KR101101437B1 - Vibration motor of flat type - Google Patents

Abstract

PURPOSE: A vibration motor of a flat type is provided to prevent damage to a magnet due to external impact by contacting a bottom bracket and a flexible circuit board. CONSTITUTION: A lower bracket(310) is fixed to one end of a shaft. An upper case(320) is combined with the lower bracket to form an internal space therein. A bearing member(370) includes a mounting hole through which the shaft is penetrated. A rotor(380) is rotated with being interlinked with the bearing member. A spacer(390) has an installation hole through which the shaft is penetrated. The upper and lower magnets(340,350) are installed in the lower bracket and the upper bracket.

Description

Flat Vibration Motors {VIBRATION MOTOR OF FLAT TYPE}

The present invention relates to a flat vibration motor, and more particularly to a flat vibration motor for generating vibration by the rotation of the rotor which is the eccentric rotor.

In portable electronic devices such as mobile phones, game consoles and portable information terminals, various types of vibration generating devices are mounted on the portable electronic devices to prevent discomfort to others by external sounds.

In general, the flat vibration motor is widely used as a receiving means of the portable terminal mainly because the vibration can be sufficiently exhibited even in the state of shortening, lightening, and slimming.

On the other hand, in recent years, many touch screens have been adopted in which a character or other menu displayed on a screen that is a display device of a portable terminal is touched with a hand or a pen to simply input a signal.

In addition, a flat vibration motor is installed in the portable terminal to allow a user to feel a touch when the screen is touched by the portable terminal.

In addition, the flat vibration motor must have a fast response speed in order to make the user feel the touch when the screen is touched.

However, when the washer is mounted on the shaft of the flat vibration motor in order to have a fast response speed, there is a problem that the rotation of the rotor is unstable because the support structure of the bearing mounted with the washer on the shaft is not firm.

An object of the present invention is to provide a flat motor that can reduce the damage of the magnet by an impact applied from the outside.

In addition, an object of the present invention is to provide a flat vibration motor that can more firmly support the bearing to reduce the rotational instability of the rotor.

In addition, an object of the present invention is to provide a high-response flat vibration motor having a high response speed by reducing the friction area.

The flat vibration motor according to the present invention includes a lower bracket having one end fixed to the shaft, an upper end fixed to the other end of the shaft, and an upper case coupled to the lower bracket to form an inner space, and mounted to penetrate the shaft. It includes a bearing member having a mounting hole, and a mounting portion in which the bearing member is press-mounted therein extends upward in the axial direction, and a rotor which rotates in conjunction with the bearing member.

The flat vibration motor may further include a spacer fixed to the upper case so as to reduce the friction area of the bearing member with the shaft, and having an installation hole through which the shaft penetrates.

The rotor may have a protrusion extending upwardly from the mounting portion in an axial direction to reduce a friction area with the spacer.

A bottom of the rotor may be supported by a lower rib of the lower bracket into which the shaft is inserted and coupled, and a support portion extending downward in an axial direction to correspond to the mounting portion.

The flat vibration motor may further include upper and lower magnets installed on the lower bracket and the upper case to face the coil provided in the rotor.

The flat vibration motor is mounted on the lower bracket but has a body portion which is in contact with the lower magnet so as to prevent breakage of the lower magnet by an impact from the outside, and a flexible circuit board having an extension portion extending from a portion of the body portion. It may further include.

The lower bracket may be provided with a mounting groove into which the flexible circuit board is inserted and mounted such that the body portion and the lower magnet are not in contact with each other.

The lower bracket may be formed to be disposed on the bottom edge of the lower magnet, and may have an inflow groove into which an excess adhesive flows in when the lower magnet is attached.

The lower bracket may be provided to be in contact with the outer circumferential surface of the lower magnet and may have an installation guide part for guiding the mounting position of the lower magnet.

The upper case is provided with an upper rib formed with an insertion groove into which one end of the shaft is inserted, and the insertion groove may include an elastic member for providing an elastic force to the shaft.

According to the present invention, by installing the flexible circuit board on the lower bracket so that the body portion of the flexible circuit board does not contact the lower magnet, there is an effect that can reduce the damage to the lower magnet by the impact from the outside.

That is, when the bottom of the lower magnet is in contact with the lower bracket and the flexible circuit board having different elastic strains, and the impact is applied from the outside, the damage of the lower magnet may be reduced due to the difference in the strain between the lower bracket and the flexible circuit board. It works.

In addition, according to the present invention, the bearing member can be more firmly supported through the rotor having a mounting portion inserted therein, thereby reducing the rotational instability of the rotor.

In addition, the present invention has the effect of realizing a high response with a fast response speed by reducing the friction area with the spacer through the protrusion extending from the mounting portion.

In addition, according to the present invention, by reducing the friction area between the shaft and the bearing member through the spacer and reducing the friction area between the spacer and the upper surface of the bearing member through the inclined portion of the bearing member, the driving torque of the rotor can be increased. It is effective to realize high response with fast response speed.

1 is a schematic cross-sectional view showing a flat vibration motor according to a first embodiment of the present invention.
2 is an exploded perspective view showing a lower bracket, a flexible substrate, and a lower magnet according to a first embodiment of the present invention.
3 is a schematic perspective view showing a rotor according to a first embodiment of the present invention.
4 is a schematic cross-sectional view showing a flat vibration motor according to a second embodiment of the present invention.
5 is a schematic cross-sectional view showing a flat vibration motor according to a third embodiment of the present invention.
6 is a schematic perspective view showing a rotor according to a third embodiment of the present invention.
7 is a schematic cross-sectional view showing a flat vibration motor according to a fourth embodiment of the present invention.
8 is a schematic cross-sectional view showing a flat vibration motor according to a fifth embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments which fall within the scope of the inventive concept may be easily suggested, but are also included within the scope of the present invention.

