KR100434289B1 - rotor of squirrel cage induction motor - Google Patents

Abstract

The present invention relates to a rotor of a squirrel cage induction motor that can improve the characteristics by reducing the resistance of the rotor conductor by simply and effectively removing the reaction layer formed on the interface between copper and aluminum.

To this end, the present invention provides a plurality of first slots 111 formed radially at predetermined intervals, and a plurality of second slots positioned radially at a predetermined interval from the first slots. A rotor iron core (100) configured by stacking a plurality of steel plates (110) provided with the first slot and the second slot so as to be continuous in the axial direction, respectively; Rotor conductors 120 and 130 having high conductivity dissimilar metals in the first slot and the second slot, respectively, for generating torque by current induced from the stator winding; The squirrel cage induction motor is provided to connect the rotor conductors to both ends of the rotor core and constitutes a circuit, and includes an end ring 140 made of the same component as the rotor conductor provided in the second slot. Provide the rotor of.

Description

Rotor of squirrel cage induction motor

The present invention relates to a squirrel cage induction motor, and more particularly, to a squirrel cage induction motor that can improve characteristics by effectively removing a reaction layer formed at the interface between the rotor conductor and reducing resistance of the rotor using copper and aluminum. It is about a rotor.

In general, an electric motor is a machine that obtains rotational power by converting electrical energy into mechanical energy, and is roughly classified into an AC motor and a DC motor, and among them, an induction motor is a kind of AC motor.

The induction motor is composed of a stator and a rotor, and torque is generated in the rotor by a rotating magnetic field generated when an alternating current flows through the stator winding, thereby rotating the motor. The induction motor as described above has a squirrel cage induction motor in which copper or aluminum round rods form the rotor conductor according to the winding form of the rotor, and the winding induction in which the winding is connected to the rotor as well as the stator. There is a wound-rotor induction motor.

Among these, the rotor structure of the squirrel cage induction motor will be described with reference to the accompanying drawings.

1 is a cross-sectional view illustrating a rotor structure of a general squirrel cage induction motor, wherein the rotor of the squirrel cage induction motor generates a torque by interaction of current and magnetic flux induced by a stator winding (not shown). 15) and a rotor iron core 10 of a magnetic body forming a passage of magnetic flux. At this time, the rotor iron core 10 is a circular silicon steel plate 11 is formed radially at a predetermined interval on the outer circumferential side of the rotor of the rotor slot along the axial direction It is composed of a plurality of laminated so as to be continuous, a metal such as aluminum or copper of high conductivity is inserted into the rotor slot 13 to form a rotor conductor (15). In addition, end-rings 17 are provided at both ends of the rotor conductor 15 to form a circuit by connecting the rotor conductors to each other. At this time, the rotor conductor 15 and the end ring 17 are generally made of aluminum, which is capable of die casting.

The rotor of the squirrel cage induction motor configured as described above interacts with the magnetic flux while current flowed from the stator winding through the rotor conductor 15 to generate a rotational torque according to Fleming's left hand law.

However, in order to improve performance in the above-described induction motor, the resistance of the rotor conductor 15 should be small. However, the aluminum applied to the rotor conductor 15 has a lower electrical conductivity than copper, causing a problem of deterioration of the characteristics of the induction motor.

In order to solve this problem, the applicant has proposed a rotor structure of a squirrel cage induction motor in which a copper rod is inserted, which is well illustrated in FIG. 2.

Figure 2 is a cross-sectional view showing the rotor structure of the cage type induction motor disclosed in Korean Utility Model Publication No. 2001-000679, the rotor of the cage type induction motor according to the publication number is a copper rod 35 forming a rotor conductor The end ring 37 is inserted into the electron core 30 and formed by aluminum die casting at both ends of the copper rod. In this case, although the resistance of the rotor conductor is reduced, the performance is improved, but the disadvantage that a high resistance reaction layer is formed between the copper rod 35 and the aluminum end ring 37 has been raised. Such a reaction layer influences the path of the secondary current, and as a result, the secondary current is concentrated on one side of which has good coupling with the end ring, resulting in a problem of deterioration in characteristics due to an increase in resistance. .

On the other hand, Figure 3 is a cross-sectional view showing the rotor structure of the squirrel cage induction motor described in Japanese Patent Laid-Open No. 8-223878, the rotor of the squirrel cage induction motor according to the publication number between the aluminum conductor 45 and the copper rod 49 By forming the plating layer 48 in the reaction layer, the reaction layer between the copper rod and the aluminum conductor was removed. However, in this case, since the specific gravity of aluminum as the rotor conductor is much higher, the conductor resistance could not be reduced much. This is because the aluminum die-casting method for forming the rotor conductor should be secured a space in which the aluminum melt can be injected, for this purpose is limited to the size of the copper bar (49). In addition, since the plating layer 48 is formed long along the longitudinal direction of the rotor slot 43, the cost increase due to this could not be ignored.

