KR20070067853A - Generator - Google Patents

Abstract

A bidirectional generator using an electromagnet is provided to improve the power generation efficiency of the generator by rotating a coil and a magnet in the generator in opposite directions with each other. An inner rotation case(2) is coupled inside a case(1) using a bearing(4). A rotation shaft(5) penetrates the center of the case. A coil(3) is wound inside the inner case. A magnet(6) is arranged to correspond to the coil on the rotation shaft, such that the magnet and the coil are rotated independently. First and second magnets(21,22) with different polarities are coupled with a center axis(20), which is coupled with an end of the rotation shaft. The rotor(30) is formed outside the rotation shaft. Plural electromagnets(31) are arranged in a ring-like shape on the rotor. The electromagnets are aligned to face the magnets. A controller sequentially applies the current to the electromagnet such that the magnetization direction of the electromagnet is equal to the magnetization directions of the magnets.

Description

Bidirectional power generation device using electromagnets {Generator}

1 is a cross-sectional view showing a bidirectional power generation device using an electromagnet of the present invention.

2 is a view showing an operating state of the present invention.

3 is a view showing another embodiment of the present invention.

Explanation of symbols for main parts of the drawings

1: case, 2: internal rotating case,

3: coil, 4: bearing,

5: axis of rotation, 6: magnet,

10: connecting member, 12: bearing,

17: brush, 18: finish plate,

20: central axis, 21: first magnet,

22: second magnet, 23: insulator,

30: rotating body, 31: electromagnet,

32: controller, 40,41: gearbox,

The present invention relates to a bidirectional power generation apparatus using an electromagnet, and in particular, the central axis and the rotating body rotate in opposite directions by the repulsive force generated by the same magnetic poles of the electromagnet facing the magnet under the control of the controller. The present invention relates to a bidirectional power generation apparatus using electromagnets in which rotational force is transmitted to an internal rotating case and a rotating shaft so that the coil and magnet of the generator rotate in opposite directions to improve power generation efficiency.

In general, the generator refers to a device that generates electricity by driving by external power, such a generator is installed in automobiles, industrial, large buildings and the like.

Generators installed in automobiles are generated by using the rotational power of the engine, and generators installed in other places are mostly generated by rotating by the driving force of the motor.

In the conventional generator, a stator made of a coil is installed at an inner periphery of the case, and a rotor made of a permanent magnet corresponding to the coil is installed at a rotating shaft formed to penetrate the center of the case.

That is, in the conventional generator, as the rotating shaft rotates, the rotor formed on the rotating shaft rotates at a high speed to intersect the outer coil. At this time, the magnetic flux is applied to the coil to generate electric current.

However, the conventional generator has a problem that the electricity generation efficiency is lowered because only the rotor formed on the rotating shaft is rotating to generate electricity, and for this reason, the high-capacity generators are not only bulky but also expensive to produce. There was a problem that would act as an economic burden to the.

Accordingly, the present invention for solving the above problems is to form an inner rotary case in which the coil is wound inside the case, and a magnet corresponding to the coil is formed on the rotating shaft penetrating the center of the case coil and the magnet The independent rotation is possible, and the first and second magnets having different magnetic poles to the central axis connected to the front end of the rotating shaft facing each other, and the rotating body connected to the rotating case is formed on the outer side of the central shaft, A plurality of electromagnets are arranged in an annular shape to face the magnets, and a control device that sequentially applies current to the electromagnets so as to have the same magnetic poles as the electromagnets facing the magnets is connected to each electromagnet, and the magnets are controlled by the control device. As the magnetic poles of the electromagnets facing each other become equal, The whole is rotated in the opposite direction, the rotational force is transmitted to the inner rotary case and the rotating shaft to provide a two-way power generating device using an electromagnet to improve the power generation efficiency by rotating the coil and magnet of the generator in the opposite direction. do.