In addition, in describing the present invention, when it is determined that a detailed description of related known functions or phrases may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, a flat vibration motor according to a first embodiment of the present invention will be described with reference to the drawings.

1 is a schematic cross-sectional view showing a flat vibration motor according to a first embodiment of the present invention, Figure 2 is an exploded perspective view showing a lower bracket, a flexible substrate, and a lower magnet according to a first embodiment of the present invention, 3 is a schematic perspective view showing a rotor according to a first embodiment of the present invention.

1 to 3, the flat vibration motor 100 according to an embodiment of the present invention includes a lower bracket 110, an upper case 120, a shaft 130, a lower magnet 140, and an upper magnet ( 150, a flexible circuit board 160, a bearing member 170, a rotor 180, and a spacer 190.

Here, when defining the term for the direction, the axial direction refers to the up and down direction relative to the shaft 130, as shown in Figure 1, the radial direction relative to the outer end of the rotor 180 or relative to the shaft 130 Means the center direction of the shaft 130 with respect to the outer end of the rotor 180, the circumferential direction means the direction to rotate along the outer peripheral surface of the shaft (130).

One end of the lower bracket 110 is fixed to the shaft 130, and for this purpose, the lower bracket 110 is formed with a lower rib 111 into which one end of the shaft 130 is inserted. The lower rib 111 has a shaft support groove 111a into which the shaft 130 is inserted.

In addition, the lower bracket 110 may be provided to contact the outer circumferential surface of the lower magnet 140 may include an installation guide 112 to guide the mounting position of the lower magnet 140. The installation guide 112 may be formed of a stepped portion contacting the outer circumferential surface of the lower bracket 110, and the outer circumferential surface of the lower magnet 140 contacts the installation guide 112 formed of the stepped portion when the lower magnet 140 is installed. By doing so, the lower magnet 140 can be mounted at a certain position.

In addition, the lower bracket 110 is formed to be disposed on the bottom edge of the lower magnet 140 when the lower magnet 140 is mounted to include an inflow groove 113 into which the surplus adhesive applied to the lower magnet 140 is introduced. Can be.

That is, an adhesive for adhesion to the lower bracket 110 is applied to the bottom of the lower magnet 140, and the inflow groove 113 allows the excess adhesive applied to the bottom of the lower magnet 140 to flow into the lower magnet 140. ) To prevent contamination by the excess adhesive applied to the).

The lower bracket 110 may be provided with a mounting groove 114 into which the flexible circuit board 160 is inserted. Details of the mounting groove 114 will be described later.

The upper case 120 is fixed to the other end of the shaft 130, is coupled to the lower bracket 110 to form an internal space.

That is, the upper case 120 may be provided with an upper rib 122 having a shaft groove 121 in which the other end of the shaft 130 is inserted. In addition, the upper case 120 may be formed to have a cup shape to be coupled to the lower bracket 110 to block the inflow of dust or foreign matter from the outside to protect the inside.

On the other hand, both ends of the shaft 130 are fixed to the lower bracket 110 and the upper case 120. That is, one end of the shaft 130 is inserted into the shaft support groove 111a formed in the lower rib 111 of the lower bracket 110, and the shaft groove 121 formed in the upper rib 122 of the upper bracket 120. The other end is installed and fixed.

In addition, the shaft groove 121 in which the other end of the shaft 130 is inserted may be interposed with an elastic member 135 that provides an elastic force to the shaft 130. That is, when the shaft 130 floats when the rotor 180 rotates, an elastic member 135 that provides an elastic force to the shaft 130 may be inserted into the shaft groove 121.

The lower magnet 140 is installed to be disposed at the edge of the lower bracket 110. In addition, the lower magnet 140 serves to rotate the rotor 180 by the electromagnetic interaction. To this end, the lower magnet 140 may be formed to have an annular ring shape.

In addition, the upper magnet 150 is fixedly installed in the upper case 120 to be disposed in the inner space formed by the lower bracket 110 and the upper case 120, by the electromagnetic interaction with the lower magnet 140 It serves to rotate the rotor 180. The upper magnet 150 may also be formed to have an annular annular shape.

The flexible circuit board 160 is installed on the lower bracket 110, and the body portion 162 and the body portion 162 which are not in contact with the lower magnet 140 to prevent breakage of the lower magnet 140 by the impact from the outside. It may have an extension 164 extending from a portion of the).

That is, the flexible circuit board 160 is inserted into and mounted in the mounting groove 114 provided in the lower bracket 110, and the mounting groove 114 is inserted into and mounted in the mounting groove 114. The bottom surface of the lower magnet 140 is formed so as not to contact the body portion 162 of the flexible circuit board 160.

In other words, when the flexible circuit board 160 is mounted in the mounting groove 114, the mounting groove 114 may not allow the body 162 of the flexible circuit board 160 to contact the bottom surface of the lower magnet 140. May be formed on the lower bracket 110 so as not to interfere with the mounting position of the lower magnet 140.

On the other hand, as the flexible circuit board 160 is inserted into the mounting groove 114, the thickness increase of the flat vibration motor 100 by the flexible circuit board 160 can be further reduced.

As such, since the body 162 of the flexible circuit board 160 is not in contact with the lower magnet 140, damage to the body 162 of the lower magnet 140 due to external impact can be reduced.

Looking at this in more detail, the lower bracket 110 is made of a metal material that is a magnetic material, the flexible circuit board 160 is made of a synthetic resin material. Accordingly, the elastic strain of the lower bracket 110 and the flexible circuit board 160 are different from each other.

As such, when the lower magnet 140 is mounted such that portions of the lower magnet 110 and the flexible circuit board 160 having different elastic strains are in contact with each other, that is, a portion of the bottom surface of the lower magnet 140 is lower bracket ( When mounted in a state spanning 110 and the flexible circuit board 160, when an impact is applied from the outside, the amount of impact transmitted to the lower magnet 140 through the lower bracket 110 and the flexible circuit board 160 is different from each other. . Accordingly, the lower magnet 140 is damaged in a portion mounted in a state spanning the lower bracket 110 and the flexible circuit board 160.

