KR101506556B1 - Linear Motor - Google Patents

Abstract

According to the present invention, there is provided a linear vibration motor, wherein the linear vibration motor includes a fixed portion having an inner space formed therein and a magnet, and a coil positioned to face the magnet, wherein the vibrating portion is accommodated in the inner space of the fixed portion An elastic member connecting the stator portion and the vibrator portion and a damping member provided on one surface of the stator portion or the vibrator portion facing the elastic member to mitigate metallic high frequency coupling due to friction, Thereby increasing the degree of freedom of design through the linear vibration motor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a linear vibration motor.

A general vibration motor is a component that converts electric energy into mechanical vibration using the principle of generating an electromagnetic force. The vibration motor is mounted on a mobile communication terminal, a portable terminal, or the like, and is used for silent incoming notification.

In addition, as the market for wireless communications and mobile phones is rapidly expanding, mobile communication terminals with various functions are becoming more and more demanded, so that miniaturization and quality improvement of mobile communication terminals are required. And the performance and technology are being developed every day in order to improve the quality and improve the quality remarkably.

In addition, in recent years, with the rapid increase in the launch of mobile phones with large LCD screens, the adoption of the touch screen method has increased the demand for vibration caused by touch.

Particularly, the performance required for the vibration due to the touch of the touch screen is that the operating life time must be increased as the number of times of use is increased as compared with the vibration occurring at the time of first reception, and the response speed of the vibration So that the user can feel the vibration when touching.

The linear vibration motor, which is a vibration motor capable of satisfying the above characteristics, has a resonance frequency determined by a spring and a vibrator portion to be connected to the spring, and is excited by an electromagnetic force to generate vibration. And the electromagnetic force is generated by an interaction between a magnet of the vibrator and a current having a constant frequency applied to the coil of the stator.

In the linear vibration motor constructed as described above, touching occurs due to collision with the case or the bracket while the vibrator moves up and down. In order to prevent this, the MF is applied to form a ring-shaped band or a damping material ).

However, when MF is used, since it is made of liquid, it is scattered around in case of an excessive impact and is separated from its position due to the excessive shock, so that the damping function is weakened and the damping occurs in the vibration operation, and the damping material of rubber, So that it is not only easy to arrange it in a limited space but also has a problem that the degree of freedom of design is lowered.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems of the prior art, and it is an object of the present invention to provide a damping member, which is disposed between an elastic member and a weight body or between a resilient member and a case space, Which can not only mitigate the metallic high frequency coupling due to friction of the motor, but also increase the degree of design freedom through space utilization.

A linear vibration motor according to a first embodiment of the present invention includes a fixed portion formed with an inner space and having a magnet mounted thereon and a coil positioned to face the magnet, And a damping member disposed on one surface of the fixed member and positioned to face the elastic member, wherein at least a portion of the elastic member is disposed between the damping member and the vibration member, And is disposed between the engaging portions.
The stator includes a case having an inner space formed therein for accommodating the vibrator and a lower portion thereof opened, and a bracket for sealing the inner space of the case, and the damping member is installed on one side of the case opposite to the elastic member .
The magnet is mounted on one or both of the case and the bracket.
A seating part is formed on one or both of the case and the bracket on which the magnet is mounted.
A plate yoke is coupled to one surface of the magnet.
The coil is formed in a hollow shape so that the magnet can pass through the coil.
The vibrator unit further includes a weight moving together with the coil.
The weight is provided with a yoke, one end of the elastic member is coupled to the stator, and the other end is coupled to the yoke.
One end of the elastic member is coupled to the stator, and the other end is coupled to the coil.
And a printed circuit board having one end coupled to the coil and the other end coupled to the stator.
The printed circuit board includes an engaging plate fixed to the stator, an elastic part extending from the engaging plate and extending in a spiral direction so as to have an elastic force, and an elastic part provided at an end of the elastic part, And a contact portion for applying power.
The magnet includes a first magnet coupled to one surface of the bracket and a second magnet opposed to the first magnet and coupled to one surface of the case.
And a plate yoke coupled to one surface of the first magnet or one surface of the second magnet.
According to another aspect of the present invention, there is provided a linear vibration motor comprising: a stationary portion having an inner space formed therein and having a magnet; a coil positioned to face the magnet; and a weight moving together with the coil, And a damping member disposed on one surface of the vibrating portion and positioned to face the elastic member, wherein at least one of the damping member And a part thereof is disposed between the elastic member and the vibrator portion.
And the damping member is installed on one side of the weight body.
According to another aspect of the present invention, there is provided a linear vibration motor comprising: a stationary portion having an internal space formed therein and having a coil; and a magnet positioned to face the coil, And a damping member disposed on one surface of the fixed member and positioned to face the elastic member, wherein at least a portion of the elastic member is disposed between the damping member and the vibration member, And is disposed between the engaging portions.
The stator includes a case having an inner space formed therein for accommodating the vibrator unit and a lower portion thereof, and a bracket for sealing the inner space of the case.
And a printed circuit board is coupled to the coil.
The yoke is coupled to the magnet.
One end of the elastic member is coupled to the stator, and the other end is coupled to the yoke.

