KR101953224B1 - The FPCB for a linear vibrator - Google Patents

Abstract

The present invention relates to a flexible printed circuit board (FPCB) used for a vertically vibrating linear vibration motor which can reduce a bending angle in a situation that a weight is vertically vibrated. To this end, the FPCB used for a vertically vibrating linear vibration motor for supplying external power to a coil, comprises a coil connection unit, a power connection unit, and a bending unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a flexible circuit board used in a vertical vibration type linear vibration motor,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flexible circuit board used in a vertical vibration type linear vibration motor and more particularly to a flexible circuit board for supplying power to a coil in a vertical vibration type linear vibration motor, And more particularly, to a flexible circuit board used in a vertical vibration type linear vibration motor which is designed to reduce the angle of repeated bending and thereby increase the service life.

[0002] Vibration motors that generate vibration are used in various fields such as various healthcare products and medical devices. Among them, most of them are used in portable devices including mobile phones, mainly for transmitting signals without generating external noise, Especially, in the mobile phone field where the thickness becomes thinner, a compact and small vibration motor is required.

Conventionally, most of vibration motors used in mobile phones are equipped with a weight for weighting the rotating rotor to be eccentric by applying the principle of a general motor as it is, so as to obtain mechanical vibration according to rotation.

However, in such a structure, electric contact is made by a brush of a thin metal plate to supply electric power to the coil of the rotor, and electrical spark and abrasion occurs due to repeated rotation, thereby contaminating the inside and worn by the brush. There was a drawback that there was a limit.

FIG. 5 is a conceptual diagram showing the structure of a vertical vibration type linear vibration motor, FIG. 6 is a conceptual view showing movement of a flexible circuit board, and FIGS. 7 to 8 are plan views showing a conventional flexible circuit board, The linear vibrator includes a case 11 having a cylindrical shape with an open bottom and a bracket 12 mounted to a lower portion of the case 11 and a linear vibration motor 1 A weight 15 for passing the magnets 13 through which the coils 14 are mounted and a spring 15 for connecting and fixing the upper surface of the weight 15 and the inner upper portion of the case 11, And a flexible circuit board 17 (FPCB) for supplying external power to the coils 14. [

The flexible circuit board 17 includes a coil connection portion 171 and a power connection portion 172 at both ends of which the coil 14 is connected to an external power source. The flexible circuit board 17 includes a bent portion 173 extending between the coil connection portion 171 and the power connection portion 172.

At this time, as shown in the figure, the flexible circuit board 17 according to the upward and downward movement of the weight 15 repeatedly flexes at a portion where the coil connecting portion 171 and the power connecting portion 172 are connected to the bending portion 173, The bending part 173 is buckled due to the rapid up-and-down movement, which is a cause of shortening the life span.

As a method for solving such a problem, a variety of shapes have been developed as shown in FIGS. 7 to 8 in a direction in which the length of the bending portion 173 is made as long as possible and the angle of bending is reduced to improve durability .

Korea Patent Registration No. 10-1141726-0000 (April 24, 2012) Korea Patent Registration No. 10-1184408-0000 (September 13, 2012) Korean Patent Registration No. 10-1339606-0000 (December 03, 2013) Korean Patent Registration No. 10-1548936-0000 (Aug. 26, 2015)

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the above-mentioned problems, and an object of the present invention is to provide a vertical vibration type linear vibration motor capable of reducing a bending angle in a vertical vibration state of a weight by forming a path of a bending portion of a flexible circuit board as long as possible And to develop a flexible circuit board.

Another object of the present invention is to develop a flexible circuit board for use in a vertical vibration type linear vibration motor capable of preventing collision of a bent portion adjacent to a coil connection portion while a weight rapidly falls.

According to an aspect of the present invention, there is provided a linear vibration motor including a magnet fixed at a center of a lower surface of a case and a weight through which a magnet penetrates and a coil is mounted, A flexible circuit board (2) (FPCB) comprising a coil connection part (21), a power connection part (22) and a bent part (23) extending between the coil connection part (21) and supplying external power to the coil.