However, since the body 162 of the flexible circuit board 160 according to the present invention is mounted on the lower bracket 110 so that the body portion 162 is not in contact with the lower magnet 140, the lower magnet 140 is connected to the lower bracket 110 and the flexible circuit board. It is possible to reduce the breakage caused by the difference in the elastic strain of (160).

The bearing member 170 has a mounting hole 171 into which the shaft 130 is inserted. That is, the bearing member 170 is mounted to the shaft 130.

The rotor 180 is mounted to the bearing member 170 such that the outer circumferential surface of the bearing member 170 is press-fitted, and has a coil 182 disposed to face the lower magnet 140 to rotate together with the bearing member 170. do.

That is, the coil 182 provided in the rotor 180 allows the rotor 180 to rotate through electromagnetic interaction with the lower magnet 140 and the upper magnet 150.

In addition, the rotor 180 may be provided with a weight 186 to be rotated by an eccentric rotor, and the coil 182 may be provided to be disposed at both sides of the weight 186.

In addition, a circuit board 184 is provided at a bottom of the rotor 180, and a commutator (not shown) is connected to a bottom of the circuit board 184 to be electrically connected to the flexible circuit board 160. ) May be provided.

That is, power is applied in order of the flexible circuit board 160, the brush (not shown), the commutator (not shown) of the circuit board 184, and the coil 182 of the rotor 180. The rotor 180 is rotated by electromagnetic interaction with the upper and lower magnets 140 and 150.

At this time, since the weight 186 is provided in the rotor 180, the rotor 180 is eccentrically rotated.

On the other hand, since the flat vibration motor 100 according to an embodiment of the present invention includes upper and lower magnets 140 and 150, the driving torque generated in proportion to the increased magnetic flux density is increased. Accordingly, the time to reach the normal vibration is faster, it is possible to implement a fast response speed.

The spacer 190 is fixedly installed on the upper case 120 to reduce the friction area of the bearing member 170 with the shaft 130, and an installation hole 192 through which the shaft 130 penetrates is formed.

That is, the spacer 190 is fixedly installed on the upper case 120 to be disposed above the bearing member 170, and has a mounting hole 192 through which the shaft 130 penetrates. Accordingly, the length of the bearing member 170 may be reduced as compared with the case where the spacer 190 is not provided.

As a result, the contact area of the inner circumferential surface of the bearing member 170 in contact with the outer circumferential surface of the shaft 130 may be reduced, thereby reducing the friction area between the bearing member 170 and the shaft 130 to reduce the driving torque. Can be.

Therefore, the time to reach the normal vibration is faster to implement a faster response speed.

The spacer 190 serves to space the coil 182 of the rotor 180 from the upper magnet 150 by a predetermined distance. That is, the spacer 190 serves to mount the rotor 180 so that the coil 182 and the upper magnet 150 do not interfere when the rotor 180 rotates.

In addition, the spacer 190 serves to provide an elastic force when the bearing member 170 and the rotor 180 float by the rotation of the rotor 180. That is, when the rotor 180 is rotated, the rotor 180 and the bearing member 170 are floated a predetermined distance by the rotation, and the spacer 190 is the rotor 180 is returned to its original position when the rotation of the rotor 180 is stopped. Resilience may be provided to allow for recovery.

As described above, by installing the flexible circuit board 160 to the lower bracket 110 so that the body portion 162 of the flexible circuit board 160 does not contact the lower magnet 140, by an impact applied from the outside. It is possible to reduce the damage of the lower magnet 140.

That is, when a part of the bottom surface of the lower magnet 140 contacts the lower bracket 110 and the flexible circuit board 160 having different elastic strains and is impacted from the outside, the lower bracket 110 and the flexible circuit board are exposed. The breakage of the lower magnet 140 may be reduced due to the difference in elastic strain of the 160.

Hereinafter, a flat vibration motor according to another embodiment of the present invention will be described with reference to the drawings. However, the same components as those described in the above embodiments will be replaced with the above description, and detailed description thereof will be omitted herein.

4 is a schematic cross-sectional view showing a flat vibration motor according to a second embodiment of the present invention.

Referring to FIG. 4, the flat vibration motor 200 according to the second embodiment of the present invention may include a lower bracket 210, an upper case 220, a shaft 230, a lower magnet 240, and an upper magnet 250. , A flexible circuit board 260, a bearing member 270, a rotor 280, and a spacer 290.

Here, when defining the term for the direction, as shown in Figure 4, the axial direction refers to the up and down direction relative to the shaft 230, the radial direction relative to the shaft 230, or the outer end direction of the rotor 280 The outer direction of the rotor 280 means the center direction of the shaft 230, the circumferential direction means the direction of rotation along the outer peripheral surface of the shaft 230.

On the other hand, the lower bracket 210, the upper case 220, the shaft 230, the lower magnet 240, the upper magnet 250, the flexible circuit board of the flat vibration motor 200 according to another embodiment of the present invention 260, the rotor 280, and the spacer 290 are the lower bracket 110, the upper case 120, the shaft 130, and the lower magnet of the flat vibration motor 100 according to the embodiment of the present invention described above. It corresponds to the same components as the 140, the upper magnet 150, the flexible circuit board 160, the rotor 180, and the spacer 190, and a detailed description thereof will be omitted and replaced with the above description. .

Hereinafter, a bearing member 170 and another bearing member 270 according to an embodiment of the present invention will be described.

The bearing member 270 has a mounting hole 271 into which the shaft 230 is inserted. That is, the bearing member 270 is mounted to the shaft 230.