The present invention has been made to solve the above problems, an object of the present invention is to improve the characteristics by reducing the resistance of the rotor conductor by simply and effectively removing the reaction layer formed on the interface between copper and aluminum. It is to provide a rotor of the squirrel cage induction motor.

1 is a cross-sectional view showing a rotor structure of a general squirrel cage induction motor

2 is a cross-sectional view showing the rotor structure of the cage-type induction motor disclosed in Korean Utility Model Publication No. 2001-000679

3 is a cross-sectional view showing the rotor structure of a cage induction motor described in Japanese Patent Laid-Open No. 8-223878;

Figures 4a and 4b is a cross-sectional view and a longitudinal cross-sectional view showing the rotor structure of the squirrel cage induction motor according to the present invention, respectively

Explanation of symbols on the main parts of the drawings

100: rotor iron core 110: steel plate

111: first slot 113: second slot

120: copper rotor conductor 130: aluminum rotor conductor

140: end ring 150: plating layer

In order to achieve the above object, the present invention provides a plurality of first slots formed radially at predetermined intervals, and a plurality of second slots positioned radially at a predetermined distance from the first slot and radially formed at predetermined intervals. A rotor iron core configured by stacking a plurality of steel sheets provided such that the first slot and the second slot are continuous in the axial direction, respectively; A rotor conductor having high conductivity dissimilar metals provided in the first slot and the second slot, respectively, for generating torque by current induced from the winding of the stator; Rotors of the squirrel cage induction motor including end rings made of the same components as the rotor conductors provided in the second slot, the rotor conductors being connected to each other at both ends of the rotor iron core. To provide.

Therefore, when the rotor of the squirrel cage induction motor according to the present invention is applied to the first slot as copper and aluminum to the second slot, respectively, the rotor may naturally solve the reaction layer formed between the copper and the aluminum. It is not necessary to have a plating layer of, and when the internal volume of the first slot is large, the specific gravity of copper in the rotor conductor can be increased to further improve the characteristics.

Hereinafter, with reference to the accompanying drawings, the rotor of the squirrel cage induction motor according to a preferred embodiment of the present invention will be described in detail as follows.

First, Figures 4a and 4b is a cross-sectional view and a longitudinal cross-sectional view showing a rotor structure of the squirrel cage induction motor according to the present invention, respectively.

The squirrel cage induction motor according to the present invention has a stator (not shown), a rotor which forms a concentric circle with the stator and maintains a predetermined void in the inner circumference of the stator, and is pressed into the center of the rotor to drive the rotational force of the rotor. It consists largely of a shaft to transmit to.

Among these rotors, as illustrated in FIGS. 4A and 4B, the first slot includes a steel plate 110 in which a plurality of first slots 111 and second slots 113 are radially formed at a predetermined interval. And a rotor iron core 100 which is formed by stacking the second slot and the second slot so as to be continuous along the axial direction, and the rotor which is provided in the first slot and the second slot, respectively, and generates torque by current induced from the winding of the stator. Consists of the conductors 120 and 130 and end rings 140 provided to connect the rotor conductors to both ends of the rotor iron core to form a circuit.

As shown in Figure 4a, the steel plate 110 constituting the rotor iron core is an annular silicon steel sheet is formed with an indentation port 115, the shaft 20 is installed in the center, the outer center of the indentation A plurality of first slots 111 are formed radially on the peripheral side, and a plurality of second slots 113 are formed radially on the center side of the first slots. At this time, the first slot 111 and the second slot 113 are separated from each other, one of them is provided with a rotor conductor (hereinafter, copper rotor conductor) consisting of copper on the other side, A rotor conductor (hereinafter referred to as an aluminum rotor conductor) comprising aluminum is provided.

At this time, it is preferable that the copper rotor conductor 120 is provided in the first slot 111 and the aluminum rotor conductor 130 is provided in the second slot 113. As can be seen from the drawing, since the first slot 111 is formed on the outer circumferential side of the steel sheet 110 and its inner volume is larger than that of the second slot 113, copper having a relatively high conductivity is formed in the first slot 111. When inserted into the slot, the characteristics can be further improved. At this time, the second slot 113 may solidify the aluminum melt to form the rotor conductor 130, but greatly contributes to forming end rings provided at both ends of the rotor conductor. That is, in order for the rotor conductors 120 and 130 to form a circuit, the rotor conductors provided in the slots 111 and 113 should be connected to each other through both ends thereof. The end ring is responsible for this role. By the way, the end ring is mainly made of aluminum because copper is impossible to die-cast. Therefore, when the aluminum molten liquid is injected through the second slot 113 and pressurized during the die casting process, the aluminum rotor conductor 130 is formed in the second slot and aluminum end rings are formed at both ends thereof. Can be formed. Therefore, the second slot 113 need not be larger than the number of the first slots 111, and the size of the second slot 113 is also sufficient if the size of the aluminum melt can be injected.

