KR101019837B1 - Rotor for generator and electric motor discharging and absorbing the high density of the same magnetic pole of permanent magnet - Google Patents

Abstract

The present invention relates to a rotor for a generator and a motor that discharges high-density magnetic flux formed between opposite poles of a permanent magnet, and more particularly, an equilateral trapezoidal permanent magnet with the same pole facing the rotor body. The winding coil cuts the magnetic flux drawn out at right angles to the circumference of the rotor body between the same poles facing each other by installing the winding coil at right angles. The present invention relates to a rotor for a generator and a motor for discharging a high-density magnetic flux that is formed between opposite poles of a permanent magnet capable of generating induced current electromotive force.

The present invention is rotated integrally with the rotor shaft 15, a plurality of isosceles trapezoidal permanent magnets of the same standard consisting of N pole and S pole in the circumferential direction is installed so that the same polarity facing each other 10; A stator 20 for receiving the rotor body 10 and having a plurality of coil winding holes 21 penetrating from one side to the other side in a circumferential direction at predetermined intervals; The coil winding hole 21 formed along the circumferential direction passes through two adjacent coil winding holes 21 and is wound around the stator 20, and is located at the center between the opposite poles of the permanent magnet 40. Passing coil winding hole 21 and the coil winding hole 21 located in the center of the upper side of the equilateral trapezoidal permanent magnet 40 includes a winding coil 30 is wound around the stator 20 a predetermined number, The winding coil 30 from the coil winding hole 21 located at the center between the same poles facing each other of the permanent magnet 40 has the permanent magnet among the coil winding holes 21 in which the winding coil 30 is wound a predetermined number. The winding coil 30 drawn from the coil winding hole 21 located in the center between the opposite poles facing the same 40 and from the coil winding hole 21 located in the center of the upper side of the equilateral trapezoidal permanent magnet 40 is Equilateral side of the coil winding hole 21 in which the winding coil 30 is wound around a certain number in the vicinity That the inlet to the coil winding hole 21 in the top of the side center of the permanent magnet 40 is characterized.

Rotor body, stator, winding coil, permanent magnet, same pole

Description

ROTOR FOR GENERATOR AND ELECTRIC MOTOR DISCHARGING AND ABSORBING THE HIGH DENSITY OF THE SAME MAGNETIC POLE OF PERMANENT MAGNET}

The present invention relates to a rotor for a generator and a motor that discharges high-density magnetic flux formed between opposite poles of a permanent magnet, and more particularly, an equilateral trapezoidal permanent magnet with the same pole facing the rotor body. The winding coil cuts the magnetic flux drawn out at right angles to the circumference of the rotor body between the same poles facing each other by installing the winding coil at right angles. The present invention relates to a rotor for a generator and a motor for discharging a high-density magnetic flux that is formed between opposite poles of a permanent magnet capable of generating induced current electromotive force.

In general, the generator generates electromotive force by the electromagnetic induction action by the rotational movement to convert the mechanical energy into electrical energy, a linear movement has also been developed.

Conventional rotating field-type generators forcibly rotate the rotor to generate an electromotive force proportional to sinθ due to the stator coil cutting the magnetic flux of the rotor's electromagnets or permanent magnets. The electromotive force proportional to sin θ generated by the conductor rotating the magnetic flux is supplied to the load as an output voltage.

In the conventional permanent magnet generator, the cross section of the permanent magnet coupled to the outside of the body has a rectangular shape. As described above, the rotor using a rectangular magnet has a problem in that the winding force cuts the magnetic flux proportional to sinθ, resulting in a decrease in efficiency in proportion to the generated electromotive force.

The present invention was devised in view of the above circumstances, and an object of the present invention is to install a plurality of permanent magnets facing the same pole along the circumferential direction on the rotor body, and install a winding coil on the stator surrounding the rotor body. Induction current of the maximum efficiency generated in the winding coil by making the winding coil cut at right angles, ie, sinθ = 1, is discharged at right angles to the rotor body circumference between opposite poles of adjacent permanent magnets. It is to obtain the electromotive force to obtain a large power.

