (P2005-246605A)), by installing the permanent magnet and electromagnet on the drive shaft of the driving device that rotates by receiving energy from the outside to generate electricity There is proposed an energy saving device used as energy of the drive device.

In the magnetic rotating device, various types of devices, such as a controller, an identification device, and a device for controlling the generated electric power, are added to the rotating device consisting of a permanent magnet and an electromagnet.

Since it is difficult to control the magnetic force by the permanent magnet alone, in order to control the magnetic force, electricity is generated while controlling the magnetic force using the permanent magnet and the electromagnet and used in the apparatus.

By using a combination of permanent magnets and electromagnets for magnetic force control as described above, the apparatus becomes larger, requires additional equipment, increases costs, and also complicates management.

The present invention, in order to solve the problems seen above, a circular rotating magnetic body in which a plurality of permanent magnets are mounted and rotated inside a circular fixed magnet (4 · 4-1) in which a plurality of permanent magnets are mounted and fixed By inserting, burying and separating (3 · 3-1), the magnetic force is generated while the repulsive force of the magnetic force is generated and the magnetic force is controlled while the repulsive force is lost.

It is an object of the present invention to provide an apparatus and method for directly reducing the energy supplied to a driving device by directly supplying the driving force of the magnetic force generated while controlling the repulsive force of the magnetic force as described above.

A connecting rotary shaft 2-1 is provided with a rotary shaft connector 2 for connecting to a rotary shaft of a drive device that operates a rotary operation. A circular fixed plate A is inserted into the connecting rotary shaft 2-1 to form a center. Fixed to the hydraulic device connected to the movable bearings (2-2, 2-3) protrudingly mounted to the stator magnets (4, 4-1) in order from the left and right outer sides of the fixing plate (A). 5-1), the permanent magnet is mounted on the circular frame (L) and the fixed magnet (4 · 4-1) with the movable bearing (2-2 · 2-3) protrudingly mounted, and the permanent magnet is mounted A rotating magnet 3 · 3-1 inserted and buried in the 4 · 4-1 is inserted and mounted in the connecting rotary shaft 2-1, and the fixed magnet 4 · 4-1 and the fixed plate A 4 supporting ring rods 10 are attached to the vibration shield (B).

The hydraulic device 5 · 5-1 is connected to the projection of the movable bearing 2-2 · 2-3 protruding from the stator magnet 4 · 4-1 and is fixed at both ends thereof during operation. 4 · 4-1) is moved toward the center where the fixing plate A is placed and retracted to its original position.

The stationary magnet body 4 · 4-1 is a non-magnetic body, which is a circular plate, and a moving bearing 2-2 · 2-3 protrudes outwardly and is mounted at the center thereof, and a circular rim L is provided at the inner side. A plurality of permanent magnets 7 are mounted, a circular space is secured inside by laying the circular rim L, and the rotating magnets 3 · 3-1 are inserted and buried in the circular space.

In the above circular rim (L) is made of a long quadrilateral of the size to which the permanent magnet (7) can be mounted in a circle along the inner circumferential end, the permanent magnet (7) along the circumference of the circular rim (L) ) Is mounted in plural and the magnetic poles are mounted in an inclined direction.

In the above, a safety distance for preventing contact between the stator magnet 4 · 4-1 and the rotor magnet 3 · 3-1 is secured to 10 mm (mm).

The rotating magnet 3 · 3-1 is circular as a non-magnetic material, and is sized to be buried in the circular rim L of the stator magnet 4 · 4-1. The magnetic poles of the permanent magnets 8 are inclined in the same direction, and the insertion hole C is placed in the center thereof. ) Is rotated together.

In the apparatus configured as described above, by the operation of the hydraulic device 5 · 5-1, the stationary magnet body 4 · 4-1 inserts and embeds the rotor magnet body 3 · 3-1, and permanently built therein. The magnets face each other with the same magnetic pole (N) and a repulsive force is generated so that the rotating magnet 3 · 3-1 rotates, and the rotating magnet body is operated by the opposite operation of the hydraulic device 5 · 5-1. While (3 · 3-1) is separated from the insertion and the burial, the repulsive force is lost and the repulsive force of the permanent magnet magnetic force is controlled.

By the above operation, the repulsive force of the magnetic force of the permanent magnet is controlled.

As described above, the permanent magnet is controlled so that the magnetic force is energized.

By controlling the repulsive force of the magnetic force, it can be easily used by being connected to the rotating shaft of a drive device with a rotating shaft such as an electric motor and an internal combustion engine.

The repulsive force of the magnetic force is directly used for the driving device, thereby greatly saving energy.

