KR20110095107A - Linear vibration generating device - Google Patents

Abstract

PURPOSE: A linear vibration generating device is provided to arrange a part only on one surface of a heavy object, thereby enhancing vibration features by obtaining the volume of the heavy object. CONSTITUTION: A stator(22) supports the entire weight of a vibrator(21). The vibrator includes a yoke(31) and a permanent magnet(32). The stator includes an external case(35), a bracket(36), and a coil(37). The bracket supports the weight of the vibrator when the vibrator vibrates. A cylindrical burring unit is arranged in an upper part which is in the same axis as the coil.

Description

Linear Vibration Generator {LINEAR VIBRATION GENERATING DEVICE}

The present invention relates to a linear vibration generating device, and more particularly to a coin-type linear vibration generating device employed in a portable terminal.

In general, the linear vibration actuator used as a silent receiver of a mobile terminal has a shorter stroke and a faster vibration characteristic at start and stop than a conventional eccentric rotation type vibration motor due to the elastic force of the elastic member. Therefore, it has responded to the trend of slimming portable terminals.

Such a linear vibration generator is generally composed of a vibrator including a permanent magnet and a stator supporting the vibrator, and the interaction between the electromagnetic force generated by applying a current to a coil disposed on the stator and the magnetic force generated from the permanent magnet. As the permanent magnet moves up and down, vibration is generated.

Conventional linear vibration generating device is provided with a stator having a coil in the case, a vibrator having a permanent magnet, and a yoke is provided to fix the permanent magnet, and elastically supporting the yoke in which the permanent magnet is fixed An elastic member is provided to generate vibration.

However, when the linear vibration generating device generates an up / down vibration, in addition to the up / down movement, the vibration of the vibrator may be left or right due to the characteristics of the elastic member and the residual vibration generated vibration. Due to this, a failure such as disconnection of the coil due to contact due to shaking with the coil generating electromagnetic force may occur.

In addition, the weight body is an important factor in the generation of vibration force of the linear vibration generating device, but when the weight is low, the vibration is reduced, but moving up / down, due to noise failure and trouble due to the touch that can occur during vibration, There is a limit to increase the volume within the thickness of the motor limited to a certain size, which causes a difficulty in improving the vibration force because there is a limit to the volume of the weight in the vibration actuator.

The configuration of the conventional linear vibration generating device is disclosed in detail in Korean Patent Laid-Open Publication No. 2005-0122101.

Further, another conventional linear vibration generating device is disclosed in Japanese Patent Laid-Open Publication No. 2008-107506.

A configuration of a conventional linear vibration generating device 10 will be described with reference to FIG. 1. As shown in FIG. 1, the conventional linear vibration generating device 10 includes a vibrator 11 and a stator 12. The vibrator 11 includes a yoke 110, a permanent magnet 111, and a weight body. 112, the stator 12 includes an outer diameter case 120, a bracket 121, and a coil 122. The vibrator 11 has a structure that is supported at the upper and lower points by the bracket 121 and the outer case 120.

The permanent magnet 111 is provided to extend downward from the center of the yoke 110, the weight 112 is provided on the outer peripheral surface of the yoke 110. The permanent magnet 111 is disposed coaxially with the coil 122 to form a magnetic path together. In addition, an elastic body 13 is provided between the yoke 110 and the outer diameter case 120 to support the oscillator 11 during operation. The elastic body 13 is formed between the ceiling case 120 and the upper surface of the yoke 110 to support the vibrator 11. That is, the conventional linear vibrator 10 has a structure in which the vibrator 11 is supported by the outer case 120 supporting the bracket 121 and the elastic body 13.

In addition, the plate 113 is provided on the bottom surface of the permanent magnet 111, the horizontal collision preventing portion 130, such as magnetic fluid is provided in the portion where the magnetic is concentrated, the vertical collision preventing portion 131, 132 of the damper function It was a structure provided. Reference numeral 122 denotes a printed board.

