KR20150121553A - Linear Vibrator - Google Patents

Abstract

A linear vibrator according to the present invention comprises: a case having an accommodation space formed therein; a coil in a cylindrical shape which is accommodated in the accommodation space, and generates a magnetic flux according to an electric signal; a circuit board connected to one side of the coil to apply the electric signal to the coil; a vibrating body which is disposed on an outside of the coil, and electromagnetically interacts with the coil to vibrate; a spring to elastically support the vibrating body relative to the case; and a fixing body disposed on an inside of the coil and mounted on the case. An inside of the spring is mounted between an upper surface of an inside of a center of the case and an upper portion of the fixing body. An outside of the spring elastically supports the vibrating body. Therefore, the linear vibrator according to the present invention can secure a wide width of the spring by a physical, direct mounting relationship between the inside of the spring and the case and the fixing body and an arrangement relationship by the mounting relationship to contribute to design freedom for a physical dimension such as a length, a breadth, and a width of the spring, a shape, etc. Accordingly, the linear vibrator can be designed according to a vibration width, a vibration quantity, and a resonant frequency of the vibrating body intended by a maker.

Description

{Linear Vibrator}

The present invention relates to a linear oscillator.

In general, a method for notifying a call from a communication device is a method in which a ring tone is used or a vibration is generated in a device to generate a vibration sound.

Among them, the vibration method is mainly used when it is desired not to damage the other person through the ring tone. For this purpose, a small vibration generating device built in the device is driven to transmit driving force to the case of the device, Vibration.

The vibration generator, which is currently applied to mobile phones, is a component that converts electrical energy into mechanical vibration by using the principle of electromagnetic force generation, and is used for silent notification of an alarm mounted on a mobile phone.

On the other hand, the first vibrator adopts a method of generating vibration by rotating a mass having an eccentricity by a motor, but the technical problem of miniaturization and thinning close to portability is that the vibration is generated by the rotation, Technology.

Particularly, recently, a smartphone having a display is configured with a display, and a touch panel is mounted on a display, so that a haptic technique in which a vibration occurs every time a user tries to use a smartphone using a touch, In this case, it is required that the reaction of the vibration is performed quickly, so application of the linear oscillator is essential.

As one example of such a linear oscillator, a linear oscillator is disclosed in Korean Patent Publication No. 10-2013-0018975.

Such a linear oscillator includes a case forming an internal space as shown in Fig. 1, a coil forming a magnetic field in accordance with the received electrical signal, a permanent magnet vibrating in a vertical direction interacting with the magnetic field generated in the coil, And a spring for elastically supporting the vibrating body.

Particularly, the spring includes an extension portion connecting the outer side and the inner side of the spring, the upper surface of the oscillator being coupled to the inner side of the spring, the outer side of the spring being coupled to the upper portion of the case, and thereby elastically supporting the oscillator.

The extension of the spring is a component that greatly affects the resonance frequency of the oscillator.

는

의 관계를 가진다. 여기서 m은 진동체의 무게, k는 탄성계수를 의미한다.Resonance frequency of oscillator

The

. Where m is the weight of the vibrating body and k is the modulus of elasticity.

At this time, the elastic modulus k is determined by the width and length of the extended portion.

In order to design a low resonance frequency to be output, the resonance frequency can be adjusted by changing the weight of the vibrating body.

However, in the case of an ultra-small linear oscillator, there is a limit in reducing the weight of the vibrating body to the maximum.

Therefore, it is necessary to design the resonance frequency by adjusting the length or width of the extension portion. However, if the width of the extension portion is reduced to a certain value or less, there is a problem in the durability of the extension portion. have.

Therefore, the resonance frequency should be adjusted by varying the length of the extension.

However, in the conventional linear vibrator, the inner side of the spring is coupled to the vibrating body, and the outer side of the spring is attached to the case, so that the spring has a coupling relation and an arrangement structure for supporting the vibrating body. As can be seen, the length l of the extension part can not but be reduced due to the coupling relation and arrangement relation between the respective components.

For the above reasons, there are many limitations in designing a linear oscillator to oscillate at a specific resonance frequency.

Accordingly, the linear vibrator of the present invention is designed to solve the above-mentioned problems, and more particularly, to ensure the freedom of the physical numerical physical value of the width or length of the extension portion in designing the spring.

It is also an object of the present invention to simplify the production process of the linear oscillator of the present invention than the conventional linear oscillator.

According to an aspect of the present invention, there is provided a magnetic bearing device comprising: a case having a housing space therein; a cylindrical coil accommodated in the housing space and provided to generate a magnetic flux according to an electrical signal; A circuit board for applying an electrical signal to the coil, a vibrating body provided outside the coil for vibrating electromagneticly with the coil, a spring for elastically supporting the vibrating body with respect to the case, Wherein an inner side of the spring is coupled between an inner upper surface of the center of the case and an upper portion of the fixture, and an outer side of the spring elastically supports the vibrator .