According to the present invention, the damping member is disposed between the elastic member and the weight member or between the elastic member and the case space to mitigate the metallic high-frequency coupling due to friction between the elastic member and the weight member or between the elastic member and the case, There is an effect of providing a linear vibration motor capable of increasing the degree of freedom of design.

1 is a schematic cross-sectional view of a linear vibration motor according to a first embodiment of the present invention;
Fig. 2 is a schematic exploded perspective view of the linear vibration motor shown in Fig. 1. Fig.
3 is a schematic sectional view of a linear vibration motor according to a second embodiment of the present invention;
4 is a schematic cross-sectional view of a linear vibration motor according to a third embodiment of the present invention;
5 is a schematic cross-sectional view of a linear vibration motor according to a fourth embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The objects, particular advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. Also, the terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic cross-sectional view of a linear vibration motor according to a first embodiment of the present invention, and FIG. 2 is a schematic exploded perspective view of the linear vibration motor shown in FIG. The linear vibration motor 100 includes a stator 110, a vibrator unit 120 and an elastic member 125 connecting the stator unit and the vibrator unit. The stator unit 110 includes a magnet 111b and a case yoke 114. The vibrator unit 120 includes a coil 121, a weight 122, a printed circuit board 123, Member 124, and a circular yoke 126. [

More specifically, the case 112, which is the stator part 110, is formed with an inner space to cover the vibrator part, and is coupled to the bracket 113. The bracket 113 is fixedly coupled to the printed circuit board 123. The magnets 111a and 111b may include a first magnet 111a coupled to an inner upper surface of the bracket 113 facing the weight and a second magnet 111a coupled to an inner upper surface of the case And a second magnet 111b. The first magnet 111a and the second magnet 111b preferably have the same polarities to face each other to increase magnetic efficiency. That is, the first magnet 111a is composed of S poles 111a 'and N poles 111a' which are two different poles, and the second magnet 111b is composed of S poles 111b 'and N poles (111b "), and the N pole 111a" and the N pole 111b "are opposed to each other.

The case 112 and the bracket 113 are respectively formed with seating portions 112a and 113a for coupling the magnets 111a and 111b to the center thereof.

The plate yoke 114 is selectively coupled to an upper portion of the first magnet 111a or a lower portion of the second magnet 111b.

The coil 121 as the vibrator 120 is positioned to face the magnets 111a and 111b and the weight 122 is coupled to the coil 121. The printed circuit board 123 has a Is coupled to the coil 121, and the other end is coupled to the bracket 113. One end of the elastic member 125 is coupled to the case 112 and the other end is coupled to the coil 121. The damping member 124 is positioned on the upper surface of the weight 122 opposite to the elastic member 125.
That is, at least a part of the damping member 124 is disposed between the elastic member 125 and the vibrator portion.

The printed circuit board 123 includes an engaging plate 123a fixed to and coupled to the bracket, an elastic portion 123b extending from the engaging plate 123a and extending in a helical direction so as to have an elastic force, And a contact portion 123c provided at an end of the elastic portion 123b and coupled to the coil for applying external power.

A fixing groove 123d for fixing the bracket 113 to the fixing plate 123a of the printed circuit board 123 is formed in the fixing plate 123a. (113b) are formed. The contact portion 123c of the printed circuit board is preferably formed in a disk shape so as to correspond to the shape and size of the coil to be contacted. That is, the printed circuit board 123 is formed so as to surround at least a part of the outer circumferential surface of the magnet so as not to make contact with the magnet when the vibrator vibrates.

 The printed circuit board 123 extends in the spiral direction and surrounds the first magnet 111a to be coupled with the coil 121. As a result, 120 are elastically supported at the bottom. To this end, the printed circuit board 123 preferably has a spring shape or a coil spring shape extending in a spiral direction.

