KR20100012178A - Electric motor having ratary plate with devided coil and devided magnet - Google Patents

Abstract

PURPOSE: A motor is provided to rotate a rotation plate with only minimum current using attractive force and repulsive force between a magnet and a coil. CONSTITUTION: A plurality of coils(11) are radially arranged on a rotation plate(10). A plurality of magnets(21) are radially arranged on upper and lower fixing plates(20). A plurality of vertical support stand(30) fix the upper and lower fixing plates. The rotation plate is arranged between the upper fixing plate and the lower fixing plate. The rotation plate is continuously rotated with attractive force and repulsive force between the coil and the magnet.

Description

Electric motor having ratary plate with devided coil and devided magnet}

The present invention relates to an electric motor used as a power generating means of various mechanical devices, and in particular, a horizontal winding coil body forms a rotary plate dividedly disposed on a non-conductor, and the coil body is disposed to face the coil body on the upper and lower sides thereof. Since the fixed plate of the nonmagnetic material having a magnet body is formed, the magnet body, the attraction force and the repulsive force are generated by the sign of the electric charges formed in the coil body when the power is applied to the coil body. It relates to a transmission device that can be rotated at high speed alone.

An electric motor is a device that converts electrical energy into mechanical energy by using a force that a current-carrying conductor receives in a magnetic field and generally refers to a motor. According to the type of power, it is classified into DC motor and AC motor. AC motor is divided into three phase AC and single phase AC. Today, three phase AC motor is mainly used.

A device that converts electrical energy into mechanical work by using the force that electric currents receive in a magnetic field. Most electric motors produce rotational power, but also produce linear motion.

The motor started to be made when Faraday discovered electromagnetic induction in 1831. Early motors were made to swing the moving part without rotating by using the attraction force and repulsive force of the permanent magnet. In the 1830s, today's DC motor types were first made using armatures and DC-excited electromagnets, but with low output and only in the research phase.

Later, when Ferraris and Tesla discovered a rotating magnetic field created by alternating current, each independently invented a two-phase alternating current motor. Three-phase AC motors have become the mainstream of today's AC motors since Dobrowalski, Germany, first made a three-phase three-phase AC motor in 1889.

In addition, both the DC motor and the AC motor operate on the same principle. When a conductor in which current flows is placed in a magnetic field, electromagnetic force (Lorentz force) is generated in a direction perpendicular to the direction of the magnetic field. A magnet is placed inside the motor to create a magnetic field, and when a current flows through the wire connected to the shaft, an electromagnetic force is generated, which is rotated by Fleming's left-hand law to generate power. The electromagnetic force acting on the conductor is proportional to the strength of the magnetic field, the strength of the current and the length of the conductor.

The most common electric motor according to this principle is that the shade is the basic configuration of the lampshade, the rotor 110 of the permanent magnet or electromagnet is built in the stator 100 of the permanent magnet or electromagnet as shown in FIG. something to do.

In particular, when the DC motor is a four-contact as shown in FIG. 2, the rotor made of electromagnet receives power through the contact point, so that a continuous rotational motion is generated through attraction and repulsion by electromagneticization.

However, such a general electric motor is substantially cylindrical and has a permanent magnet or an electromagnet as a component of the rotating core, and in the process of alternately rotating the attractive force and the repulsive force of each pole, the maneuverability or rotational endurance is reduced due to the weight or magnetic attraction of the rotating center shaft. And, the alternating function of 6 polarity or less is that the efficiency is extremely limited due to the limitation of manpower and repulsive force.

In particular, in the case of a DC motor, the initial starting force is excellent, whereas when the load is generated on the rotating side by the power supply method as described above, when the speed is lowered, the DC resistance is lowered, and heat is suddenly generated due to a sudden increase in supply power demand. The problem is a combination.

As a result, power consumption of the main power and the rotational power versus the power consumption of the device to be added due to the above problems are not overcome.

