KR100314007B1 - Rotor for disk type motor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotor of a disk-type motor. In the related art, a rotor disk constituting the rotor has a support width for supporting a permanent magnet, so that the size of the rotor disk, i.e., its outer diameter, becomes large, so There is a problem in that the efficiency of the motor is reduced by increasing windage loss or friction loss due to the high speed rotation of the rotor disk, and the present invention not only reduces the size of the rotor disk constituting the rotor. By enhancing the structural strength to prevent the separation of permanent magnets to improve the reliability of the motor and to reduce the wind losses generated during the high-speed rotation of the rotor disk to increase the efficiency of the motor.

Description

ROTOR FOR DISK TYPE MOTOR

The present invention relates to a rotor of a disc-shaped motor, and more particularly, to a rotor of a disc-shaped motor which can enhance structural strength as well as minimizing a loss generated during high speed rotation of a rotor disc into which a permanent magnet is inserted.

In general, a motor converts electrical energy into kinetic energy and outputs power to the outside. The motor may be of various types, and as an example of the motor, a disk type motor (aka Axial-flux type motor) may be a record player, a VCR player, or a CD player. It is applied to low speed rotation and low power, but nowadays it is applied to high speed / low power, such as drum motor (approximately 9000 RPM) for playing digital video camera (Digital vedio camer). Its application is expanding.

1 and 2, a plurality of stator disks 100 formed by inserting a plurality of winding coils 11 into a disk 10 having a predetermined thickness and an outer diameter, as shown in FIGS. It is fixedly coupled to the motor case 200. The plurality of stator disks 100 form a stator S.

The stator disk 100 includes a plurality of rotor disks 300 formed by inserting a plurality of permanent magnets 31 formed in a predetermined shape into the disk 30 having a predetermined thickness and an outer diameter to correspond to the winding coils 11. And alternately positioned between and is fixedly coupled to the motor shaft 400 is inserted into the center thereof. The plurality of rotor disks constitute a rotor (R).

The number of stator disks 100 constituting the stator S and the rotor disks 300 constituting the rotor R is set according to the output of the motor, and the stator disks 100 are respectively located on the outer side. Alternatively, the back yoke 500 is attached to the outer surface of the rotor disk 300 to guide the flow of magnetic flux.

As shown in FIG. 3, the operation of the disk-shaped motor is formed in the permanent magnet 31 coupled to the rotor disk 300 and the current flowing through the winding coil 11 when a current is applied to the winding coil 11. Due to the interaction of the magnetic flux, the rotor disk 300 is rotated under the rotational force. The rotational force of the rotor composed of the rotor disks 300 is transmitted to the motor shaft 400 so that the motor shaft 400 rotates.

On the other hand, as an example of the conventional structure of the rotor disk constituting the rotor, as shown in Figure 4, the disk 30 is made of a plurality of permanent magnets 31 of trapezoidal shape having a predetermined thickness is combined, The permanent magnets 31 are radially coupled to the disk 30 at regular intervals on the same circle. Between the circle (r) made by the outside of the permanent magnets and the rim circle (D) of the disk, that is, the outer diameter is coupled to have a predetermined support width (t), the support width (t) of the rotor disk 300 It is formed to a length having structural strength that can support the centrifugal force of the permanent magnet 31 during rotation.

However, the rotor disk 300 of the conventional disk-type motor as described above has a support width t for supporting the permanent magnet 31, so that the size of the rotor disk 300, i.e., the outer diameter R, becomes larger. Therefore, when the rotor disk 300 rotates at high speed, windage loss or friction loss due to the high speed rotation of the rotor disk 300 increases, thereby degrading the efficiency of the motor.

An object of the present invention devised in view of the above problems is to provide a disk-type motor that can not only minimize the loss generated during high-speed rotation of the rotor disk into which the permanent magnet is inserted, but also enhance the structural strength.

1 is a front cross-sectional view showing a typical disk-type motor,

2 is a perspective view of the disk-shaped motor,

3 is a side view showing the operating principle of the disk-type motor,

4 is a front view of the rotor disk constituting the disk-shaped motor,

5 is a front sectional view showing a disk-shaped motor of the present invention;

6 is a front view of the rotor disk constituting the disk-shaped motor of the present invention.

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

70; Disk 71; Permanent magnet

72; Annular support member 200; Motor case

400; Motor shaft 600; Stator disc

In order to achieve the object of the present invention as described above, a plurality of disks are inserted between the plurality of stator disks coupled to the inside of the motor case at a predetermined interval and coupled to the motor shaft, and the windings are respectively coupled to the stator disks. A plurality of permanent magnets respectively coupled to the permanent magnet indentation grooves formed in the disk so as to face the coil, and coupled to surround the disk's rim so as to be in contact with the outer circumferential surface of the disk and the outer surface of the permanent magnet, thereby permanently rotating the disk. A rotor of a disc-shaped motor is provided, comprising an annular support member for reinforcing and supporting a centrifugal force of a magnet.