The configuration of the present invention for achieving the above object is axially rotated integrally with the rotor shaft 15, a plurality of equilateral trapezoidal permanent magnets of the same standard consisting of N pole and S pole in the circumferential direction is the same A rotor body 10 provided with polarities facing each other; A stator 20 for receiving the rotor body 10 and having a plurality of coil winding holes 21 penetrating from one side to the other side in a circumferential direction at predetermined intervals; The coil winding hole 21 formed along the circumferential direction passes through two adjacent coil winding holes 21 and is wound around the stator 20, and is located at the center between the opposite poles of the permanent magnet 40. Passing coil winding hole 21 and the coil winding hole 21 located in the center of the upper side of the equilateral trapezoidal permanent magnet 40 includes a winding coil 30 is wound around the stator 20 a predetermined number, The winding coil 30 from the coil winding hole 21 located at the center between the same poles facing each other of the permanent magnet 40 has the permanent magnet among the coil winding holes 21 in which the winding coil 30 is wound a predetermined number. The winding coil 30 drawn from the coil winding hole 21 located in the center between the opposite poles facing the same 40 and from the coil winding hole 21 located in the center of the upper side of the equilateral trapezoidal permanent magnet 40 is Equilateral side of the coil winding hole 21 in which the winding coil 30 is wound around a certain number in the vicinity That the inlet to the coil winding hole 21 in the top of the side center of the permanent magnet (40) is characterized in that characterized.

As described above, according to the present invention, the permanent magnet is installed on the rotor body so that the same pole faces each other, and the winding coil is installed on the stator surrounding the rotor body. The winding coils are cut at right angles to discharge the high-density magnetic flux that is sucked out at right angles to the circumference of the maximum electromotive force sinθ = 1 which is the current of electromotive force proportional to sinθ output in the first rotational power generation process of the existing rotating field-type rotating electromagnetic magnetic power generation. It is effective to obtain a large power by flowing the current of the winding coil.

Hereinafter, with reference to the accompanying drawings will be described in detail a rotor for a generator and a motor for discharging the high-density magnetic flux formed between the same pole facing the permanent magnet of the present invention.

1 is a perspective view showing a rotor for a generator and a motor for discharging a high-density magnetic flux is formed between the same pole facing each other of the permanent magnet according to an embodiment of the present invention, Figure 2 according to an embodiment of the present invention 3 is a plan view showing a planar state of the rotor, and FIG. 3 is an exploded perspective view showing a rotor for a generator and an electric motor for discharging high density magnetic fluxes formed between opposite poles of a permanent magnet according to an embodiment of the present invention; Figure 4 is a state diagram showing a rotor according to another embodiment of the present invention, Figure 5 is a state diagram showing a rotor according to another embodiment of the present invention.

As shown in the drawings, the rotor and the rotor for discharging and sucking the high-density magnetic flux formed between the opposite poles of the permanent magnet according to the present invention, the rotor body axially rotates integrally with the rotor shaft, the stator, Winding coil and a permanent magnet installed on the rotor body.

The rotor body 10 is a nonmagnetic body, the rotor shaft 15 is penetrated through the center.

Here, the rotor body 10 is provided with a plurality of permanent magnets 40 consisting of the N pole and the S pole in the circumferential direction to face the same polarity.

In other words, as shown in FIG. 2, a plurality of permanent magnets 40 of the same size are installed around the circumference of the rotor body 10, but the lower side facing the upper edges of the permanent magnets adjacent to each other. Install it longer than corners.

In the above structure, all of the magnetic flux which is discharged and sucked at the opposite pole surface is discharged between the upper edge edges with long edges.

Here, the installation of the permanent magnet 40 in the rotor body 10 will be described in detail. A straight line that divides the cross-sectional area of the rotor body 10 into six equal lines is drawn, and the permanent line is installed so that the straight line is in the center. Coupling groove 13 of the same size as the size of the magnet 40 is formed.

Then, the plurality of permanent magnets 40 may be installed in the coupling groove 13 to face the same polarity.

The stator 20 accommodates the rotor body 10 as an insulator, and a plurality of coil winding holes 21 are formed to penetrate from one side to the other side in the circumferential direction, and the coil Winding hole 21 is the center between the opposite poles of the permanent magnet formed in the rotor body is located in any one of the coil winding hole 21, the other coil winding hole 21 is close to the trapezoidal permanent magnet upper It is formed at regular intervals to be located in the center of the side.

Here, the thickness of the stator 20 is equal to the thickness of the rotor body 10, and the minimum interval between the outer diameter of the rotor body 10 and the inner diameter of the stator 20 is not in contact.

In addition, the coil winding hole 21 is formed so as to penetrate from one side surface between the inner diameter and the outer diameter of the stator 20 to the other side, four permanent magnets 40 installed in the rotor body 10 In this case, eight coil winding holes are formed, and in the case of six permanent magnets 40, 12 coil winding holes are formed. In the case of eight permanent magnets 40, 16 coil winding holes are installed.