The present invention for achieving the above object,

According to claim 1,

An inner rotary case is bearing-coupled to the inside of the case, and a rotating shaft is formed through the center of the case. A coil is wound around the inner side of the inner rotary case, and a magnet corresponding to the coil is installed on the rotating shaft, thereby independent of the coil and the magnet. Make it rotatable,

Opposite coupling of the first and second magnets having different magnetic poles to the central axis connected to the distal end of the rotating shaft, and the rotating body connected to the rotating case is formed on the outer side of the central shaft,

A plurality of electromagnets are arranged in an annular shape on the rotating body to face the magnets, and a control device for sequentially applying current so as to have the same stimulus as the magnets as the electromagnets facing the magnets is connected to each electromagnet.

According to claim 2,

The control device is located in the opposite position to each other and supply the current of different polarity to the electromagnets facing the first and second magnets and the magnetic poles of the electromagnets and the magnets are the same, so that the central axis and the rotating body are mutually It rotates in the opposite direction, and subsequently controls the central axis and the rotating body to continuously rotate by supplying a control current to the neighboring electromagnets at regular intervals thereafter.

According to claim 3,

The control device is characterized in that when the central axis and the rotating body maintains a predetermined number of revolutions, it controls the electromagnets present at the multiple position control or the drainage position of 3 on the basis of an arbitrary electromagnet.

According to claim 4,

An armature for electrical discharge is formed inside the rear end of the coil, and a brush that receives electricity in contact with the armature is formed on a finishing plate coupled to the rear end of the case.

According to claim 5,

A connecting member made of an insulator is formed at one end of the inner rotating case, and a rotating body is coupled to one end of the connecting member, and an insulator is formed between the rotating shaft and the central axis.

According to claim 6,

Between the rotating shaft and the central shaft to form a first speed reducer for increasing the rotational speed of the central shaft to the rotating shaft, and forming a connecting member made of a non-conductor at one end of the inner rotary case, between the connecting member and the rotating body It is characterized in that a second speed reducer for increasing the rotational speed of the rotating body to transfer to the inner rotary case through the connecting member.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, FIGS. 1 to 3.

Reference numeral 1 represents a case forming the outline of the generator.

In the center of the case 1, a rotating shaft 5 is formed therethrough, and an inner rotary case 2 is coupled to the inside of the case 1 by a bearing 4 so that independent rotation is possible. Is installed.

The coil 3 is wound on the inner circumferential surface of the inner rotating case 2, and the magnet 6 is formed on the rotating shaft 5 so as to face the coil 3.

That is, the coil 3 is rotated independently by the internal rotary case 2, the magnet 6 is rotated independently by the rotary shaft (5).

In addition, an insulator 23 made of a non-conducting non-conductor is formed at the front end of the rotation shaft 5, and a central axis 20 having a predetermined length is coupled to the insulator 23.

In addition, the connecting member 10 is formed to protrude from one end of the inner rotary case 2, the connecting member 10 is formed as a non-conductive non-conductive, the cylindrical rotating body at the front end of the connecting member 10 Combine 30.

At this time, the rotating body 30 is positioned on the outside of the central axis 20, and the first and second magnets 21 and 22 having different magnetic poles are opposed to the central axis 20, A plurality of electromagnets 31 are arranged in an annular shape on the rotating body 30 so as to face the magnets 21 and 22, and the magnets 21 and 22 as the electromagnets 31 facing the magnets 21 and 22. The control device 32 for sequentially applying current to have the same magnetic pole is connected to each electromagnet 31.

As shown in FIG. 2A, the electromagnet 31 has a plurality of electromagnets M1 to M6 (Ma1 to Ma6) disposed in an annular shape on the rotating body 30 to face the first and second magnets 21 and 22. In the present invention, by using the repulsive force of the same magnetic pole of the magnets (21, 22) and the electromagnet (31) facing as described above in the opposite direction to the central axis (20) and the rotating body (30) Rotate

It is the control device 32 that enables rotation in such opposite directions.

The control device 32 is located in the opposite position to each other and the electromagnet and the magnet facing each other by supplying a current of different polarity to the electromagnet (31: M1, Ma1) facing the first and second magnet (21,22) The magnetic poles of the same cause the central axis 20 and the rotating body 30 to rotate in opposite directions due to the repulsive force, and the neighboring electromagnets M2, Ma2 (M3, Ma3) ,,,, The control current is sequentially supplied to control the central axis 20 and the rotating body 30 to rotate continuously.