However, the conventional linear vibration generating device is made of a structure that is difficult to expand the volume of the weight body, there is a limitation in improving the vibration characteristics.

In addition, the conventional linear vibration generating apparatus has a problem of degrading the assemblability in an assembling process such as concentric management or coil soldering.

In addition, the conventional linear vibration generator has a problem that it is difficult to maintain a constant gap between components.

The present invention is to provide a linear vibration generating device with improved vibration characteristics by changing the magnetic circuit as compared to the conventional.

In addition, the present invention is to provide a linear vibration generating device that can be assembled / fixed to all the components in one direction improved assembly.

In addition, in the present invention, by placing the yoke and the permanent magnet to form a magnetic circuit only on one side (open space) of the weight body, the minimum gap between the components due to the shaking caused during the operation of the vibrator is maintained to improve product reliability It is to provide a linear vibration generating device.

In addition, the present invention is to provide a linear vibration generating apparatus for arranging the yoke and the permanent magnet to form a magnetic path only on one side of the weight body, it is advantageous to secure the area to the other surface of the weight body to improve the vibration characteristics.

In addition, the present invention is to provide a linear vibration generating device that can be configured in a thin through the weight thickness control, due to the sufficient volume of the weight.

In addition, the present invention is to provide a linear vibration generating device that can be concentrically managed before assembly as the vibrator is coupled to the stator to improve assembly.

In addition, the present invention is to provide a linear vibration generating device that extends the life of the product by installing a collision preventing portion in the portion where the magnetic concentration.

In addition, the present invention is to provide a linear vibration generating device having a step on the plate in order to prevent the collision occurring during operation.

In addition, the present invention is to provide a linear vibration generating device that improves the durability of the product by solving the coil disconnection problem.

Therefore, the present invention is to solve the above problems, the linear vibration generating device according to the present invention includes a stator including a coil provided on the bracket; A vibrator including a yoke having a burring extending downward, and a permanent magnet providing a magnetic circuit together with the yoke; And an elastic body disposed on the bracket to surround the outside of the coil to support the vibrator.

In addition, the linear vibration generating device according to the present invention includes a stator including a coil provided on the bracket; And a yoke having a burring extending downward, and a vibrator including a permanent magnet providing a magnetic circuit together with the yoke and providing a vibration force together with the coil.

As described above, the linear vibration generating device according to the present invention improved the vibration characteristics by changing the magnetic circuit. In particular, the present invention has a structure that is advantageous for maintaining a constant gap between components during operation, contributed to the improvement of assemblability, and achieved the advantage of improving product durability. In addition, the present invention can be placed only on one side of the weight body, it is advantageous to secure the volume of the weight body to improve the vibration characteristics, to prevent damage to the stator due to the vibration of the vibrator, and to provide a collision prevention part in the magnetic concentration Thereby achieving the advantage of extending product life.

1 is a cross-sectional view showing the configuration of a conventional linear vibration generating device.
2 is a cross-sectional view showing the configuration of a linear vibration generating device according to a first embodiment of the present invention.
FIG. 3 is a cross-sectional view illustrating the structure of the vibrator of the linear vibration generating device shown in FIG. 2 separately.
4 is a cross-sectional view showing the configuration of a linear vibration generating device according to a second embodiment of the present invention.
5 is a cross-sectional view showing the configuration of a linear vibration generating device according to a third embodiment of the present invention.
6 is a cross-sectional view showing the configuration of a linear vibration generating device according to a fourth embodiment of the present invention.
7 is a cross-sectional view showing a magnetic circuit generated during operation of the linear vibration generating device according to the present invention.

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

As shown in FIG. 2, the linear vibration generating device 20 according to the first embodiment of the present invention is employed at a predetermined position of a mobile terminal commonly used, such as a cellular phone or a smart phone, and is used as a silent receiving device. As a compact and slim vibration motor, the appearance is coin-shaped.