The bent portion 23 includes a first curved portion 231 extending integrally with the tapered portion 222 and bent in a circular arc shape of 40 to 60 degrees and a first curved portion 231 extending in a straight line extending from the first bent portion 231, A first semicircular curved portion 233 bent in an arc shape at an angle of 180 degrees or less at the first rectilinear section 232 and a second semicircular curved portion 233 bent in a straight line at the first semicircular bent portion 233 A second semicircular curved portion 235 bent in an arc shape at an angle of 180 degrees or less at the second straight portion 234, And a third rectilinear section (236) extending in a straight line from the portion (235) to a path opposite to the second rectilinear section (234).

In addition, the apparatus may further include a cylindrical case having an opened bottom, a bracket mounted on a lower portion of the case, and a spring for connecting and fixing the upper surface of the weight and the inner upper portion of the case.

The power connection part 22 of the flexible circuit board 17 includes a first power connection part 221 which is in close contact with the bottom surface of the bracket and to which power is applied and a taper part 222 ).

The coil connecting part 21 is formed as a circular arc of 90 to 180 ° and is integrally connected to the third rectilinear part 236 at an intermediate point and is tightly fixed to the bottom surface of the weight, And a second power connection part 212 extending from the third straight line part 236 to one side of the close contact part 211 and electrically connected to the coil.

A second curved portion 237 formed by a convex curve extending from a point formed by an obtuse angle among the points connected with the acute angle of both sides where the third rectilinear portion 236 and the tightly fixed portion 211 meet, .

The first semi-circular curved portion 233 is bent in an arc shape at an angle of 180 ° and the second rectilinear portion 234 extends in an opposite path parallel to the first rectilinear portion 232, The second semi-circular curve portion 235 may be bent in an arc shape at an angle of 180 ° and the third rectilinear portion 236 may extend in an opposite path parallel to the second rectilinear portion 234.

The center line of the second rectilinear section 234 and the center axis of the magnet may be coupled to each other so as to intersect with each other in the upper surface space of the magnet.

The first semicircular curved portion 233 is curved in an arc shape at an angle of less than 180 degrees and the second semicircular curved portion 235 is curved in an arc shape at an angle of less than 180 degrees, And the coil connecting portion 216 is integrally connected at a position offset to the opposite side of the second power connecting portion 212 of the coil connecting portion 21 by being extended at an acute angle to the second rectilinear portion 234 .

As described above, according to the present invention, the bending portion of the flexible circuit board is staggered by the first to third straight line portions and the first to second semicircular bent portions, so that the bent angle at the portion where the coil connecting portion and the power connection portion are connected to the bent portion Thereby improving durability.

Further, the second curved portion formed between the coil connecting portion and the third rectilinear portion has an effect of preventing the flexible circuit board from being damaged by preventing the curved portion of the weight from buckling and colliding with the weight when the weight is lowered.

1 is a plan view showing a flexible circuit board according to an embodiment of the present invention;
2 is a plan view showing a flexible circuit board according to another embodiment of the present invention.
3 is a conceptual diagram illustrating movement in an AA cross section according to an embodiment of the present invention.
FIG. 4 is a conceptual diagram illustrating movement in a BB cross section according to an embodiment of the present invention. FIG.
5 is a conceptual diagram showing a structure of a vertical vibration type linear vibration motor
Fig. 6 is a conceptual view showing the movement of the flexible circuit board
7 to 8 are plan views showing a conventional flexible circuit board

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a plan view showing a flexible circuit board according to an embodiment of the present invention, and FIG. 2 is a plan view showing a flexible circuit board according to another embodiment of the present invention. FIG. 2 is a conceptual diagram illustrating movement in an AA cross section according to an embodiment of the present invention. FIG. 3 is a conceptual view illustrating movement in a BB cross section according to an embodiment of the present invention. A magnet fixed to a center of a lower surface of the case; a center having a weight through which the magnet penetrates and on which the coil is mounted; and a spring for connecting and fixing the upper surface of the weight and the inner upper portion of the case, A vertical vibration type linear vibration motor (not shown) for supplying external power to the coil, which is composed of a coil connecting portion 21, both ends of which are connected to an external power source, and a power connection portion 22 and a bend portion 23, A flexible circuit board (2;

The power connection part 22 of the flexible circuit board 17 includes a first power connection part 221 which is in close contact with the bottom surface of the jug bracket and to which power is supplied and a taper part 222, Respectively.

