KR101321009B1 - Flexible printed circuit board and vibration motor therewith - Google Patents

Abstract

PURPOSE: A flexible printed circuit board (FPCB) and a vibration motor having the same are provided to use a reinforcing opening extending from a center opening to a soldering portion, thereby reinforcing the coupling structure of a coil and the FPCB. CONSTITUTION: A stator includes a coil (32) provided on a base (31). A vibrator is supported on the base. An FPCB (39) is arranged between the base and the coil to electrically connect an external power source to the coil. The FPCB comprises a center opening (390), a pair of soldering portions, and at least one reinforcing openings (394,395). The pair of soldering portions having a pad shape is provided to be radially spaced apart from the center opening. The at least one reinforcing opening extends from the center opening to the soldering portion.

Description

FLEXIBLE PRINTED CIRCUIT BOARD AND VIBRATION MOTOR THEREWITH}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration motor that is employed in a portable terminal and provides vibration to an incoming signal notification or input operation or game function, and in particular, a flexible circuit board electrically connecting a coil disposed inside the vibration motor case and an external power source. It is about.

In general, the vibrating motor used as a silent receiver of a mobile terminal has a short stroke length of the moving part and has a fast vibration characteristic at the start and stop compared to the conventional eccentric rotation type vibration generator due to the elastic force of the elastic member.

The vibrating motor is generally composed of a vibrator including a magnet and a stator supporting the vibrator, and the vibrator is moved by the interaction of the electromagnetic force generated by applying a current to the coil and the magnetic force generated from the magnet to generate vibration. do.

Conventional vibration motors are disclosed in detail in Korean Patent Laid-Open Publication No. 2005-0122101. In addition, a conventional vibration motor has been disclosed in Japanese Patent Laid-Open Publication No. 2008-107506.

In a conventional vibration motor, a flexible circuit board is used to electrically connect a coil disposed inside the vibration motor and an external power source. A conventional technique for preventing coil disconnection in a conventional vibration motor has been disclosed in 'Korean Patent Publication No. 10-2011-28960'.

However, the coil disconnection phenomenon still occurs in the structure in which the coil is mounted on the flexible circuit board in the conventional vibration motor.

1 and 2, a structure of the flexible circuit board 10 employed in the conventional vibration motor will be described. Referring to FIG. 1, the stator includes an outer case 13, a base 11, and a coil 12 provided on the base 11. The vibrator includes a yoke 14, a magnet 15, and a weight 16. The base 11 is a member coupled to the outer case 13. The coil 12 is a coreless coil, which is disposed with the magnet 15 on the base 11 to provide a driving force for the vibrator in interaction with the magnet. In particular, the yoke 14 and the magnet 15 are arranged coaxially with the coil 12 (vibration center axis) to form a vibration force. A plate 18 may be further provided between the magnet 15 and the base 11, and an elastic body 17 may be provided between the plate 18 and the base 11. The plate 18 is made of a magnetic material, and constitutes an external magnetic field leakage preventing and magnetic closing circuit. That is, since the plate 18 is a magnetic material, the magnetic circuit generated by the yoke 14 and the magnet 15 is concentrated toward the center where the coil 12 is located. The elastic body 17 is an elastic force is generated in a direction away from the upper end and the lower end. In addition, a flexible circuit board is used to electrically connect the coil to an external power source, not shown. The flexible circuit board 19 is mounted on the base 11, and the coil 12 is mounted concentrically. Adhesive 20 is applied to reinforce the bond between the coil 12 and the flexible circuit 19.

As shown in FIGS. 2 and 3, the flexible circuit board 19 employed in the conventional vibration motor has a circular center opening 190 at the center and a region to which the coil is attached around the center opening 190. 192, and a soldering region 193 for connecting the coil start leader line 123 drawn in the radial direction and the coil end leader line 124 has a shape extending in the radial direction.

4 and 5, the coil 12 employed in the conventional vibration motor is a coreless coil manufactured by winding a coil wire a plurality of times. The start lead line 123 and the end lead line 124 are used. The start lead line 123 and the end lead line 124 are drawn in a radial direction from the center to be soldered to the soldering region 193 of the flexible circuit board.

The conventional coreless coil has a shape of a core jig having a structure in which a winding is started from an inner diameter portion to an outer diameter portion and the winding is finished at the outer diameter portion. Therefore, the coreless coil 12 is located at the start lead line 123 in the inner diameter, the end lead line 124 is in the outer diameter. Also, the start leader line 123 and the end leader line 124 of the coil 12 are located at the bottom 121 of the coil 12, and the start leader line 123 and the end leader line located at the bottom 121. Reference numeral 124 is a structure which is drawn out in the radial direction and in contact with the soldering region.

