JP2019134511A - Vibration motor - Google Patents

Abstract

To provide a vibration motor with improved damper member assembly.SOLUTION: A vibration motor 100 includes a stationary portion S having a housing 1, a vibrating body 5 supported so as to be able to vibrate laterally with respect to the housing, elastic members 61 and 71 located between the housing and the vibrating body, and damper members 59A and 59B, and the housing includes through holes 121A and 121B that face the damper member in the vertical direction.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a vibration motor.

  Conventionally, various devices such as a smartphone are provided with a vibration motor. Here, Patent Document 1 discloses the following haptic actuator.

  The haptic actuator of Patent Document 1 performs a vibration operation using an electromagnetic force generated by a magnet and a coil. The haptic actuator includes a case, a fixing member, a vibrating body, and an elastic member. The case includes a base and a lid coupled to the upper part of the base. The fixing member is fixedly attached to the case. The fixing member includes a shaft member fixedly mounted on the upper portion of the base and a coil wound around the shaft member. The vibrating body vibrates in the left-right direction around the fixed member. The elastic member is bent several times and elastically supports the vibrating body so that the vibrating body maintains the initial position.

  An insertion member is inserted and disposed in the bowl-shaped space formed by bending the elastic member. After the electromagnetic force is removed, when the vibrating body vibrates left and right due to the elastic force of the elastic member, the insertion member decreases the falling time of the vibrating body against the elastic force of the elastic member.

JP 2017-47415 A

  However, in Patent Document 1, if the insertion member is first assembled when the haptic actuator is assembled, the insertion member may be deformed when another member is assembled.

  In view of the above problems, an object of the present invention is to provide a vibration motor that improves the assembling property of a damper member.

An exemplary vibration motor of the present invention includes a stationary part having a housing,
A vibrating body supported so as to be able to vibrate laterally with respect to the housing;
An elastic member positioned between the housing and the vibrating body;
A damper member;
With
The said housing | casing is set as the structure which has a through-hole facing the said damper member in an up-down direction.

  According to the exemplary vibration motor of the present invention, the assembling property of the damper member can be improved.

FIG. 1 is an overall perspective view of a vibration motor according to an embodiment of the present invention as viewed from above. FIG. 2 is an exploded perspective view of the vibration motor with the cover removed. FIG. 3 is an exploded perspective view showing the vibration motor in detail. FIG. 4 is a plan view seen from above showing a state in which the cover of the vibration motor is removed. FIG. 5 is a graph showing an example of characteristics of the damper member. FIG. 6 is a plan view of the vibration motor viewed from above. FIG. 7 is an exploded perspective view of the vibration motor according to the first modification with the cover removed. FIG. 8 is a plan view seen from above showing a state in which the cover of the vibration motor according to the first modification is removed. FIG. 9 is a partially exploded perspective view of the vibration motor according to the second modification with the cover removed. FIG. 10 is a diagram of the first flat plate portion or the second flat plate portion viewed in the horizontal direction in the second modification. FIG. 11 is a schematic view showing a haptic device according to an embodiment of the present invention.

  Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings. In the following drawings, the horizontal direction, which is the direction in which the vibrating body vibrates, is represented by the X direction. Specifically, one side in the horizontal direction is represented by the X1 direction, and the other side in the lateral direction is represented by the X2 direction. In addition, a vertical direction that is a direction orthogonal to the horizontal direction is represented as a Y direction. Specifically, one side in the vertical direction is represented as Y1 direction, and the other side in the vertical direction is represented as Y2 direction. In addition, a vertical direction (height direction) that is a direction orthogonal to the horizontal direction and the vertical direction is expressed as a Z direction. Specifically, the upper side is represented as the Z1 direction, and the lower side is represented as the Z2 direction. However, this definition of direction does not indicate the positional relationship and direction when incorporated in an actual device.

<1. Overall configuration of vibration motor>
FIG. 1 is an overall perspective view of a vibration motor 100 according to an embodiment of the present invention as viewed from above. FIG. 2 is an exploded perspective view of the vibration motor 100 with the cover 12 removed. FIG. 3 is an exploded perspective view showing the vibration motor 100 in detail.