1, the bent portion 23 includes a first curved portion 231 extending integrally with the tapered portion 222 and bent in an arc shape, and a second curved portion 231 extending from the first bent portion 231 A first semicircular curved portion 233 bent in an arc shape in a direction different from the first rectilinear portion 232 and a second semicircular curved portion 233 bent in a straight line at the first semicircular bent portion 233 A second semi-circular curved portion 235 bent in an arc shape in a direction different from the second rectilinear portion 234 in the second rectilinear portion 234, and a second semi- And a third rectilinear section 236 that extends in a straight line at the second rectilinear section 235.

According to one aspect, the first curved portion 23 may be integrally extended with the tapered portion 222 and bent in a circular arc shape of 40 to 60 degrees.

1, the first semi-circular curved portion 233 is curved in an arc shape in a direction different from the first rectilinear portion 232, so that the second rectilinear portion 234, which extends straight in the first semi-circular curved portion 233, Extends in a direction different from the direction of the first rectilinear section (232). Thus, the flexible circuit board shown in Fig. 1 extends in a serpentine manner in the space of the upper surface of the magnet, and consequently a longer-length flexible circuit board can be located in the limited space.

1, the second rectilinear section 234 extends at an acute angle to the first rectilinear section 232 and the third rectilinear section 236 extends at an acute angle to the second rectilinear section 234 The second straight line portion 234 is extended from the first straight line portion 234 to the first straight line portion 234 of the coil connecting portion 21, Or an obtuse angle with the second rectilinear section 232, or an obtuse angle with the second rectilinear section 234.

2, the bent portion 23 includes a first curved portion 231 extending integrally with the tapered portion 222 and bent in an arc shape, and a second curved portion 231 extending from the first bent portion 231 A first semicircular curved portion 233 bent in a circular arc of 180 ° in the first rectilinear section 232 and a second semicircular curved portion 233 bent in a straight line in the first semicircular bent portion 233, A second rectilinear section 234 extending in an opposite path parallel to the first rectilinear section 232, a second semi-circular section 235 bent in a 180 ° arc in the second rectilinear section 234, And a third rectilinear section (236) extending in a straight line in the semicylindrical bend (235) to an opposite path parallel to the second rectilinear section (234);

The coil connection part 21 is formed in a circular arc shape of 90 to 180 ° and is integrally connected to the third rectilinear part 236 at an intermediate point and tightly fixed to the bottom of the weight, And a second power connection part 212 extending from the linear part 236 to one side of the contact fixing part 211 and electrically connected to the coil. .

The exemplary embodiments shown in FIGS. 1 and 2 enable the length of the bent portion 23 to be effectively extended. In most prior arts, in the process of forming a path that avoids the central magnet, The width of the flexible circuit board 2 is excessively narrowed in order to increase the length of the flexible circuit board 2 in a limited space, resulting in a reduction in durability.

That is, if the magnet is fixed and the moving direction of the magnetic force is not changed, if the height of the magnet is set to be low, a sufficient space for the flexible circuit board 2 to pass therethrough is secured, .

In this case, if the center line 300 of the second rectilinear section 234 and the center axis 310 of the magnet are coupled so as to intersect with each other in the upper surface space of the magnet, the length of the flexible circuit board 2 is maximized The vertical vibration type linear vibration motor can be constructed.

In other words, the second rectilinear portion 234 of the present invention passes over the magnet, and this path secures a length of at least twice as much as that of the prior art, so that the angle at which the flexible circuit board 2 is bent is greatly reduced, The durability of the circuit board 2 is increased.

In this embodiment, a second curved portion 237 formed by a point formed by an obtuse angle convexly curved out of the points connected with the acute angle of both sides of the third straight line portion 236 and the tight fitting portion 211, ) Of the present invention is further provided.

