KR100346276B1 - Combination structure of bearing in vibration motor - Google Patents

Abstract

PURPOSE: A combination structure of a bearing in a vibration motor is provided to combine firmly the metal bearing for supporting a rotary shaft by improving the combination structure of the metal bearing. CONSTITUTION: An outer case(1) has a cylindrical shape. An inner case(2) has the cylindrical shape. The outer case(1) and the inner case(2) of cylindrical shape are formed with one body. An inner end portion inserted into the inner case(2) is connected to a shaft portion of a rotor(4). A vibration weight(31) is combined with a rotary shaft(3). A bearing loading portion(2c) is formed on an outer end portion of the inner case(2). An outer end bearing(55) is inserted into the bearing loading portion(2c). A plurality of grooves(2d) are formed on an end portion of the inside of the inner case(2). An inner end bearing(56) has a projection(56a). The projection(56a) of the inner end bearing(56) is combined with the projection(56a). A ring-shaped rim portion is formed on an outer circumference of the projection(56a). In addition, the ring-shaped rim portion is formed on an inner circumference of the projection(56a).

Description

Bearing coupling structure of vibration motor

The present invention relates to a vibration motor for use in a mobile phone, and more specifically, to a coupling structure of a metal bearing supporting a rotating shaft of the vibration motor.

Figure 1 is a small-type motor of the cylindrical type of vibration motor for use in a mobile phone, etc. The configuration of the cylindrical outer case (1), and after forming the cylindrical inner case (2) extending or newly joined from the outer case The metal bearings 51 and 52 are coupled to the inner ends of the inner end portions 21 and the inner ends 22 of the inner case 2, respectively, and the rotary shaft 3 is connected to the inner diameters of the metal bearings 51 and 52. And a rotor 4 including a coil 41 and a brush structure 6 provided on one side of the rotor at an inner end of the rotary shaft 3.

However, since the conventional vibration motor has a cylindrical outer case 1 having a diameter of only a few mm, the metal bearings 51 and 52 are inserted into the inner diameter of the cylindrical inner case 2, and the metal bearing 51. In order to refit the rotating shaft 3 to the inner diameter of the 52, the diameters of the rotating shaft 3, the metal bearings 51 and 52, the inner case 2, etc. are small and thin. There is a frequent, short lifespan problem.

On the other hand, there is an improved cylindrical vibration motor as shown in Figure 2 to compensate for the problems with the conventional motor as described above.

This does not insert the beary into the inner diameter of the inner case 2, but forms the bearing seat 23 with the tip portion larger than the inner diameter of the inner case 2 to fit the bearing 53, and the inner end portion with the inner case. The bearing 54 is fitted to the outer diameter of (2) to support the rotating shaft (3).

However, in this improved cylindrical vibration motor, the assembly is dependent on the frictional force between the outer diameter of the inner case 2 and the inner diameter of the extension portion 54a of the bearing, so that the bearing on the inner end side cannot be firmly fixed. As a result, the fastening force is weak and the fastening force is weak, so that the bearing to be fixed rotates little by little along the axis of rotation.

Therefore, the present invention has been made to solve the above-mentioned conventional problems, the main object of the invention is to improve the fastening force of the motor by improving the structure to be more firmly coupled to the metal bearing supporting the rotating shaft, It is to go further and increase the reliability of the product.

1 is a cross-sectional view showing a conventional vibration motor,

Figure 2 is a cross-sectional view showing another conventional vibration motor,

3 is a cross-sectional view showing a vibration motor of the present invention,

4 is an enlarged cross-sectional view of the main portion of the present invention;

5a to 5e are sectional views of main parts of still another embodiment of the present invention;

6 is a perspective view of main parts of the embodiment according to FIG. 5C;

Explanation of symbols for main parts of the drawings

1: outer case 2: inner case

3: rotating shaft 4: rotor

6: brush structure 2a: magnet

2c: Seating part 2d: Uneven groove

31: vibrating weight 41: coil

42: coupling portion 43: extension shaft

55: outer end bearing 56: inner end bearing

56a: projection 56b, 56c: phantom

A characteristic means of the present invention for achieving the above object is a cylindrical outer case, a cylindrical inner case formed integrally with the cylindrical outer case, and a rotor having a brush structure at the inner end fitted into the inner case. In the vibration motor is connected to the shaft portion of the vibration motor consisting of a rotating shaft coupled to the end of the outer end is exposed to the outside, the outer end of the inner case to form a bearing seating portion to fit the outer end bearing, the inner case The inner end of the concave and convex groove is formed, and the metal bearing to be fitted therein is to form a projection on the inner end to be coupled by these concave groove and the projection.

