KR100975326B1 - Electric generator with fixing plate comprising segmented magnets and rotary disk having segmented coil - Google Patents

Abstract

The present invention relates to a power generation device capable of producing electric power by using the rotational force or hydropower or wind power of the power unit, in particular, in the fixed plate made of a non-magnetic material spaced up and down, respectively formed a magnet body divided in four directions, Between the fixed plate by forming a rotating disk in which the coil portion made of a horizontal winding radially arranged,

Since the electric power is generated by the charge induction to the rotating coil part spaced apart from the separately divided magnet body, there is no load due to the attraction of each other, so it is possible to produce high power at high speed and high efficiency at low speed. Due to the rotational centrifugal force of the disc itself and the alternating action of attraction and repulsive force by the added magnet body, it increases the maneuvering force and the continuous rotational force of the rotating disc, so that the power loss is minimized to a high degree even with weak wind, wave, steam or hydraulic power. While the power source is electric energy, the electric power source can generate power and freely transform the current through the generator, and can store the surplus current, greatly reducing the amount of current consumed. To produce.

Power generation, fixed plate, rotating disk, magnet body, no load, coil portion, momentum

Description

Electric generator with fixing plate comprising segmented magnets and rotary disk having segmented coil}

The present invention relates to a power generation device capable of producing electric power by using a rotational force, hydraulic power or wind power of a power unit, and in particular, a magnet body is formed on the fixed plate spaced up and down to face each other, and the horizontal winding between the fixed plate Since the coil part is formed to be spaced apart from the rotating disk formed in correspondence with the magnet body, when the rotating disk is rotated by a driving device or hydraulic or wave force, electric charge is induced from the magnet body to the coil and current is generated. Since no attraction occurs between the magnets, the power output is excellent, but when the rotational power source of the rotating disk is the driving motor, the driving power of the target object is increased while greatly reducing the power consumption of the driving motor. The present invention relates to a power generator having groundbreaking characteristics in power production.

A generator is a device that converts mechanical energy into electrical energy. When a cylindrical magnetic body is rotated by rotating power from hydraulic, wave, or steam or diesel engines, it is located near the magnetic body. It is a device that generates electric current by inducing charge in a coil wound on an iron core core.

That is, in the general power generation apparatus, when the rotor 100 made of a magnetic material is rotated inside the stator core 110 in a state where the coil 111 is wound as shown in FIG. 1, electricity is generated in the coil 111 of the stator. It will flow.

Power generators that can be easily seen around us include generators for bicycle lights, and generators for cars are the same principle. Unlike the bicycle generator, the permanent magnet is built into the coil of the bicycle, but the electromagnetic generator (rotor coil) is wound instead of the permanent magnet.

However, the general power generation apparatus as described above has a problem in that it is necessary to rotate the magnetic material having a relatively heavy weight, thus excessively maneuvering or rotating power.

In addition, since the core core for inductive activation of the conventional method is attracted to each other and the rotational magnetic material in the center, excessive rotational kinetic force is required to exceed the attraction force, so the energy consumption is extremely high. In addition, the attraction force acts as a rotational resistance of the magnetic body, resulting in unnecessary consumption of the rotational power for rotating the magnetic body.

In particular, the conventional cylindrical magnetic material and the core core has only a four-pole induction due to the limitation of space, so the high-speed rotation is required to produce the required electricity has a problem of extremely low economic efficiency.

In addition, when the magnetic material is forcibly rotated by using the rotational force of a separate drive motor, and the electricity produced from the power generation device is to be converted and used through a transformer, the electricity lost from the drive motor and the power generation device. As energy is enormous, power generation systems of this type are typically known to have an energy efficiency of about 35%, making them extremely inefficient and uneconomical.

The present invention is to solve the problems as described above, in the fixed plate of the non-magnetic material spaced apart up and down to form a magnet body is divided in four directions, respectively, between the fixed plate coil portion made of a horizontal winding is disposed radially Forming a rotating disk, the magnet body of the fixed plate located on the lower portion of the rotating disk induces electric charge by inducing the coil portion, the magnet body located on the fixed plate of the upper side attracts and repulsive force in the rotational direction to the coil portion By alternately providing

Since electric power is produced through the horizontal cross rotation of the magnet body and the coil part, no load rotation is generated without mutual attraction, which shows excellent power productivity even at low speed rotation. In addition, it is an object of the present invention to provide a power generation device having a very excellent economic efficiency as well as minimizing the load loss of the rotating disk.