  The vibration motor 100 includes a stationary part S, a vibrating body 5, and a pair of elastic members 6 and 7. The stationary part S includes a housing 1, a substrate 2, and a coil part L.

  The housing 1 includes a base plate 11 and a cover 12. The base plate 11 is a plate-like member that extends in the lateral direction, and includes a base portion 11A and a protruding base portion 11B that protrudes from one lateral end of the base portion 11A toward the lateral side. The cover 12 has a top surface portion 121 located above and side portions extending downward from the four sides of the top surface portion 121. The side portions include side portions 12A and 12B that face each other in the lateral direction. The cover 12 is attached to the base plate 11 from above. The housing 1 accommodates the substrate 2, the coil portion L, the vibrating body 5, and the elastic members 6 and 7 inside.

  The board | substrate 2 is fixed to the upper surface of the baseplate 11, and is comprised by FPC (flexible printed circuit board). The substrate 2 may be a rigid substrate. The substrate 2 extends in the lateral direction, and includes a base 201 and a projecting portion 202 that projects from one lateral end of the base 201 to the lateral one side. One end portion in the lateral direction of the protruding portion 202 is disposed on the protruding base portion 11B. Terminals 21 </ b> A and 21 </ b> B are provided at the end of the protruding portion 202.

  The coil part L includes a core 3 and a winding part 4. The core 3 includes a core portion 3A that is configured by laminating thin plates in the vertical direction and extends in the horizontal direction, and a plate portion 3B that is fitted and fixed to both lateral ends of the core portion 3A. The winding part 4 is sandwiched by the plate part 3B from both sides in the lateral direction, and is configured by winding a conducting wire around the core part 3A. The plate portion 3B is fixed to the upper surface of the base plate 11. As a result, the coil portion L is fixed on the base plate 11.

  One lead wire of the winding part 4 is electrically connected to the terminal 21A, and the other lead wire is electrically connected to the terminal 21B. Thereby, by applying a voltage to the terminals 21 </ b> A and 21 </ b> B from the outside of the vibration motor 100, a current can be passed through the winding portion 4 to drive the coil portion L. By controlling the current flowing through the winding part 4, the coil part L generates a north pole on one side in the lateral direction and a south pole on the other side in the lateral direction, and a south pole on the other side in the lateral direction and the other side in the lateral direction. The state where the N pole is generated on the side is switched. That is, the coil portion L generates a lateral magnetic flux.

  The vibrating body 5 includes a first plate 52, a second plate 53, a first magnet part M1, a second magnet part M2, a first magnetic piece 57A, a second magnetic piece 57B, and a first weight part 58A. And a second weight part 58B.

  The first plate 52 has an L-shape when viewed from the lateral direction, and includes a piece portion 521 extending in the vertical direction and a piece portion 522 extending downward from one longitudinal end of the piece portion 521. The second plate 53 has an L-shape when viewed from the lateral direction, and includes a piece portion 531 extending in the longitudinal direction and a piece portion 532 extending downward from the other longitudinal end of the piece portion 531. The first plate 52 and the second plate 53 are arranged to face each other in the vertical direction.

  The first magnet part M <b> 1 extending in the lateral direction includes a first magnet 54 </ b> A, a second magnet 55 </ b> A, and a third magnet 56 </ b> A, and is fixed to the first plate 52. The second magnet part M <b> 2 extending in the lateral direction includes a first magnet 54 </ b> B, a second magnet 55 </ b> B, and a third magnet 56 </ b> B, and is fixed to the second plate 53. The first magnet part M1 and the second magnet part M2 are arranged so as to sandwich the coil part L from both sides in the vertical direction. The first weight part 58A and the second weight part 58B are arranged so as to sandwich the first magnet part M1 and the second magnet part M2 from both lateral sides. Both the first weight portion 58A and the second weight portion 58B are fixed to the first plate 52 and the second plate 53.

  The first magnetic piece 57A is fixed to the first weight part 58A on one side in the horizontal direction, and is sandwiched between the first magnet part 54A and the first magnet part 54B from both sides in the vertical direction. The second magnetic piece 57B is fixed to the second weight 58B on the other side in the horizontal direction, and is sandwiched from both sides in the vertical direction by the second magnet part 55A and the second magnet part 55B.