In addition, the bearing member 270 is formed with an inclined portion 272 on the upper side to reduce the friction area with the spacer 290. That is, when the bearing member 270 is rotated in conjunction with the rotor 280 to reduce the friction area between the bearing member 270 and the spacer 290 to the upper side of the bearing member 270 to implement a fast response speed The inclined portion 272 is formed.

In other words, since the inclined portion 272 is formed on the upper side of the bearing member 270, the friction area between the upper surface of the bearing member 270 and the bottom surface of the spacer 290 is reduced, and thus the torque required for rotation. Is reduced.

As a result, the torque required for rotation is reduced by reducing the frictional force, thereby realizing a faster response speed.

According to the flat vibration motor 200 according to another embodiment of the present invention, like the flat vibration motor 100 according to the embodiment of the present invention, the body of the flexible circuit board 260 on the lower magnet 240 By installing the flexible circuit board 260 on the lower bracket 210 so that the part 262 does not contact, it is possible to reduce the damage of the lower magnet 240 by the impact applied from the outside.

That is, when a portion of the bottom surface of the lower magnet 240 contacts the lower bracket 210 and the flexible circuit board 260 having different elastic strains and is impacted from the outside, the lower bracket 210 and the flexible circuit board are exposed. The breakage of the lower magnet 240 may be reduced due to the difference in elastic strain of 260.

In addition, the flat vibration motor 200 according to another embodiment of the present invention, through the inclined portion 272 formed on the upper side of the bearing member 270 as described above, the upper surface of the bearing member 270 and the spacer ( The friction area with the bottom of 290 can be reduced, thereby reducing the torque required for rotation.

As a result, by reducing the friction between the bearing member 270 and the spacer 290, the torque required for rotation is reduced, thereby realizing a faster response speed.

Hereinafter, a flat vibration motor according to a third embodiment of the present invention will be described with reference to the drawings.

5 is a schematic cross-sectional view showing a flat vibration motor according to a third embodiment of the present invention, Figure 6 is a schematic perspective view showing a rotor according to a third embodiment of the present invention.

5 and 6, the flat vibration motor 300 according to the third embodiment of the present invention includes a lower bracket 310, an upper case 320, a shaft 330, a lower magnet 340, and an upper magnet. 350, a flexible circuit board 360, a bearing member 370, a rotor 380, and a spacer 390.

On the other hand, here also defined a term for the direction, as shown in Figure 5, the axial direction refers to the up and down direction relative to the shaft 330, the radial direction of the outer end of the rotor 380 relative to the shaft 330 Direction or the center direction of the shaft 330 with respect to the outer end of the rotor 380, the circumferential direction means the direction of rotation along the outer peripheral surface of the shaft 330.

One end of the lower bracket 310 is fixedly installed, and for this purpose, a lower rib 311 having a shaft support groove 311a into which the shaft 330 is inserted may be formed in the lower bracket 310. .

The lower bracket 310 may include an installation guide 312, and the outer circumferential surface of the lower magnet 340 contacts the installation guide 312 when the lower magnet 340 is installed on the lower bracket 310. By doing so, the lower magnet 340 can be mounted at a certain position.

In addition, the lower bracket 310 is formed to be disposed on the bottom edge of the lower magnet 340 when the lower magnet 340 is mounted to include an inlet groove 313 into which the surplus adhesive applied to the lower magnet 340 flows. Can be.

On the other hand, the lower bracket 310 may be provided with a mounting groove 314 into which the flexible circuit board 360 is inserted. In addition, the mounting groove 314 is formed at a position where the flexible circuit board 360 inserted therein and the lower magnet 340 mounted on the lower bracket 310 do not contact each other. Details thereof will be described later.

The upper case 320 is fixedly installed at the other end of the shaft 330, and is coupled to the lower bracket 310 to form an inner space.

That is, the upper case 320 may be provided with an upper rib 322 having a shaft groove 321 into which the other end of the shaft 330 is inserted, and the upper case 320 is coupled to the lower bracket 310. It may be formed to have a cup shape to protect the inside by blocking the inflow of dust or foreign matter from the outside.

Both ends of the shaft 330 are fixed to the lower bracket 310 and the upper case 320. That is, one end of the shaft 330 is inserted into the shaft support groove 311a formed in the lower rib 311 of the lower bracket 310, and the shaft groove 321 formed in the upper rib 322 of the upper bracket 320. The other end is installed and fixed.

In addition, the shaft groove 321 into which the other end of the shaft 330 is inserted may be interposed with an elastic member 335 that provides an elastic force to the shaft 330. That is, when the shaft 330 rises when the rotor 380 rotates, an elastic member 335 providing elastic force to the shaft 330 may be inserted into the shaft groove 321.

The lower magnet 340 is installed to be disposed on the edge of the lower bracket 310. In addition, the lower magnet 340 serves to rotate the rotor 380 by electromagnetic interaction. To this end, the lower magnet 340 may be formed to have an annular ring shape.

In addition, the upper magnet 350 is fixed to the upper case 320 so as to be disposed in the inner space formed by the lower bracket 310 and the upper case 320, and by the electromagnetic interaction with the lower magnet 340 It serves to rotate the rotor 380. In addition, the upper magnet 350 may also be formed to have an annular ring shape.

The flexible circuit board 360 is installed in the lower bracket 310, but is in contact with the lower magnet 340 so as to prevent the lower magnet 340 from being damaged by an impact from the outside, and the body part 362 and the body part 362. It may have an extension 364 extending from a portion of the.

That is, the flexible circuit board 360 is inserted into and mounted in the mounting groove 314 provided in the lower bracket 310, and the mounting groove 314 is inserted into and mounted in the mounting groove 314. The bottom surface of the lower magnet 340 is formed so as not to contact the body portion 362 of the flexible circuit board 360.