The present invention improves the above-described problems, wherein a horizontal winding coil body forms a rotating plate dividedly disposed on a non-conductor, and a vision having a magnet body disposed opposite to the coil body on the upper and lower sides of the rotating plate. By forming a fixed plate made of a conductor, the magnetic body and a high attraction force and repulsive force is generated by the sign of the electric charges formed on the coil body as the power is applied to the coil body to cause the rotation action of the rotating plate, the rotation of the rotating plate According to the action, the polarity of the DC power applied to the coil body is switched, and the sign of the charge on the coil body is switched according to the polarity of the magnet body, and according to the charge sign of the coil body and the polarity of the magnet body, Due to the continuous action, by means of a rotating plate having a split coil body and a fixed plate having a split magnet body, which allow the above-mentioned rotating body to be rotated at high speed with only a minimum of current. It is an object of the present invention to provide a transmission.

The present invention for achieving the object as described above, the horizontal winding coil body is provided with a rotating plate which is a non-conductive conductor divided radially, the upper fixing plate and the lower side is a non-magnetic body in which the magnet body opposed to the coil body is divided Each of the fixing plate is provided with a space between the upper fixing plate and the lower fixing plate, the rotating plate is configured to allow free rotation of the rotating plate,

In the coil body connected in series, the initial force of the rotating plate is generated by the sign of the charge induced in the coil body and the polarity of the upper and lower magnet bodies by supplying the DC power, and applied to the coil body according to the rotation of the rotating plate. The polarity of the DC power source is forced to be switched so that the sign of the charge induced in the coil body is repeatedly switched, while the rotation plate rotates continuously while the attraction force and the repulsive force with the magnet body act repeatedly.

The present invention, the magnet body and the attraction force and the repulsive force is generated by the sign of the electric charge applied to the coil body wound horizontally to secure the initial maneuverability of the rotating plate, applied to the coil body in accordance with the rotation action of the rotating plate As the polarity of the DC power source is variable, the attraction and repulsion force between the magnet body and the coil body continuously arranged are repeatedly performed, so that the rotating plate can be rotated at a high speed with only a minimum of current, which is very efficient and minimum under the set rotation speed. It is very economical because it requires a current consumption of.

The terms or words used in this specification and claims are not to be construed as being limited to the common or dictionary meanings, and the inventors can appropriately define the concept of terms in order to explain their invention in the best way. Based on the principle, it should be interpreted as meaning and concept corresponding to 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 3 is an exploded perspective view of the transmission according to the invention, Figure 4 is a side view of the transmission according to the invention, Figure 5 is a plan view of a rotating plate of the transmission according to the invention.

As shown in the transmission device according to the present invention, the upper and lower fixing plate 20 and the lower fixing plate 20 'is formed to be spaced apart from each other on the upper and lower sides of the rotating plate 10 which can be freely rotated.

The rotating plate 10 is made of synthetic resin, which is a non-conductor, and the coil bodies 11 and 11 ', which are horizontally wound in a flat state, are radially divided on the center of the rotary plate 10. Each of the coil bodies 11 and 11 'is connected in series.

In addition, in the upper fixing plate 20 and the lower fixing plate 20 'made of a nonmagnetic material, the magnet bodies 21 and 21' facing the coil bodies 11 and 11 'of the rotating plate 10 are radial. If the coil bodies 11, 11 'are divided into 8 or 16 divisions, the magnet bodies positioned in the upper fixing plate 20 and the lower fixing plate 20' are fixed in a divided form. The number of 21) and 21 'is also composed of 8 or 16 individual populations.

In the center of the rotating plate 10 is a vertical rotating shaft 12 is formed, the rotating shaft 12 is transmitted to the rotating power of the rotating plate 10 that rotates in accordance with the supply of power to rotate to various driven bodies It is to act as a means for transmitting power, it is also possible to form the contacts 13, 13 'for supplying power to the coil body (11, 11') as needed.

In addition, the contact point 13, 13 'may be formed directly on the outer surface of the rotating shaft 12 or may be formed on the rotating plate 10, the grounding method is by a mechanical grounding means or an optical sensor Various grounding methods such as grounding means can be selected and applied.

In particular, the magnet bodies 21 and 21 ', which are divided into the upper fixing plate 20 and the lower fixing plate 20', may be used as a single object, but may overlap at least one or more magnet bodies. Since a stronger magnetic force is formed at the overlapping portion of the overlapping magnets, it may be more ideal to construct two or three magnets having the same magnetic force to form the magnet bodies 21 and 21 '.

