KR101272729B1 - Linear vibration motor - Google Patents

Abstract

The present invention relates to a linear vibrating motor, and an object thereof is to provide a technique capable of preventing contact failure due to vibration of a vibration spring provided inside the linear vibrating motor.
According to the present invention, the following effects are obtained.
First, since the soldering point on the flexible printed circuit board part is formed inside the perforation of the vibration spring part, the vibration space of the weight part can be secured, and the thickness of the soldering point is reduced by the height of the soldering point.
Therefore, the present invention has the effect that the overall thickness is reduced compared to the conventional linear vibration motor in which the soldering point is not formed inside the perforated vibration spring portion.
Second, since the soldering point on the flexible printed circuit board part is formed in the perforation of the vibration spring part, the soldering point is not impacted by the vertical vibration of the vibration spring part. Therefore, the defective contact rate between the coil portion and the flexible printed circuit board is reduced, and the life of the product is extended.
Third, as the position of the soldering point is close to the coil part, there is an effect of improving the disconnection and lifting problems of the coil lead-out line.

Description

LINEAR VIBRATION MOTOR}

The present invention relates to a linear vibration motor.

In general, the linear vibration motor is a motor having a vibration function by the vertical motion, unlike the conventional rotary motor is a motor capable of adjusting the strength of the vibration force. These linear vibration motors have recently been installed in mobile phones, toys, game machines, etc. Beyond the constant vibration that can be felt in conventional rotary motors, the strength of the vibration force is adjusted so that the more dynamic vibration can be felt so that the existing rotary motor can be quickly The trend is replacing.

The above-described linear vibration motor includes a coil, a magnet, a vibration spring, and the like. When a current is applied to the coil, an electric field is generated in the coil, and a magnetic field is generated in the magnet, thereby vibrating the magnet in the vertical direction. In addition, the vibration force is installed in the lower portion of the magnet by the vibration of the magnet vibrating in the vertical direction, the vibration force is transmitted to the outside.

Such conventional linear vibration motor technology is described in Korean Patent Publication Nos. 10-2011-0028102, 10-2010-0024367, and 10-2010-0103959.

On the other hand, Figure 1 shows a linear vibration motor according to the prior art, the coil constituting the conventional linear vibration motor is electrically connected to the flexible printed circuit board through the soldering. However, when the vibration spring is coupled to the upper side of the flexible printed circuit board and vibrates in the up and down direction, continuous impact is applied to the soldering points formed on the flexible printed circuit board, resulting in poor contact and shortening the life of the product.

The present invention has been made to solve the above-described problems, and an object thereof is to provide a technology capable of preventing contact failure due to vibration of a vibration spring provided inside a linear vibration motor.

In one aspect of the present invention, the linear vibration motor has a hollow cylindrical shape, and an upper case part having a structure in which one side is closed to achieve this object; A magnet part disposed inside the upper case part and generating a magnetic field; A weight part vibrating in the longitudinal direction of the upper case part under the influence of a magnetic field generated by the magnet part; A yoke part coupled to one side of the magnet part such that the magnet part vibrates stably in the upper case part; A coil part formed larger than the diameter of the magnet part to generate an electromagnetic field by receiving power from the outside; A vibration spring part having a center open to receive the coil part, at least one perforation formed in the circumferential direction, and transmitting vibration force generated by vibration of the magnet part to the outside; A flexible printed circuit board connected to the coil part through soldering and transferring current to the coil part so as to generate an electromagnetic field by reacting with the magnet part; And a lower case part coupled to the other side of the upper case part and fixing the flexible printed circuit board part. And a soldering point on the flexible printed circuit board part electrically connected to the coil part, wherein the soldering point is formed in the perforation of the vibration spring part.

The soldering point on the flexible printed circuit board portion is formed in two perforations adjacent to the center of the vibration spring portion is characterized in that it is electrically connected to the coil portion.

The soldering point on the flexible printed circuit board part may be formed in each of the perforations adjacent to the center of the vibration spring and another perforation adjacent to the center of the vibration spring, and electrically connected to the coil part.

The linear motor is coupled to the other side of the magnet portion, the plate portion for concentrating the magnetic field generated in the magnet portion in a fixed direction; And further comprising:

The linear motor may include: a damper part disposed on one side of the flexible printed circuit board part to mitigate vibration noise generated from an electromagnetic field formed between the coil part and the magnet part; And further comprising:

As described above, the present invention has the following effects.

First, since the soldering point on the flexible printed circuit board part is formed inside the perforation of the vibration spring part, the vibration space of the weight part can be secured, and the thickness of the soldering point is reduced by the height of the soldering point.

