KR20130049189A - Development magnetic induced - Google Patents

Abstract

PURPOSE: A magnetic field induction generator using magnetic path is provided to maximize generator maintenance and power generation effect, by excluding power generation disturbance like rotation disturbance and MRO(Maintenance Repair and Operating) components like a slip ring and a brush in case that electromotive force is generated and the influence of reverse action due to a load is occurred. CONSTITUTION: A stator core and a magnetic field pole are separated and fixed to face with each other, and a rotor(400) is loaded with independent magnetic paths(400a,400b) in a separate space. Magnetic field of a field magnet(300) passes through a stator core through the magnetic path when the magnetic field pole crosses the magnetic path. Electromotive force is generated by a coil wound around the stator core. A hollow shaft(500) is fixed to the front and the rear of a yoke, and has a wire to supply an excitation current to the field magnet. The hollow shaft is combined to the field magnet. The field magnet comprises a number of cores(304) divided along the circumference, and forms two poles(300A, 300B) by winding a coil(303) around each core. The field magnet is separated from one stator core(202) plane. A power generator comprises a pulley to connect a cooling fan and an external power source together with a rotor installed with a bearing on both sides of the shaft.

Description

Development of magnetic field induction generator using magnetic field

   The present invention relates to a magnetic field induction generator using a magnetic furnace

More specifically, the stator core and the field stimulation are fixed and spaced apart from the magnetic field range or slightly apart from the magnetic field range for uniform motive power input and stable generator output without generating the electromotive force of the generator and adjusting the power output by the load current. When the magnetic field is intersected with the magnetic pole by rotating the rotor equipped with the independent magnetic field coupled to the ferromagnetic material in the space, a circuit is formed through the magnetic field through the stator core, and electromotive force is generated by the coil wound on the stator core. It is about power generation apparatus

In general, a generator is a device that converts mechanical energy into electrical energy, and is used in a wide range of industrial, home, and other applications.

In converting mechanical energy into electrical energy as described above, the coils 21 are wound around the field 30 and the stator core 22, and DC power is applied to the field 30 to form magnetic poles 3A and 3B. A small void is placed between the field 30 and the stator core 20 to rotate the field 30 to induce a magnetic field that changes over time in the stator coil 21 so that electromotive force is generated according to the law of electromagnetic induction.

However, the above power generation method causes secondary power generation deterioration factors due to electromotive force generation and load use. That is, when a certain range of magnetic field generated in the field magnetic poles 3A and 3B affects the stator coil 21. By using them, voltage and current are generated, and by using them, a reverse magnetic field is generated, and a magnetic collision occurs between the field magnetic field and the reverse magnetic field in the stator coil 21. This is a common phenomenon of a general generator. In order to overcome the resistance caused by nuclear power and hydroelectric power, many dynamic power sources and auxiliary facilities must be installed or used.

The general power generation method as described above will be described with reference to the accompanying drawings.

There are many methods of generating a general generator, but here, for the convenience of explanation, the method of generating a rotating field type excitation method is illustrated and described.

1 is a perspective view of a general generator separation

FIG. 2 is a cross-sectional view of a general generator of FIG. 1.

In the general generator shown in FIGS. 1 and 2, the stator 20 is formed by stacking a plurality of thin sheets of silicon steel, and a plurality of cores 22 are provided at regular intervals along an inner circumferential surface and are formed in a slot formed by the core. Insulating material 23 is provided to insulate the coil 21 from the core 22, and the coil is wound and mounted inside the yoke 10.

Like the stator 20, the field 30 is formed by stacking a plurality of silicon steel sheets to form a plurality of cores 32 in a circumferential shape. Furthermore, a coil 33 is wound around the plurality of cores 32 to form an N pole and an S pole. The sequential arrangement is mounted and the rotating shaft 50 is fixed through the center, and the cooling fan 60 and the slip ring 52 are mounted on a predetermined portion of the shaft, and the DC power 90 is supplied through the brush 80. The excitation current is supplied to the winding 33 to provide the magnetic poles 3A and 3B. The magnetic poles are rotatably installed at a predetermined interval along the outer circumferential surface with minute pores inside the stator 20.