However, in the assembly process of the conventional vibration motor as described above, the following problems occurred in the assembly process of the coil and the flexible circuit board.

In the process of assembling the flexible circuit board, particularly in the process of attaching the flexible circuit board to the base, the linear part of the flexible circuit board is pulled outward and then attached to the base. At this time, the flexible circuit board is pulled out and is instantaneously stretched, thus causing breakage in the portion P (shown in FIG. 2) between the circular and linear portions of the flexible circuit board. If the part is broken, disconnection of the coil lead line occurs, which causes a driving failure of the vibration motor.

In addition, during the process of assembling the coil concentrically on the flexible circuit board, the coil is pressed on the flexible circuit board, and the disconnection phenomenon of the start lead-out line 123 frequently occurs during the pressing process. The end leader line is located on the outer surface of the coil bottom and is drawn radially in a horizontal state, while the start lead line is located on the inner surface of the coil bottom and traverses the coil bundle portion and then is drawn out in the radial direction. to be. However, in order for the starting lead line to cross the coil bundle at the inner diameter surface, a bent portion S (shown in FIG. 5) is generated, and when the coil is pressed by the flexible circuit board in the bent portion S, a stress is generated. Is generated, and there is a problem that the disconnection phenomenon of the start leader line occurs as the stress develops. This causes a driving failure of the vibration motor.

Accordingly, the present invention provides a flexible circuit board and a vibration motor having the same, which reinforce the coupling structure between the coil and the flexible circuit board in the assembling process of the vibration motor.

In addition, the present invention provides a flexible circuit board and a vibration motor having the same while minimizing the coil disconnection, in particular, the start lead-line disconnection phenomenon of the coil while reinforcing the coupling structure between the coil and the flexible circuit board.

In order to solve the above problems, the flexible circuit board according to the present invention includes a stator including a base, and a coil provided on the base; A vibrator supported on the base; And a flexible circuit board positioned between the base and the coil to electrically connect an external power source to the coil, the flexible circuit board of the vibration motor comprising: a center opening; A soldering portion provided at a radially spaced position in which the start lead line and the end lead line of the coil are positioned in the central opening; And at least one reinforcing opening extending from the central opening to the soldered portion.

The present invention also provides a vibrator including a magnet; And a stator having a base, a flexible circuit board provided on the base, and a coil provided on the flexible circuit board, wherein the flexible circuit board electrically connecting the coil to an external power source. A circular portion having a center; A linear portion extending radially from the circular portion; A soldering portion provided at a position spaced apart from the center toward the linear portion; And at least one reinforcing opening extending toward the soldering portion, filled with an adhesive, and allowing the coil to be connected to the base by the filled adhesive to reinforce the coupling state of the flexible circuit board and the coil.

The present invention also provides a vibration motor comprising: a base; A flexible circuit board having a circular portion having a center and a linear portion extending radially from the circular portion, and attached to the base; And a coreless coil mounted concentrically on the circular portion, wherein the flexible circuit board has at least one reinforcing opening extending from the circular portion toward the linear portion, and the reinforcing opening is filled with adhesive. Reinforcing the coupling state of the coil and the flexible circuit board disposed on the base.

As described above, the present invention reinforces the coupling structure between the coil and the flexible circuit board employed in the vibration motor. In particular, the present invention prevents the starting lead wire disconnection phenomenon of the coil.

1 is a cross-sectional view showing a configuration of a vibration motor employing a conventional flexible circuit board.
2 is a plan view showing a conventional flexible circuit board employed in the vibration motor.
3 is a plan view showing a state in which a coil is mounted on a conventional flexible circuit board.
4 is a plan view showing a coreless coil employed in a vibration motor.
5 is a bottom view showing a coreless coil employed in a vibration motor.
6 is a cross-sectional view showing the configuration of a vibration motor employing a flexible circuit board according to a first embodiment of the present invention.
7 is a plan view showing a flexible circuit board according to a first embodiment of the present invention.
8 is a plan view illustrating a coil mounted on a flexible circuit board according to a first embodiment of the present invention.
9 is an enlarged cross-sectional view illustrating a coupling state of a flexible circuit board, a coil, and a base according to the first embodiment of the present invention;
10 is a plan view illustrating a flexible circuit board according to a second exemplary embodiment of the present invention.
11 is a plan view illustrating a flexible circuit board according to a third exemplary embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described the present invention. Like reference numerals refer to like elements.

