KR20070054363A - Induction motor utilizing an end-turn - Google Patents

Abstract

The present invention relates to an induction motor utilizing an end turn, the induction motor comprising a stator to form an end turn by winding the coil, and a rotor core provided with a stator and a void, wherein the rotor core has one end An end turn application portion extending to face the turn and providing a passage of magnetic flux generated from the end turn protrudes adjacent to the end turn in a portion facing the end turn and is formed by the compression of the soft magnetic powder. Accordingly, the present invention provides a passage through which the rotor has a structure adjacent to the end turn, whereby the magnetic flux generated from the end turn can induce a current in the rotor conductor, and thus the magnetic flux of the end turn is increased to increase the torque of the rotor. By making it available, it has the effect of improving efficiency.

Rotor core, stator core, soft magnetic powder, rotor conductor, end turn

Description

INDUCTION MOTOR UTILIZING AN END-TURN}

1 is a cross-sectional view showing an induction motor according to the prior art,

2 is a cross-sectional view showing an induction motor utilizing an end turn according to the present invention,

3 is a perspective view of a rotor according to the present invention.

<Description of Symbols for Main Parts of Drawings>

110: stator 111: coil

112: stator core 113: end turn

120: rotor 121: rotor conductor

122: rotor core 123: end turn using portion

124: shaft hole 130: shaft

140: casing 141: holder

142: Bearing

The present invention relates to an induction motor utilizing an end turn, and more particularly, to an induction electric synchronization using an end turn which can use the magnetic flux of the end turn to increase the torque of the rotor.

In general, an electric motor is a device that obtains rotational force by converting electrical energy into mechanical energy, and is widely used in home appliances as well as industrial equipment, and is divided into an AC motor and a DC motor.

On the other hand, an induction motor, which is a kind of AC motor, induces a current in the secondary winding by the electromagnetic induction of the primary winding of the coil connected to the power supply, and obtains a rotational torque by the interaction of the current induced in the secondary winding and the rotating magnetic field. .

Referring to the attached induction motor according to the related art as follows.

1 is a cross-sectional view showing an induction motor according to the prior art. As shown, the conventional induction motor 10 includes a stator 11 fixed to the casing 14, a rotor 12 rotatably installed with a gap in the stator 11, And a shaft 13 that is pressed into the center of the rotor 12 and rotates with the rotor 12.

The stator 11 is composed of a coil 11a that receives an AC power source to form a rotating magnetic field and a stator core 11b of a magnetic body that forms a passage for magnetic flux generated by the rotating magnetic field of the coil 11a.

The stator core 11b is formed by stacking a plurality of silicon steel sheets having the same shape along the axial direction, and a plurality of slots (not shown) are radially formed at regular intervals along an inner circumferential surface, and a coil 11a is formed in the slot. It is wound in the way of distribution, concentration, and concentric circles.

The rotor 12 is provided with a rotor conductor 12a that generates torque by the interaction of the current induced by the coil 11a with the magnetic flux, and a magnetic conductor that provides a passage for the magnetic flux while the rotor conductor 12a is provided. Of the rotor core 12b.

As the rotor conductor 12a, a metal or a magnet such as aluminum or copper having high conductivity is used.

The rotor core 12b is formed by stacking a plurality of silicon steel sheets having the same shape along the axial direction, and a plurality of slots (not shown) parallel to the axial direction are formed radially at regular intervals on the outer circumferential surface or inside, The rotor conductor 12a is provided to be parallel to the axial direction similarly to the coil 11a.

End rings 12c are provided at both ends of the rotor core 12b so as to form a single circuit by connecting the rotor conductors 12a installed inside.

The end ring 12c is generally made of aluminum (Al) capable of die casting with the rotor conductor 12a when the rotor conductor 12a installed inside the rotor core 12b is a metal.

The shaft 13 is fixed to penetrate through the rotor core 12b and is rotatably installed in the holder 14a located on both sides of the casing 14 via the bearing 14b.

The operation of the induction motor 10 according to the related art is as follows.

As the AC power is applied to the coil 11a, a magnetic field is generated in a direction perpendicular to the axis so that the magnetic flux rotates through the stator core 11b, and the rotating magnetic flux of the rotor 12 of the rotor 12 through the air gap. ), The current is induced in the rotor conductor 12a. At this time, the current induced in the rotor conductor 12a generates a torque in the rotor 12 along with the magnetic flux according to Fleming's left hand law.

The conventional induction motor 10 has an end-turn 11c which forms a circuit by connecting coils 11a between the stator core 11b slots to both ends of the stator core 11b in the coil 11a. ), The induction motor 10 should be formed with a plurality of poles in the stator 11 to form a rotating magnetic field, for this purpose, the coil 11a is not wound between the slots of the adjacent stator core 11b Since the windings are skipped over the slots of the several stator cores 11b, the endturns 11c have only a change in length depending on the winding method of the coil 11a, and inevitably exist.

However, in the induction motor 10, the end turn 11c can generate a magnetic flux that affects the torque of the rotor 12 by exposing the generated magnetic flux to air, that is, the effective magnetic flux. It occupies a considerable part of the coil 11a wound by the. Therefore, the end turn 11c increases the copper loss, which is the resistance of the coil 11a itself, but does not help to improve the efficiency of the induction motor 10.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to provide a passage through which a magnetic flux generated from an end turn can induce a current in the rotor conductor by having a structure in which the rotor is adjacent to the end turn. Therefore, it is possible to provide an induction motor that utilizes an end turn that improves efficiency by allowing the magnetic flux of the end turn to be used to increase the torque of the rotor.