In other words, when the flexible circuit board 360 is mounted in the mounting groove 314, the mounting groove 314 may prevent the body 362 of the flexible circuit board 360 from contacting the bottom surface of the lower magnet 340. May be formed in the lower bracket 310 so as not to interfere with the mounting position of the lower magnet 340.

As such, the body portion 362 of the flexible circuit board 360 is not in contact with the lower magnet 340, so that the lower magnet 340 and the body portion 362 of the flexible circuit board 360 are contacted by external impact. The breakage of the lower magnet 340 in the portion can be reduced.

The bearing member 370 has a mounting hole 371 in which the shaft 330 is inserted and mounted. That is, the bearing member 370 is mounted to the shaft 330.

The rotor 380 is mounted to the bearing member 370 such that the outer circumferential surface of the bearing member 370 is press-fitted, and has a coil 382 disposed to face the lower magnet 340 to rotate together with the bearing member 370. do.

That is, the coil 382 provided in the rotor 380 causes the rotor 380 to rotate through electromagnetic interaction with the lower magnet 340 and the upper magnet 350.

In addition, the rotor 380 may be provided with a weight 386 to rotate the eccentric rotor, the coil 382 may be provided to be disposed on both sides of the weight (386).

In addition, a circuit board 384 is provided on the bottom of the rotor 380, and a commutator (not shown) to which a brush (not shown) for electrically connecting to the flexible circuit board 360 is connected to the bottom of the circuit board 384. ) May be provided.

That is, power is applied in order of the flexible circuit board 360, the brush (not shown), the commutator (not shown) of the circuit board 384, and the coil 382 of the rotor 380. The rotor 380 is rotated by electromagnetic interaction with the upper and lower magnets 340 and 350.

At this time, since the weight 386 is provided in the rotor 380, the rotor 380 is eccentrically rotated.

On the other hand, since the flat vibration motor 300 has upper and lower magnets 340 and 350, the driving torque generated in proportion to the increased magnetic flux density is increased. As a result, the time to reach the normal vibration is faster, thereby realizing a faster response speed.

In addition, the mounting portion 389 in which the bearing member 370 is press-mounted therein may be formed in the rotor 380 extending upward in the axial direction. That is, the bearing member 370 is inserted into the mounting portion 389. Accordingly, the bearing member 370 can be supported more firmly.

On the other hand, the bearing member 370 is inserted into the mounting portion 389 to reduce the friction area between the bearing member 370 and the shaft 330, thereby realizing a faster response speed.

That is, the axial length of the bearing member 370 can be reduced, so that the friction area between the inner circumferential surface of the bearing member 370 and the outer circumferential surface of the shaft 330 can be reduced, thereby reducing the torque required for rotation. Accordingly, a faster response speed can be realized.

In addition, the rotor 380 may include a protrusion 387 extending upward from the mounting portion 389 in the axial direction so as to reduce the friction area with the spacer 390. That is, the protrusion 387 is in contact with the spacer 390 fixed to the upper case 320 to reduce the friction area during rotation of the rotor 380 to implement a faster response speed.

To this end, the protrusion 387 may be formed in a shape in which the cross-sectional area is narrowed toward the upper side. That is, the protrusion 387 may be formed to have a conical shape having a wide cross-sectional area at the lower side so that the contact area with the spacer 390 may be reduced.

In addition, the bottom of the rotor 380 is supported by the lower rib 311 of the lower bracket 310 into which the shaft 330 is inserted and coupled, and a support 388 extending downward in the axial direction to correspond to the mounting portion 389. Can be formed.

Accordingly, the support 388 is supported by the lower rib 311, so that the rotor 380 can be rotated more stably, and eventually the driving torque generated in proportion to the increased magnetic flux density by the upper and lower magnets 340 and 350. It is possible to realize stable rotational response even with increasing.

The spacer 390 serves to space the coil 382 of the rotor 380 from the upper magnet 350 by a predetermined distance. That is, the spacer 390 serves to mount the rotor 380 so that the coil 382 and the upper magnet 350 do not interfere when the rotor 380 rotates.

Meanwhile, in the present embodiment, the case in which the spacer 390 is mounted on the shaft 330 is described as an example, but the spacer 390 may be omitted by changing the shape of the mounting portion 389 and the protrusion 387. It may be.

That is, when the mounting portion 389 and the protrusion 387 extend longer in the axial direction, the spacer 390 may not be employed by allowing the protrusion 387 to directly contact the upper case 320.

Hereinafter, a flat vibration motor according to a fourth embodiment of the present invention will be described.

7 is a schematic cross-sectional view showing a flat vibration motor according to a fourth embodiment of the present invention.

Referring to FIG. 7, the flat vibration motor 400 according to the fourth embodiment of the present invention includes a lower bracket 410, an upper case 420, a shaft 430, a lower magnet 440, and an upper magnet 450. , A flexible circuit board 460, a bearing member 470, a rotor 480, and a spacer 490.

Here, when defining terms for the direction, the axial direction refers to the up and down direction with respect to the shaft 430, as shown in Figure 7, the radial direction relative to the outer end direction of the rotor 470 relative to the shaft 430 or The outer direction of the rotor 470 refers to the center direction of the shaft 430, the circumferential direction means the direction of rotation along the outer peripheral surface of the shaft 430.

One end of the lower bracket 410 is fixed to the shaft 430, and for this purpose, a lower rib 411 to which one end of the shaft 430 is inserted is formed in the lower bracket 410. The lower rib 411 is formed with a shaft support groove 411a into which the shaft 430 is inserted.

In addition, the lower bracket 410 may be provided to contact the outer peripheral surface of the lower magnet 440 may be provided with an installation guide 412 for guiding the mounting position of the lower magnet 440. The installation guide part 412 may be formed of a stepped portion contacting the outer circumferential surface of the lower bracket 410, and the outer circumferential surface of the lower magnet 440 contacts the installation guide part 412 formed of the stepped portion when the lower magnet 440 is installed. By doing so, the lower magnet 440 may be mounted at a predetermined position.