Hereinafter, the configuration of the present invention will be described in more detail according to the preferred embodiments represented in the accompanying drawings.

Figure 3 is a cross-sectional view of a vibration motor according to an embodiment of the present invention can see a cylindrical outer case 1, and a cylindrical inner case 2 located inside the cylindrical case, the inner and outer cylindrical at this time The cases 2 and 1 may be separately molded and joined, or may be integrally molded at a time, and are represented as an integral part in the drawings of the present invention.

A magnet 2a is inserted into and fixed to an outer diameter of the inner case 2, and a rotating shaft 3 is inserted into the center of the rotating shaft 3, at which a vibrating weight 31 is coupled to an outer end thereof. The end is fixedly connected to the center of the rotor 4.

In addition, the rotor 4 is composed of a coupling portion 42 and a coil 41 wound in a cylindrical shape at the coupling portion, and the brush structure 6 is coupled to the extension shaft 43 of the coupling portion 42. The coil 41 can rotate between the magnet 2a of the cylindrical inner case 2 and the cylindrical outer case 1.

In particular, the rotation shaft 3 is supported by a bearing at the center of the inner case 2, but a seating portion 2c is formed at the outer end of the inner case 2 to insert and fix the outer end bearing 55. The inner end portion 56 of the inner case 2 is fixed to the inner end bearing 56, and as shown in FIG. 5A, the protrusion 56a is formed at the end of the inner case 2, and the fitting An uneven groove 2d is formed in the cross section of the inner end bearing 56 so that the protrusion 56a can be pushed therein.

At this time, the protrusions 56a and the uneven grooves 2d are preferably formed in a plurality of two or more, respectively, as shown in Figure 5b to strengthen the fastening force.

In addition, the protrusion 56a and the uneven groove 2d may be coupled to each other by forming a depth direction in a semicircular shape as shown in FIG. 5C.

5d is a configuration of another embodiment of the present invention, which is different from the previous embodiment, except that the protrusion 56a is formed at the end of the inner end bearing 56, and the annular guide portion 5b for engaging the outward of the protrusion is formed. ) Is characteristic.

5E is a configuration of another embodiment of the present invention, which is different from the previous embodiment, except that the protrusion 56a is formed at the end of the inner end bearing 56, and the annular guide portion 56c for coupling guided inside the protrusion is formed. ) Is characteristic.

In the present invention configured as described above, the inner and outer bearings 56 and 55 support the rotating shaft 3 inserted into the inner case 2, but the outer end bearing 55 is fitted to the seating portion 2c. And the inner end is supported by the new inner end bearing 56 of the present invention, thereby causing normal rotation, and thus vibration is generated by the vibration weight 31 coupled to the end of the rotating shaft 3. .

In the present invention as described in detail above, because the protrusion 56a of the inner end bearing 56 is coupled to the uneven groove 2d of the inner case 2 by forcibly fitting, the fastening force is excellent, It can be easily inserted into the inner case 2 by using the annular groove 56b, so that the productivity is improved. In particular, since the inner end bearing 56 does not rotate along the rotation shaft 3, there is no fear of failure and a long service life. You lose.

Claims (3)

A cylindrical outer case 1, a cylindrical inner case 2 integrally formed with the cylindrical outer case 1, and an inner end fitted into the inner case 2, the rotor 4 having a brush structure. In the vibration motor connected to the shaft portion of the rotation shaft consisting of a rotating shaft (3) coupled to the outer end exposed to the outside, At the outer end of the inner case 2, a bearing seating portion 2c is formed to fit the outer end bearing 55, A plurality of uneven grooves 2d are formed at the inner end of the inner case 2, and the inner end bearing 56 to be fitted therein has a protrusion 56a formed therein so that these uneven grooves 2d and the protrusions ( 56a) is coupled to the bearing structure of the vibration motor, characterized in that it is to be coupled by. The method of claim 1, The inner end bearing (56) is a bearing coupling structure of a vibration motor, characterized in that to form a coupling guide annulus portion (56b) on the outer periphery of the projection (56a). The method of claim 1, The inner end bearing (56) is a bearing coupling structure of a vibration motor, characterized in that to form an annular guide ring portion (56c) for engaging the inner periphery of the projection (56a).

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