Wherein the spring has an inner engaging portion which is engaged with an inner upper surface at the center of the case and in which a fixing member insertion groove is formed at a center with respect to a plane, an outer engaging portion which is engaged with the outer upper end portion of the vibrating member, And an extension portion extending from the coupling portion to the outer coupling portion and formed in a circular winding shape.

The fixed body includes a body portion provided to be in contact with the inside of the coil, a fixed body upper fixing portion having an upper step portion with a smaller diameter than the body portion, and a lower step portion formed with a smaller diameter than the body portion And the fixture body lower fixing part, wherein the fixture upper fixation part is fitted into the fixture insertion groove, so that the inner joint part is fixed and supported by the upper step part.

And the fixed body is a magnetic body for uniformly distributing a magnetic flux distribution generated in the coil.

Therefore, as shown in FIG. 2, the linear vibrator of the present invention can largely secure the extension L of the present invention by the coupling relationship in which the inside of the spring is physically directly fixed by the case and the fixing body, Since the physical constraint such as the length and width of the spring can be minimized, there is less restriction on the elastic modulus k, and accordingly, the linear vibration of the oscillator depends on the vibration characteristics of the oscillator, It is possible to expect an effect of freely designing.

In addition, the production efficiency of the linear oscillator can be increased by minimizing / simplifying the production process of the linear oscillator.

1 is a cross-sectional view showing a cross section of a linear oscillator shown in the prior art (Korean Patent Laid-Open Publication No. 10-2013-0018975).
Fig. 2 is an explanatory view showing the length of the extension of the present invention. Fig.
3 is an exploded perspective view showing components of the linear vibrator according to the present invention.
4 is a cross-sectional view showing a cross section of the linear oscillator of the present invention.
5 is a plan view of a spring which is a component of the linear oscillator of the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for the sake of brevity.

First, for clarity of explanation, the components of the linear vibrator 100 of the present invention will be described, and then the coupling relationship between the respective components will be described.

1. Description of Components of Linear Oscillator (100) of the Present Invention

The linear oscillator 100 of the present invention is roughly composed of a case 110, a coil 120, a circuit board 130, a vibrating body 140, a fixing body 150 and a spring 160, 5 to FIG.

The case 110 is a component for embedding a component therein, and includes an upper case 111 and a lower case 112.

The upper case 111 is coupled with the lower case 112, and a space for receiving the components therein is formed.

An opening 111H is formed in a part of the lower side of the upper case 111 side surface.

The lower case 112 is formed in a circular shape so as to be coupled with the upper case 111 and the seating part 112P is extended in a direction in which the opening 111H is formed inside the lower case 112. [

In this case, it is most preferable that the seating part 112P is formed at the outer side of the lower case 112 in the side face direction where the opening part 111H formed in the upper case 111 is located.

Further, according to the embodiment of the present invention, a predetermined step portion and a fitting portion for fixing the fixture 150 to the center of the upper case 111 and the lower case 112 may be further provided.

The coil 120 forms a magnetic field so that the vibrating body 140 can be vibrated according to an electrical signal supplied through the circuit board 130.

The circuit board 130 is a component for applying an electrical signal to the coil 120 and is seated on the seating part 112P so that one side of the coil 120 and the circuit board 130 are in direct contact with each other.

The oscillator 140 is a component that vibrates by electromagnetic interaction with the coil 120, and is provided with a permanent magnet 141 and a weight member 142.

The permanent magnet 141 is provided with an empty space corresponding to the volume of the permanent magnet 141 at the center of the weight member 142. The permanent magnet 141 is fitted and fixed to the empty space, And is oscillated in an up-and-down direction by an electromagnetic reaction with a magnetic flux generated in the rotor.

The weight member 142 is engaged with the permanent magnet 141 such that when the permanent magnet 141 vibrates by the coil 120, the weight member 142 is brought into contact with the weight member 142 in the same volume (vibration space, inside the case 110) Thereby securing a large oscillation width of the vibrating body 140. [

The fixed body 150 is a component that engages with the case 110 and is preferably provided as a magnetic body for uniformly distributing magnetic flux generated from the coil 120.

The fixed body 150 includes a body portion 153 provided to be in contact with the inside of the coil 120 and a fixed body upper fixing portion 151 having an upper step portion a having a smaller diameter than the body portion 153, And a lower fixed portion 152 formed with a lower step portion b having a diameter smaller than that of the body portion 153. [

The fixed body lower fixing portions 151 and 152 are divided to facilitate description of the coupling relationship between the spring 160 and the upper and lower cases 111 and 112. [

The fixture upper fixing portion 151 is provided to fix the fixture 150 to the upper case 111 and an upper step portion a formed to be smaller than the diameter of the body portion 153 is formed.