  The first magnet 54A and the second magnet 55A have the directions of magnetic fluxes in the opposite lateral directions. The third magnet 56A has the direction of magnetic flux in the vertical direction. With such a Halbach array structure of the first magnet part M1, the magnetic flux can be concentrated on the coil part L side. Note that leakage of magnetic flux can be suppressed by using the first magnetic piece 57A and the second magnetic piece 57B.

  The first magnet 54B and the second magnet 55B have directions of magnetic fluxes in the lateral directions opposite to each other. The third magnet 56B has a direction of magnetic flux in the vertical direction, and the direction is opposite to that of the third magnet 56A. With such a Halbach array structure of the second magnet part M2, the magnetic flux can be concentrated on the coil part L side. Note that leakage of magnetic flux can be suppressed by using the first magnetic piece 57A and the second magnetic piece 57B.

  The elastic member 6 includes a plurality of flat plate portions 61, a plurality of connecting portions 62A, and a plurality of connecting portions 62B. In the present embodiment, as an example, six flat plate portions 61 are provided, and the flat plate portions 61 are arranged side by side in the horizontal direction. That is, the flat plate portions 61 adjacent in the horizontal direction are opposed to each other in the horizontal direction. The flat plate portion 61 has a shape extending in the vertical direction when the vibrating body 5 is stationary (the state shown in FIG. 2). The stationary state of the vibrating body 5 indicates a non-operating state in which the coil portion L is not energized and the vibrating body 5 is not vibrating.

  The longitudinal direction one side edge parts of the flat plate part 61 adjacent to the horizontal direction are connected by the connection part 62A. The other ends in the vertical direction of the flat plate portions 61 adjacent in the horizontal direction are connected by a connecting portion 62B. The connecting portion 62A is bent to one side in the vertical direction. The connecting portion 62B is bent to the other side in the vertical direction. The flat plate portion 61 is alternately connected by the connecting portions 62A and 62B as it proceeds in the lateral direction. That is, in the example of the present embodiment, three connecting parts 62A are arranged in the horizontal direction on one side in the vertical direction, and two connecting parts 62B are arranged in the horizontal direction on the other side in the vertical direction.

  The first flat plate portion 611 located at the other side end of the flat plate portion 61 is fixed to the first weight portion 58A, and the second flat plate portion 612 located at the one side end of the flat plate portion 61 is fixed to the case 12. It is fixed to the inner wall of the side surface portion 12A.

  The elastic member 7 has the same configuration as that of the elastic member 6, and the elastic member 7 includes a flat plate portion 71, a connecting portion 72A, and a connecting portion 72B. The first flat plate portion 711 located at one side end in the horizontal direction of the flat plate portion 71 is fixed to the second weight portion 58B, and the second flat plate portion 712 located at the other side end in the horizontal direction among the flat plate portion 71 is the case 12. It is fixed to the inner wall of the side part 12B.

  Thereby, the elastic member 6 is positioned between the side surface portion 12 </ b> A of the cover 12 and the vibrating body 5, and the elastic member 7 is positioned between the side surface portion 12 </ b> B of the cover 12 and the vibrating body 5. The vibrating body 5 is supported by the elastic members 6 and 7 so as to vibrate laterally with respect to the cover 12 (housing 1).

<2. Damper member configuration>
In the vibration motor 100, the stationary part S further includes a first damper member 59A and a second damper member 59B. FIG. 4 is a plan view seen from above showing a state in which the cover 12 of the vibration motor 100 is removed.

  The first damper member 59A is fixed to the plate portion 3B on one side in the lateral direction of the core 3 of the coil portion L. The first damper member 59A is affixed and fixed to a surface on one side in the horizontal direction of the plate portion 3B by, for example, a double-sided tape.

  The second damper member 59B is fixed to the plate portion 3B on the other side in the lateral direction of the core 3 of the coil portion L. The second damper member 59B is affixed and fixed to the other surface in the lateral direction of the plate portion 3B, for example, with a double-sided tape.