In addition, the lower bracket 410 is formed to be disposed on the bottom edge of the lower magnet 440 when the lower magnet 440 is mounted to include an inflow groove 413 into which the surplus adhesive applied to the lower magnet 440 flows. Can be.

That is, an adhesive for adhesion to the lower bracket 410 is applied to the bottom surface of the lower magnet 440, and the inflow groove 413 allows the excess adhesive applied to the bottom surface of the lower magnet 440 to flow into the lower magnet 440. ) To prevent contamination by the excess adhesive applied to the).

In addition, the lower bracket 410 may be provided with a mounting groove 414 into which the flexible circuit board 460 is inserted. That is, the flexible circuit board 460 may be inserted into the mounting groove 414 and may not protrude from the upper surface of the lower bracket 410.

The upper case 420 is fixed to the other end of the shaft 430, it is combined with the lower bracket 410 to form an internal space.

That is, the upper case 420 may be provided with an upper rib 422 having a shaft groove 421 into which the other end of the shaft 430 is inserted. In addition, the upper case 420 may be formed to have a cup shape to be coupled to the lower bracket 410 to block the inflow of dust or foreign matter from the outside to protect the inside.

On the other hand, both ends of the shaft 430 are fixed to the lower bracket 410 and the upper case 420. That is, one end of the shaft 430 is inserted into the shaft support groove 411 a formed in the lower rib 411 of the lower bracket 410, and the shaft groove 421 formed in the upper rib 422 of the upper bracket 420. The other end is installed and fixed.

In addition, the shaft groove 421 into which the other end of the shaft 430 is inserted may be interposed with an elastic member 435 for providing an elastic force to the shaft 430. That is, when the shaft 430 floats when the rotor 480 rotates, an elastic member 435 providing elastic force to the shaft 430 may be inserted into the shaft groove 421.

The lower magnet 440 is installed to be disposed at the edge of the lower bracket 410. In addition, the lower magnet 440 serves to rotate the rotor 480 by electromagnetic interaction. To this end, the lower magnet 440 may be formed to have an annular ring shape.

In addition, the upper magnet 450 is fixed to the upper case 420 so as to be disposed in the inner space formed by the lower bracket 410 and the upper case 420, and by the electromagnetic interaction with the lower magnet 440 It serves to rotate the rotor 480. The upper magnet 450 may also be formed to have an annular annular shape.

The flexible circuit board 460 is installed on the lower bracket 410. That is, the flexible circuit board 460 is inserted into and disposed in the mounting groove 414 of the lower bracket 410. Accordingly, when the lower magnet 440 is installed in the lower bracket 410, the lower magnet 440 is inclined. It can be prevented from being installed.

The bearing member 470 has a mounting hole 471 into which the shaft 430 is inserted. That is, the bearing member 470 is mounted to the shaft 430.

In addition, the bearing member 470 is formed with an inclined portion 472 on the upper side to reduce the friction area with the spacer 490. That is, when the bearing member 470 rotates in conjunction with the rotor 480, the friction area between the bearing member 470 and the spacer 490 is reduced to the upper side of the bearing member 470 so as to realize a fast response speed. The inclined portion 472 is formed.

In other words, since the inclined portion 472 is formed on the upper side of the bearing member 470, the friction area between the upper surface of the bearing member 470 and the bottom surface of the spacer 490 is reduced, and thus the torque required for rotation. Is reduced.

As a result, the frictional force is reduced, so that the torque required for rotation is reduced (in other words, the driving torque for rotating the rotor is increased), and thus a faster response speed can be realized.

The rotor 480 is mounted to the bearing member 470 such that the outer circumferential surface of the bearing member 470 is press-fitted, and has a coil 482 disposed to face the lower magnet 440 to rotate together with the bearing member 470. do.

That is, the coil 482 provided in the rotor 480 allows the rotor 480 to rotate through electromagnetic interaction with the lower magnet 440 and the upper magnet 450.

The rotor 480 may be provided with a weight 186 (see FIG. 3) to be rotated by an eccentric rotor, and the coil 482 may be provided on both sides of the weight 186 (see FIG. 3). .

In addition, a circuit board 484 is provided on the bottom of the rotor 480, and a commutator (not shown) to which a brush (not shown) is connected to electrically connect the flexible circuit board 460 to the bottom of the circuit board 484. ) May be provided.

That is, the power is applied in order of the flexible circuit board 460, the brush (not shown), the commutator (not shown) of the circuit board 484, and the coil 482 of the rotor 480. The rotor 480 is rotated by electromagnetic interaction with the upper and lower magnets 440 and 450.

At this time, since the weight 186 (see FIG. 3) is provided in the rotor 480, the rotor 480 is eccentrically rotated.

On the other hand, since the flat vibration motor 400 according to the fourth embodiment of the present invention includes upper and lower magnets 440 and 450, the driving torque generated in proportion to the increased magnetic flux density is increased. Accordingly, the time to reach the normal vibration is faster, it is possible to implement a fast response speed.

The spacer 490 is fixed to the upper case 420 so as to reduce the friction area with the shaft 430 of the bearing member 470, and an installation hole 492 through which the shaft 430 penetrates is formed.

That is, the spacer 490 is fixed to the upper case 420 so as to be disposed above the bearing member 470, and has a mounting hole 492 through which the shaft 430 penetrates. Accordingly, the length of the bearing member 470 may be reduced as compared with the case where the spacer 490 is not provided.

As a result, the contact area of the inner circumferential surface of the bearing member 470 in contact with the outer circumferential surface of the shaft 430 may be reduced, thereby reducing the friction area between the bearing member 470 and the shaft 430, thereby reducing the driving torque. Can be.

Therefore, the time to reach the normal vibration is faster to implement a faster response speed.