The present invention for achieving the object as described above, the power generation plate and the induction fixed plate of the non-magnetic material spaced apart up and down respectively formed separately, and the non-magnetic disk having a rotation axis between the power generation plate and the induction fixed plate to form To; In the power generation stationary plate, at least one magnet in a state in which at least one magnet is overlapped is formed in a radial division, and induction stationary plate is formed in the induction magnet body is formed in a fixed position and a corresponding position in a fixed position, the disc Wherein the coil portion is formed to be divided in the position corresponding to the generator magnet and the induction magnet body,

The coil part is flattened through a horizontal winding, and each coil part is connected in series, so that electric charges are induced from the power generating magnet of the power generation stationary plate to the coil part according to the rotation of the disk, thereby generating power, and the induction magnet body of the induction fixed plate. Is configured to increase the rotational force of the disc by providing attractive force and repulsive force according to the sign of the electric charge generated in the rotating coil part.

According to the present invention, since electric power is generated by charge induction to a coil unit that is spaced apart from an independently divided magnet body, no loads are generated due to attraction between each other, thereby producing excellent power productivity and high efficiency power at low speed. Due to the alternating action of the rotational centrifugal force of the rotating disc itself and the attraction force and the repulsive force by the added magnet body, it increases the maneuvering power and the continuous rotational power of the rotating disc, minimizing the power loss, so that the weak wind, wave, steam or hydraulic power Even though it is possible to produce high power, but the power source is electric energy, it is possible to freely transform the boosted and transformed current through the power generation device and to store the surplus current so that the amount of consumed current can be greatly reduced. It is to maximize the efficiency.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor may properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is an exploded perspective view of the power generation device according to the invention, Figure 3 is an overall front view of the power generation device according to the invention, Figure 4 is an enlarged plan view of the rotating disk of the power generation device according to the present invention.

As shown in the drawing, the power generating device according to the present invention has a power generation fixing plate 10 and an induction fixing plate 20 spaced apart from each other through separate supporters 40 and 40 ', and the power generation fixing plate 10 and the induction fixing plate are separated. Rotating disk 30 is located between the 20, the rotating shaft 31 formed in the center of the rotating disk 30 is the power generation fixing plate 10 and the induction fixing plate (10) through a separate bearing (41) 20) is configured to be rotated between.

At this time, the power generation fixing plate 10 and the induction fixing plate 20 and the rotating disk 30 are all made of a nonmagnetic material such as a synthetic resin material, which should be made of a material that is not magnetized or interfered with or affected by magnetism.

In addition, in the power generation stationary plate 10, the power generating magnets 11 and 11 'are radially divided, and the power generating magnets 11 and 11' are positioned at the center of the rotating disk 30. It is arranged in a radially divided form as a reference, and each of the power generating magnets 11 (1 ') has a form of 8 divisions or 16 divisions.

In addition, the induction fixing plate 20 is formed with the induction magnets 21 and 21 'having the same division and arrangement as the power generation magnets 11 and 11', and the rotating disk described above. The coil portions 32 and 32 'having the same number, position, and area as those of the power generating magnets 11, 11' and the induction magnets 21, 21 'are formed at 30. .

Accordingly, when the rotating disk 30 is rotated, the coil parts 32 and 32 'induce charge from the power generating magnets 11 and 11' of the power generation fixing plate 10 located below. The coil parts 32 and 32 'are wound horizontally in a flat form, and thus the magnetic force of the power generating magnets 11 and 11' is applied to the entire coil parts 32 and 32 '. This effect can produce the maximum power, and each coil unit 32, 32 'is connected in series, so in the case of 8 divisions, the production of electricity from eight coil units 32, 32' at the same time. In the case of 16 divisions, electricity is simultaneously produced from 16 coil parts 32 and 32 ', and each coil part 32 and 32 is rotated once during the rotation disk 30. ') Is passed through 8 or 16 power generation magnets (11, 11'), so the amount of charge induced is the amount of power corresponding to 8 squared or 16 squared You will get.