  As shown in FIG. 4, in a non-operating state in which the vibrating body 5 is stationary without supplying current to the coil portion L, the one side surface of the first damper member 59A contacts the first magnetic piece 57A. The surface on the other side in the lateral direction of the second damper member 59B is in contact with the second magnetic piece 57B. Accordingly, during normal operation in which the current is supplied to the coil portion L and the vibrating body 5 vibrates, the first damper member 59A contacts the first magnetic piece 57A, and the second damper member 59B contacts the second magnetic piece 57B. . Thereby, the vibration of the vibrating body 5 is stabilized and the noise generated from the vibration motor 100 can be reduced.

  If the damper member can contact the vibrating body 5 during normal operation, the damper member does not necessarily need to contact the vibrating body 5 in the non-operating state. Further, the magnetic piece is not essential, and the damper member may contact the weight part during normal operation.

  The first damper member 59A has a two-layer structure, and includes an outer layer 591 disposed on one side in the horizontal direction and an inner layer 592 disposed on the other side in the horizontal direction. The second damper member 59B also has a two-layer structure, and includes an outer layer 591 disposed on the other side in the lateral direction and an inner layer 592 disposed on the one side in the lateral direction.

  The outer layer 591 is harder than the inner layer 592. Such a two-layered damper member has characteristics as shown in FIG. In FIG. 5, the horizontal axis indicates the amount of displacement of the vibrating body 5, and the vertical axis indicates the hardness of the damper member. When the vibration body 5 is displaced from zero displacement and the damper member is pressed and contracted, first, due to the action of the inner layer 591, the hardness increases with a gentle inclination with respect to the displacement. Then, when the displacement reaches Th, which is the threshold value of the displacement amount, and further displaced, the hardness increases with respect to the displacement amount with a steep slope by the action of the outer layer 592.

  Accordingly, when the vibrating body 5 is compressed in the normal operation and then is displaced in the reverse direction, the hard outer layer 592 can be used as a starting point, and the vibration of the vibrating body 5 can be stabilized. Further, the displacement of the vibrating body 5 can be restricted at the time of a drop impact when the vibration motor 100 is dropped.

  It is also possible to configure the coil portion L as an air-core coil without providing the core 3 and fix the damper member to the winding portion. However, since the winding portion is affected by the load applied to the damper member, the winding portion 4 can be protected by fixing the damper members 59A and 59B to the core 3 as shown in FIG. Thereby, the influence on a magnetic characteristic can be suppressed.

<3. Assembling the damper member>
FIG. 6 is a plan view of the vibration motor 100 as viewed from above, and shows a state in which the cover 12 is attached in FIG.

  As shown in FIG. 6, the top surface 121 of the cover 12 has a first through hole 121A and a second through hole 121B arranged side by side in the horizontal direction. 121 A of 1st through-holes and 121B of 2nd through-holes penetrate the top-surface part 121 to an up-down direction, respectively.

  The first through hole 121A is located above the first damper member 59A and faces the first damper member 59A in the vertical direction. The second through hole 121B is located above the second damper member 59B and faces the second damper member 59B in the up-down direction.

  Thereby, when the vibration motor 100 is assembled, the elastic members 6, 7 and the vibrating body 5 are assembled inside the housing 1, from the outside of the housing 1 through the first through hole 121 </ b> A and the second through hole 121 </ b> B, respectively. Each damper member 59A, 59B can be assembled. When the damper member is assembled first, the damper member may be deformed when assembling other members. However, by assembling using the through holes 121A and 121B in this way, the deformation of the damper member is suppressed. The damper member can be easily assembled.

  The through holes 121A and 121B have rounded portions R1 and R2 at four corners, respectively. Thereby, the stress concentration produced at the corners of the through holes 121A and 121B can be suppressed, and the deformation of the cover 12 can be suppressed.

  Further, the through holes 121A and 121B have recesses H1 and H2 that fit into the plate portion 3B of the core 3, respectively. Although positioning of the vibrating body 5 is possible by the recesses H1 and H2, the through holes 121A and 121B need to be molded with high accuracy. Therefore, when the through holes 121A and 121B are molded by punching, stress is released by the rounded portions R1 and R2 located on both sides in the longitudinal direction of the recesses H1 and H2, and deformation of the through holes 121A and 121B is suppressed.

<4. First Modification>
Next, a first modification of the vibration motor will be described. FIG. 7 is an exploded perspective view of the vibration motor 101 according to the first modification with the cover 1200 removed. FIG. 8 is a plan view seen from above showing a state in which the cover 1200 of the vibration motor 101 is removed.