The linear vibration generating device 20 is composed of a vibrator 21 and a stator 22, in particular, the stator 22 is configured to support the entire weight of the vibrator 21. The vibrator 21 includes a permanent magnet, and the stator includes a coil. In particular, the vibrator includes a yoke 31 and a permanent magnet 32 provided in the yoke 31. The stator 22 includes an outer case 35, a bracket 36, and a coil 37. As the stator 22 and the vibrator 21 are relative to each other, the stator 22 means a part fixed to the vibrator 21, and the vibrator 21 vibrates with respect to the stator 22. It means part.

As illustrated in FIGS. 2 and 3, the yoke 31 is a place where the permanent magnet 32 is mounted, and forms a magnetic circuit together with the permanent magnet 32. The yoke 31 extends vertically downward from the center. And a cylindrical burring portion 310 (burring) disposed coaxially upward from the coil 37. The cylindrical burring portion 310 forms an important magnetic path together with the permanent magnet 32 and the coil 37. The permanent magnet 32 is mounted to the yoke 31, it is configured in a ring shape wrapped while being spaced apart from the outer peripheral surface 313 of the cylindrical burring portion 310.

As shown in FIG. 2, the outer case 35 is a member forming the outer shape of the linear vibration generating device 20 together with the bracket 36 to be described later. The outer case 35 has a simple cover shape and is made of magnetic material. The bracket 36 is a member coupled to the bottom of the outer diameter case 35 and supports the entire weight of the vibrator when the vibrator 21 vibrates. The coil 37 is disposed on the bracket 36 together with the permanent magnet 32 to provide a driving force. In particular, the yoke 31 and the permanent magnet 32 are arranged coaxially with the coil 37 (vibration center axis) to form a vibration force.

2 and 3, specifically, the permanent magnet 32 is formed in a ring shape and includes an upper surface 320, a lower surface 321, an outer diameter surface 322, and an inner diameter surface 323. It is spaced apart from the outer circumferential surface 313 of the burring portion, and disposed to wrap while facing.

In addition, the burring portion 310 has already been described as having a cylindrical shape extending downward from the center of the yoke 31, the burring portion 310 is disposed to penetrate the center of the permanent magnet (32). In addition, the burring portion 310 is disposed facing the upper portion of the coil 37, the permanent magnet 32 is disposed facing the outer upper portion of the coil 37. This configuration provides a gap with the burring portion outer circumferential surface 313 and the permanent magnet inner diameter surface 323, and provides a gap with the burring portion outer circumferential surface 313 and the coil 37 inner diameter surface, and the permanent gap. Magnet inner diameter surface 323 provides a gap with the coil outer diameter surface.

The yoke 31 is made of a magnetic material, and the permanent magnet 32 extends downward from the center of the horizontal extension part 312 and the horizontal extension part 312 attached to the bottom surface 314 of the coil 37. And a cylindrical burring portion disposed to be spaced apart coaxially (a vibration central axis) and providing a magnetic circuit generated by operating together with the permanent magnet 32. The horizontal extension part 312 and the burring part 310 is manufactured in one piece. In particular, the burring portion 310 is formed in a hollow shape, the upper end is open, the lower end 311 may be manufactured in an open shape, or may be configured in a closed shape. In particular, the outer diameter portion of the horizontal extension portion 315 and the outer diameter of the permanent magnet 32 is configured the same, the inner diameter of the permanent magnet 32 is larger than the outer diameter of the burring portion 310 is configured.

In addition, the vibrator 21 further includes a high specific gravity weight 33 provided in the permanent magnet 32. The weight body 33 is composed of a disk-shaped upper portion 330 and a cylindrical and hollow lower portion 331, the upper portion 330 closes the upper side of the permanent magnet 32 and the yoke 31, the lower 331 closes the outer circumferential portions of the permanent magnet 32 and the yoke 31. The weight body 31 has an open space 332 with only one surface open, and the open space 332 is closed at an upper portion thereof and is opened at a lower portion thereof. In particular, the yoke 31 and the permanent magnet 32 is completely accommodated in the open space 332. The open space 332 is configured to have a cylindrical shape vertically open from the bottom surface 333 of the weight body, and is disposed in surface contact with the yoke 31 and a part of the permanent magnet 32. In particular, the weight inner diameter surface 334 is disposed in surface contact with the permanent magnet outer diameter surface 322, and is disposed in surface contact with the outer diameter surface 315 of the horizontal extension portion. The permanent magnet outer diameter surface 322 is provided with a nonmagnetic material so that the magnetic circuit of the linear vibration generator is concentrated toward the center.

