KR100754448B1 - Generator and moter decreasing counter electromotive force by slit phenomenon of permanent magnet - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a generator and a motor in which back EMF is reduced due to a slit phenomenon of a permanent magnet. This is to provide a generator and a motor to be reduced. This is a secondary rotor 30 of a permanent magnet rotatable around the rotor 20 in a motor having a stator wound around a coil to form a magnetic field and a permanent magnet rotor configured to be rotatable inside the stator. ) Is arranged eight, the rotor 20 and the auxiliary rotor 30 is made of a circular, the auxiliary rotor 30 is the central axis for supporting the rotor 20 and the rotation of the central axis It consists of a bearing for supporting the guide, the rotor 20 is made of a permanent magnet of four poles, the auxiliary rotor 30 is made of a permanent magnet of two poles.

Stator, rotor, auxiliary rotor

Description

Generator and motor reducing counter electromotive force by slit phenomenon of permanent magnet}

1 is a configuration diagram of a conventional general motor

Figure 2 shows the winding state of the stator of the Figure 1 motor

Figure 3 is a motor configuration state according to the present invention

4 is a cross-sectional view of the rotor of FIG. 3 in accordance with the present invention.

(Explanation of symbols for the main parts of the drawing)

10: stator

20: main rotor

30: auxiliary rotor

The present invention provides a generator and a motor in which the counter electromotive force is reduced due to the slit phenomenon of the permanent magnet to reduce the counter electromotive force generated in the existing generator and the motor by disposing a permanent magnet rotatable to the rotor portion of the existing motor and the generator. It is about.

In general, a rotor generator or motor having a permanent magnet (hereinafter referred to as a "motor") places a permanent magnet as a rotor and an armature winding as a stator, and switches the power applied to the stator by an electronic circuit. To drive.

In general, a brushless motor using a rotor of a permanent magnet, as shown in FIG. 1, has a gap in the stator 1 wound around the coil 1a and the stator 1 to generate a rotor magnetic field. It consists of a rotor (2) having a permanent magnet and a position detection unit (3) for detecting the position of the rotor (2).

The stator 1 is generally formed by laminating a thin silicon steel sheet in an axial direction, and a slot is formed radially toward a central axis therein, and each of the slots applies a current to form a magnetic field. This is wound.

The rotor (2) is made of a permanent magnet, is installed axially in the center of the stator (1), is configured to achieve the same number of poles as the number of poles of the stator (1).

Referring to the operation of the general brushless motor having the configuration as described above are as follows.

When power is applied to the motor, the photoelectric element of the portion that is not covered by the rotating plate while the rotating plate of the position detecting unit 3 is stopped receives the light source to detect the position of the rotor 2.

On the basis of this detected information, the stator 1 is excited by switching the power applied to the faulter 1 in the transistor of the position detection unit 3 or the electronic circuit using the MOSEF. When the rotor (2) made of a permanent magnet and the magnetic circuit is configured to generate a mutual electromagnetic phenomenon to obtain a driving force.

In this way, the position of the rotor is detected according to which photoelectric element is receiving, and the power applied to the coil 1a of the stator is switched based on the detected information.

In other words, since the switching operation of the electronic circuit is performed while detecting the position of the rotor, the brake motor is started.

FIG. 2 is a view schematically showing the winding of the coil 1a of the stator 1 of the brushless motor of FIG. 1, wherein the stator 1 is formed by laminating a thin silicon steel sheet in an axial direction, and has a concentric shaft therein. A slot 6 is formed radially toward the inside, and each of the slots 6 is wound with a coil 1a for applying a current to form a magnetic field.

The coil 1a wound in the slot 6 of the stator 1 is connected to form three windings called phases.

The wound phase forms a magnetic field in the stator, which causes the rotor 2 to rotate at a constant speed.

However, this generated counter electromotive voltage, in which the brushless motor having such a permanent magnet rotor essentially generates counter electromotive voltage during rotation of the rotor, cancels the rotor field generated between the rotor 2 and the stator 1. There was a problem that has been consumed.

Therefore, efforts are being made to solve the counter electromotive voltage generated during the rotation of the rotor 2 to obtain the counter electromotive force.

This is because if the counter voltage consumed is eliminated, additional power is obtained as much as it is eliminated, thereby reducing the power consumption.

As disclosed in Korean Utility Model Publication No. 1998-029083 (August 5, 1998) as a conventional technique for solving the counter electromotive force, the rotor is rotated by installing an auxiliary winding inside the brushless motor. There is a technique of obtaining a back EMF generated in the city to supply a load with a small input power in a device using a plurality of loads.

In addition, the technology of the non-commutator DC motor using the back electromotive force disclosed in the Korean Patent Publication No. 2005-0054590 (June 10, 2005) as another technology, the power is applied to the core of the stator similar to the above technology Connect an electromotive force detector to detect the counter electromotive force on the non-current core except the phase of the core through which power is applied and current flows in the core of the rectifier DC motor, and connect the rectifier to rectify the pure counter electromotive force component to the electromotive force detector. The rectifier is connected to power storage means in which the counter electromotive force is stored, and the power storage means uses the counter electromotive force by connecting an output control unit for outputting the stored counter electromotive force to switch power.

The prior art as described above has a disadvantage in that the method or configuration for solving the counter electromotive force through the electrical means is complicated in most cases and the counter electromotive force obtained thereby is limited.

The present invention is to solve the conventional problems as described above, the purpose of which is to improve the mechanical configuration inside the motor is a simple method to reduce the back EMF due to the slit phenomenon of the permanent magnet to reduce the back EMF generator And providing a motor.