  The structural differences of the vibration motor 101 from the vibration motor 100 described above are a cover 1200, elastic members 60, 70, and damper members 81A, 82A, 81B, 82B.

  The elastic member 60 includes a plurality of flat plate portions 601, a plurality of connecting portions 602A, and a plurality of connecting portions 602B. In the present embodiment, as an example, six flat plate portions 601 are provided, and the flat plate portions 601 are arranged side by side in the horizontal direction. That is, the flat plate portions 601 adjacent in the horizontal direction face each other in the horizontal direction. The flat plate portion 601 has a shape extending in the vertical direction when the vibrating body 5 is stationary (the state shown in FIG. 7).

  Ends on one side in the vertical direction of the flat plate portions 601 that are adjacent to each other in the horizontal direction are connected by a connecting portion 602A. The other ends in the vertical direction of the flat plate portions 601 that are adjacent to each other in the horizontal direction are connected by a connecting portion 602B. The connecting portion 602A is bent to one side in the vertical direction. The connecting portion 602B bends to the other side in the vertical direction. The flat plate portion 601 is alternately connected by the connecting portions 602A and 602B as it proceeds in the lateral direction. That is, in the example of the present embodiment, three connecting portions 602A are arranged in the horizontal direction on one side in the vertical direction, and two connecting portions 602B are arranged in the horizontal direction on the other side in the vertical direction.

  The first flat plate portion 6011 located at one end in the horizontal direction of the flat plate portion 601 is fixed to the inner wall of the side surface portion 1200 </ b> A of the cover 1200. That is, the first flat plate portion 6011 is fixed to the housing 10 including the cover 1200 and the base plate 11. In addition, the second flat plate portion 6012 located at the other lateral end of the flat plate portion 601 is fixed to the first weight portion 58A. That is, the second flat plate portion 6012 is fixed to the vibrating body 5.

  The first damper member 81A is disposed in a space 6011A adjacent to the other longitudinal side of the first flat plate portion 6011. The first damper member 81A is fixed to only the inner wall of the inner wall of the side surface portion 1200A of the cover 1200 and the flat plate portion 601 adjacent to the first flat plate portion 6011 with, for example, a double-sided tape.

  If the first damper member 81 </ b> A is fixed to the flat plate portion 601 adjacent to the first flat plate portion 6011, the fixing surface of the flat plate portion 601 may be bent and stable fixing may not be maintained. Since the fixing surface is not deformed when it is fixed to the housing 10 as in this embodiment, a stable fixing strength can be ensured. In addition, when fixing to the flat plate portion 601, the fixing surface may be deformed by pressing the first damper member 81A or the like, but there is no such concern when fixing to the housing 10 side. Can be fixed more reliably.

  The first damper member 81A can be fixed to at least one of the inner wall and the flat plate portion 601.

  The second damper member 82A is disposed in a space 6012A adjacent to the other side in the longitudinal direction of the second flat plate portion 6012. The second damper member 82A is fixed to only the first weight portion 58A among the first weight portion 58A and the flat plate portion 601 adjacent to the second flat plate portion 6012 by, for example, a double-sided tape.

  If the second damper member 82A is fixed to the flat plate portion 601 adjacent to the second flat plate portion 6012, the fixing surface of the flat plate portion 601 may be bent, so that stable fixing may not be maintained. Since the fixing surface is not deformed when it is fixed to the first weight portion 58A as in the present embodiment, a stable fixing strength can be ensured. Further, in the fixing operation, the fixing surface may be deformed by pressing the second damper member 82A and the like when being fixed to the flat plate portion 601, but there is such a concern when fixing to the first weight portion 58A side. Since there is no, it can fix more reliably.

  The second damper member 82A can be fixed to at least one of the first weight portion 58A and the flat plate portion 601.

  The elastic member 70 has the same configuration as the elastic member 60, and the elastic member 70 includes a plurality of flat plate portions 701, a connecting portion 702A, and a connecting portion 702B. A first flat plate portion 7011 located at the other lateral end of the flat plate portion 701 is fixed to the inner wall of the side surface portion 1200B of the case 1200, and a second flat plate portion 7012 located at one lateral end of the flat plate portion 701 is provided. It is fixed to the second weight part 58B.

