KR100861610B1 - Vibration motor - Google Patents

Abstract

Vibration motor 100 of the present invention is installed on the upper surface of the coil 120 to which the external power is applied, the base 110 and the shaft 130 is fixed to the central portion, and rotatable on the top of the shaft 130 The bearing 150 to be inserted and coupled to the coil 120, the magnet 141 is installed facing the coil 120 and the weight 142 for forming a vibration during rotation is fixedly installed on one side and between the bearing 150 Yoke 140 for accommodating the bearing 150 to form a space, and coupling means 160 for filling the space so that at least a part is fitted to the yoke 140 through injection molding to secure the bearing 150 to the yoke 140. It characterized in that it comprises a).

Vibration motor, injection molding, coupling groove, coupling protrusion, yoke

Description

Vibration Motor

1 is a schematic cross-sectional view of a vibration motor according to an embodiment of the present invention;

2 is a schematic perspective view of the yoke of FIG. 1;

3 is a schematic cross-sectional view of a conventional vibration motor; And

4 is a schematic perspective view illustrating the yoke of FIG. 3.

<Explanation of symbols for main parts of drawing>

100: vibration motor 110: base

120: coil 130: shaft

140: yoke 143: holder

145: coupling groove 150: bearing

160: coupling means 161: coupling protrusion

170: housing 171: edge portion

The present invention relates to a vibration motor, and more particularly, to a vibration motor in which the yoke and the bearing are fastened by injection molding such as resin in order to prevent deformation of the bearing.

Vibration motors are installed in mobile communication devices such as mobile phones to inform users of the reception status of communication through vibration generation. Vibration motors are rotors consisting of yokes and bearings with magnets and weights installed, bases and coils. It consists of a stator composed of.

Here, in general, although the bearing is press-fitted to the yoke, the bearing may be deformed when the bearing is press-fitted. In order to solve this problem, a technique for fastening the yoke and the bearing by injection molding of resin and the like has been proposed. An example of such a vibration motor is illustrated in FIGS. 3 and 4.

As shown in Figure 3 and 4, the conventional vibration motor 200 is a base 210, coil 220, shaft 230, yoke 240, bearing 250, injection resin 260 and It consists of a housing 270.

The base 210 is for supporting the vibration motor 200 as a whole. The base 210 is made of iron or aluminum in a plate shape, and the shaft 230 is fixed to the center portion.

The coil 220 is to rotate the rotor, that is, the yoke 240 with a force generated between the magnet 241 installed on the yoke 240 by receiving an external power source, and is fixed to the upper surface of the base 210. Is installed.

The shaft 230 is for rotatably supporting the rotor, that is, the yoke 240 and the bearing 250, and has a lower end fixed to the center portion of the base 210 and an upper end fixed to the housing 270. It is installed.

The yoke 240 is a magnet 241, the weight 242 and the bearing 250 is fixedly installed and rotated, the holder 243 for receiving the bearing 250 is formed in the center portion, where the holder ( 243 has an inner diameter larger than the outer diameter of the bearing 250 to form a space between the bearing 250.

The bearing 250 is rotatably inserted into the shaft 230 and fixedly coupled to the holder 243 of the yoke 240 via the injection resin 260.

Injection resin 260 is a coupling means for fixedly coupling the bearing 250 and the yoke 240, and is filled in the space formed between the bearing 250 and the holder 243 through injection molding, It hardens through the method to couple the bearing 250 and the yoke 240.

The housing 270 is to surround and protect the vibration motor 200 as a whole, and the upper end of the shaft 230 is fixed to the center portion.

However, in the conventional vibration motor 200 having the above-described configuration, since the inner circumferential surface of the holder 243 and the outer circumferential surface of the injection resin 260 are in surface contact with each other after curing of the injection resin 260, the yoke 240 and the injection resin are in contact with each other. Failed to secure a sufficient fastening force between the (260), due to this there was a fear that the yoke 240 is easily separated by the impact from the outside given to the vibration motor 200.

The present invention has been made to solve the above problems of the prior art, an object of the present invention is to form a coupling groove in the inner peripheral surface of the holder of the yoke and at least a portion of the injection resin is injected into the coupling groove during the injection molding of the injection resin The present invention provides a vibration motor capable of sufficiently securing the clamping force between the yoke and the injection resin by forming a coupling protrusion fitted into the coupling groove after curing the injection resin.

In order to achieve the above object of the present invention, the present invention is a base to which a coil to which the external power is applied is installed on the upper surface and the shaft is fixed to the central portion, and a bearing rotatably inserted into the upper portion of the shaft, A magnet is installed facing the coil, and a weight for forming vibration during rotation is fixed to one side, and a yoke for accommodating the bearing to form a space between the bearing and at least a part of the yoke is inserted through the injection molding. It is possible to provide a vibration motor, characterized in that it comprises a coupling means for filling the space to secure the bearing to the yoke.

Here, the yoke has an inner diameter larger than the outer diameter of the bearing and has a holder for accommodating the bearing therein, the holder extending toward the base to have a height corresponding to the bearing, and a space in which the coupling means is filled between the outer peripheral surface of the bearing. It is characterized by having an inner peripheral surface forming a.

In addition, the inner circumferential surface of the holder has a coupling groove formed in at least a portion along the circumferential direction, characterized in that the coupling means has a coupling protrusion formed on the outer circumferential surface to correspond to the coupling groove.

In addition, the coupling groove is characterized in that formed in a pair to face each other.

In addition, the coupling protrusion is formed by filling the coupling groove during injection molding, characterized in that for supporting the yoke in the axial direction after curing.

Hereinafter, a vibration motor according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

As shown in FIG. 1, the vibration motor 100 includes a base 110, a coil 120, a shaft 130, a yoke 140, a bearing 150, a coupling means 160, and a housing 170. Consists of.