In addition, when the central axis 20 and the rotating body 30 maintain a constant rotation speed, the control device 32 controls the electromagnets present at the multiple positions or the drainage position of 3 based on the arbitrary electromagnets. By the repulsive force of the 21 and 22 and the electromagnet 31, the central axis 20 and the rotating body 30 are continuously rotated in opposite directions while maintaining a constant speed.

When the central shaft 20 and the rotating body 30 is rotated in the opposite direction, the rotational force is transmitted to the rotating shaft 5 and the inner rotary case 2 as it is, the coil 3 and the magnet 6 mutually Since it rotates in the opposite direction, power generation efficiency is improved.

On the other hand, the bearing 12 is interposed between the connecting member 10 and the rotary shaft 5, the closing plate 18 is fitted to the rear of the case 1 is coupled, after the coil 3 An armature 16 for discharging electricity is formed inside the end portion, and an inner surface of the finish plate 18 is provided with a brush 17 that receives electricity while being in contact with the armature 16. The electricity generated through the brush 17 is discharged to the outside.

In addition, a connection member 10 formed of a non-conductor is formed at one end of the inner rotation case 2, and the rotation member 30 is coupled to one end of the connection member 10, and the rotation shaft 5 and the central axis are connected to each other. An insulator 23 is formed between the 20 to prevent electricity induced in the electromagnet 31 from being transferred to the coil 3 inside.

Referring to the operation of the present invention configured as described above is as follows.

First, as shown in FIG. 2A, the control device 32 faces the M1 electromagnet 31 and the first magnet 21 of the N pole, and the Ma1 electromagnet 31 and the second magnet 22 of the S pole face each other. In the state where the M1 electromagnet 31 has the N pole and the Ma1 electromagnet 31 supplies the control current so as to have the S pole, the central axis 20 is driven by the repulsive force of the electromagnet 31 and the magnets 21 and 22. ) And the rotating body 30 are rotated in opposite directions, and by this rotation, the M2 electromagnet 31 faces the first magnet 21 as shown in FIG. 2B, and the Ma2 electromagnet 31 has the second magnet. When the control device 32 supplies a control current to the M2 and Ma2 electromagnets 31 when facing the 22, the center shaft 20 and the central shaft 20 are driven by the repulsive force of the M2 and Ma2 electromagnets 31 and the magnets 21 and 22. The rotating body 30 is rotated in the opposite direction to each other.

When such control is sequentially controlled in the order of ① to ⑥ as shown in the drawing, the central axis 20 and the rotating body 30 are continuously connected to each other by the repulsive force of the M1 to M6 and the Ma1 to Ma6 electromagnets and the magnets 21 and 22. If the central axis 20 and the rotating body 30 is rotated at a constant speed, the control device 32 is present in the number control position or the drainage position of 3 relative to any electromagnet By controlling the electromagnets, the revolving force of the magnets 21 and 22 and the electromagnets 31 allows the central axis 20 and the rotor 30 to rotate continuously in opposite directions while maintaining a constant speed.

As described above, when the rotating body 30 and the central shaft 20 rotate in opposite directions, the rotating force is transmitted to the rotating shaft 5 and the inner rotating case 2, and the magnet 6 formed on the rotating shaft 5 is formed. ) And the coil 3 formed in the inner rotary case 2 are to be generated while rotating in the opposite direction to be expected to improve the power generation efficiency.

And, Figure 3 shows another embodiment of the present invention,

Between the rotary shaft 5 and the central shaft 20 to form a first speed reducer 40 to increase the rotational speed of the central shaft 20 to the rotating shaft 5, the inner rotary case (2) A connecting member 10 formed of an insulator is formed at one end of the connecting member 10, and the rotational speed of the rotating body 30 is increased between the connecting member 10 and the rotating body 30 to rotate internally through the connecting member 10. The second gearhead 41 to be transmitted to the case 2 is formed.