In addition, the magnet bodies 21 and 21 'have a planar rectangular shape, and the planar width and length are 1: 4 ratios, and the height is approximately equal to 2 with respect to the above ratios. The one with the highest numerical value will have the greatest generation in efficiency.

That is, since the magnetic bodies 21 and 21 'will be determined by the strength of the magnetic force and the repulsive force according to the strength of the magnetic force rather than the size, the magnetic force increases and concentrates by overlapping the magnetic bodies 21 and 21' having the same magnetic force. As expected, when the strong magnetic field from the narrow surface affects the coil bodies 11 and 11 'by using a narrow surface rather than a wide surface, the expansion of the divided population of the magnet bodies 21 and 21' is increased. Leads to securing as much area as possible,

On the other hand, when the wide side of the magnet is to be used, the area of the corresponding coil bodies 11 and 11 'must also be widened, so in this case, it is economical to form the coil bodies 11 and 11'. Since the synergistic effect of the rotational maneuverability obtained compared to the spending is insignificant, it is most ideal to form the magnet bodies 21 and 21 'as the above-mentioned planar ratio, which is derived by experiment.

In addition, the coil bodies 11 and 11 'and the magnet bodies 21 and 21' are ideally manufactured to have the same area in plan view, and are effective without losing mutual attraction and repulsive force between magnetic and electromagnetic fields. It is to drive.

In addition, it is most effective to minimize the upper and lower separation widths between the coil bodies 11 and 11 'and the magnet bodies 21 and 21', in which case the magnet body of the upper fixing plate 20 The magnet body of the lower fixing plate 20 'should be kept at a distance that does not interfere with each other to prevent the loss of manpower and repulsion due to magnetic interference.

At this time, the upper fixing plate 20 and the lower fixing plate 20 'is fixed to the vertical supports 30, 30' to maintain a constant distance from each other, the upper fixing plate 20 and the lower fixing plate 20 The rotating plate 10 positioned between ') has the rotating plate 12 because the bearings 31 and 31' coupled to the rotating shaft 12 are fixed to the upper fixing plate 20 and the lower fixing plate 20 ', respectively. 10) has a structure that can be freely rotated between the upper fixing plate 20 and the lower fixing plate 20 '.

The electric transmission device of the present invention having such a configuration is characterized in that when the electromagnetic field is induced by supplying power to the coil bodies 11 and 11 ′ disposed in the rotating plate 10 with the magnet bodies 21 and 21 ′. The rotating plate 10 is rotated by the attraction and repulsion,

When the DC power is provided to the coil bodies 11 and 11 ', electric charges are induced in the coil bodies 11 and 11', and the electric charges are applied to the coil bodies 11 and 11 '. Positive and negative signs are generated depending on the winding direction.

The sign characteristic of the electric charge is such that attraction or repulsive force is generated according to the magnetic polarity of the magnet bodies 21 and 21 'located above and below the coil bodies 11 and 11'.

That is, as shown in FIG. 6, the contacts 13 and 13 ′ divided into two times the number of individuals of the coil bodies 11 and 11 ′ are intermittently divided into two to be energized with each other. It is sufficient to ground each end of the DC power supply to the contacts 13 and 13 'of the

The polarity of the DC power supplied to the coil bodies 11 and 11 'when the ground portion of the contacts 13 and 13' is changed by the rotation of the contacts 13 and 13 'or the DC power supply. As a result, the sign of the charges induced from the coil bodies 11 and 11 'is changed.

Accordingly, when the initial power is applied to the coil bodies 11 and 11 'during initial startup, the positive and negative signs will be induced through the coil bodies 11 and 11' as shown in FIG. 7A. As the charge is induced as described above, the attraction force is generated due to the polarity of the magnet bodies 21 and 21 ', so that the rotating plate 10 has an initial maneuvering force.

In this state, the coil body 11 rotates and the coil bodies 11 and 11 ′ pass through the upper and lower magnet bodies 21 and 21 ′, and the coil body 11 rotates. If the polarity of DC power applied to

As shown in FIG. 7B, while the sign of charges induced from the coil bodies 11 and 11 ′ is changed, the attraction force between the coil bodies 11 and 11 ′ and the magnet bodies 21 and 21 ′ is lost. Since the repulsive force is generated between the coil bodies 11 and 11 ′ and the magnet bodies 21 and 21 ′, it serves to push the rotating plate 10 in a state of receiving and attracting the preceding force more quickly.