And, in the case of winding the winding coil 30 in the coil winding hole 21 to be described in detail with reference to Figure 2, the winding coil 30 is wound through the first hole (23a) in the second hole (23b) After a certain number of windings, the winding coil 30 from the first hole 23a is introduced into the third hole 24a, and the winding coil 30 is wound in the third hole 24a and the fourth hole 24b. do.

Thereafter, the winding coils emerging from the fourth hole 24b are introduced into the sixth hole 25b, and the winding coil 30 is wound a predetermined number of times in the sixth hole 25b and the fifth hole 25a. The winding coil (25a) is introduced into the seventh hole (26a), and a predetermined number of winding coils (30) are wound around the seventh hole (26a) and the eighth hole (26b), and exited through the eighth hole (26b). The winding coil 30 is introduced into the 10th hole 27b, and the winding coil 30 is wound around the 10th hole 27b and the 9th hole 27a.

After that, the winding coil 30 from the 9th hole 27a is introduced into the 11th hole 28a, and a predetermined number of winding coils are wound around the 11th hole 28a and the 12th hole 28b, and then 12th hole. Winding coil 30 comes out to (28b).

Looking at the current direction generated in the winding coil circuit when the generator rotor configured as shown in FIG. 2 rotates in the right direction, the sixth hole 25b in the winding coil wound in the sixth hole 25b and the fifth hole 25a The side winding coil cuts the high-density N-pole magnetic flux discharged at right angles to the circumference of the rotor body 10 to the left, so that the maximum current entering the winding coil of the sixth hole 25b is generated by the right hand rule of Fleming.

The current entering the winding coil of the sixth hole 25b comes out of the winding coil of the fifth hole 25a at the position of the structure not cutting the magnetic flux entering the S pole from the N pole of the rotor body.

The current from the winding coil of the 5th hole 25a is transferred to the 7th hole 26a winding coil 30 in the position which does not cut the magnetic flux which enters the S pole from the N pole of the rotor body 10. Enter

The current entering the winding coil of the seventh hole 26a cuts the high-density S-pole magnetic flux that is wound at right angles to the circumference of the rotor body 10 to the left by the winding coil of the eighth hole 26b. Is joined with the maximum current from the winding coil of the eighth hole 26b.

The current from the winding coil of the 8th hole 26b cuts the high-density N pole magnetic flux from which the winding coil of the 10th hole 27b is discharged at right angles to the circumference of the rotor to the left. Join the maximum current into the winding coil of 27b).

The current entering the winding coil of the tenth hole 27b comes out of the winding coil of the nineth hole 27a at a position where the magnetic flux entering the N pole of the rotor body 10 to the S pole is not cut.

The current from the winding coil of the 9th hole 27a enters the winding coil of the 11th hole 28a in the position which does not cut the magnetic flux which goes into the S pole from the N pole of the rotor body 10. As shown in FIG.

The current entering the winding coil of the 11th hole 28a cuts the high-density S-pole magnetic flux which the winding coil of the 12th hole 28b is sucked at right angles to the circumference of the rotor body 10 to the left, and according to Fleming's right hand rule By joining the maximum current from the winding coil of the 12th hole 28b.

The electric current from the winding coil of the 12th hole 28b cuts the high-density N-pole magnetic flux from which the winding coil of the 2nd hole 23b is discharged at right angles to the circumference of the rotor body 10 to the left, and according to Fleming's right hand rule This joins the maximum current entering the winding coil of the second hole 23b.

The current entering the winding coil of the second hole 23b comes out of the winding coil of the first hole 23a at a position where the magnetic flux entering the N pole of the rotor body from the N pole to the S pole is not cut.

The current from the winding coil of the first hole 23a enters the winding coil of the third hole 24a at a position where the magnetic flux entering the N pole from the rotor body to the S pole is not cut.

The current entering the winding coil of the third hole 24a cuts the high-density S-pole magnetic flux from which the winding coil of the fourth hole 24b is sucked at right angles to the rotor circumference to the left, and according to Fleming's right hand law, Join the maximum current from the winding coil of 24b).

The current from the winding coil of the 4th hole 24b cuts the high-density N-pole magnetic flux from which the winding coil of the 6th hole 25b is discharged at right angles to the circumference of the rotor body 10 to the left, and thus Fleming's right hand rule Is joined with the maximum current entering the winding coil of the sixth hole 25b.