Another embodiment of the present invention is applied when a large power generation device is configured, and in the case of a large power generation device, since the central shaft 20 and the rotating body 30 are largely formed, the high speed rotation is prevented. By increasing the speed using the first gearbox 40 and the second gearbox 41, the coil 3 and the magnet 6 can be generated while rotating at high speed.

As described above, the present invention forms an inner rotary case in which a coil is wound inside of the case, and a magnet corresponding to the coil is formed on a rotating shaft passing through the center of the case so that the coil and the magnet are independently rotated. The first and second magnets having different magnetic poles may be opposed to the central axis connected to the distal end of the rotating shaft, and the rotating body connected to the rotating case may be formed on the outer side of the central shaft, Two electromagnets arranged in an annular shape so as to face the magnet, and a control device for sequentially applying current to the same magnet as the electromagnet facing the magnet is connected to each electromagnet to face the magnet according to the control of the control device. As the magnetic poles of the electromagnet become equal, the central axis and the rotating body It is rotated in the opposite direction, and the rotational force is transmitted to the inner rotating case and the rotating shaft so that the coil and magnet of the generator rotate in the opposite direction to improve the power generation efficiency. have.

Claims (6)

An inner rotary case 2 is coupled to the bearing 4 inside the case 1, and a rotation shaft 5 penetrates through the center of the case 1, and a coil is formed on an inner surface of the inner rotary case 2. 3) is wound, and the rotating shaft 5 is provided with a magnet 6 corresponding to the coil 3 so that the coil 3 and the magnet 6 can be independently rotated, The first and second magnets 21 and 22 having different magnetic poles are opposed to the central axis 20 connected to the distal end of the rotary shaft 5, and the rotary body 30 is connected to the rotary case 2. Is formed on the outside of the central axis 20, A plurality of electromagnets 31 are arranged in an annular shape on the rotating body 30 so as to face the magnets 21 and 22, and the magnets 21 and 22 as the electromagnets 31 facing the magnets 21 and 22. Bidirectional power generation apparatus using an electromagnet, characterized in that the control device 32 for sequentially applying the current to have the same magnetic pole is connected to each electromagnet 31. The method of claim 1, The control device 32 is located in the opposite position to each other and the electromagnet and the magnet facing each other by supplying a current of different polarity to the electromagnet (31: M1, Ma1) facing the first and second magnet (21,22) The magnetic poles of the same cause the central axis 20 and the rotating body 30 to rotate in opposite directions due to the repulsive force, and the neighboring electromagnets M2, Ma2 (M3, Ma3) ,,,, Bidirectional power generation apparatus using an electromagnet, characterized in that for controlling the rotation of the central axis 20 and the rotating body 30 by sequentially supplying a control current. The method of claim 1, The control device 32 is characterized in that when the central axis 20 and the rotating body 30 maintains a predetermined number of revolutions, it controls the electromagnet present in the other number control or drainage position of 3 based on any electromagnet Bidirectional power generation device using electromagnets. The method of claim 1, Brushes for forming the armature (16) for the electrical discharge into the rear end of the coil (3), and is supplied with electricity in the state in contact with the armature (16) to the closing plate 18 coupled to the rear end of the case ( Bidirectional power generation apparatus using an electromagnet, characterized in that 17) formed. The method of claim 1, A connecting member 10 made of a non-conductor is formed at one end of the inner rotating case 2, and the rotating body 30 is coupled to one end of the connecting member 10, and the rotating shaft 5 and the central axis 20 are formed. Bi-directional power generation apparatus using an electromagnet, characterized in that the insulator (23) is formed between. The method of claim 1, Between the rotary shaft 5 and the central shaft 20 to form a first speed reducer 40 to increase the rotational speed of the central shaft 20 to the rotating shaft 5, the inner rotary case (2) A connecting member 10 formed of an insulator is formed at one end of the connecting member 10, and the rotational speed of the rotating body 30 is increased between the connecting member 10 and the rotating body 30 to rotate internally through the connecting member 10. A bidirectional power generation apparatus using an electromagnet, characterized in that a second gearhead (41) is transmitted to the case (2).

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