In order to achieve the above object, the present invention provides an induction motor including a stator that forms an end turn by winding a coil and a rotor core that is provided with a space between the stator and one side of the rotor core. An end turn utilization portion extending to see and providing a passage of the magnetic flux generated from the end turn, protrudes adjacent to the end turn in a portion facing the end turn, and is formed by compression of the soft magnetic powder.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

2 is a cross-sectional view showing an induction motor utilizing an end turn according to the present invention. As shown, the induction motor 100 utilizing the end turn according to the present invention is a stator (110) is fixed to the casing 140, and is installed to rotate while leaving a space in the stator 110 and soft magnetic A rotor 120 having a rotor core 122 formed by the compression of the powder and having an end turn-use portion 123 provided on one side thereof, and pressed into the center of the rotor 120 to rotate together with the rotor 120. A shaft 130.

The stator 110 includes a coil 111 that receives an AC power source to form a rotating magnetic field, and a stator core 112 of a magnetic material that forms a passage for magnetic flux generated by the rotating magnetic field of the coil 111. 111 is wound around a plurality of slots (not shown) that are radially formed along the inner circumferential surface of the stator core 112 to form an end turn 113 on both sides of the stator core 112.

The rotor 120 has a rotor conductor 121 for generating torque by the interaction of the current induced by the coil 111 with the magnetic flux, and a magnetic conductor provided with the rotor conductor 121 and providing a passage for the magnetic flux. The rotor core 122 is made of.

The rotor conductor 121 is made of a highly conductive metal such as aluminum (Al) or copper (Cu) or a magnet (magnet), and like the coil 111 is installed in the slot of the rotor core 122 parallel to the axial direction. By being parallel to the axial direction, it is installed along the outer circumferential surface of the rotor core 122 or installed inside the rotor core 122.

As shown in FIGS. 2 and 3, the rotor core 122 is longer than the stator core 112 by extending one side, that is, the upper side facing the end turn 113 of the stator 110, A slot facing the end portion 113, which has an air gap in the end turn 113 along the outer circumferential surface of the portion facing the 113, that is, the extended portion, is provided to protrude, and the rotor conductor 121 is installed therein, And the shaft hole 124 to which the shaft 130, which is installed through the bearing 142 is inserted into the holder 141 of the casing 140 is fixed.

The end turn using portion 123 provides a passage through which the magnetic flux of the end turn 113 moves so that the magnetic flux generated from the end turn 113 induces a current in the rotor conductor 121.

The rotor core 122 is formed by the compression of the soft magnetic powder to form the slot (not shown) and the shaft hole 124 as well as the end turn 113, respectively. The soft magnetic powder is iron-based particles. And each of the soft magnetic powders is coated to be electrically insulated.

The rotor core 122 is provided with a compression member such as a punch and the like by providing a molding space including a shape corresponding to the rotor core 122 in a compression molding machine in order to be compression molded into soft magnetic powder, and filling the molding space with soft magnetic powder. Compression is made to have a slot (not shown) as well as the end-turn portion 123. At this time, the soft magnetic powder may contain a lubricant and / or a binder and may be compressed together.

The rotor core 122 is a soft magnetic composite (also called "SMC") having a three-dimensional shape by a compression process of the soft magnetic powder, and has a higher degree of freedom than the conventional case using silicon steel sheets. By allowing freedom, it is possible to form the end-turn-use part 123 unlike the silicon steel laminated structure having only the same shape in the related art.

The operation of the induction motor using an end turn having such a structure is performed as follows.

The rotational magnetic flux is formed through the stator core 112 by the application of AC power to the coil 111, and the current is induced in the rotor conductor 121 by the rotational magnetic flux linking with the rotor conductor 121 through the air gap. The current induced in the rotor conductor 121 generates a torque together with the magnetic flux. At this time, a conventional end turn 11c (shown in FIG. 1) is induced by causing the rotor conductor 121 to conduct current along the end turn use portion 123 through the magnetic flux gap generated from the end turn 113. The magnetic flux generated from the above is exposed to air, thereby improving the inefficient part which cannot be effectively used.

Therefore, the efficiency of the induction motor 100 is improved by allowing the magnetic flux generated from the end turn 113 to be used for increasing the torque of the rotor 120 as an effective magnetic flux.

As described above, the induction motor utilizing the end turn according to the present invention has a structure in which the rotor is adjacent to the end turn provides a passage through which the magnetic flux generated from the end turn can induce a current in the rotor conductor, As a result, the magnetic flux of the endturn can be used to increase the torque of the rotor, thereby improving efficiency.

What has been described above is just one embodiment for implementing the induction motor utilizing the end turn according to the present invention, the present invention is not limited to the above embodiment, as claimed in the following claims Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

Claims (1)

In the induction motor comprising a stator to form an end turn by winding the coil, and a rotor core provided with a space between the stator, The rotor core, One end extends to face the end turn, and an end turn use portion that provides a passage of magnetic flux generated from the end turn protrudes adjacent to the end turn in a portion facing the end turn and is compressed to the soft magnetic powder. Induction motor utilizing the end turn formed by.

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