1 is a side sectional view of a magnetic power generator, illustrating the configuration of the device.
2 is a configuration diagram of a rotating magnet, illustrating a mounting state of a permanent magnet.
3 is a mounting diagram of the permanent magnet, illustrating a state in which the permanent magnet is encountered with the same magnetic pole.
4 is a view of connecting the support bar of the stator magnet and the fixed plate.
5 illustrates a state in which a rotating magnet is buried in the stator magnet.

Hereinafter will be described an embodiment of the present invention.

In Fig. 1, the connecting rotary shaft 2-1 is connected to the rotary shaft of the driving device for rotating operation, and the rotary shaft connector 2 is provided.

A circular fixed plate A is inserted into the connecting rotary shaft 2-1, and fixed to the center thereof. The hydraulic device 5 · 5-1 and the moving bearing 2 are sequentially rotated from left and right about the fixed plate A. The stator magnet (4, 4-1) and the rotor magnet (3, 3-1), each of which is protruded and mounted therein, are inserted into and mounted on the connecting rotary shaft (2-1). The support round bar 10 is attached to the vibration shield B attached to 4 * 4-1) and the fixed plate A. As shown in FIG.

The hydraulic device 5 · 5-1 is connected to a moving bearing 2-2 · 2-3 protrudingly mounted on the stator magnet 4 · 4-1 inserted into the outer ends of the connecting rotary shaft 2-1. At the time of operation, the stator magnet 4 · 4-1 is moved to the stationary plate A and retracted to its original position.

Although not shown, the hydraulic device 5 · 5-1 is connected to and controlled by an external hydraulic device.

The hydraulic device 5 · 5-1 may be replaced by a pneumatic device, a screw method, a clutch method, or may be manually operated.

The stationary magnet body 4 · 4-1 is a non-magnetic body which is a circular plate, and the moving bearings 2-2 · 2-3 protrude outwardly and are mounted at the center thereof, and a circular rim L is attached from the inside side thereof. A circular space is secured inside, and vibration shields B are provided on the upper and lower sides and both sides of the stator magnet 4 · 4-1.

In the above circular rim (L) is made of a long quadrilateral of the size to which the permanent magnet (7) can be mounted in a circle along the inner circumferential end, the permanent magnet (7) along the circumference of the circular rim (L) ) Is mounted in plural and the magnetic poles are mounted in an inclined direction.

In the above, four supporting round bars 10 are inserted into the vibration shield B, and the supporting round bars 10 prevent vibration of the stator magnet 4 · 4-1.

In the above, the support ring 10 is processed to smoothly move the vibration shield (B), and is specially processed to prevent the vibration.

The stator magnet 4 · 4-1 has a stator magnet 4 · 4 when the rotor magnet 3 · 3-1 is inserted and buried therein and the rotor magnet 3 · 3-1 rotates. 4-1) secures a safe distance so that the rotating magnets (3 · 3-1) do not come into contact, and the safe distance is a little on the basis of 10mm (mm) which can minimize the loss of repulsive force of the magnetic force. Increase or decrease.

The stator magnet 4 · 4-1 is moved left and right by a moving bearing 2-2 · 2-3, and the moving bearing 2-2 · 2-3 is a hydraulic device (5 · 5-). Move by the operation of 1).

The moving bearings 2-2 and 2-3 are specially manufactured to support the stator magnet 4 and 4-1 and to easily move left and right.

The magnetic pole direction of the permanent magnet 7 mounted on the stator magnet 4 · 4-1 is the magnetic pole of the outer permanent magnet 8 of the rotary magnet body 3 · 3-1, as shown in FIG. It is mounted with the same magnetic pole (N) as (N), and when it encounters, the permanent magnets of both sides face in a straight line, and a repulsive force is generated.

As shown in Fig. 2, the rotating magnet body 3 占 3-1 becomes circular as a nonmagnetic body, and its size can be buried in the space in the circular edge L of the stator magnet 4 占 4-1. It is determined according to the size of the circular border (L), the insertion hole (C) is placed in the center is inserted and fixed to the connecting rotary shaft (2-1) is to rotate with the connecting rotary shaft (2-1).

The rotor magnet 3 · 3-1 has a plurality of permanent magnets 8 inclined in the same direction along the outer end circumference, and the magnetic poles of the permanent magnet 7 of the stator magnet 4 · 4-1. It is mounted to face the same magnetic pole (N) as the magnetic pole.

The rotor magnet 3 · 3-1 is inserted and buried in the circular space in the circular rim L of the stator magnet 4 · 4-1 by the movement action of the stator magnet 4 · 4-1. do.