In addition, the spacer 490 serves to dispose the coil 482 of the rotor 480 from the upper magnet 450 at a predetermined interval. That is, the spacer 490 serves to mount the rotor 480 so that the coil 482 and the upper magnet 450 do not interfere when the rotor 480 rotates.

In addition, the spacer 490 serves to provide an elastic force when the bearing member 470 and the rotor 480 float by the rotation of the rotor 480. That is, when the rotor 480 is rotated, the rotor 480 and the bearing member 470 are floated a predetermined distance by the rotation. The spacer 490 is the rotor 480 is returned to its original position when the rotation of the rotor 480 is stopped. Resilience may be provided to allow for recovery.

As described above, while reducing the friction area between the shaft 430 and the bearing member 470 through the spacer 490 and the inclined portion 472 of the bearing member 470, the spacer 490 and the bearing member ( By reducing the friction area with the upper surface of the 470, it is possible to increase the drive torque of the rotor 480 can implement a high response with a fast response speed.

Hereinafter, a flat vibration motor according to a fifth embodiment of the present invention will be described.

8 is a schematic cross-sectional view showing a flat vibration motor according to a fifth embodiment of the present invention.

Referring to FIG. 8, the flat vibration motor 500 according to the fifth embodiment of the present invention may include a lower bracket 510, an upper case 520, a shaft 530, a lower magnet 540, and an upper magnet 550. , A flexible circuit board 560, a bearing member 570, a rotor 580, and a spacer 590.

On the other hand, here also defined a term for the direction, as shown in Figure 8, the axial direction refers to the up and down direction relative to the shaft 530, the radial direction of the outer end of the rotor 580 relative to the shaft 530 Direction or the center direction of the shaft 530 with respect to the outer end of the rotor 580, the circumferential direction means the direction of rotation along the outer peripheral surface of the shaft 530.

One end of the lower bracket 510 is fixedly installed, and for this purpose, a lower rib 511 having a shaft support groove 511a into which the shaft 530 is inserted may be formed in the lower bracket 510. .

In addition, the lower bracket 510 may include an installation guide 512, and the outer circumferential surface of the lower magnet 540 contacts the installation guide 512 when the lower magnet 540 is installed on the lower bracket 510. By doing so, the lower magnet 540 can be mounted at a certain position.

In addition, the lower bracket 510 is formed to be disposed on the bottom edge of the lower magnet 540 when the lower magnet 540 is mounted to include an inlet groove 513 into which the surplus adhesive applied to the lower magnet 540 flows. Can be.

In addition, the lower bracket 510 may be provided with a mounting groove 514 into which the flexible circuit board 560 is inserted. That is, the flexible circuit board 560 may be inserted into the mounting groove 514 and may not protrude from the upper surface of the lower bracket 510.

The upper case 520 is fixed to the other end of the shaft 530, and is combined with the lower bracket 510 to form an inner space.

That is, the upper case 520 may be provided with an upper rib 522 having a shaft groove 521 into which the other end of the shaft 530 is inserted, and the upper case 520 is coupled with the lower bracket 510. It may be formed to have a cup shape to protect the inside by blocking the inflow of dust or foreign matter from the outside.

Both ends of the shaft 530 are fixed to the lower bracket 510 and the upper case 520. That is, one end of the shaft 530 is inserted into the shaft support groove 511a formed in the lower rib 511 of the lower bracket 510, and the shaft groove 521 formed in the upper rib 522 of the upper bracket 520. The other end is installed and fixed.

In addition, the shaft groove 521 into which the other end of the shaft 530 is inserted may be interposed with an elastic member 535 that provides an elastic force to the shaft 530. That is, when the shaft 530 rises when the rotor 580 rotates, an elastic member 535 that provides an elastic force to the shaft 530 may be inserted into the shaft groove 521.

The lower magnet 540 is installed to be disposed at the edge of the lower bracket 510. In addition, the lower magnet 540 serves to rotate the rotor 580 by electromagnetic interaction. To this end, the lower magnet 540 may be formed to have an annular annular shape.

In addition, the upper magnet 550 is fixedly installed in the upper case 520 to be disposed in the inner space formed by the lower bracket 510 and the upper case 520, by the electromagnetic interaction with the lower magnet 540 It serves to rotate the rotor 580. The upper magnet 550 may also be formed to have an annular annular shape.

The flexible circuit board 560 is installed on the lower bracket 510. That is, the flexible circuit board 560 is inserted into and disposed in the mounting groove 514 of the lower bracket 510. Accordingly, when the lower magnet 540 is installed in the lower bracket 510, the lower magnet 540 is inclined. It can be prevented from being installed.

The bearing member 570 has a mounting hole 571 in which the shaft 530 is inserted. That is, the bearing member 570 is mounted to the shaft 530.

The rotor 580 is mounted on the bearing member 570 such that the outer circumferential surface of the bearing member 570 is press-fitted, and includes a coil 582 disposed to face the lower magnet 540 to rotate together with the bearing member 570. do.

That is, the coil 582 provided in the rotor 580 allows the rotor 580 to rotate through electromagnetic interaction with the lower magnet 540 and the upper magnet 550.

The rotor 580 may be provided with a weight 386 (see FIG. 5) to be rotated by an eccentric rotor, and the coil 582 may be provided on both sides of the weight 386 (see FIG. 5). have.

In addition, a circuit board 584 is provided on a bottom of the rotor 580, and a commutator (not shown) is connected to a bottom of the circuit board 584 to connect a brush (not shown) to be electrically connected to the flexible circuit board 560. ) May be provided.

That is, power is applied in order of the flexible circuit board 560, the brush (not shown), the commutator (not shown) of the circuit board 584, and the coil 582 of the rotor 580. The rotor 580 is rotated by electromagnetic interaction with the upper and lower magnets 540 and 550.

At this time, since the rotor 580 is provided with a weight 386 (see FIG. 5), the rotor 580 is eccentrically rotated.