As described above, the rotor body 10 rotates right and the center between the opposite poles N poles of the permanent magnet 40 is 5 holes, 4 holes, 3 holes, 2 holes, 1 hole, When the motor rotates once through the winding coils of 12th hole, 11th hole, 10th hole, 9th hole, 8th hole, and 7th hole, the current turns right to the winding coils of the 5th and 4th hole, and 3 Current turns left in winding coils of holes 1 and 2, current turns right in winding coils of holes 1 and 12, current rotates in winding coils of holes 11 and 10, and 9 holes. The current rotates right in the winding coil of No. 8 and the holes, and the current rotates in the winding coil of Nos. 7 and 6. That is, in the 5th and 4th holes, → direction, in the 3rd and 2nd holes, the ← direction, in the 1st and 12th holes, the → direction, and in the 11th and 10th holes, the ← direction, In the 9th and 8th holes, an alternating current occurs with +-being changed three times when the co-rotator facing each other rotates in the → direction and in the 7th and 6th holes in the ← direction.

In the above, it can be seen that the number of alternating currents changed to +-when the rotor body 10 rotates once is the total number of permanent magnets / 2.

That is, when the rotor body 10 rotates once, an alternating current occurs when +-is changed twice when there are four permanent magnets, and when there are eight permanent magnets, an alternating current occurs when +-is changed four times. Done.

In addition, the permanent magnets installed in the rotor body 10 may be at least four or more even numbers. (Total number of permanent magnets = (n + 1) x 2, n is the number of permanent magnets installed on the rotor body with the same pole facing each other)

Here, if the total number of permanent magnets is 4, the frequency should be 1800 RPM for 60Hz, and if the total number of permanent magnets is 6, the rotor should be 1200RPM for the frequency 60Hz, and the total number of permanent magnets In the case of eight, it would be desirable for the rotor to be 900 RPM for the frequency to be 60 Hz.

When rotating the rotor body 10 in the stator 20 of the non-conductor as described above, the winding coil 30 is cut at right angles to the high-density magnetic flux that is drawn out at right angles to the circumference of the rotor body by the right hand rule of Fleming In the whole rotation process, the maximum efficiency current of sinθ = 1 of the existing rotating field rotor armature power generation flows in the unit winding coil.

1 is a perspective view showing a rotor for a generator and a motor for discharging high-density magnetic flux formed between opposite poles of a permanent magnet according to an embodiment of the present invention;

2 is a plan view showing a planar state of the rotor according to an embodiment of the present invention;

3 is an exploded perspective view showing a rotor for a generator and a motor for exhausting high density magnetic fluxes formed between opposite poles of a permanent magnet according to an embodiment of the present invention;

4 is a state diagram showing a rotor according to another embodiment of the present invention;

5 is a state diagram showing a rotor according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10: rotor body 13: coupling groove

15: rotor shaft 20: stator

21: coil winding 23a: hole 1

23b: hole 2 24a: hole 3

24b: hole 4 25a: hole 5

25b: Hole 6 26a: Hole 7

26b: Hole 8 27a: Hole 9

27b: hole 10 28a: hole 11

28b: hole 12 30: winding coil

40: permanent magnet

Claims (1)

Rotor body 10 is axially rotated integrally with the rotor shaft 15, the plurality of isosceles trapezoidal permanent magnets 40 of the same standard consisting of N pole and S pole in the circumferential direction are installed so that the same polarity facing each other Wow; A stator 20 for receiving the rotor body 10 and having a plurality of coil winding holes 21 penetrating from one side to the other side in a circumferential direction at predetermined intervals; The coil winding hole 21 formed along the circumferential direction passes through two adjacent coil winding holes 21 and is wound around the stator 20, and is located at the center between the opposite poles of the permanent magnet 40. Passing coil winding hole 21 and the coil winding hole 21 is located in the center of the upper side of the trapezoidal permanent magnet 40, the winding coil 30 is wound around the stator 20 a predetermined number, The winding coil 30 from the coil winding hole 21 located in the center between the same poles facing the permanent magnet 40 is the permanently wound coil winding hole 21 of the coil winding hole 21 wound around a predetermined number. The winding coil 30 is introduced into the coil winding hole 21 located in the center between the opposite poles of the magnet 40 and from the coil winding hole 21 located in the center of the upper side of the equilateral trapezoidal permanent magnet 40. The permanent coil of the permanent magnets, characterized in that the winding coil 30 is introduced into the coil winding hole 21 located in the center of the upper side of the trapezoidal permanent magnet 40 of the coil winding hole 21 is a number of windings adjacent to Rotors for generators and motors that discharge and absorb high-density magnetic fluxes formed between opposite poles.

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