The structure of the rotor as described above is well illustrated in FIG. 4B. As shown in FIG. 4B, the copper rotor conductor 120 provided in the first slot 111 and the aluminum rotor conductor 130 provided in the second slot 113 are mutually supported by the steel plate 110. As a result, a high resistance reaction layer is not formed between the rotor conductors 120 and 130.

However, although a reaction layer is formed between the copper rotor conductor 120 and the aluminum end ring 140, it is sufficient that plating layers 150 are provided at both ends of the copper rotor conductor to remove the reaction layer. At this time, since the plating layer 150 is formed only at both ends of the copper rotor conductor 120 as a nickel coating film, it is not necessary to be formed along the longitudinal direction of the copper rod as shown in FIG. Therefore, the cost due to the plating layer can be substantially reduced.

The rotor of the squirrel cage induction motor configured as described above is manufactured through the following process.

First, the press inlet 115 through which the shaft is press-fitted to the center of the thin silicon steel sheet 110 using a press die and a plurality of first slots 111 formed radially on the outer circumferential side and between the first slot and the press-inlet. Punching a plurality of radially formed second slots 113 is performed.

At this time, not only the mechanical stress such as torsion remains in the steel sheet 110 during the above-mentioned punching step, but also the electrical characteristics of the steel sheet are destroyed. In order to solve this problem, a heat treatment step of applying a heat treatment to the punched steel sheet 110 to remove the mechanical stress and at the same time to restore the electrical characteristics.

Next, the heat-treated steel sheet is aligned so that the first slot 111 and the second slot 113 are continuous along the axial direction, respectively, and then fixed by welding, or fixed by riveting or clamping. A lamination step of manufacturing 100) is performed. At this time, the lamination step may be preceded by the heat treatment step.

Next, after inserting a copper rod into the first slot 111 of the rotor iron core, the rotor iron core 100 is put into a mold and injected with a molten aluminum die casting step is applied to the pressure of the squirrel cage induction motor This completes the rotor. At this time, the aluminum melt is injected through the second slot 113, and as a result, the aluminum rotor conductor 130 is formed in the second slot and the end rings 140 are formed at both ends of the rotor iron core. do.

So far, the present invention has been described with reference to preferred embodiments thereof, and one of ordinary skill in the art to which the present invention pertains may implement the modified embodiment within the essential technical scope of the present invention. Here, the essential technical scope of the present invention is shown in the claims, and the modified forms within the equivalent range will be construed as being included in the present invention.

When the rotor of the squirrel cage induction motor according to the present invention applies copper to the first slot and aluminum to the second slot, respectively, a high resistance reaction layer is formed as the interface between copper and aluminum is partitioned from each other by a steel sheet. It is possible to prevent the source, thereby improving the characteristics of the induction motor by making the most of the characteristics of the copper rotor conductor.

Claims (6)

A steel sheet having a plurality of first slots radially formed at predetermined intervals and a plurality of second slots positioned at a central side of the first slots and formed radially at predetermined intervals; A rotor iron core configured by stacking a plurality of second slots such that the second slots are continuous along the axial direction; A rotor conductor having high conductivity dissimilar metals provided in the first slot and the second slot, respectively, for generating torque by current induced from the winding of the stator; An end ring provided at both ends of the rotor iron core to connect the rotor conductors to each other to form a circuit, the end ring being made of the same component as the rotor conductor provided in the second slot; And, The rotor of the squirrel cage induction motor comprising a separate plating layer: preventing a high resistance reaction layer is formed between both ends of the rotor conductor provided in the first slot and the end ring. The method of claim 1, The rotor conductor provided in the first slot is a rotor of the squirrel cage induction motor, characterized in that the copper. The method of claim 1, Rotor conductor and end ring provided in the second slot is a rotor of the squirrel cage induction motor, characterized in that the aluminum. The method of claim 3, wherein The rotor conductor and the end ring provided in the second slot are formed by aluminum die casting. delete The method of claim 1, The plating layer is a rotor of the squirrel cage induction motor, characterized in that the nickel coating film.