6 to 9, a configuration of the flexible circuit board 39 and the vibration motor 30 including the same according to the first embodiment of the present invention will be described.

As shown in FIG. 6, the vibration motor 30 employing the flexible circuit board 39 according to the first embodiment of the present invention is located at a predetermined position of an information communication device, for example, a cellular phone or a smart phone. A small component that is employed to generate vibration in a silent incoming call notification, input work or game function, includes a stator, a vibrator, an elastic body 37 and a flexible circuit board 39.

The stator may include an outer case 33, a base 31, and a coil 32 provided on the base 31. The vibrator may include a yoke 34, a magnet 35, and a weight 36. The stator and the vibrator are relative to each other, the stator means a part fixed to the vibrator, and the vibrator is supported by the stator and means a part vibrating up and down about the oscillation axis when a current is applied. Alternatively, the magnet is fixed to the base, the coil may be composed of a part of the vibrator.

The outer case 33 is a member forming a coin shape of the vibration motor 30 together with the base 31, and is configured in a simple cover shape and may be formed of a magnetic body or a non-magnetic body. The base 31 is a member coupled to the bottom of the outer case 33. The coil 32 is a coreless coil, which is disposed on the base 31 together with the magnet 35 to provide a driving force for the vibrator in interaction with the magnet. In particular, the yoke 34 and the magnet 35 are arranged coaxially with the coil 32 (vibration center axis) to form a vibration force.

The vibrator includes a yoke 34 and a magnet 35 for providing a magnetic circuit together with the yoke 34 and for providing a vibration force with the coil 32. In addition, the magnet 35 may further include a weight body 36. The yoke 34 is a place where the magnet 35 is mounted, and is a member of a metal, that is, a magnetic material, which forms a magnetic circuit together with the magnet 35. The magnet 35 is formed in a ring shape, the bottom surface of which is attached in surface contact with the plate 38 to be described later. In addition, the outer diameter surface of the magnet 35 may be provided with a nonmagnetic material so that the magnetic circuit of the vibration motor 30 is concentrated toward the center.

A plate 38 may be further provided between the magnet 35 and the base 31, and in particular, an elastic body 37 may be provided between the plate 38 and the base 31. The plate 38 is mounted on the bottom surface of the magnet 35 to maintain a close contact with the elastic body 37. The plate 38 is made of a magnetic material to form an external magnetic field leakage prevention and magnetic closure circuit. That is, since the plate 38 is a magnetic material, the magnetic circuit generated by the yoke 31 and the magnet 35 is concentrated toward the center of the coil 32. The plate 38 has a ring shape, and the inner diameter portion may be circular or polygonal, and the outer diameter portion may be smaller than or equal to the outer diameter of the magnet 35.

The elastic body 37 has a semi-conical shape, and the lower end portion has a larger diameter than the upper end portion, so that the elastic body 37 is stably disposed on the base 31. In addition, the elastic body 37 is an elastic force is generated in a direction away from the upper end and the lower end.

In addition, a flexible circuit 29 is used to electrically connect the coil 32 disposed in the vibration motor 30 to an external power source (not shown). The flexible circuit board 39 is disposed concentrically with the coil 32 on the base 31, and is located in parallel between the base and the coil. At this time, the vibration motor 30 applies a liquid adhesive 40 to the outer circumferential region of the bottom of the coil 32 to firmly bond the coil 32 to the base 31 and the flexible circuit board 39. do. A detailed coupling structure between the flexible circuit board, the coil, and the base will be described later.

6, the configuration of the flexible circuit board 39 according to the first embodiment of the present invention will be described.

The flexible circuit board 39 is a member that electrically connects the coil 32 inside the vibration motor 30 to an external power source (not shown). The flexible circuit board 39 is divided into a circular portion 39a and a linear portion 39b. do. The circular portion 39a is a portion disposed inside (the outer case) of the vibration motor 30, and the linear portion 39b is a portion located outside (the outside of the circular case). The flexible circuit board 39 includes a center c, a coil attachment part 392, a pair of solder parts 391, and reinforcing openings 394 and 395. A center opening 390 may be further provided at the center c.

The central opening 210 is formed in the center c of the circular portion 39a and is concentric with the coil 32. The center opening 390 is only an opening for concentricity, and may not be configured in the flexible circuit.