Hereinafter, the rotor of the disc-shaped motor of the present invention will be described according to the embodiment shown in the accompanying drawings.

Figure 5 shows a disk-type motor with a rotor of the present invention, as shown in the disk-type motor, stator disk 600 is coupled to a plurality of winding coils 61 therein motor case 200 Are combined at regular intervals. And the rotor disk 700 is inserted between the stator disk 600, the rotor disk 700 is fixedly coupled to the motor shaft 400 is inserted in the middle. In the stator disk 600, a plurality of winding coils 61 are inserted at predetermined intervals into a disk 60 having a predetermined thickness and area.

The rotor disk 700, as shown in Figure 6, the disk 70 having a predetermined thickness and area, and the disk 70 to correspond to the winding coil 61 coupled to the stator disk 600 A plurality of permanent magnets 71 coupled to the inside and the annular support member 72 is inserted to surround the rim of the disk 70 to reinforce and support the centrifugal force of the permanent magnet 71 when the disk 70 rotates. It is configured to include.

The magnet 70 is coupled to the motor shaft 400 is inserted into the center of the disk 70 is fixed to the shaft coupling hole (70a) and the permanent magnet 71 is coupled at a predetermined interval on the concentric circle inside the disk (70) The coupling hole 70b is formed. The magnet coupling hole 70b is formed to correspond to the winding coil 61 of the stator disk 600. The motor shaft 200 is inserted into and fixed to the shaft coupling hole 70a, and the permanent magnet 71 is inserted and fixed into the magnet coupling hole 70b.

The annular support member 72 is formed in a ring shape having a predetermined thickness and width, and an inner diameter thereof corresponds to an outer diameter of the disk 70. In addition, the annular support member 72 may be formed of a material having a stronger strength than that of the disk 70. For example, the annular support member 72 may be formed of aluminum, and the annular support member 72 may be formed of titanium. .

The permanent magnet 71 inserted into the disk 70 is preferably coupled to contact the inner circumferential surface of the annular support member 72 so that the size of the disk 70 is minimized. That is, the magnet coupling hole 70b is formed to contact the outer circumferential surface of the disk 70, and the permanent magnet 71 is fixedly fixed to the magnet coupling hole 70b.

The number of the stator disk 600 and the rotor disk 700 is determined by the required output, the plurality of stator disk 600 constitutes the stator (S), the plurality of rotor disk 700 The rotor R is constituted.

Hereinafter, the operational effects of the disk-type motor rotor of the present invention will be described.

First, the operation of the disk-type motor is the rotor by the interaction of the current flowing in the winding coil 61 and the magnetic flux formed in the permanent magnet 71 coupled to the rotor disk 700 when a current is applied to the winding coil 61 The disk 700 is rotated under the rotational force. The rotational force of the rotor R composed of the rotor disks 700 is transmitted to the motor shaft 400 so that the motor shaft 400 rotates.

The rotor disk 700 is smaller in size than the conventional rotor disk 300 because the support width (t) portion of the disk for supporting the permanent magnet is excluded and replaced by the annular support member 72. That is, the conventional rotor disk 300 is supported so that the permanent magnet is fixedly coupled in the same circle in the disk 30 and the centrifugal force of the permanent magnet 31 when the rotor disk 300 rotates following the permanent magnet 31. Since the width (t) of the rotor disk 300 increases in size, the rotor disk 700 of the present invention has the permanent magnet 71 fixedly coupled to the same circle in the disk 70 and the permanent magnet 71. Since the annular support member 72 having a stronger material than the disk 70 is coupled to the edge of the disk 70, the size of the rotor disk 700 is reduced. Due to the reduction in the size of the rotor disk 700, the windage loss or friction loss generated in the rotor disk 700 during the high speed rotation of the rotor disk 700 is reduced.

In addition, the present invention is to combine the annular support member 72 having a stronger material than the disk 70 to the disk 70, the permanent magnet 71 is coupled to the disk 70 and the material during the rotation of the rotor disk 700 The other permanent magnets 71 support the centrifugal force more effectively, thereby enhancing the structural strength.

As described above, the rotor of the disk-type motor according to the present invention not only reduces the size of the rotor disk constituting the rotor, but also enhances structural strength to prevent detachment of permanent magnets, thereby improving the reliability of the motor and By reducing windage or friction loss generated at high speed of rotation of the disk, there is an effect of increasing the efficiency of the motor.

Claims (2)

Magnetic coupling holes formed in the disc to face each of the plurality of discs coupled to the motor shaft and coupled to the motor shaft and the winding coils respectively coupled to the stator discs. A plurality of permanent magnets coupled to each other, and an annular support member coupled to enclose the rim of the disk so as to contact the outer circumferential surface of the disk and the outer surface of the permanent magnet so as to reinforce and support the centrifugal force of the permanent magnet during rotation of the disk. Rotor of the disc-shaped motor, characterized in that the configuration. The rotor of claim 1, wherein the disk is made of aluminum and the annular support member is made of titanium.