The base 110 is for supporting the vibration motor 100 as a whole, and is made in a plate shape such as iron or aluminum, and has a fastening holder 111 for fastening the shaft 130 to the center.

The fastening holder 111 is formed to protrude in a cylindrical shape, the inner diameter of which coincides with the outer diameter of the shaft 130, and the shaft 130 is fixedly press-installed.

In addition, the base 110 is provided with a circuit board 112 for applying external power to the coil 120 on the upper surface.

The coil 120 is to form a magnetic circuit together with the magnet 141 installed on the yoke 140 by receiving an external power source, and is fixed to the upper portion of the base 110 to face the magnet 141 at a predetermined interval. Is installed.

The shaft 130 is for rotatably supporting the rotor, that is, the yoke 140 and the bearing 150, and has a lower end fixed to the fastening holder 111 of the base 110 and an upper end of the housing 170. It is fixedly installed on.

Here, the upper and lower shaft 130 is supported by the fastening holder and the housing 170 of the base 110, it is preferable that the oscillation motor 100 does not swing when driving.

The yoke 140 is a magnet 141, a weight 142 and the bearing 150 is fixedly rotated, and has a holder 143 for accommodating the bearing 150 in the center portion, the magnet 141 It is made of magnetic material such as iron to prevent leakage of magnetic force.

The magnet 141 is for forming a magnetic circuit, and is fixedly attached to the lower side of the yoke 140 in a hollow annular shape.

The weight 142 is to generate vibration while rotating, and is eccentrically coupled to one side of the yoke 140.

The holder 143 extends from the lower side of the yoke 140 toward the base 110, and in this embodiment the holder 143 extends to have a height corresponding to the height of the bearing 150. In addition, the holder 143 has an inner diameter larger than the outer diameter of the bearing 150 to form a space in which the coupling means 160 is interposed between the bearing 150.

In other words, the holder 143 has an inner circumferential surface 144 which is in contact with the outer circumferential surface of the bearing 150 accommodated therein, and has a predetermined distance between the inner circumferential surface 144 of the holder 143 and the outer circumferential surface of the bearing 150. As much space is formed.

In addition, the holder 143, with reference to Figure 2, the inner peripheral surface 144 is formed with a coupling groove 145 is inserted into the coupling means 160, the coupling groove 145 is a holder 143 Along the inner circumferential surface 144 of the holder 143 extends in the circumferential direction, it is preferable that a pair is formed to face each other.

Here, after the coupling means 160, that is, the coupling means 160 in the molten state by the heat is filled in the coupling groove 145 formed in the holder 143, after the coupling means 160 is cured, A portion of the coupling means 160 filled in the coupling groove 145 is formed by the coupling protrusion 161. Therefore, the coupling protrusion 161 may increase the fastening force between the yoke 140 and the coupling means 160 by supporting the yoke 140 in the axial direction.

The bearing 150 is rotatably inserted into the shaft 130 and fixedly coupled to the holder 143 of the yoke 140 via the coupling means 160.

The coupling means 160 is for fixing the bearing 150 and the yoke 140 to be fixed. The coupling means 160 is formed of a resin, such as a resin that is melted by heat, and is formed between the bearing 150 and the holder 143 through injection molding. Filled in the space that is formed in.

Here, a portion of the coupling means 160 in the molten state is filled in the coupling groove 145, after curing the coupling means 160, the portion filled in the coupling groove 145 is a coupling protrusion corresponding to the coupling groove 145. Function as 161.

Coupling protrusion 161 may increase the coupling force between the yoke 140 and the coupling means 160 by supporting the yoke 140 in the axial direction.

The housing 170 is to cover and protect the vibration motor 100 as a whole. The upper end of the shaft 130 is fixed to the center portion. In addition, the housing 170, the edge portion 171 extends toward the base 110, the end of the edge portion 171 is fixedly coupled to the base 110.

The vibration motor of the present invention has been described above with reference to a preferred embodiment of the present invention, but it is apparent to those skilled in the art that modifications, changes and various modifications can be made without departing from the spirit of the present invention.

According to the vibration motor of the present invention, a coupling groove is formed on the inner circumferential surface of the holder of the yoke, and a part of the coupling means in the molten state is injected into the coupling groove during injection molding to form a coupling protrusion fitted into the coupling groove after curing of the coupling means. By doing so, the fastening force between the yoke and the engaging means can be sufficiently secured.

Claims (5)

A base on which a coil to which external power is applied is installed on an upper surface, and a shaft is fixed to a central portion thereof; A bearing rotatably inserted into an upper portion of the shaft; A yoke for accommodating the bearing so that a magnet is installed opposite the coil and a weight for forming vibration during rotation is fixed to one side and a space is formed between the bearing; And In the vibration motor comprising a coupling means for filling the space so that at least a part is fitted to the yoke through injection molding to secure the bearing to the yoke, The yoke has an inner diameter larger than an outer diameter of the bearing and has a holder therein for receiving the bearing, the holder extending toward the base to have a height corresponding to the bearing and between the outer circumferential surface of the bearing. Vibration motor, characterized in that it has an inner peripheral surface forming a space in which the coupling means is filled. delete The vibration motor of claim 1, wherein the inner circumferential surface of the holder has a coupling groove formed at least in a circumferential direction, and the coupling means has a coupling protrusion formed on the outer circumferential surface to correspond to the coupling groove. The vibration motor of claim 3, wherein the coupling grooves are formed in a pair to face each other. The vibration motor of claim 3, wherein the coupling protrusion is formed by filling the coupling groove during injection molding and supports the yoke in an axial direction after curing.

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