Therefore, when the field 30 rotates, the magnetic field of the magnetic pole 3A and the magnetic pole 3B generated in the coil wound on the field alternately, and when a circuit is formed on the wound stator core 22, the magnetic field passes through the core. EMF is generated in the stator coil 21

However, by using this electromotive force, a current flows to the stator coil 21 to generate a magnetic field. The polarity of the magnetic field is generated at the same polarity as the magnetic field magnetic pole polarity, and magnetic collision with the whole magnetic field magnetic field occurs, thereby causing rotational interference.

Therefore, in order to overcome rotational interference and maintain continuous development, there are problems that many dynamic power sources and auxiliary facilities must be installed or used.

In addition, the field 30 is made of a laminated steel sheet and coil, etc., there is a problem that a lot of the support is used to maintain the rotation of the heavy material.

Therefore, in order to solve the above problems, a power generation apparatus having a relatively simple assembly structure has been developed. FIGS. 3 and 4 FIG. 5 shows an example of improving the problems of the existing generators of FIGS. 1 and 2. 202 and the field stimulation (300A) (300B) is fixed to be opposed to the magnetic field range or more or slightly spaced apart from the magnetic field range, and to rotate the rotor 400 mounted with a plurality of independent magnetic path 400A (400B) in the space When the field magnetic pole 300A and the magnetic field 400A intersect, a circuit is formed in which the magnetic field of the field passes through the stator core 202 through the magnetic field 400A, and electromotive force is generated by the coil 201 wound on the stator core. To make it possible

In addition, the furnaces 300A and 300B of the rotor 400 are as shown in FIG. 7.

By arranging a plurality of ferromagnetic material 411 so that the narrow cross-sectional direction of the ferromagnetic material is from the stator core 202 toward the field magnetic pole 300A, the movement path of the magnetic field is straightened, and the ferromagnetic material 411 and the nonmagnetic material 412 are repeatedly combined. Each ferromagnetic material is used as a separate magnetic furnace (400A) (400B)

In addition, each of the separated ferromagnetic materials magnetizes each ferromagnetic material coupled to each other to maximize magnetic field transfer effects by minimizing magnetic field leakage due to dispersion and diffusion of magnetic fields.

As described above, the size of the magnetic field transmitted to the magnetic field can be changed along with the change in the cross-sectional area intersecting with the magnetic field and the rotating magnetic field generated in the field stimulus, and thus the change passing through the stator core 202 according to the changing magnetic field size. The magnetic field affects the coil 201 wound on the stator core, so that electromotive force can be generated by the law of electromagnetic induction.

In addition, the reverse magnetic field generated by using the above electromotive force is also transferred to the ferromagnetic material 411 through the stator core 202, so that the magnetic field 400 can rotate freely under the same polarity and without increasing physical motive force. Possible to improve power generation output

As described above, the general generator needs to input the generation energy to maintain the field rotational force of the heavy object for generating the electromotive force, and in order to overcome the occurrence of the reverse magnetic field due to the characteristics of the load in using the generated electromotive force and to continue to generate power. There are problems to install or use many power sources and accompanying facilities

In addition, it is cumbersome to replace consumable parts such as slip rings and brushes to draw or draw excitation current or load current.

The present invention to solve the above problems to maximize the generator maintenance and power generation effect by eliminating the power generation action, such as rotational disturbances and consumable parts such as slip rings and brushes, even under the influence of adverse effects caused by load with the generation of electromotive force The purpose is.

Other objects, or specific advantages and novel features of the present invention will become more apparent from the detailed description taken in conjunction with the accompanying drawings.

In order to achieve the above object, the magnetic field induction generating apparatus using the magnetic path according to the present invention has one end opening and a hollow cylindrical cylindrical yoke 100 and a hole 101 which can be connected with an external power source along the yoke outer peripheral surface. A stator 200 provided with a coil 201 wound on a slot formed by a plurality of cores 202 and fixed to the inner circumferential surface of the yoke;

Two poles 300A and 300B are formed in both directions along the circumferential direction with a gap spaced more or more or slightly spaced apart from the inside of the stator 200, and a plurality of cores 304 are formed in each direction to form a coil 303. Are wound and the bipolar poles 300A and 300B are fixedly installed to face the stator core 202 along the longitudinal direction of the shaft 500.