  The first damper member 81B is disposed in a space 7011A adjacent to one side in the longitudinal direction of the first flat plate portion 7011. The first damper member 81B is fixed to, for example, the inner wall of the inner wall of the side surface portion 1200B of the cover 1200 and the flat plate portion 701 adjacent to the first flat plate portion 7011 with, for example, a double-sided tape.

  The second damper member 82B is disposed in a space 7012A adjacent to one side in the longitudinal direction of the second flat plate portion 7012. Of the second weight member 58B and the flat plate portion 701 adjacent to the second flat plate portion 7012, the second damper member 82B is fixed, for example, only to the second weight portion 58B with a double-sided tape, for example.

  The first damper members 81A and 81B and the second damper members 82A and 82B can increase the vibration attenuation of the vibrating body 5 and ensure stable vibration. That is, vibration damping performance can be improved. In addition, the elastic members 60 and 70 are given resistance by the first damper members 81A and 81B and the second damper members 82A and 82B, so that the elastic members 60 and 70 are prevented from bending in the vertical direction, and the vibrating body 5 Can be prevented from contacting the cover 1200. Further, since the number of damper members is small, the assembly work of the damper members becomes efficient.

  Further, as shown in FIG. 7, the top surface portion 1201 of the cover 1200 is formed with through holes 1201A to 1201D in addition to the first through hole 121A and the second through hole 121B described above. The through holes 1201A to 1201D penetrate the top surface portion 1201 in the vertical direction. Each of the through holes 1201A to 1201D is positioned above the damper members 81A, 82A, 81B, and 82B, and faces the damper members 81A, 82A, 81B, and 82B in the vertical direction.

  Thereby, when the vibration motor 101 is assembled, the damper members are assembled from the outside of the housing 10 through the through holes 1201A to 1201D in a state where the elastic members 60 and 70 and the vibrating body 5 are assembled inside the housing 10. Can do. When the damper member is assembled first, the damper member may be deformed when other members are assembled. By assembling using the through holes 1201A to 1201D in this way, the deformation of the damper member is suppressed. The damper member can be easily assembled. It is easy to insert the damper member into the spaces 6011A, 6012A, 7011A, and 7012A through the through holes 1201A to 1201D.

  In addition, as for the through holes 1201A to 1201D, round portions may be provided at the four corners similarly to the through holes 121A and 121B. However, the through holes 1210A to 1201D require less molding accuracy than the through holes 121A and 121B.

<5. Second Modification>
FIG. 9 is a partially exploded perspective view of the vibration motor 102 according to the second modification with the cover 1210 removed.

  The structural differences of the vibration motor 102 from the vibration motor 100 described above are a cover 1210, an elastic member 62, and damper members 810A and 820A.

  The elastic member 62 has a first flat plate portion 621 at one lateral end and a second flat plate portion 622 at the other lateral end. First flat plate portion 621 is fixed to the inner wall of side surface portion 1201 </ b> A of cover 1210. The second flat plate portion 622 is fixed to the first weight portion 58A.

  FIG. 10 is a view of the first flat plate portion 621 or the second flat plate portion 622 viewed in the horizontal direction. The first flat plate portion 621 has a cutout 621A having a shape cut out from the upper edge to the lower side. The first damper member 810A is disposed in the notch 621A. For example, the first damper member 810A is fixed only to the inner wall of the side wall portion 1210A and the flat plate portion, but can be fixed to at least one as in the first modification described above.

  The second flat plate portion 622 has a cutout 622A having a shape cut out from the upper edge to the lower side. The second damper member 820A is disposed in the notch 622A. For example, the second damper member 820A is fixed only to the first weight portion 58A of the first weight portion 58A and the flat plate portion, but can be fixed to at least one as in the above-described first modification.

  The vibration damping performance of the vibrating body 5 can be improved by the first damper member 810A and the second damper member 820A. Further, since the number of damper members is small, the assembly work of the damper members becomes efficient.

  Further, as shown in FIG. 9, through holes 1211 </ b> A and 1211 </ b> B that penetrate in the vertical direction are formed in the top surface portion 1211 of the case 1210. The through hole 1211A is located above the first damper member 810A and faces the first damper member 810A in the vertical direction. The through hole 1211B is located above the second damper member 820A and faces the second damper member 820A in the vertical direction.

