KR100303880B1 - A vibrator - Google Patents

Abstract

The present invention relates to a vibrator for generating a vibration force by applying a magnetic field using a magnetostrictive element, the present invention as a means for achieving the above object the shaft,

A vibrating member for joining a rod-shaped magnetostrictive element and a nonmagnetic element to each other and fixedly supported on the shaft;

A coil wound around the outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element;

It is configured to be provided as a cover member for covering the shaft, the vibration member and the coil from the outside while fixing the shaft, a magnetic field is applied through the coil by a power source applied from the outside to cause the deformation of the magnetostrictive element The vibration force is caused by the vibration force is transmitted through the shaft and the cover member so that the vibration can be sensed, thereby providing a vibrator to facilitate the miniaturization in a simpler configuration.

Description

Vibrator {A vibrator}

The present invention relates to a vibrator, and more particularly, to a vibrator for generating a vibration force by applying a magnetic field using a magnetostrictive element.

In general, when a call is received or a message is received from a personal mobile communication device such as a mobile phone or a pager, the called device is notified. This is mainly used as a ringing device or a melody such as a bell or a melody. It is a vibration function.

In such a receiving device, in particular, the vibration motor is provided for the vibration function, most of the vibration motors currently used is the interaction between the coil (5) and the magnet (6) by the power input from the outside as shown in FIG. By causing electromagnetic force to be generated to drive the rotor eccentrically, the eccentric driving force generated at this time is transmitted to the case of the device so that the vibration is detected.

In this case, in order to allow the coil 5 to be energized, the flexible substrate 1, the brush 2, the commutator 3, the hard substrate 4, and the coil 5 must be provided and opposed to the coil 5. The magnet 6 should be attached to the position.

In addition, for the eccentric driving of the hard substrate 4, the hard substrate 4 is manufactured in a shape in which the center of gravity is biased to one side, and the hard substrate 4 must be rotatably supported by the shaft 7 so that the bearing ( Should be supported by 8).

With such a large number of parts, in particular, in order to form the commutator 3 composed of a plurality of segments on the hard substrate 4 integrally, the hard substrate 4 and the commutator 3 are integrally combined by insert injection. There is a difficulty in manufacturing and assembling, which must be molded, and a pair of coils 5 must be disposed at an appropriate electric angle on the top of the hard substrate 4.

In addition, the number of parts and assembly process required for the production of such a vibrating motor is excessive, there is a problem that the cost is increased and the burden of manufacturing cost increases.

In particular, there is a limit to the thinning of the vibration motor in the situation that the miniaturization of the device is urgently required.

Accordingly, the present invention is to solve the above problems, the present invention is to obtain a vibration force by a simpler configuration by causing the vibration means that the magnetic deformation element and the non-magnetic deformation element is integrally coupled to the shaft by the electromagnetic force. The main purpose is to make it possible.

In addition, the present invention has another object to facilitate the miniaturization of the device.

And another object of the present invention to significantly reduce the manufacturing cost of the device.

1 is a side cross-sectional view showing a conventional vibration motor,

2 is a side cross-sectional view showing one embodiment in a first embodiment according to the present invention;

3 is a plan sectional view showing another embodiment in the first embodiment;

Figure 4 is a side cross-sectional view showing an operating state according to the embodiment of FIG.

5 is a plan sectional view showing an operating state according to the embodiment of FIG.

6 is a plan sectional view showing an embodiment of a second embodiment according to the present invention;

7 is a plan sectional view showing an operating state according to the embodiment of FIG.

8 is a side sectional view showing another embodiment of the second embodiment;

9 is a plan sectional view showing an operating state according to the embodiment of FIG. 8;

10 is a side sectional view showing a third embodiment according to the present invention;

11 is a side cross-sectional view showing an operating state according to the embodiment of FIG.

12 is a side sectional view showing a fourth embodiment according to the present invention;

FIG. 13 is a partially enlarged perspective view illustrating a coupling structure of the vibration member of FIG. 12; FIG.

14 is an example of the voltage waveform input to the coil of the present invention.

<Description of the symbols for the main parts of the drawings>

10: shaft 20: vibration member

21 magnetostrictive element 22 magnetostrictive element

30 coil 40 cover member

The present invention and the shaft to achieve the above object,

A vibrating member for joining a rod-shaped magnetostrictive element and a nonmagnetic element to each other and fixedly supported on the shaft;

A coil wound around the outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element;

It is characterized in that the configuration provided with a cover member for covering the shaft and the vibration member and the coil from the outside while fixing the shaft.

That is, the present invention uses a magnetostrictive element whose shape changes when a magnetic field is applied as a means for causing vibration.