The fixed bottom lower fixing part 152 is provided to fix the fixing body 150 to the lower case 112 and the lower step part b formed to be smaller than the diameter of the body part 153 is formed.

The spring 160 is a component provided to elastically support the vibrating body 140 with respect to the upper case 111. Referring to FIG. 5, the spring 160 includes an inner coupling portion 161, an outer coupling portion 162 and an extension portion 163.

The inner engaging portion 161 is an inner portion of the spring 160 in which a fixture insertion groove 161H is formed at the center.

The outer joint portion 162 is an outer portion of the spring 160 and is a component that is fixedly coupled with the vibrating body 140 through welding, adhesive or screw coupling means.

The extension portion 163 extends from the inner coupling portion 161 and is formed as a circular / annular shape that is wound around the outer coupling portion 162. The extension portion 163 extends downward due to the weight of the vibrating body 140.

The elastic modulus k is determined by physical quantities such as shape, material, width, thickness, and height of the extension portion 163, and is a component directly involved in vibration characteristics such as vibration width, vibration amount, and resonance frequency.

2. Description of the connection relationship between the components of the linear vibrator 100 of the present invention

Hereinafter, the coupling relationship among the constituent elements of the linear vibrator 100 of the present invention will be described separately.

The spring 160 elastically supports the vibrating body 140 with respect to the upper case 111.

4, the outer coupling part 162 of the spring 160 is coupled / fixed to the upper end of the weight member 142 of the vibrating body 140 by means of welding, screws, adhesive, or the like The weight member 142 is elastically supported.

The fixing member insertion groove 161H formed in the inner coupling portion 161 is inserted into the fixing portion upper fixing portion 151 and the spring 160 is supported by the fixing member 150. [

The upper case 111 and the lower case 112 are formed such that an upper step portion a formed in the fixed body upper fixing portion 151 and a lower step portion b formed in the fixed body lower fixing portion 152 can be fitted, Are formed at the respective step portions and the fitting portions.

The fixing member 150 is firmly fixed by receiving the downward pressing force of the upper case 111 in a state where the fixing member insertion groove 161H is fitted in the fixing member upper fixing portion 151, The inner engaging portion 161 of the fixed body lower fixing portion 152 is pressed / engaged between the fixed body upper fixing portion 151 and the upper case 111 to fix the inner engaging portion 161, b are fitted into the fitting portion of the lower case 112 so that the fixing body 150 is fixed by the pressure of the engagement of the upper and lower cases 111 and 112.

The spring 160 is welded to the upper case 111 by the organic compounding relationship between the upper case 111, the lower case 112, the vibrating body 140, the fixing body 150 and the spring 160, It is possible to minimize the manufacturing process of the linear vibrator 100 and to securely fix all the components with optimal space utilization.

100: linear oscillator
110: Case
111: upper case 111H: opening
112: Lower case 112P:
120: Coil
130: circuit board
140: vibrating body
141: permanent magnet 142: weight member
150:
151: Fixture upper fixing part a: upper step part
152: Fixed body lower fixing part b: Lower step part
153:
160: spring
161: Inner engaging portion 162:
163: Extension part 160H: Fixing body insertion groove

Claims (4)

A case having a receiving space therein;
A cylindrical coil accommodated in the accommodation space and provided to generate a magnetic flux according to an electrical signal;
A circuit board contacting one side of the coil to apply an electrical signal to the coil;
A vibrating body provided outside the coil and vibrating by electromagnetic interaction with the coil;
A spring elastically supporting the vibrating body with respect to the case;
And a fixing body positioned inside the coil and engaged with the case,
Wherein an inner side of the spring is coupled between an inner upper surface at the center of the case and an upper portion of the fixed body, and an outer side of the spring elastically supports the vibrating body.
The method according to claim 1,
The spring
An inner engaging portion coupled to an inner upper surface at the center of the case and having a fixing body insertion groove formed at a center thereof with respect to a plane;
An outer coupling part coupled to an upper end of the vibrating body with respect to a cross section;
And an extension portion extending from the inner coupling portion to the outer coupling portion and formed into a circular winding shape.
3. The method of claim 2,
The fixture includes:
A body portion positioned to be in contact with the inside of the coil;
A fixed upper upper fixing part formed with an upper step part having a smaller diameter than the body part;
And a lower fixed portion formed with a lower step portion having a smaller diameter than the body portion,
And the inner joint portion is fixed and supported by the upper step portion by engaging the fixed body upper fixing portion with the fixed body insertion groove.
The method of claim 3,
Wherein the fixed body is a magnetic body for uniformly distributing a magnetic flux distribution generated in the coil.

Images