Therefore, the present invention has the effect that the overall thickness is reduced compared to the conventional linear vibration motor in which the soldering point is not formed inside the perforated vibration spring portion.

Second, since the soldering point on the flexible printed circuit board part is formed in the perforation of the vibration spring part, the soldering point is not impacted by the vertical vibration of the vibration spring part. Therefore, the defective contact rate between the coil portion and the flexible printed circuit board is reduced, and the life of the product is extended.

Third, as the position of the soldering point is close to the coil part, there is an effect of improving the disconnection and lifting problems of the coil lead-out line.

1 illustrates a flexible printed circuit board and a vibration spring of a linear vibration motor according to the prior art.
2 shows a first embodiment of the present invention.
Fig. 3 shows a second embodiment of the present invention.
4 illustrates a cross-sectional view of a linear vibration motor according to an embodiment of the 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 simplicity of explanation.

Linear vibration motor 100 according to the present invention is the upper case portion 101, the magnet portion 103, the weight portion 105, the yoke portion 107, the coil portion 109, the vibration spring portion 111, flexible It includes a printed circuit board 113, a lower case 115, a plate 117, and a damper 119, which will be described with reference to FIGS. 1 to 4.

The upper case portion 101 has a hollow cylindrical shape and has a structure in which one side is closed. As shown in FIG. 4, the upper case part 101 includes all the detailed components of the linear vibration motor 100 except for the lower case part 115 therein.

The magnet part 103 generates a magnetic field having a constant intensity inside the upper case part 101, and is coupled to the inside of the yoke part 107 to vibrate in the longitudinal direction of the upper case part 101.

The weight portion 105 is a weight having a constant weight, and the inner circumferential surface of the weight portion 105 surrounds the outer circumferential surface of the yoke portion 107 and is coupled with the yoke portion 107. At this time, when the yoke portion 107 vibrates in the up and down direction due to the electromagnetic field formed by the magnet portion 103 and the coil portion 109 reacting with each other, the weight portion 105 is upper side together with the yoke portion 107. The yoke part 107 moves in the longitudinal direction of the case part 101 to maximize the strength of the vibration.

The yoke part 107 is coupled to one side of the magnet part 103 such that the magnet part 103 stably vibrates inside the upper case part 101, whereby the magnetic field generated from the magnet part 103 is the upper case part 101. To help spread the inside of the pan evenly.

The coil part 109 is formed to be larger than the diameter of the magnet part 103 to introduce the magnet part 103 when the magnet part 103 vibrates up and down. In addition, the coil unit 109 receives power from the connected flexible printed circuit board unit 113 to generate an electromagnetic field to vibrate the magnet unit 103 in the vertical direction.

At this time, the lead lines 109a and 109b of the coil unit 109 are soldered to one side of the flexible printed circuit board unit 113, so that two soldering points P1 and P2 are formed, and thus the flexible printed circuit board unit 113. Electrical connection is possible.

The vibration spring part 111 has a center open to accommodate the coil part 109 therein, and the vibration spring part 111 transmits vibration force generated from the magnet part 103 and the weight part 105 to the outside. do.

In addition, the structure of the vibration spring portion 111 is a form in which a plurality of annular rings of different diameters are centered around the center of the vibration spring 111. Here, at least one perforation is formed in the circumferential direction of the vibration spring 111 due to the coupling between the plurality of annular rings constituting the vibration spring 111.

The flexible printed circuit board 113 is connected to the coil 109 through soldering. The flexible printed circuit board 113 transmits a current to the coil unit 109 so that the coil unit 109 reacts with the magnet unit 103 to generate an electromagnetic field. In this case, soldering points P1 and P2 on the flexible printed circuit board 113 electrically connected to the lead lines 109a and 109b of the coil unit 109 are formed in the perforations of the vibration springs 111.

As shown in FIG. 1, the conventional linear vibration motor 100 has a vibration of a vibration spring corresponding to vertical vibration of a magnet (not shown) when a current is applied to a coil. However, as the positions of the soldering points 17 and 19 formed on the flexible printed circuit board 13 overlap with the positions at which the vibration springs 11 vibrate in the vertical direction, the more the vibration of the vibration springs 11 is repeated, the soldering is performed. There was a problem that the point (17, 19) is continuously impacted, thereby increasing the contact failure rate of the coil (15).

Accordingly, in the first exemplary embodiment of the present invention, the soldering points P1 and P2 on the flexible printed circuit board 113 are disposed to be adjacent to the center of the vibration spring 111 for electrical connection with the coil unit 109. It was formed inside.