Since the weight 31 is made of a structure that wraps up and closes up to the upper portion of the yoke 31 as compared with the conventional, the upper body 330 is enlarged as compared with the conventional body, and thus is effective in increasing the volume of the weight. Existing weights are limited in weight increase because the inner and outer diameters of the weight increase in size.

A plate 34 is further provided between the permanent magnet 32 and the bracket 36, and in particular, an elastic body 38 is further provided between the plate 34 and the bracket 36. The plate 34 is mounted on the bottom surface 321 of the permanent magnet to maintain a close contact with the elastic body 36. The plate 34 is made of a magnetic material to form an external magnetic field leakage prevention and magnetic closure circuit. That is, since the plate 34 is a magnetic material, the magnetic circuit generated by the yoke 31 and the permanent magnet 32 is concentrated toward the center of the coil.

The plate 34 has an inner diameter portion 340 is provided in a circular or polygonal shape, the outer diameter portion 341 is configured to be the same or smaller than the outer diameter of the permanent magnet.

Preferably, the plate 34 is in close contact with the bottom surface 321 of the permanent magnet in contact with the horizontal extension portion 342, the upper surface of the elastic body 36 is in close contact with the coil 37 in the circumferential direction A horizontal lower end portion 343 disposed spaced apart from each other, and the inclined connecting portion 344 integrally connected between the horizontal extension portion 342 and the horizontal lower end portion 343. The space in which the vertical vibration width of the vibrator 21 is increased by the inclined connection part 344 is increased. In addition, the inclined connecting portion 344 is manufactured in a bent shape to prevent contact with the elastic body 38 generated when the maximum displacement movement of the vibrator 21. In addition, the horizontal extension portion 342 and the horizontal lower end portion 343 is configured in a ring shape, the diameter size of the horizontal extension portion 342 is configured to be larger than the diameter size of the horizontal lower portion 343.

As shown in FIG. 2, the elastic body 38 has a semi-conical shape, and a lower end portion 381 has a larger diameter size than the upper end portion 380 and is stably disposed on the bracket 36. In addition, the elastic body 38 is the elastic force is generated in the direction in which the upper end 380 and the lower end 381 are far from each other, the plate 34 is in close contact with the permanent magnet 32, the upper end 380 is Always keep in close contact with the horizontal lower end 343 in surface contact. The elastic body 38 has an inner diameter that faces the inner diameter of the plate 34, an outer diameter that faces the bracket 36, and a plurality of connection parts connecting the inner diameter portion and the outer diameter portion.

The bracket 36 includes an inclined bent portion 360 to prevent contact occurring when the vibrator 21 is operated at the maximum displacement. That is, the vibration distance is increased by the bent portion 360 to minimize the collision between the vibrator and the stator.

4 is a cross-sectional view showing the configuration of a linear vibration generating device 40 according to a second embodiment of the present invention. In FIG. 4, only the differences will be described in comparison with the linear vibration generating device 20 illustrated in FIG. 2. That is, since the detailed description of the configuration of the linear vibration generating device 40 shown in FIG. 4 except for the horizontal collision preventing part has been described above, it will be omitted.

As shown in FIG. 4, the linear vibration generating device 40 according to the second embodiment of the present invention faces the outer circumferential surface 440 of the coil 44 at the lower end of the inner diameter surface 420 of the permanent magnet 42. One horizontal collision prevention part 41 is comprised. The first horizontal collision preventing part 41 may be formed of a magnetic fluid, a grease, or a silicon material formed along the lower end of the inner surface of the permanent magnet 420, and in particular, may be formed in a plurality of spaced viscosity cloths or a ring shape. have. Since grease or silicon is relatively inexpensive than magnetic fluid, it contributes to manufacturing cost reduction.