In the above-described embodiment, warping occurs due to vertical movement between the coil connecting portion 21 and the bending portion 23. When the weight moves up and down at a high speed, a portion near the bending portion reacts later than the speed of the weight When it descends, buckling occurs in a convex shape at the upper part, and it collides with the weight in this process.

In this case, since the durability of the flexible circuit board 2 is deteriorated, the present invention provides a method of manufacturing the flexible circuit board 2 in which, when the refracted path, that is, the second curved portion 237 is formed, The curved portion 237 extends vertically so that the portion width is the same as the entire width of the curved portion and has flexibility. However, the actual width of the third straight portion 236, which is responsive to the motion, Therefore, the increased width serves to prevent buckling by reducing the ductility.

1: Linear vibration motor
11: Case 12: Bracket
13: Magnet 14: Coil
15: weight 16: spring
17: Flexible circuit board
171: coil connection part 172: power connection part
173: Bend
2: Flexible circuit board
21: coil connection
211: tightly fixed portion 212: second power connection portion
22: Power connection
221: first power connection part 222: taper part
23: Bend
231: first curved portion 232: first straight portion
233: first semicircular curved portion 234: second straight line portion
235: second semicircular curved portion 236: third straight line portion
237: second curved portion

Claims (8)

A coil connecting portion 21 and a power connecting portion 22 for connecting a coil and an external power source at both ends in a linear vibration motor including a magnet fixed at the center of the case bottom and a weight through which a magnet penetrates and a coil is mounted, And a bent portion 23 extending between the bent portions 23 to supply external power to the coils.
The bent portion 23 includes a first curved portion 231 extending integrally with the tapered portion 222 and curved in an arc shape and a first rectilinear portion 232 extending straightly from the first bent portion 231, A first semicircular curved portion 233 bent in an arc shape in a direction different from the first rectilinear section 232, a second rectilinear section 234 extending straight in the first semicircular bent portion 233, A second semi-circular curved portion 235 bent in an arc shape in a direction different from the second rectilinear portion 234 in the second rectilinear portion 234 and a third rectilinear portion 235 extending in a straight line in the second semi-circular bent portion 235, (236).
The coil connection part 21 is formed in a circular arc shape of 90 to 180 ° and is integrally connected to the third rectilinear part 236 at an intermediate point and tightly fixed to the bottom of the weight, And a second power supply connection part (212) extending from the linear part (236) to one side of the tight fitting part (211) and electrically connected to the coil. The linear vibration type linear vibration motor according to claim 1,
And a spring for connecting and fixing a top surface of the weight and an inner upper portion of the case. The flexible circuit board according to claim 1, wherein the case has a cylindrical shape. 2. The connector of claim 1, wherein the power connection (22) of the flexible circuit board
A first power supply connection part 221 which is in close contact with a bottom surface of the bracket and to which power is applied, and a taper part 222 whose width is narrowed when the bracket extends in the center direction, Flexible circuit board. delete [2] The apparatus according to claim 1, wherein a point of an obtuse angle formed between the third straight line part (236) and the tight fitting part (211) (237). The flexible circuit board according to any one of the preceding claims, The method according to claim 1,
The first semi-circular curved portion 233 is bent in an arc shape at an angle of 180 degrees,
The second rectilinear section 234 extends in an opposite path parallel to the first rectilinear section 232,
The second semi-circular curve portion 235 is bent in an arc shape at an angle of 180 degrees,
And the third rectilinear section (236) extends in an opposite path parallel to the second rectilinear section (234). The method according to claim 6,
And the central axis of the second rectilinear section (234) and the central axis of the magnet are arranged to cross each other in an upper surface space of the magnet. The method according to claim 1,
The first semicircular curved portion 233 is bent in an arc shape at an angle of less than 180 degrees,
The second semicircular curved portion 235 is bent in an arc shape at an angle of less than 180 degrees,
The third rectilinear section 236 extends at an acute angle to the second rectilinear section 234 and extends in a widening shape so that the third rectilinear section 236 is integrally formed at a position offset to the opposite side of the second power connection section 212 of the coil connection section 21 A flexible circuit board for use in a vertical vibration linear motor.

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