 The circular yoke 126 is coupled between the coil 121 and the weight 122 to increase the magnetic flux of the magnet. In addition, the circular yoke 126 may be coupled to the upper portion of the weight 122 and may be engaged with the hollow portion 122a of the weight.

The elastic member 125 is coupled to the coil 121 and the weight 122 through the circular yoke 126.

The weight 122 is formed with a hollow portion 122a and the circular yoke 126 and the coil 121 are accommodated in the hollow portion and the magnets 111a and 111b and the plate yoke (114) to be in linear motion.

The elastic member 125 and the circular yoke 126 are wound around the hollow portions 125a, 126a, and 121a so as to linearly move the magnets 111a and 111b and the plate yoke 114, Is formed.

In addition, the damping member according to the present invention can improve the characteristics of the motor through correction of the elastic modulus of the elastic member as a fixing member having a constant damping coefficient.

In addition, the printed circuit board 123 according to the present invention is preferably made of an elastic FPC.

When the external power is supplied to the coil 121 through the printed circuit board 123, the vibrator unit is linearly vibrated by the electromagnetic force of the coil and the first and second magnets 111a and 111b. At this time, when the displacement of the vibrator portion 120 is increased, the friction due to the contact between the elastic member 125 and the weight 122 is blocked by the damping member 124, so that the metallic high- Not only can it be mitigated, but also the freedom of design through space utilization can be increased.

3 is a schematic cross-sectional view of a linear vibration motor according to a second embodiment of the present invention. The linear vibration motor 200 includes a stator 210, a vibrator unit 220 and an elastic member 225 connecting the stator unit and the vibrator unit. The stator unit 210 includes a magnet And a plate yoke 214. The vibrator unit 220 includes a coil 221, a weight 222, a printed circuit board 223, A damping member 224 and a circular yoke 226. The same reference numerals as in the linear vibration motor 100 of the first embodiment shown in Fig. 2 denote the same technical constructions and are implemented such that only the mounting position of the damping member 224 is different. That is, the damping member 224 is provided on one surface of the stator portion facing the elastic member, and at least a part of the elastic member is disposed between the damping member and the vibrator portion.

More specifically, the damping member 224 is coupled to the lower surface of the case 212 facing the elastic member 225. In this way, when the vibrator portion 220 is vibrated, not only the metallic high-frequency coupling due to the friction between the elastic member 125 and the case 212 can be alleviated, but also the degree of freedom of design through space utilization is increased .

When external power is supplied to the coil 221 through the printed circuit board 223, the vibrator portion is linearly vibrated by the electromagnetic force of the coil and the first and second magnets 211a and 211b. At this time, when the displacement of the vibrator portion 220 is increased, the friction due to the contact between the elastic member 225 and the case 212 is blocked by the damping member 224, so that the metallic high- Not only can it be possible to increase the degree of freedom of design through space utilization.

4 is a schematic cross-sectional view of a linear vibration motor according to a third embodiment of the present invention. The linear vibration motor 300 includes a stator 310 and a vibrator 320. The stator includes a coil 311 and a printed circuit board 312 coupled to the coil 311 A bracket 313 to which the printed circuit board is fixed and a case 314 having an internal space formed to cover the vibrator and coupled to the bracket 313.

The vibrator 320 includes a magnet 321 positioned to face the coil 311, a yoke 323 coupled to the magnet 321, a weight 323 coupled to the outer surface of the yoke 323, And a damping member 324 coupled to an upper surface of the weight 322 opposite to the elastic member 325. The damping member 324 is coupled to the stator 322 at one end thereof, Respectively.

When external power is supplied to the coil 311 through the printed circuit board 312, the vibrator 320 is linearly vibrated by the electromagnetic force of the coil 311 and the magnet 321 . At this time, when the displacement of the vibrator 320 is increased, the friction due to the contact between the elastic member 325 and the weight 322 is blocked by the damping member 324, so that the metallic high- Not only can it be mitigated, but also the freedom of design through space utilization can be increased.

5 is a schematic cross-sectional view of a linear vibration motor according to a fourth embodiment of the present invention. The linear vibration motor 400 according to the fourth embodiment of the present invention includes a stator section 410 and a vibrator section 420. The stator section includes a coil 411, A case 414 having an inner space formed to cover the vibrator and coupled to the bracket 413, and a case 414 coupled to the bracket 413. The case 414 is connected to the bracket 413, And a damping member 424 coupled to the lower portion of the case.
That is, the damping member 424 is provided on one surface of the stator portion facing the elastic member, and at least a part of the elastic member is disposed between the damping member and the vibrator portion.