In addition, since the contact points 13 and 13 'are divided into two times the number of the coil bodies 11 and 11', the DC power supply is the nose when the rotating plate 10 rotates. Since the polarity of the DC power is once again switched between the unitary body 11 and the coil body 11 'as shown in FIG. 7C, the magnet body 21 and 21' rotate as shown in FIG. 7D. This is to be induced.

Therefore, in the DC power supply, the polarity is switched at the center of the divided coil bodies 11 and 11 ', and the magnetism of different polarity exists between the coil body 11 and the coil body 11' and is continuous. Since the polarity must be switched for the pulling force, the number of coils 11 and 11 'is twice as large as that of the coil bodies 11 and 11'.

As the polarity of the DC power source is switched as described above, the magnet body 21 and 21 'and the attraction force and repulsive force are continuously generated therebetween, so that the rotating plate 10 can maintain a high rotational speed even with a minimum of current. It is.

This rotational efficiency, when applying a DC power of 1.5V and 15mA in the state that applied a weight of 40 grams to the rotating shaft 12 of the rotating plate 10, the conventional electric motor was not started, according to the present invention The rotating plate 10 was confirmed by the experiment that the rotation is good,

In order to rotate 40 grams of mass at a high speed of 1200rpm, 280mA is consumed in the conventional electric motor, while the electric device according to the present invention has been confirmed to consume only 70mA of current, which is about 4 times more efficient. It became.

In particular, the thickness or tight spacing of the conductors of the coil bodies 11 and 11 'or the strength of the magnet bodies 21 and 21' or the coil bodies 11 and 11 'and the magnet bodies 21 and 21'. In case of setting the interval between them to an optimum situation, the characteristic more than the efficiency illustrated above will appear.

Such a transmission device of the present invention comprises a basic configuration of disposing the upper fixing plate 20 and the lower fixing plate 20 'having the magnet bodies 21 and 21' above and below the single rotating plate 10 as described above. However, in order to construct a more efficient device, as shown in FIG. 8, a second rotating plate 10 ′ is further formed on the upper fixing plate 20 to form the magnet bodies 21 and 21 ′ of the upper fixing plate 20. Can be shared by the rotor 10 (10 '),

A third rotating plate 10 " is further formed under the lower fixing plate 20 'so that the rotating plates 10 and 10 " share the magnet bodies 21 and 21' on the lower fixing plate 20 '. This allows for greater efficiency compared to the additional configuration.

The embodiments described in the present specification and the drawings shown in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical idea 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 conventional electric motor

2 is a four-contact configuration diagram of a conventional DC motor

3 is an exploded perspective view of the power transmission apparatus according to the present invention;

Figure 4 is an overall side view of the transmission according to the invention

5 is a plan view of the rotating plate of the power transmission apparatus according to the present invention

6 is a connection diagram of a coil body and a contact of a transmission apparatus according to the present invention;

7a to 7d is a coil body rotational operation of the transmission according to the invention,

7A is a state diagram in which attraction between a coil body and a magnet body to which power is applied

7B is a state diagram in which repulsive force is generated between the coil body and the magnet body by switching the power supply polarity;

7C is a state diagram in which the polarity of the power source is switched while the coil body passes between the magnet body and the magnet body;

7D is a state diagram in which attraction force between the coil body and the magnet body is generated by switching the power supply polarity;

8 is another embodiment of the transmission according to the invention

Explanation of symbols on the main parts of the drawings

10.10 ', 10 ": Swivel plate 11,11': Coil body

12: rotation axis 13,13 ': contact

20: upper fixing plate 20 ': lower fixing plate

21,21 ': Magnetic body

30,30 ': Support 31,31': Bearing

Claims (10)