Meanwhile, in the second embodiment of the present invention, the soldering points P1 and P2 on the flexible printed circuit board unit 113 may be adjacent to the center of the drilling and vibration spring 111 adjacent to the center of the vibration spring 111. One on each of the other perforations.

Unlike the first embodiment in which the lead lines 109a and 109b of the coil unit 109 are arranged in an 11-character shape and soldered to the flexible printed circuit board unit 113, the coil unit 109 Since the soldering process is performed using the initial positions of the leader lines 109a and 109b without aligning the leader lines 109a and 109b, the automation of the process is easy.

As shown in Figs. 2 to 3, the positions of the soldering points P1 and P2 of the first and second embodiments are formed in the perforations, so that the soldering points P1 and P2 and the coil portion 109 can be separated. The distance is shortened compared to the distance between the soldering point and the coil configured in the conventional linear vibration motor, thereby improving the disconnection and lifting problems of the lead wire of the conventional linear vibration motor.

In addition, in order to form soldering points P1 and P2 in the perforations of the vibrating springs 111, the sizes of the soldering points P1 and P2 of the first and second embodiments may be adjusted to the existing soldering points shown in FIG. 1. Compared with this, the two patterns can be soldered at a time, thereby simplifying the work process.

Since the soldering points P1 and P2 on the flexible printed circuit board part 113 shown in the first and second embodiments are formed in the perforations of the vibration spring part 111, the soldering points P1 and P2 are the vibration springs. The shock caused by the vertical vibration of the part 111 is not received. Therefore, the defective contact rate between the coil unit 109 and the flexible printed circuit board 113 is reduced, and the life of the product is extended.

The lower case part 115 is coupled to the other side of the upper case part 101 and fixes the flexible printed circuit board part 113.

The plate part 117 is coupled to the other side of the magnet part 103, and concentrates the magnetic field generated in the magnet part 103 in a fixed direction to help the magnet part 103 vibrate effectively.

The damper part 119 is positioned between the flexible printed circuit board part 113 and the lower case part 115 to mitigate vibration noise generated between the flexible printed circuit board part 113 and the lower case part 115.

4 is a cross-sectional view of the linear vibration motor 100 according to an exemplary embodiment of the present invention. In the case where vertical vibration of the vibration spring part 111 occurs due to the application of current to the coil part 109, the flexible printed circuit is shown. It can be seen that there is no impact on the soldering points P1 and P2 formed on the substrate portion 113.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. And the scope of the present invention should be understood as the following claims and their equivalents.

11: vibrating spring
13: flexible circuit board
15: coil
17, 19: soldering point
R: Impact location
100: linear vibration motor
101: upper case part
103: magnet part
105: weight part
107: yoke part
109: coil part
109a, 109b: leader line
111: vibrating spring part
113: flexible printed circuit board
115: lower case part
117: plate portion
119: damper part
P1, P2: soldering point

Claims (5)

An upper case portion having a hollow cylindrical shape and having a structure in which one side is closed;
A magnet part disposed inside the upper case part and generating a magnetic field;
A weight part vibrating in the longitudinal direction of the upper case part under the influence of a magnetic field generated by the magnet part;
A yoke part coupled to one side of the magnet part such that the magnet part vibrates stably in the upper case part;
A coil part formed larger than the diameter of the magnet part to generate an electromagnetic field by receiving power from the outside;
A vibration spring part having a center open to receive the coil part, at least one perforation formed in the circumferential direction, and transmitting vibration force generated by vibration of the magnet part to the outside;
A flexible printed circuit board connected to the coil part through soldering and transferring current to the coil part so as to generate an electromagnetic field by reacting with the magnet part;
A lower case part coupled to the other side of the upper case part and fixing the flexible printed circuit board part;
A plate part coupled to the other side of the magnet part and concentrating a magnetic field generated in the magnet part in a fixed direction; And
A damper part disposed on one side of the flexible printed circuit board part and configured to mitigate vibration noise generated from an electromagnetic field formed between the coil part and the magnet part; Including but not limited to:
The soldering point on the flexible printed circuit board portion electrically connected to the lead wire of the coil portion is characterized in that formed in the perforation of the vibration spring portion
Linear vibration motor. The method of claim 1,
The soldering point on the flexible printed circuit board portion is formed in two perforations adjacent to the center of the vibration spring portion is characterized in that it is electrically connected to the coil portion
Linear vibration motor. The method of claim 1,
The soldering point on the flexible printed circuit board portion is formed in each of the perforations adjacent to the center of the vibration spring portion and another perforation adjacent to the center of the vibration spring portion, characterized in that electrically connected to the coil portion.
Linear vibration motor. delete delete

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