The vibrator 420 includes a magnet 421 positioned to face the coil 411, a yoke 423 coupled to the magnet 421, a weight 423 coupled to the outer surface of the yoke 423, 422), an elastic member (425) having one end coupled to the stator portion and the other end coupled to the yoke.

When the external power is supplied to the coil 411 through the printed circuit board 412, the vibrator 420 is linearly vibrated by the electromagnetic force of the coil 411 and the magnet 421 . At this time, when the displacement of the vibrator 420 is increased, friction due to contact between the elastic member 425 and the case 414 is blocked by the damping member 424, thereby alleviating the metallic high frequency coupling due to friction Not only can it be possible to increase the degree of freedom of design through space utilization.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the same is by way of illustration and example only and is not to be construed as limiting the present invention. It will be apparent that modifications and improvements can be made by those skilled in the art.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Linear vibration motor 110:
111a, 111b: Magnet 113: Bracket
114: Plate yoke 120: Oscillator
121: coil 112: case
122: Weight
123: printed circuit board 124: damping member
125: elastic member 126: circular yoke
200: Linear vibration motor 210:
211a, 211b: Magnet 213: Bracket
214: Plate yoke 220: Oscillator
221: coil 212: case
222: Weight
223: printed circuit board 224: damping member
225: elastic member 226: circular yoke

Claims (20)

A stationary bar portion on which an inner space is formed and on which a magnet is mounted;
A vibrator portion including a coil positioned to face the magnet and a weight moving together with the coil, the vibrator portion being accommodated in the inner space of the stationary portion;
An elastic member connecting the stator portion and the vibrator portion;
A damping member installed on one surface of the stator and positioned to face the elastic member; And
And a printed circuit board which is formed so as to surround at least a part of an outer circumferential surface of the magnet so that one end thereof is coupled to the coil and the other end is coupled to the stationary part and is not in contact with the magnet when the oscillator vibrates,
The vibrator unit includes a printed circuit board coupled to one side of the vibrator unit in the vibrating direction thereof and an elastic member coupled to the other side of the vibrator unit,
And at least a part of the elastic member is disposed between the damping member and the vibrator portion.
The method according to claim 1,
The stator section
A case having an inner space formed therein for accommodating the vibrator unit and an open bottom,
And a bracket for sealing the inner space of the case,
Wherein the damping member is provided on one surface of the case opposite to the elastic member.
The method of claim 2,
And the magnet of the stationary portion is mounted on one or both of the case and the bracket.
The method of claim 3,
Wherein a seating portion is formed on one or both of the case and the bracket on which the magnet of the fixed portion is mounted.
The method according to any one of claims 1 to 4,
Wherein the stator section further comprises a plate yoke coupled to one surface of the magnet.
The method according to any one of claims 1 to 4,
Wherein the coil is formed in a hollow shape to allow the magnet to pass therethrough.
delete The method according to claim 1,
The weight is provided with a yoke,
Wherein one end of the elastic member is coupled to the stator and the other end is coupled to the yoke.
The method according to claim 1,
Wherein one end of the elastic member is coupled to the stator and the other end is coupled to the coil.
delete The method according to claim 1,
Wherein the printed circuit board includes:
An engaging plate fixed to the stationary portion;
An elastic part extending from the coupling plate and extending in a spiral direction so as to have an elastic force; And
And a contact portion provided at an end of the elastic portion and coupled to the coil for applying external power.
The method of claim 2,
The magnet
A first magnet coupled to one surface of the bracket; and a second magnet opposed to the first magnet and coupled to a surface of the case.
The method of claim 12,
And a plate yoke coupled to one surface of the first magnet or one surface of the second magnet.
A stationary bar portion on which an inner space is formed and on which a magnet is mounted;
An oscillator portion including a coil positioned to face the magnet and a weight coupled to the coil, the oscillator portion being accommodated in the inner space of the stationary portion;
An elastic member connecting the stator portion and the vibrator portion;
A damping member installed on one surface of the vibrator and positioned to face the elastic member; And
And a printed circuit board which is formed so as to surround at least a part of an outer circumferential surface of the magnet so that one end thereof is coupled to the coil and the other end is coupled to the stationary part and is not in contact with the magnet when the oscillator vibrates,
The vibrator unit includes a printed circuit board coupled to one side of the vibrator unit in the vibrating direction thereof and an elastic member coupled to the other side of the vibrator unit,
And at least a part of the damping member is disposed between the elastic member and the vibrator portion.
15. The method of claim 14,
And the damping member is installed on one surface of the weight body.
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