As shown in Fig. 4, the fixed plate A is a non-magnetic material, which is a circular plate of the same size as the stationary magnet body 4 · 4-1. ) Is inserted, the rotating bearing (6) is mounted in the center and inserted into the connecting rotary shaft (2-1), the fixing plate (A) is fixed at the central position of the connecting rotary shaft (2-1), the connecting rotary shaft (2- It prevents the vibration of 1) and the vibration of the support round bar (10).

In the above, the drive device for connecting the connection rotary shaft 2-1 is used in connection with the rotary shaft in an electric motor, an internal combustion engine, or another type of drive device.

In the apparatus configured as described above, when the hydraulic device 5 · 5-1 is operated, as shown in FIG. 5, both of the stator magnets 4 · 4-1 move toward the stationary plate A to rotate the rotor magnets ( 3 · 3-1) is inserted and buried, and the permanent magnets embedded in the fixed magnet 4 · 4-1 and the rotating magnet 3 · 3-1 while being inserted and buried are the same magnetic poles (N). A repulsive force is generated as it encounters, and this repulsive force is applied to the rotating magnet 3 · 3-1 to rotate the rotating magnet 3 · 3-1.

On the other hand, when the hydraulic device 5 · 5-1 is operated in reverse, the revolving magnet body 3 · 3-1 is separated from the insertion and investment, and the repulsive force is lost.

By the above operation, the repulsive force of the permanent magnet magnetic force is controlled.

As described above, the repulsive force of the magnetic force is controlled, and the magnetic repulsive force of the permanent magnet is motorized and used.

In the above description, the number of the stationary magnets 4 · 4-1 and the rotating magnets 3 · 3-1 may increase or decrease, and the number of permanent magnets 7 · 8 may also increase or decrease.

As described above, the number of rotations and the repulsive force of the magnetic force can be adjusted according to the increase and decrease of the number of the stationary magnets 4 · 4-1 and the rotating magnets 3 · 3-1.

In the present invention, the initial operation of the drive body is rotated by the energy supplied from the outside, after which only the reduced energy is supplied or rotated, or rotates only by the repulsive force of the magnetic force.

In the present invention, there is no heat generation in the rotation operation, thereby preventing deterioration of the permanent magnet due to heat.

The present invention is to control the magnetic force of the permanent magnet, it is connected to the rotary shaft of the drive device having a rotary shaft, such as an electric motor, an internal combustion engine is widely used.

The present invention can be used as a power source of a small generator.

A: fixed plate B: vibration shield
C: insertion hole L: border
1: drive device 2: rotary shaft connector
2-1: Connecting shaft 2-22-2: Moving bearing
3 · 3-1: Rotating magnet 4,4-1: Fixed magnet
5, 5-1: Hydraulic device 6: Rotating bearing
7: permanent magnet 8: permanent magnet
10: support round bar 12: space

Claims (3)

A circular bearing plate (A) is inserted into the connecting rotary shaft (2-1) and fixed to the center, and a movable bearing protrudes from the left and right outer sides of the fixing plate (A) in order to protrude and be mounted on the stator magnet (4, 4-1). Hydraulic device (5, 5-1) connected to (2-2, 2-3), permanent magnet is mounted on the circular rim (L), and the fixed magnet with the movable bearing (2-2, 2-3) protrudingly mounted A rotating magnet body 3 · 3-1, in which a sieve 4 · 4-1 and a permanent magnet is mounted and inserted into and buried in the stationary magnet body 4 · 4-1, is inserted into the connecting rotary shaft 2-1. Magnetically controlled magnetic motorization device, characterized in that the four support ring rods 10 are attached to the vibration shield (B) attached to the stationary magnet body (4 · 4-1) and the fixed plate (A) . 2. The stationary magnet body 4 · 4-1 is a non-magnetic body having a circular plate, and the movable bearings 2-2 · 2-3 protrude outwardly and are mounted at the center thereof, and have a circular edge on the inside side. (L) is laid and a plurality of permanent magnets 7 are mounted, and a circular space is secured inside by laying a circular rim L, and a rotating magnet body 3 · 3-1 is inserted into this circular space. Magnetically controlled magnetic motorizing device, characterized in that the investment. The magnetic force of the magnetic force is generated according to claim 1 or 2, wherein the revolving magnet body 3 · 3-1 is inserted and embedded in the stator magnet 4 · 4-1. Magnetic force control magnetic motorization apparatus characterized in that the repulsive force of the magnet is removed while being separated from the magnetic force is controlled.

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