  Thereby, damper member 810A, 820A can be assembled | attached via through-hole 1211A, 1211B, and a deformation | transformation of a damper member can be suppressed. Moreover, it is easy to insert the damper member into the notches 621A and 622A through the through holes 1211A and 1211B.

  Note that the notch may have a shape that is notched upward from the lower edge of the first flat plate portion 621 and the second flat plate portion 622. In this case, a through hole may be provided in the base plate below the notch.

<6. Tactile device>
As shown in FIG. 11, the vibration motors of the above-described embodiments including the vibration motor 100 can be mounted on the haptic device 200, for example. The tactile device 200 gives a tactile stimulus to a person who operates the tactile device 200 by the vibration of the vibration motor 100. As the haptic device 200, for example, a mobile phone including a smartphone, a tablet, a game device, and a wearable terminal can be employed.

  The haptic device 200 according to the present embodiment includes the vibration motor 100, a substrate 110 on which the vibration motor 100 is mounted, and a control unit 120. The vibration motor 100 is electrically and mechanically connected to the substrate 110. The control unit 120 outputs a drive current to the vibration motor 100 via the substrate 110. The vibration motor 100 vibrates according to a drive signal from the control unit 120. The tactile device 200 vibrates so as to give a tactile stimulus to a person who operates the tactile device 200 by the vibration of the vibration motor 100.

<7. Effects according to this embodiment>
As described above, the vibration motor (100, etc.) according to the present embodiment includes a stationary part S having a housing (1, etc.), a vibrating body 5 supported so as to be able to vibrate laterally with respect to the housing, And an elastic member (such as 6A) positioned between the casing and the vibrating body, and a damper member (such as 59A). The casing has a through hole (121A or the like) facing the damper member in the vertical direction.

  According to such a configuration, at the time of assembling the vibration motor, the damper member can be assembled from the outside of the casing through the through hole in a state where the elastic member and the vibrating body are assembled inside the casing. Therefore, it is possible to easily assemble the damper member while suppressing deformation of the damper member.

  The stationary portion S has a coil portion L disposed inside the vibrating body 5, and the damper member 59 </ b> A is fixed to one end portion in the lateral direction of the coil portion. In the operating state, the vibrating body comes into contact with the damper member.

  Thereby, a vibration body contacts a damper member at the time of normal operation, and the vibration of a vibration body is stabilized and a noise can be reduced. Moreover, it is easy to fix the damper member to the end of the coil portion through the through hole.

  The elastic member 60 includes at least three flat plate portions 601 that are arranged to face each other in the horizontal direction, and connecting portions 602A and 602B that connect the end portions of the flat plate portions adjacent in the horizontal direction. The first flat plate portion 6011 which is the flat plate portion arranged at one end in the horizontal direction is fixed to the inner wall of the housing 10 and the second flat plate portion 6012 which is the flat plate portion arranged at the other end in the horizontal direction. Is fixed to the vibrating body 5, and the damper members 81A and 82A are provided in at least one of a space 6011A vertically adjacent to the first flat plate portion and a space 6012A vertically adjacent to the second flat plate portion. Be placed.

  Thereby, the vibration damping performance of the vibrating body can be improved by the damper member. Further, it is easy to assemble the damper member in the space through the through hole, and the work efficiency is improved because the number of the damper members is small.

  The elastic member 62 includes at least three flat plate portions arranged to face each other in the horizontal direction and a connecting portion that connects ends of the flat plate portions adjacent in the horizontal direction. The first flat plate portion 621 that is the flat plate portion arranged at the side end is fixed to the inner wall of the housing, and the second flat plate portion 622 that is the flat plate portion arranged at the other end in the lateral direction is the vibrating body. 5, at least one of the first flat plate portion and the second flat plate portion is provided with notches 621A and 622A, and at least one of the notches has a shape cut out from the upper edge of the flat plate portion to the lower side. Alternatively, the damper member 810A, 820A is disposed in the notch from the lower edge of the flat plate portion to the upper side.

  Thereby, the vibration damping performance of the vibrating body can be improved by the damper member. Further, it is easy to assemble the damper member into the notch through the through hole, and the work efficiency is improved because the number of the damper members is small.