The soldering portion 391 is provided in pairs in a pad shape at a position spaced apart from the central opening 390 in the radial direction (coil start line and end line withdrawal directions). The soldering portion 391 refers to a land region to which the start lead line and the end lead line of the coil are soldered and connected. In addition, the flexible circuit 39 includes a pair of external power input units 393 to be spaced apart from the pair of soldering portions 391.

The reinforcing openings 394 and 395 extend radially from the center c and / or the center opening 390 and extend to the soldering portion 391. The reinforcing openings 394 and 395 are formed of two openings, each of which includes a first reinforcing opening 394 and a second reinforcing opening 395. The first reinforcing opening 394 is an inner opening in communication with the central opening 390, and the second reinforcing opening 395 is in communication with the first reinforcing opening 394, but located outside. This means an open opening to the soldering portion 391. In particular, the first reinforcing opening is located close to the coil attachment portion, and when the coil 32 is mounted on the flexible circuit 39, a portion of the bottom surface of the coil 32 and the first and second reinforcing openings are provided. Is filled with adhesive in the face-to-face state. 8 illustrates a state in which a coil is mounted on the flexible circuit board.

When the coil 32 is attached to the flexible circuit board 39, the inner diameter of the coil 32 is approximately equal to the outer circumference of the central opening 390, and the outer diameter of the coil 32 is the inner diameter of the coil attaching portion 392. Is approximately the same as

The first and second reinforcing openings 394 and 395 preferably extend linearly from the center opening 390 to the soldering portion 391, but are not necessarily limited to the linearity.

As shown in FIGS. 8 and 9, in the assembling process, the vibration motor 30 has a flexible circuit board 39 attached to the base 31 and coils concentrically with the flexible circuit board 39. 32 is mounted. Subsequently, an adhesive 40 is applied along the lower peripheral area of the coil 32 to reinforce the bonding state between the flexible circuit board 39 and the coil 32. When the adhesive 40 is applied, the adhesive is filled in the first and second reinforcing openings 394 and 395, particularly the second reinforcing opening 395 provided in the flexible circuit. Therefore, the adhesive 40 has a structure in direct contact with the base 31, the flexible circuit board, the coil 32 and the base 31 is composed of a body. That is, the first and second reinforcing openings 394 and 395 provided in the flexible circuit board reinforce the coupling state of the flexible circuit board and the coil.

Referring to FIG. 10, a configuration of a flexible circuit board 49 according to a second embodiment of the present invention will be described.

The flexible circuit board 49 is divided into a circular portion 49a and a linear portion 49b. The circular portion 49a is a portion disposed inside (the outer case) of the vibration motor, and the linear portion 49b is a portion located outside (the outside of the circular case). The flexible circuit board 49 includes a center c, a coil attaching portion 492, a pair of soldering portions 491, and first and second reinforcing openings 494 and 495. A center opening 490 may be further provided at the center c. The center opening 490 is only an opening for concentricity, and may not be configured in the flexible circuit board.

The soldering portion 491 is provided in pairs in a pad shape at a position spaced apart from the center opening 490 in the radial direction (coil start line and end line withdrawal directions). The soldering portion 491 refers to a land region to which the start lead line and the end lead line of the coil are soldered and connected. The flexible circuit board 49 includes a pair of external power input units 493 to be spaced apart from the pair of soldering portions 491.

The first reinforcing opening 494 reinforces the coupling structure of the coil and the flexible circuit board 49 and also serves to prevent coil disconnection. The coreless coil is provided with a start lead wire and an end lead wire, and the start lead wire and the end lead wire are connected toward the soldering portion 491. Since the starting lead line is bent at the coil bottom inner diameter and directed to the soldering portion 491, coil breakage may occur at the bent portion. If the coil is applied concentrically to the flexible circuit board in the bent state of the start lead line, there is a fear that the coil break occurs in the bent portion.

However, the stress applied to the bent state of the starting leader line by the first reinforcing opening 494 is alleviated, thereby performing two functions.

The first and second reinforcing openings 494 and 495 extend in the radial direction (coil leader line direction) from the center c and / or the center opening 390, respectively. The first reinforcing opening 494 is an inner fan-shaped opening communicating with the center opening 490, and the second reinforcing opening 495 is in communication with the first reinforcing opening 494. Located on the outside, it is an open straight opening to the soldering portion 491. In particular, the first reinforcing opening 494 is located close to the coil attachment portion 492, and when the coil is attached to the flexible circuit board, the first reinforcing opening 494 is in contact with a portion of the bottom surface of the coil.