In addition, a second horizontal collision preventing part 45 is further provided on the inner surface 430 of the plate 43. The second horizontal collision preventing part 45 may be formed of a magnetic fluid, a grease or a silicon material formed along the plate inner diameter surface 430, and in particular, a plurality of spaced point coatings or a ring shape. Since grease or silicon is relatively inexpensive than magnetic fluid, it contributes to manufacturing cost reduction. In addition, the second horizontal collision preventing portion 45 may be formed over the upper surface of the plate inner diameter surface 430 and the elastic body 46. According to this configuration, when the linear vibration generating device 40 is operated, the horizontal collision is prevented by the first and second horizontal collision preventing portions 41 and 45 so that an effective vibration is provided.

5 is a cross-sectional view showing the configuration of a linear vibration generating device 50 according to a third embodiment of the present invention. In FIG. 4, only the differences will be described in comparison with the linear vibration generating device 20 illustrated in FIG. 2. That is, since the detailed description of the configuration of the linear vibration generating device 50 shown in FIG. 5 except for the vertical collision preventing part has been described above, it will be omitted.

As shown in FIG. 5, the linear vibration generating device 50 according to the third embodiment of the present invention further includes a first vertical collision preventing part 52 on the ceiling surface 510 of the outer case 51. . The first vertical collision preventing portion 52 is made of a polymer of silicone or foam component and is attached to the ceiling surface 510 in a one-sided adhesive manner.

In addition, a second vertical collision preventing part 55 is further provided on the inner bottom surface 530 of the coil 53, specifically, on the inner bottom surface of the coil installed on the bracket 54. The second vertical collision preventing unit 55 is made of a polymer of silicone or foam component and is attached to the bottom surface 530 by one side attachment type. According to this configuration, the vertical collision is prevented by the first and second vertical collision preventing portions 52 and 55 during the operation of the linear vibration generating device 50, thereby providing an effective vibration.

6 is a cross-sectional view showing the configuration of a linear vibration generating device 60 according to a fourth embodiment of the present invention. In FIG. 6, only the difference will be described in comparison with the linear vibration generating device 20 illustrated in FIG. 2.

As shown in FIG. 6, the yoke 61 constituting the linear vibration generating device 60 includes a horizontal extension portion 610 and a cylindrical burring portion 612, and the horizontal extension portion 610 is permanent. The magnet 62 is disposed. The horizontal extension part 610 is provided with a ring-shaped mounting guide groove 613 on the bottom. The mounting guide groove 613 is formed to provide the accuracy of the coupling when the permanent magnet 62 is mounted on the bottom, and to provide the quickness of the coupling. In addition, the cylindrical burring portion 612 has a lower end 615 is composed of a closed end. The lower end portion 615 forms a magnetic circuit together with the permanent magnet 62 and forms a driving force together with the coil 66. In addition, the lower end 615 is formed for convenience of manufacturing the yoke 61. The lower end 615 is disposed above the inner side of the coil 66 and moves up and down.

The outer diameter of the horizontal extension portion 610 is configured to be smaller than the inner diameter of the open space of the weight body 64, a gap (g) between the outer diameter surface 614 of the horizontal extension portion and the inner diameter surface 640 of the open space. ) Exists. The gap g is used as a space for providing an adhesive.

The plate 63 is installed between the permanent magnet 62 and the elastic body 67, is composed of a magnetic material to prevent magnetic leakage, and to concentrate the magnetic circuit to the center. The plate 63 has an inner diameter / outer diameter portion having a circular or polygonal shape. In addition, the outer diameter of the plate 63 is less than or equal to the outer diameter of the permanent magnet 62, the inner diameter of the plate 63 is configured to be smaller than or equal to the inner diameter of the permanent magnet 62. In this configuration, the yoke 61, the permanent magnet 62 and the plate 63 is configured to be completely accommodated in the interior space of the weight 64.