In addition, as described above, the coil parts 32 and 32 'which receive electric charges from the magnetic force of the power generating magnets 11 and 11' have the power generating magnets 11 and 11 'and the coil part as is well known. The narrower the intervals of (32) and (32 '), the more the amount of charges induced is increased, and thus the power generation efficiency can be further improved by securing a minimum separation distance.

In particular, the power generating magnets 11 and 11 'may be made of a single entity, but more powerful magnetic force is formed at the overlapping portions of the overlapping magnets by stacking at least one magnet body. Therefore, it would be more ideal to construct two or three magnets having the same magnetic force to form the power generating magnets 11 and 11 '.

In addition, the above-described generator magnets 11 and 11 'have a planar rectangular shape, and the planar width and length are 1: 4 in an ideal ratio, and the height is approximately 2 to the above ratio. Using the one with the corresponding value will have the greatest generation in terms of efficiency.

That is, since the amount of charge will be determined according to the strength and weakness of the magnetic force rather than the size, the magnetoelectric body 11 (11 ') is expected to increase and concentrate the magnetic force by using the power generation magnet body 11 (11') having the same magnetic force. Similarly, if a strong magnetic field from the narrow surface affects the coil portions 32 and 32 'by using a narrow surface rather than a wide surface, it is possible to increase the number of divided magnets in the generator magnets 11 and 11'. In order to use the large surface of the magnet, the area of the corresponding coil parts 32 and 32 'must also be widened together. Therefore, in this case, the coil parts 32 and 32' are replaced. Since the synergistic effect of the amount of power generated compared to the economic expenditure to form is insignificant, it is the most ideal to form the power generating magnets (11, 11 ') in the plane ratio as described above is derived by the experiment.

Therefore, the power generator of the present invention transfers electric charges generated in the process of moving the coil parts 32 and 32 'from the upper part of the stationary magnet body 11 and 11' to the coil parts 32 and 32 '. Since the method of producing electric power through the induction by the magnetic force generated by the magnetic force between the generator magnet (11) (11 ') and the coil portion (32) (32'), the rotating disk (30) ) Is free rotation without load, and only a very small frictional resistance by the bearing 41 acts as a loss of kinetic energy, so that almost all of the kinetic energy applied to the rotating shaft 31 can be converted into electrical energy. will be.

In addition, the induction magnets 21 and 21 ′ on the induction fixing plate 20 positioned above the rotation disk 30 are for improving the rotational motion force of the rotation disk 30 rotating as described above. As described above, induction of electric charges generated while the coil parts 32 and 32 'of the rotating disk 30 passes over the upper portion of the power generating magnets 11 and 11' occurs. Alternatively, the negative sign is instantaneously switched induction and has a characteristic of generating alternating current, so that the magnetic force of the induction magnets 21 and 21 'affects only the coil parts 32 and 32'. By the magnetic force of the induction magnets (21) (21 ') it is possible to obtain a further improved rotational motion force of the rotating disk (30).

That is, at the moment when the coil part 32 enters the upper center of the power generating magnet body 11 by the rotation of the rotating disk 30, the coil part 32 is rotated in the rotating disk 30 or the coil. According to the winding direction of the positive or negative signs of the charge is induced, the induction magnets 21, 21 'is the charge of the charge formed in the coil portion 32, 32' of the rotating disk 30 is rotating According to the sign provides repulsion by the attraction force as shown in FIG. 5 and the electromagnetic force as shown in FIG. Will have.

Here, the sign and the induction magnet body 21 (21 ') acting on the coil parts 32, 32' as described above, the polarity of the magnet arrangement direction, the coil winding direction or the rotation direction of the rotating disk 30 It can be adjusted and changed by using, so it is necessary to set and use a suitable structure and direction.

In particular, the magnetic force of the induction magnets 21 and 21 'is preferably spaced apart so as not to affect the magnetic force of the power generating magnets 11 and 11', and the induction magnets 21 ( If the magnetic force of the 21 ') affects the magnetic force of the power generating magnets 11 and 11', the amount of induction of electric charge will be relatively reduced.

Such a power generation device is applied to a variety of rotational power as shown in Figure 7 when the rotating disk 30 is rotated to produce electricity from the coil unit 32, 32 'in the rotating disk 30 through a transformer The necessary current or voltage can be changed, and the output electricity from the transformer can be connected to the required electricity consumer, and in some cases, the electricity provided from the power generator by connecting power storage means to the transformer. You just need to save it.

