KR100538686B1 - Vibration Generator - Google Patents

Abstract

The present invention relates to a vibration motor that can reduce the size of the product to be mounted by reducing the length of the vibration motor.

In the vibration motor according to the present invention is provided with a magnet and a coil coupled to the rotating shaft on the outside of the housing, the vibration motor for generating vibration during rotation by the eccentric mass coupled to the rotating shaft to the outside of the housing, The length of the rotating shaft has a length accommodated inside the housing, has a predetermined height and width on one side of the outer circumference of the coil, and attaches an eccentric mass having an arc cross section using an adhesive, an adhesive tape or a shrink tube.

Description

Vibration Motor

The present invention relates to a vibration motor for generating vibration by embedding a mobile phone, a pager, and other products, and more particularly, to a vibration motor that can reduce the size of the mounted product by reducing the length of the vibration motor.

In general, mobile phones, pagers, and other products use vibration as one means of informing a user of a signal.

In a conventional method of generating vibration, an eccentric mass is attached to a rotating shaft of the motor to rotate the motor to generate vibration.

Looking at the configuration of a conventional vibration motor, as shown in Figures 1 and 2 to fix the yoke (53) using a bracket 52 in the interior of the housing 51, the magnet 56 on the outside of the yoke (53) Combine. The rotor assembly, in which the cylindrical coil 58 is coupled to the rotary shaft 59 by using the mold 60, the rotary shaft 59 is inserted into the yoke 53, and the coil 58 is disposed outside the magnet 56. Position it.

The upper part of the mold 60 is fixed to the segment 61 bent in the middle, and the segment 61 and the brush 64 connected to the power supply terminal of the base brush 65 are brought into contact with each other, so that external power is supplied to the coil ( 58).

When a current is applied to the vibration motor, the coil 58 is magnetized to rotate the rotor assembly. At this time, vibration is generated by the eccentric mass 63 coupled to the lower end of the rotation shaft 59.

However, in the conventional vibration motor as described above, since the eccentric mass 63 is exposed to the outside, there is a limit in reducing the length of the vibration motor.

In addition, the rotating eccentric mass 63 is exposed to the outside, and sometimes there is a problem that the rotation is not caused by another member, which causes a defect.

In addition, since the contact of the brush 64 and the segment 61 on the upper part of the vibration motor is perpendicular, this also has a limit in reducing the length of the vibration motor.

The present invention is to solve the above problems, an object of the present invention is to provide a vibration motor that can reduce the size of the vibration motor by reducing the length of the vibration motor.

In order to achieve the above object, the vibration motor of the present invention includes a magnet inside the housing and a coil coupled to a rotating shaft on the outside of the magnet, and rotates by an eccentric mass coupled to the rotating shaft to the outside of the housing. In the vibration motor for generating a vibration, the length of the rotating shaft has a length accommodated in the housing, has a predetermined height and width on the outer peripheral side of the coil, characterized in that the eccentric mass having an arc-shaped cross section is attached. do.

The eccentric mass is attached to the coil using an adhesive.

The eccentric mass may also be attached to the coil using adhesive tape.

In addition, the eccentric mass is characterized in that it is attached to the coil using a shrink tube that contracts when heat is applied.

Hereinafter, the vibration motor of the present invention will be described with reference to the accompanying drawings.

The housing 1 is formed in a cylindrical shape using a thin plate material. The other components of the vibration motor of the present invention are accommodated in the housing 1.

The bracket 2 is coupled to the lower portion of the housing 1. The outer periphery of the bracket 2 is formed with a jaw whose outer diameter matches the inner diameter of the housing 1 along the circumference and the bracket 2 and the housing 1 are coupled.

In the center of the bracket (2) the yoke (3) is located perpendicular to the bracket (2). A magnet 6 having magnetic properties is attached to the outer circumference of the yoke 3, and the yoke 3 is coupled to the center of the bracket 2 using the lower metal 4 and the upper metal 5.

The rotor assembly (Fig. 5) is accommodated in a space formed by the inner wall of the housing 1 and the magnet 6.

The rotor assembly comprises a coil 8, a rotating shaft 9, a segment 11, a PCB 12 and an eccentric mass 13.

The coil 8 is formed in a cylindrical shape as in a conventional vibration motor.

The rotating shaft 9 is coupled to the coil 8 using the mold 10. The rotating shaft 9 of the present invention allows the length to be received inside the housing 1 without protruding outward from the housing 1.

The PCB 12 and the segment 11 are coupled to the upper surface of the mold 10. The segment 11 and the PCB 12 are connected to the coil 8 so that current drawn into the segment 11 flows through the PCB 12 to the coil 8.

On the other hand, on one side of the outer circumference of the coil 8, an eccentric mass 13 having a predetermined height and width and having an arc cross section is attached. The eccentric mass 13 has a curvature substantially equal to the curvature of the outer side of the coil 8, and consists of a plate-shaped member of a material with a high specific gravity, such as a metal. At this time, the eccentric mass 13 does not surround all of the outer circumference, but only surrounds a part of the outer circumference.