The magnet body 21 (21 ') having a rotating plate (10), which is a non-conductor in which the horizontally wound coil bodies (11) (11') are radially divided, and is opposed to the coil bodies (11) (11 '). ) Is provided with an upper fixing plate 20 and a lower fixing plate 20 ', each of which is a non-magnetic body in which parts are disposed, The rotation plate 10 is spaced apart between the upper fixing plate 20 and the lower fixing plate 20 ', and configured to allow free rotation of the rotating plate 10, The coils 11 and 11 ′ connected in series are supplied with a DC power source, and the polarities of the charges induced by the coil bodies 11 and 11 ′ and the upper and lower magnet bodies 21 and 21 ′. To generate an initial starting force of the rotating plate 10, and to force the polarity of the DC power applied to the coil bodies 11 and 11 'according to the rotation of the rotating plate 10 to be forcibly switched to the coil body 11 ( Division of the rotating plate 10 is continuously rotated while the sign of the charge induced at 11 ') is repeatedly switched, while the attraction force and the repulsive force with the magnet bodies 21 and 21' are repeatedly applied. An electric drive by a rotating plate having a coil body and a fixed plate having a split magnet body. The method of claim 1, At the center of the rotating plate 10, a vertical rotating shaft 12 is formed, and the rotating shaft 12 has a number of contacts 13 corresponding to twice the number of individual coil bodies 11 and 11 'arranged separately. (13 '), wherein the contacts (13) and (13') are intermittently sequentially energized with each other and the contacts (13) and (13 ') are divided into both ends of the coil body (11) (11') in series. To be energized, The contacts 13 and 13 'grounded at the positive and negative poles of the DC power supply are sequentially changed in polarity of the DC power applied to the coil bodies 11 and 11' according to the rotational action of the rotary shaft 12. The sign of the electric charge induced from the coil bodies 11 and 11 'is switched so that the attraction force and the repulsive force with the magnet bodies 21 and 21' are continuously applied. Transmission by a fixed plate having a magnet body. The method of claim 1, The upper fixing plate 20 and the lower fixing plate 20 'are spaced apart and fixed by vertical supports 30 and 30', and a rotation shaft 12 is formed at the center of the rotating plate 10. The rotating shaft 12 is fixed to the bearing 31, 31 'coupled to the upper fixing plate 20 and the lower fixing plate 20', the rotating plate 10 and the rotating shaft 12 is the upper fixing plate 20 And a rotating plate having a split coil body and a fixed plate having a split magnet body, the free rotating from the lower fixing plate 20 '. The method of claim 1, The coil body 11, 11 'and the magnet body 21, 21' and the rotating plate having a split coil body characterized in that arranged to be divided into any one of the divided number of 8 divided or 16 divided to each other; Transmission by a fixed plate having a split magnet body. The method of claim 1, The magnet bodies 21 and 21 'are formed to have a rectangular shape on the plane, and the ratio of the width and the length of the plane is 1: 4, and the height is 2 with respect to the above ratio, and the radially divided parts thereof are disposed. And a rotating plate having a split coil body and a fixed plate having a split magnet body, wherein at least two magnet bodies overlap each other within a range in which a ratio is maintained. The method of claim 1, The coil bodies 11 and 11 'are formed by horizontal winding so as to have the same area as the horizontal plane of the magnet bodies 21 and 21'. Powertrain. The method of claim 1, The coil bodies 11, 11 ′ and the magnet bodies 21, 21 ′ are formed to have a minimum separation width, and the magnet bodies 21 opposing the upper and lower sides of the coil bodies 11, 11 ′, respectively. The magnetic field of (21 ') is formed so as to be spaced apart from each other to interfere with the coil bodies (11) and (11') so as not to interfere with mutually corresponding magnet bodies (21) and (21 '). An electric drive by a rotating plate having an integrated body and a fixed plate having a split magnet body. The method of claim 1, A rotating plate having a split coil body and a fixed plate having a split magnet body, wherein the second rotating plate 10 'is disposed on the upper side of the upper fixing plate 20 having the magnet bodies 21 and 21'. Power transmission by The method of claim 1, A rotating plate having a split coil body and a split magnet body, each of which is arranged by separating the second rotating plate 10 'below the lower fixing plate 20' having the magnet bodies 21 and 21 '. Transmission by fixed plate. The method of claim 1, The second rotating plate 10 'is arranged on the upper side of the upper fixing plate 20 having the magnet bodies 21 and 21', and the third rotating plate 10 "is disposed below the lower fixing plate 20 '. A rotation plate having a split coil body and a fixed plate having a split magnet body.

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