A horizontal collision preventing portion 68 is further provided to face the upper portion of the outer circumferential surface of the coil 66 by joining the lower end portion of the inner diameter of the permanent magnet 62 and the inner diameter surface of the plate 63. The horizontal anti-collision part 68 may be formed of a magnetic fluid, a grease, or a silicon material formed along a lower end of the inner surface of the permanent magnet 62, and may be particularly formed in a plurality of spaced point applications or a ring shape. According to this configuration, when the linear vibration generating device 60 is operated, horizontal collision with the coil 66 is prevented in advance by the horizontal collision preventing unit 68, thereby providing an effective vibration.

The coil 66 is mounted on the bracket 69 and has a coil soldering portion 72 on the outer surface of the substrate 70 to be electrically connected to the outside by the substrate 70. At this time, the substrate 70 and the bracket 69 are provided with a connection opening, respectively, to provide a passage for electrically connecting from the outside by the connecting means. The connecting means may be composed of any one selected from soldering, thermal fusion, welding, liquid soldering process. This draws the solder wire of the coil to the outside through the connection opening, and forms the coil solder 72 on the outer surface of the substrate from the drawn coil through the process. In addition, such a structure is provided with a coil soldering portion 72 having a predetermined thickness in the connection opening formed in the bracket 69, which has the effect of reducing the height of the coil soldering portion. It is effective in improving durability problems. The substrate 70 is a printed circuit board, of course, may be configured as a flexible circuit.

7 is a view showing a magnetic circuit formed in the linear vibration generating device according to the present invention. As shown in FIG. 7, the magnetic circuit of the N pole generated from the permanent magnet 80 passes through the horizontal extension 810 of the yoke 81 toward the burring portion 812, and the permanent magnet ( The magnetic field of the S pole generated at 80 is directed toward the coil 83. As a result, the magnetic circuit of the linear vibration generating device according to the present invention is provided in a donut shape by the permanent magnet and the yoke, and provides the driving force of the vibrator together with the coil 83.

Claims (10)

In the linear vibration generator,
A stator including a coil provided on the bracket;
A vibrator including a yoke having a burring extending downward, and a permanent magnet providing a magnetic circuit together with the yoke; And
And an elastic body disposed on the bracket to surround the outside of the coil to support the vibrator. The linear vibration generating device of claim 1, wherein the burring portion has a cylindrical shape, penetrates through the center of the permanent magnet, and an outer circumferential surface of the burring portion is disposed to maintain a distance from the inner diameter surface of the permanent magnet. The linear vibration generating device according to claim 1, wherein the burring part is disposed to face the upper part of the coil, and the permanent magnet is disposed to face the coil outer part. According to claim 1, wherein the vibrator further comprises a weight body, the weight body has an open space with only one side open, the open space is closed by the upper portion, the lower portion is open, the open space Linear vibration generating device characterized in that the yoke and a permanent magnet is configured to accommodate. The linear vibration generating device according to claim 4, wherein the weight inner diameter surface is disposed in surface contact with the outer diameter surface of the permanent magnet. The linear vibration generating device of claim 1, wherein the outer surface of the permanent magnet has a nonmagnetic material and concentrates the magnetic circuit toward the coil. The linear vibration generating device according to claim 1, wherein the burring portion is formed in a hollow shape, an upper end is opened, and a lower end is opened or closed. According to claim 1, wherein the coil is provided on the bracket is connected to the outside by a substrate, the substrate and the bracket is provided with a coil connection opening, respectively, characterized in that the coil soldering portion is formed in the opening of the bracket Linear vibration generator. The linear vibration generator of claim 8, wherein the coil soldering part is performed by any one of soldering, heat fusion, welding, and liquid soldering. In the linear vibration generator,
A stator including a coil provided on the bracket; And
And a yoke having a burring portion extending downward, and a vibrator including a permanent magnet providing a magnetic circuit together with the yoke and providing a vibration force together with the coil.

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