The flexible circuit board 49 is filled with adhesive by the first and second reinforcing openings 494 and 495, so that the flexible circuit board and the coil are structurally reinforced on the base. Since the reinforcing structure in which the adhesive is filled in the openings for the first and second reinforcing parts has already been described in detail, it will be omitted.

In addition, the first reinforcing opening 494 may be configured to have a size equal to or greater than a region including the start lead line and the end lead line of the coil. Since the start lead line and the end lead line of the coil are respectively drawn out in the soldering portion 491, that is, in the radial direction, at the coil inner diameter and the outer diameter, the shape of the first reinforcing opening 494 is also preferably configured as a fan shape. . However, the shape of the first reinforcing opening 494 need not be limited to a fan shape, and may be variously changed as long as the shape includes the start lead line and the end lead line of the coil.

A configuration of a flexible circuit board 59 according to a third embodiment of the present invention will be described with reference to FIG. 11. The flexible circuit board 59 has a reinforcing opening 594 between the male solder portions 591. The reinforcing opening 594 extends linearly in the radial direction from the center. The reinforcing opening 594 is provided at a radially spaced position from the center c or the center opening 590 to fill the adhesive when the adhesive is applied. Since the reinforcing opening 594 is filled with an adhesive to reinforce the coupling state between the coil and the flexible circuit board, the configuration will be omitted since it has been described in detail.

Claims (18)

A stator including a base and a coil provided on the base;
A vibrator supported on the base; And
In the flexible circuit board of the vibration motor comprising a flexible circuit board positioned between the base and the coil to electrically connect an external power source to the coil,
Center opening;
A soldering portion provided at a radially spaced position in which the start lead line and the end lead line of the coil are positioned in the central opening; And
And at least one reinforcing opening extending from the central opening to the soldered portion. The flexible circuit board of claim 1, wherein the reinforcing opening comprises a first reinforcing opening facing the bottom of the coil. The flexible circuit board of claim 1, further comprising a second reinforcing opening positioned between the soldering portions. The flexible circuit board of claim 1, wherein the central opening communicates with the reinforcing opening. The flexible circuit board of claim 1, wherein the reinforcing opening is linear. The flexible circuit board of claim 1, wherein the reinforcing opening comprises a first opening having a fan shape extending in a radial direction from the center opening. 7. The flexible circuit board of claim 6, wherein the reinforcing opening includes a second linear opening in communication with the first opening and positioned between the soldering portions. delete A vibrator comprising a magnet; And
A vibration motor comprising a stator having a base, a flexible circuit board provided on the base, and a coil provided on the flexible circuit board,
Flexible circuit board for electrically connecting the coil to an external power source
A circular portion having a center;
A linear portion extending radially from the circular portion;
A soldering portion provided at a position spaced apart from the center toward the linear portion; And
And at least one reinforcing opening extending toward the soldering portion, filled with an adhesive, and connected to the base by the filled adhesive, thereby reinforcing the bonded state of the flexible circuit board and the coil. Vibration motor made. The vibration motor according to claim 9, wherein the center is provided with a center opening, and the center opening communicates with the reinforcing opening. 11. The method of claim 10 wherein the reinforcing opening is
A first reinforcing opening extending in the radial direction from the central opening and facing the bottom of the coil; And
And a second reinforcing opening extending from said first reinforcing opening and positioned between said soldering portions. 10. The vibration motor according to claim 9, wherein the center has a central opening, and the reinforcing opening is located between the soldered portion spaced apart from the central opening. 12. The vibrating motor according to claim 11, wherein the sector-shaped first reinforcing opening includes a region in which a start lead line and an end lead line of the coil exist. The vibration motor according to any one of claims 9 to 13, wherein the coil is a coreless coil. In a vibration motor,
Base;
A flexible circuit board having a circular portion having a center and a linear portion extending radially from the circular portion, and attached to the base; And
Consists of a coreless coil mounted concentrically on the circular portion,
The flexible circuit board has at least one reinforcing opening extending from the circular portion toward the linear portion, and an adhesive is filled in the reinforcing opening to reinforce the coupling state of the coil and the flexible circuit board disposed on the base. Vibration motor characterized in that. The vibration motor of claim 15, wherein the reinforcing opening extends in a radial direction from the circular portion. The vibration motor of claim 15, wherein the reinforcing opening is formed at a radially spaced position from the center of the flexible circuit board. The vibration motor of claim 15, wherein the reinforcing opening is positioned between a pair of soldering portions provided on the flexible circuit board.

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