The present invention for achieving this object is a rotatable around the rotor (20) in a motor having a stator coiled to form a magnetic field and a permanent magnet rotor configured to be rotatable inside the stator; Eight auxiliary rotors 30 of permanent magnets are arranged, the rotor 20 and the auxiliary rotor 30 is made of a circular, the auxiliary rotor 30 to support the rotor 20 It consists of a central shaft and a bearing for guiding and supporting the rotation of the central axis, the rotor 20 is made of a permanent magnet of four poles, the auxiliary rotor 30 is made of a permanent magnet of two poles .

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The present invention will be described in detail with reference to the accompanying drawings as follows.

3 is a schematic cross-sectional view of a motor according to the present invention.

The stator 10 and the rotor 20, which are the main components of the motor, have been described in detail in the above-described prior art, and thus description thereof will be omitted. Hereinafter, the rotor 20 is represented as the main rotor.

In the present invention, a plurality of auxiliary rotors 30 rotatable between the stator 10 and the main rotor 20 are arranged and configured, and the main rotor 20 and the auxiliary rotor 30 are circular.

The auxiliary rotor 30 has a rotating shaft like the main rotor 20 and the rotating shaft is configured to be smoothly rotatable by a conventional bearing.

The auxiliary rotor 30 having the rotating shaft is configured of a permanent magnet like the main rotor. At this time, the physical properties of the permanent magnet of the main rotor 20 and the auxiliary rotor 30 can be configured the same or different.

4 is a cross-sectional view illustrating the arrangement of the main rotor 20 and the auxiliary rotor 30 configured in FIG. 3, wherein the auxiliary rotor 30 is circumferentially outside the circumferential surface of the main rotor 20. It is appropriately arranged to pass through the center of the electrons 20.

In this embodiment, eight auxiliary rotors 30 having the same cross-sectional area are arranged around the main rotor 20. However, the number of the auxiliary rotors 30 and the size of the cross-sectional area are appropriately modified. It is possible to do that.

For example, it is possible to form two or four poles of the main rotor 20 and the auxiliary rotor 30, and four auxiliary rotors 30 with respect to the polarity of the main rotor 20. Alternatively, it can be arranged in eight.

In the present embodiment, as shown in FIG. 4, the main rotor 20 has four poles, and eight auxiliary rotors 30 are arranged around the main rotor 20. It is positioned to the opposite polarity attracting each other by.

At this time, the auxiliary rotor 30 has a polarity, as shown in the figure

It is also possible to comprise two poles, and of course, it is also possible to comprise four poles, as in the form of the main rotor 20.

Referring to the operating state according to the present invention configured as described above are as follows.

The driving of the motor is performed in the same manner as the conventional motor.

In the conventional case, the position detection means for determining the position of the main rotor 20 is made.

However, in the case of the present invention, since the eight auxiliary rotors 30 located close to the main rotor 20 always show different polarities from the main rotor 20, the main rotor ( As in the position reading of 20), it performs the same function as detecting the position through the auxiliary rotor 30.

When the magnetic field is formed by the stator 10 by the position detection of the auxiliary rotor 30 and the main rotor 20, the auxiliary rotor 30 and the main rotor 20 rotate in the same manner as in the conventional motor. This will be done.

When the rotation is made, the main rotor 20 and the auxiliary rotor 30 are rotated in the same shape as one rotor by the polarities attracted to each other.

As such, when the counter electromotive force is generated when the rotor is rotated in the same shape as the one rotor, the auxiliary rotor is not rotated together with the main rotor 20 by the counter electromotive force, and the auxiliary rotor 30 is the main rotor ( 20) The sliding phenomenon continues to occur while rotating.

However, the auxiliary rotor 30 that rotates while this slippage phenomenon is caused to rotate the main rotor 20 rapidly due to the change in polarity of the main rotor 20 linked thereto.

That is, the slit phenomenon of the auxiliary rotor 30 using the counter electromotive force is generated by this phenomenon, and the slit phenomenon serves to accelerate the main rotor, thereby reducing the load using the counter electromotive force.

Therefore, even if a load is generated by various devices connected to the rotating shaft of the motor, the function of compensating for the degradation of the motor according to the load by using the counter electromotive force is performed.

In the present embodiment, this has been explained through a motor. However, in the case of a generator, in addition to the amount of power generated in the existing generator according to the use of the generator, a function of assisting the amount of power added through the counter electromotive force is performed.

The present invention improves the structure of a conventional motor or generator, the slit phenomenon of the auxiliary rotor occurs when the counter electromotive force is generated through the auxiliary rotor rotatably installed opposite the polarity of the rotor around the rotor. By the slit phenomenon to accelerate the main rotor 20 by the function to improve the performance of the motor or to additionally assist the power generation of the generator.

As described above, the generator and the motor in which the counter electromotive force is reduced due to the slit phenomenon of the permanent magnet of the present invention may be provided with a plurality of auxiliary rotors around the main rotor, thereby reducing the counter electromotive force.

Claims (4)

In a motor having a stator 10 wound around a coil to form a magnetic field, and a permanent magnet rotor 20 configured to be rotatable inside the stator, Disposing eight auxiliary rotors 30 of the permanent magnet rotatable around the rotor 20, the rotor 20 and the auxiliary rotor 30 is made of a circular, The auxiliary rotor 30 is composed of a central shaft for supporting the rotor 20, and a bearing for guiding and supporting the rotation of the central axis, The rotor 20 is made of a permanent magnet of 4 poles, the auxiliary rotor 30 is a generator and motor is reduced back electromotive force due to the slit phenomenon of the permanent magnet, characterized in that made of a permanent magnet of two poles. delete delete delete

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