The pores 503 are installed at a predetermined portion of the hollow shaft 500 for supplying current to the field by fixing the field 300, and wires are wired, and both ends of the yoke 100 and the yoke cover 103 pass through the rule. It is fixed to the shaft by nuts 501

In addition, the rotor 400 equipped with a plurality of magnetic paths 400A and 400B in a space separated from each other is mounted on a fixed shaft 500 by mounting a bearing 502 and a cooling fan 600 to an external power source connecting fleece 700. Possibly installed

In addition, the magnetic furnace 400A and 400B of the rotor 400 repeatedly stack a plurality of ferromagnetic materials 411 and nonmagnetic materials 412 as shown in FIGS. 7 and 8, but the narrow cross-sectional surface of the ferromagnetic materials 411 has a field. The magnetic field is linearized in the direction of the stator core surface 202 on the magnetic pole surface, and the ferromagnetic material in the stacked form is coupled by the bolts 413 to complete one magnetic path, and the shaft is fixed to the shaft 500 again. Rotor 400 including a magnetic path, as shown in FIG. 8, is further bounded by the upper cover 401A of the nonmagnetic material and the lower disk 401B of the hollow disk-shaped binding body 402 mounted thereon. ) Is composed

In addition, the magnetic field 400A is used as a magnetic field 400A connecting the field magnetic pole 300A and the stator core 1 surface and another magnetic field 400B is connected to the field magnetic pole 300B and another stator core 1 surface. When the rotor 400 rotates, the magneto 400A and the magneto 400B are alternately arranged on one surface of the stator core, and the electromotive force is generated in the coil 201 wound on the stator core by repeating the circuit configuration.

In addition, one by one ferromagnetic material 411 coupled to the magnetic field 400 is to move only the magnetic field of the cross-sectional area size when the field crosses the field generation cross-sectional area to the magnetic field 400 to transfer the partial magnetic field and to the bound surrounding ferromagnetic material Suppresses the spread of the maximal stimulus to minimize the collision with the reverse magnetic field in the stator core 202

Therefore, the generation of the reverse magnetic field according to the electromotive force and the load is also characterized in that the reverse magnetic field of the same size as the increase or decrease of the magnetic field movement of the magnetic field is directly affected by the magnetic field, and the magnetic field is subjected to the same polarity of the polarity, thereby making the smoother rotational movement.

The power generation device of the present invention can significantly reduce the weight of the field for generating electromotive force, thereby minimizing the mechanical energy source for basic rotation maintenance, and also minimizing adverse effects such as rotation disturbance according to the load. Produce power generation.

1 is a perspective view of a typical generator separation
FIG. 2 is a cross-sectional view of a general generator of FIG. 1.
Figure 3 is an exploded perspective view showing an embodiment of the power generation apparatus of the present invention
4 is a cross-sectional view showing the embodiment of FIG.
5 is a sectional view showing main parts of the embodiment of FIG. 3;
6 is a side view showing a field mounting state of the power generation device of FIG.
7 is a perspective view of main parts of the rotor according to the embodiment of FIG. 3.
8 is a side view showing a mounting state of the rotating body shown in the embodiment of FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the magnetic field induction generating apparatus using a magnetic furnace according to the present invention.

In the magnetic field induction generating apparatus using a magnetic path according to the present invention, as shown in FIGS. 3 and 4, a coil wound stator 200 is mounted on an inner circumferential surface of the yoke 100 and fixed on a shaft 500. In addition, the rotating body 400 mounted with the bearing 502 on the fixed shaft 500 and the fleece 700 for input of an external power source to the cooling fan 600 are rotatably mounted.