  Further, the through hole (121A, etc.) has a rounded portion (R1, etc.) at the corner. Thereby, the stress concentration produced at the corners of the through holes can be suppressed, and deformation of the housing can be suppressed.

<8. Other>
As mentioned above, although embodiment of this invention was described, if it is in the range of the meaning of this invention, embodiment may be variously deformed.

  The present invention can be used for a vibration motor provided in, for example, a smartphone, a wearable device, and the like.

  DESCRIPTION OF SYMBOLS 100-102 ... Vibration motor, S ... Static part, 1, 10 ... Case, 11 ... Base plate, 12, 1200, 1210 ... Cover, 2 ... Substrate, L ... -Coil part, 3 ... core, 3A ... core part, 3B ... plate part, 4 ... winding part, 5 ... vibrating body, 52 ... first plate, 53 ... -2nd plate, M1 ... 1st magnet part, M2 ... 2nd magnet part, 54A, 54B ... 1st magnet, 55A, 55B ... 2nd magnet, 56A, 56B ... 1st 3 magnets, 57A ... 1st magnetic piece, 57B ... 2nd magnetic piece, 58A ... 1st weight part, 58B ... 2nd weight part, 59A ... 1st damper member, 59B. ..Second damper member, 591 ... outer layer, 592 ... inner layer, 6, 7 ... elastic member, 61, 71 ... flat plate , 62A, 62B, 72A, 72B ... connecting part, 611, 711 ... first flat plate part, 612, 712 ... second flat plate part, 121A ... first through hole, 121B ... first 2 through-holes, 1201A to 1201D... Through-holes, R1, R2... Rounded portion, H1, H2... Recessed, 60, 70. First flat plate portion, 6012, second flat plate portion, 602A, 602B, connection portion, 81A, first damper member, 82A, second damper member, 701, flat plate portion, 7011. ..First flat plate portion, 7012 ... second flat plate portion, 702A, 702B ... connecting portion, 81B ... first damper member, 82B ... second damper member, 1211A, 1211B ... through Hole 62... Elastic member 621. -1st flat plate part, 622 ... 2nd flat plate part, 621A, 622A ... Notch, 810A ... 1st damper member, 820A ... 2nd damper member, 110 ... Substrate, 120 ..Control unit, 200 ... tactile device

Claims (5)

A stationary part having a housing;
A vibrating body supported so as to be able to vibrate laterally with respect to the housing;
An elastic member positioned between the housing and the vibrating body;
A damper member;
With
The housing has a through hole facing the damper member in the vertical direction.
Vibration motor. The stationary part has a coil part arranged inside the vibrating body,
The damper member is fixed to one end portion in the lateral direction of the coil portion,
The vibration motor according to claim 1, wherein the vibration body is in contact with the damper member in a normal operation state of the vibration body. The elastic member has at least three flat plate portions disposed to face each other in the horizontal direction, and a connecting portion that connects ends of the flat plate portions adjacent in the horizontal direction.
The first flat plate portion, which is the flat plate portion arranged at one side end in the lateral direction, is fixed to the inner wall of the housing,
The second flat plate portion, which is the flat plate portion arranged at the other end in the lateral direction, is fixed to the vibrating body,
2. The vibration motor according to claim 1, wherein the damper member is disposed in at least one of a space vertically adjacent to the first flat plate portion and a space adjacent to the second flat plate portion in the vertical direction. The elastic member has at least three flat plate portions disposed to face each other in the horizontal direction, and a connecting portion that connects ends of the flat plate portions adjacent in the horizontal direction.
The first flat plate portion, which is the flat plate portion arranged at one side end in the lateral direction, is fixed to the inner wall of the housing,
The second flat plate portion, which is the flat plate portion arranged at the other end in the lateral direction, is fixed to the vibrating body,
A notch is provided in at least one of the first flat plate portion and the second flat plate portion,
At least one of the notches is a shape that is notched downward from the upper edge of the flat plate portion, or a shape that is notched upward from the lower edge of the flat plate portion,
The vibration motor according to claim 1, wherein the damper member is disposed in the notch.   The vibration motor according to any one of claims 1 to 4, wherein the through hole has a rounded portion at a corner.

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