In addition, as shown in FIG. 8, a second disc 30 ′ is formed under the power generation fixing plate 10, and a second induction fixing plate 20 ′ is formed under the second disc 30 ′. Thus, when each of the rotating disks 30, 30 'is rotated at the same time, it is possible to produce electricity at the same time to the two rotating disks 30, 30' from a single power generation stationary plate 10, more reasonable Will be

As shown in FIG. 9, when the second disc 30 ′ and the second power generation stationary plate 10 ′ are formed on the upper side of the induction fixing plate 20, two rotating discs are formed from a single induction fixing plate 20. 30) (30 ') to be able to provide a rotational motion at the same time.

The power generation means consisting of the power generation stationary plate 10, the induction stationary plate 20 and the rotating disk 30 can be configured to overlap them in succession up and down, so that power generation can be made simultaneously from them. The rotating disks 30 located in the plurality of power generating means are simultaneously mounted on a single rotating shaft 31 so that the rotating disks 30 rotate at the same speed so that uniform and stable power generation can be achieved.

Accordingly, when the aberration is connected to the end of the rotary shaft 31 and installed in a dam, river or river, and general water and sewerage, the aberration is rotated by hydraulic power. ) Is rotated so that high-efficiency power generation is achieved. At this time, there is no attractive force between the rotating disk 30 and the magnetic magnet body 11 and 11 ', so that it is extremely weak. Even if the rotation of the rotating shaft 31 and the rotating disk 30 is made possible to produce power.

In addition, by connecting the windmill to the rotary shaft 31 may be used as a wind power generator, it may be to generate power by rotating the rotary disk 30 through the wind or steam pressure, and the like. When the rotating shaft 31 is grounded to the rotating body of the power unit, the rotating motion force of the rotating body is transmitted to the rotating force of the rotating disk 30, thereby producing a high level of power, and the rotating disk 30 at this time. The amount of power loss of the power unit for rotating the engine is weak or extremely low than the amount of electricity produced from the coil parts 32 and 32 'of the rotating disk 30, which is a very reasonable power generation device in terms of utilization of surplus energy. Could be.

The embodiments described in the present specification and the drawings shown in the drawings are only the most preferred basic embodiments of the present invention, and do not represent all of the technical ideas of the present invention, and various equivalents and modifications that may be substituted for them are provided. It should be understood that there may be examples.

1 is a schematic configuration diagram showing a general conventional power generation device

Figure 2 is an exploded perspective view of the power generation device according to the present invention

3 is an overall front view of a power generation apparatus according to the present invention;

Figure 4 is an enlarged view of the rotating disk of the power generation apparatus according to the present invention

5 is a power generation process diagram of the power generation apparatus according to the present invention, an enlarged cross-entry view between the coil unit and the magnet body;

Figure 6 is a power generation process of the power generation apparatus according to the present invention, the enlarged cross-deviation between the coil portion and the magnet body

7 is a configuration diagram of a power generation system using a power generation device according to the present invention;

8 is another embodiment of the power generation device according to the present invention

Figure 9 is another embodiment of the power generation device according to the present invention

Explanation of symbols on the main parts of the drawings

10,10 ': Power generation station 11,11': Power magnet

20,20 ': guide plate 21,21': guide magnet

30,30 ': Disk 31: Rotating shaft

32,32 ': coil part

40,40 ': Support 41: Bearing

Claims (13)

The rotation disc 30 of the nonmagnetic material coupled by the rotation shaft 31 from the power generation fixing plate 10 and the induction fixing plate 20 between the power generation fixing plate 10 and the induction fixing plate 20 of the nonmagnetic material spaced apart from each other Located in the power generation stationary plate 10 and the induction stationary plate 20, the magnetic field magnets 11, 11 'and the induction magnets 21, 21' corresponding to each other are fixedly formed, and the coil unit in the rotating disk In the power generation apparatus in which (32) and (32 ') are divided, The power generating magnets 11 and 11 'are rectangular parallelepipeds having a ratio of width to length and height of 1: 4: 2, and the power generating magnets 11 and 11' are maintained in a ratio with respect to their width. A power generating apparatus according to a rotating disk having a split coil portion and a fixed plate having a split magnet body, characterized in that at least two or more magnet bodies are overlapped within each other. delete delete delete delete delete delete delete delete delete delete delete delete

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