3 and 4, as shown in FIG. 3 and FIG. 5, the present invention shows the appearance of various components which will be described later as the appearance of the power generator. The yoke 100 has a cylindrical shape in consideration of the rotation radius of the rotor 400 rotating therein. Shape

Accordingly, the yoke of the present invention has a hole 101, one end of which is opened and a coupling hole is installed so that the shaft 500 is coupled to the bolt 501 in the center of the hollow cylindrical shape, and the external power input device (belt, etc.) is openable. In addition, the periphery of the hole is provided with a ventilation hole 102 along the circumferential direction and fixed to the shaft 500 together with the yoke by the yoke connection cover 103 and the nut 501. The yoke appearance can be modified accordingly for installation location or connection to other parts and the bracket or rib can be coupled to the yoke.

The stator 200 is formed by stacking a plurality of thin sheets of silicon steel sheets as shown in FIGS. 3 and 4, and a plurality of cores 202 are provided at regular intervals along the inner circumferential surface and formed by the cores. Insulating material 203 is installed in order to insulate from coil 201 and coil is wound and is fixed to inner circumferential surface of yoke 100 and at the same time draws power line to outside.

As shown in FIGS. 5 and 6, a plurality of cores 304 are divided in two directions along the circumferential direction about the axis 500 with a space slightly spaced from the inside of the stator core, respectively. Coil 303 of the winding is bipolar (300A) (300B) is slightly fixed to the shaft facing each other with one stator core 202 surface in a state slightly spaced apart

Here, as shown in FIG. 4, the hollow shaft has pores 503 for inserting the lead wire of the field winding on the side of the field, through which the lead wire 305 is wired, and supplies current to the field winding 303 so that the field magnetic pole ( 300A) and 300B are formed, and the yoke connection cover 103 and the coupling hole are fixed with a nut 501.

As shown in FIGS. 7 and 8, the nonmagnetic material having the bearings 502 mounted on the fixed shaft 500 for fastening and fastening the independent magnetic paths 400A and 400B, respectively, and connecting to an external power source. The upper cover (401A) consisting of the upper and the support binding to the upper surface of the ruler and fastening the lower surface of the ruler to the hollow disk-shaped binding body 402 to complete the upper magnetic path (400A) of the rotor and also to the lower cover (401B) In the same manner as in the sieve 402, but the coupling between the gyro 400A and the gyro 400A is attached to the upper cover (401A) and installed in the lower middle part. The joints are arranged in sequence with a space corresponding to the size of the cross-sectional area. Also, they are rotatably installed with some air gap inside the stator and outside the field.

100: season 101: Opened hole 102: Ventilation opening
200: stator 201 stator coil 202: stator core
300: field 300A: field stimulation (A) 300B: field stimulation (B) 303: field coil
400: rotor 401A: rotor cover (A) 401B: rotor cover (B) 402: binder 400A: furnace (A) 400B: furnace (B) 411: ferromagnetic 412: nonmagnetic 413: bolt
500: hollow shaft 501: nut 502: bearing 503: pores for wiring
600: cooling fan
700: fleece

Claims (3)

The stator core and field magnetic poles are fixed to each other over the magnetic field range or somewhat spaced apart from each other, and rotate the rotor equipped with an independent magnetic field in the space separated by the magnetic field magnetic field through the magnetic field. A device in which a passing circuit is formed and electromotive force is generated by a coil wound on a stator core
Hollow shaft coupled to the field and the pores are installed in a predetermined portion is equipped with a wire for supplying the excitation current to the field and fixedly mounted in front and rear of the yoke
A plurality of cores 304 are divided in both directions along the circumferential direction about an axis, and coils 303 are wound around each core to form bipolar 300A and 300B and one stator core 202. Fields fixed to the shaft, facing away from each other, facing slightly apart
Generators with rotors equipped with bearings on both sides of the shaft, with pleats for connecting cooling fans and external power sources The method of claim 1, wherein
Rotor consisting of a combination of the upper cover and the lower cover of a non-magnetic material bearing a bearing on a fixed shaft, and a plurality of magnetic paths are supported and fastened respectively to the upper and lower parts
The method according to claim 2, wherein
The ferromagnetic material is a stack of ferromagnetic materials and non-magnetic materials. The ferromagnetic material is coupled by bolts and an array of ferromagnetic materials with narrow cross-sectional planes directed from the field magnetic pole face to the stator core plane.
Representative figure
1
Index
- One

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