The rotor assembly is fitted to the yoke 3 and the magnet 6. The rotating shaft 9 of the rotor assembly is inserted into the yoke 3 and the coil 8 is located outside the magnet 6. At this time, the eccentric mass 13 attached to the outer side of the coil 8 is located in the space formed by the inner wall of the housing 1 and the coil 8.

Here, the method of attaching the eccentric mass 13 to the outside of the coil 8 may be various, but may be attached using an adhesive, an adhesive tape and a shrink tube, or may be integrally injected.

When attaching the eccentric mass 13 to the coil 8, an adhesive is applied on the outside of the coil 8 and the eccentric mass 13 is attached using the applied adhesive, or the eccentric mass on the outside of the coil 8 The eccentric mass 13 may be attached to the outer side of the coil 8 by positioning (13) and surrounding the outer side of the coil 8 and the eccentric mass 13 with an adhesive tape. In addition, by using a shrinking tube that contracts when heat is applied, the eccentric mass 13 is placed outside the coil 8 and surrounded by the shrink tube so as to surround the coil 8 and the eccentric mass 13, and then heat is applied. An eccentric mass may be attached to the coil 8.

A brush 14 and a base brush 15 are provided on an upper portion of the rotor assembly.

Brush 14 for supplying current to the segment 11 is formed as 'b', the lower portion is to be curved to facilitate contact with the segment 11, any part of the lower portion by its elasticity Always in contact with

The uppermost part of the housing 1 is sealed using the base brush 15. A base brush 15 having a power terminal configured to supply the current supplied from the outside to the coil 8 of the vibration motor of the present invention is coupled to the upper end of the housing 1. One end of the brush 14 is coupled to the lower portion of the base brush 15 so as to be connected to the power terminal.

By combining the vibration motor made as described above with an appropriate position in the device, for example, a mobile phone, a signal is generated to the user.

The operation of the vibration motor of the present invention having the configuration as described above is as follows.

When it is necessary to generate a vibration signal in the device to which the vibration motor of the present invention is applied, the control unit (not shown) applies power to the power terminal of the base brush 15. The current drawn into the power supply terminal of the base brush 15 is transmitted to the segment 11 through the brush 14 and then to the coil 8 through the PCB 12. When a current is applied to the coil 8, the coil 8 becomes magnetized and the rotor assembly starts to rotate.

When the rotor assembly rotates, vibration is generated by the eccentric mass 13 attached to the outside. Since only the outer portion of the coil 8 of the eccentric mass 13 is attached, the rotational center and the center of mass are eccentric when the rotor assembly is rotated, so that vibration occurs.

The vibration generated by the rotation of the rotor assembly is transmitted to the whole of the device to inform the user that a signal has been received.

Vibration motor of the present invention having the configuration and action as described above can be expected the following effects.

The eccentric mass is not coupled to the outside of the vibration motor, but is accommodated in an empty space inside, thereby reducing the overall length of the vibration motor and further miniaturizing the vibration motor. By miniaturizing the vibration motor, the apparatus to which the vibration motor is applied can also be miniaturized.

In addition, when the eccentric mass is incorporated in the vibration motor and the eccentric mass is rotated from the outside, the probability that the rotation of the eccentric mass is inhibited by other members is reduced.

In addition, by making the brush and the segment in parallel contact, it is possible to improve the efficiency of the vibration motor by preventing a poor contact between the brush and the segment.

1 is an exploded perspective view of a vibration motor of the prior art.

Figure 2 is a side cross-sectional view of a vibration motor of the prior art.

Figure 3 is an exploded perspective view of the vibration motor according to the present invention.

Figure 4 is a side cross-sectional view of a vibration motor according to the present invention.

5 is a perspective view of the rotor assembly of the vibration motor according to the present invention.

Figure 6 is a perspective view of the rotor assembly according to another embodiment of the vibration motor according to the present invention.

Figure 7 is a perspective view of the rotor assembly according to another embodiment of the vibration motor according to the present invention.

※ Explanation of main code of drawing ※

1 housing 2 bracket 3 yoke

4: lower metal 5: upper metal 6: magnet

7 washer 8 coil 9 rotating shaft

10 Mold 11: Segment 12: PCB

13: eccentric mass 14: brush 15: base brush

21: adhesive tape 22: shrink tube 51: housing

52: bracket 53: yoke 54: lower metal

55: upper metal 56: magnet 57: washer

58: coil 59: rotating shaft 60: mold

61 segment 63 eccentric mass 64 brush

65: Base Brush

Claims (4)

A magnet (6) and a coil (8) coupled to the rotating shaft (9) outside the magnet (6) are provided inside the housing (1), and coupled to the rotating shaft (9) outside of the housing (1). In a vibration motor that generates vibration during rotation by the eccentric mass, A rotor assembly including a coil 8, a rotating shaft 9, a segment 11, a PCB 12, and an eccentric mass 13 is formed in a space formed by the inner wall of the housing 1 and the magnet 6. Accepted, The length of the rotating shaft (9) has a length that is accommodated inside the housing (1), On the outer circumferential side of the coil 8, the eccentric mass 13 having a predetermined height and width and having an arc cross section is attached, Brush 14 for supplying current to the segment 11 is formed in a 'b' shape, but the lower portion is a vibration motor, characterized in that formed to be curved. delete delete delete