On the other hand, since the flat vibration motor 500 has upper and lower magnets 540 and 550, the driving torque generated in proportion to the increased magnetic flux density is increased. As a result, the time to reach the normal vibration is faster, thereby realizing a faster response speed.

In addition, the rotor 580 may be provided with a mounting portion 589 in which the bearing member 570 is press-mounted therein. That is, the bearing member 570 is inserted into the mounting portion 589. Accordingly, the bearing member 570 can be supported more firmly.

On the other hand, the bearing member 570 is inserted into the mounting portion 589 to reduce the friction area between the bearing member 570 and the shaft 530, thereby realizing a faster response speed.

That is, the axial length of the bearing member 570 can be reduced, so that the friction area between the inner circumferential surface of the bearing member 570 and the outer circumferential surface of the shaft 530 can be reduced, thereby reducing the torque required for rotation. Accordingly, a faster response speed can be realized.

In addition, the rotor 580 may include a protrusion 587 extending upward from the mounting portion 589 in the axial direction so as to reduce the friction area with the spacer 590. That is, the protrusion 587 is in contact with the spacer 590 fixed to the upper case 520 to reduce the friction area during rotation of the rotor 580 to implement a faster response speed.

To this end, the protrusion 587 may be formed in a shape in which the cross-sectional area is narrowed toward the upper side. That is, the protrusion 587 may be formed to have a conical shape having a wide cross-sectional area of the lower side so that the contact area with the spacer 590 may be reduced.

In addition, the bottom surface of the rotor 580 is supported by the lower rib 521 of the lower bracket 510 into which the shaft 530 is inserted and coupled, and a support portion 588 extending downward in an axial direction to correspond to the mounting portion 589 is provided. Can be formed.

Accordingly, the support part 588 is supported by the lower rib 521, so that the rotor 580 can be rotated more stably, and eventually the driving torque generated in proportion to the increased magnetic flux density by the upper and lower magnets 540 and 550. It is possible to realize stable rotational response even with increasing.

The spacer 590 serves to dispose the coil 582 of the rotor 580 from the upper magnet 550 by a predetermined distance. That is, the spacer 590 serves to mount the rotor 580 so that the coil 582 and the upper magnet 550 do not interfere when the rotor 580 rotates.

Meanwhile, in the present embodiment, the case in which the spacer 590 is mounted on the shaft 530 is described as an example, but the spacer 590 may be omitted by changing the shapes of the mounting portion 589 and the protrusion 587. It may be.

That is, when the mounting portion 589 and the protrusion 587 extend longer in the axial direction, the spacer 590 may not be employed by allowing the protrusion 587 to directly contact the upper case 520.

As described above, the bearing member 570 can more firmly support the bearing member 570 through the rotor 580 having the mounting portion 589 inserted therein, thereby preventing rotational instability of the rotor 580. Can be reduced.

In addition, by reducing the friction area with the spacer 590 through the protrusion 587 extending from the mounting portion 589 it is possible to implement a high response with a fast response speed.

In addition, the axial length of the bearing member 570 can be reduced by the mounting portion 589 having the protrusion 587 formed thereon, so that the friction area between the inner circumferential surface of the bearing member 570 and the outer circumferential surface of the shaft 530 can be reduced. It can be reduced, enabling high response with fast response speed.

100, 200, 300, 400, 500: flat vibration motor
110, 210, 310, 410, 510: lower bracket
120, 220, 320, 420, 520: upper case
130, 230, 330, 430, 530: shaft
140, 240, 340, 440, 540: lower magnet
150, 250, 350, 450, 550: upper magnet
160, 260, 360, 460, 560: Flexible Circuit Board
170, 270, 370, 470, 570: bearing member
180, 280, 380, 480, 580: rotor
190, 290, 390, 490, 590: spacer

Claims (10)

A lower bracket to which one end of the shaft is fixed;
An upper case fixed at the other end of the shaft and coupled to the lower bracket to form an inner space;
A bearing member having a mounting hole through which the shaft is mounted; And
A rotor formed inside the mounting portion in which the bearing member is press-fitted and extending upward in an axial direction, the rotor being rotated in conjunction with the bearing member;
Including;
And a spacer fixed to the upper case so as to reduce an area of friction of the bearing member with the shaft, the spacer having an installation hole through which the shaft penetrates. delete The method of claim 1,
The rotor is a flat vibration motor, characterized in that the protrusion extending from the mounting portion in the axial direction upward to reduce the friction area with the spacer. The method of claim 1,
The bottom of the rotor is supported on the lower rib of the lower bracket is inserted into the shaft, the flat vibration motor, characterized in that the support portion extending in the axially downward to correspond to the mounting portion is formed. The method of claim 1,
Flat vibration motor further comprises upper and lower magnets installed in the lower bracket and the upper case so as to face the coil provided in the rotor. The method of claim 5,
And a flexible circuit board installed on the lower bracket, the flexible circuit board including a body part which is in contact with the lower magnet so as to prevent breakage of the lower magnet by an impact from the outside, and an extension part extending from a portion of the body part. motor. The method of claim 6,
And a mounting groove in which the flexible circuit board is inserted into the lower bracket so that the body portion and the lower magnet are in contact with each other. The method of claim 5, wherein the lower bracket
It is formed to be disposed on the bottom edge of the lower magnet, the flat vibration motor, characterized in that provided with an inlet groove in which excess adhesive is introduced when the lower magnet is bonded. The method of claim 5, wherein the lower bracket
Flat vibration motor is formed so as to contact the outer circumferential surface of the lower magnet and having an installation guide for guiding the mounting position of the lower magnet. The method of claim 1,
The upper case is provided with an upper rib formed with an insertion groove for inserting one end of the shaft,
The insertion groove is a flat vibration motor, characterized in that the elastic member is provided to provide an elastic force to the shaft.

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