Magnetostrictive elements have already been known for a long time, and in the past, the magnetostriction was too small to be used, but recently, a device exhibiting a large magnetostriction even at room temperature has been found.

On the other hand, magnetostriction in a magnetostrictive element is a phenomenon that occurs when the shape of the magnetostrictive element changes in order to preserve the total energy to a minimum.

Therefore, the present invention is to replace the vibration motor by causing the vibration by applying the device using such a magnetostriction property.

In particular, the magnetostrictive properties of the magnetostrictive elements are integrated into the deformation direction of the magnetostrictive elements so that the restoring force can be performed more quickly. The member is configured to be joined to cause vibration.

When described in detail with reference to the accompanying drawings a specific embodiment according to the present invention as follows.

2 shows a first embodiment according to the present invention, the main configuration of which is the shaft 10, the vibration member 20 mounted on the shaft 10, and the coil 30. And a cover member 40.

That is, the shaft 10 is a vertical rod, and the vibration member 20 mounted on the shaft 10 joins the rod-shaped magnetostrictive element 21 and the nonmagnetic element 22 to each other to form the shaft 10. One end is coupled to the configuration so that the eccentric support.

The coil 30 is configured to be wound around the outer circumferential surface of the vibration member 20 including the magnetostrictive element 21 and the nonmagnetic element 22 to form a magnetic field by a power source applied from the outside, and the cover member 40 ) Is detachably coupled to the bracket 41 for firmly fixing the shaft 10 and the cover 42 for protecting the shaft 10 and the vibrating member 20 and the coil 30 from outside. It is a configuration to make it possible.

In particular, the vibrating member 20 may be formed in a configuration in which the magnetostrictive element 21 and the nonmagnetic deformable element 22 are bonded to each other, as described above, and are joined to each other up and down, as shown in FIG. It may be formed in a circumferential direction, i.e., a structure joined to the left and right.

This is a very important arrangement to determine the bending deformation direction of the vibration member 20.

Looking at the operation of the present embodiment according to such a configuration when the power supplied from the outside is applied to the coil 30 to form a magnetic field, the magnetostrictive element 21 of the vibration member 20 is bent deformation by its own deformation characteristics At this time, the non-magnetic deformation element 22 integrally bonded with the magnetostriction element 21 is also forcibly bent.

In particular, when the vibration member 20 is formed in a structure in which one end is supported so as to be eccentric with respect to the shaft 10, the amount of deformation at the other end becomes larger.

When the application of the magnetic field to the coil 30 is stopped, the magnetostrictive element 21 is restored to its original state by the property of restoring to the original shape of the nonmagnetic element 22.

Deformation of the vibration member 20 is determined as shown in Figs. 4 and 5 depending on where the magnetostrictive element 21 is bonded to the non-magnetic deformation element 22.

That is, in the case where the magnetostrictive element 21 and the non-magnetic element 22 are joined up and down on the same horizontal line, the vibration member 20 is deflected in the opposite direction in which the magnetostrictive element 21 is positioned. The vibration member 20 is caused by the magnetostrictive element 21 when the magnetostrictive element 21 and the nonmagnetic element 22 are laterally joined in the circumferential direction. The bending deformation in the circumferential direction causes the vibration force in the radial direction of the shaft.

When the deformation and restoration of the vibrating member 20 are repeatedly performed at regular intervals, the deformed shock of the vibrating member 20 which is eccentrically supported is transmitted to the shaft 10. Vibration force is induced, and the vibration is transmitted to the case of the device through the bracket 41 of the cover member 40 to perform a reception function capable of sufficiently sensing.

In addition, when the heavy weight body 50 is formed integrally with the outer end corresponding to one end supported by the shaft 10 of the vibration member 20, the eccentric load of the vibration member 20 becomes larger and larger. It is more effective because vibration force can be obtained.

6 shows a second embodiment according to the present invention. As shown in the drawing, the outside of the present embodiment is wrapped by a cover member 40 provided with a bracket 41 and a case 42. The shaft 10 is firmly mounted, and the shaft 10 is provided with a vibration means 20, which is similar to the configuration of the first embodiment described above.

However, in the present embodiment, the vibration means 20 firmly fixed to the shaft 10 is to ensure that the central portion is stably supported with respect to the shaft 10.

That is, the rod-shaped magnetostrictive elements 21 and the non-magnetic element 22 are arranged on the same horizontal line in the cross direction with respect to the shaft 10 so as to be integrally bonded to one another, and one end is simultaneously joined. The central portion is to be fixed to the shaft (10). Therefore, the non-magnetic straining rod 22 is joined to the side and the rear end of the magnetostrictive rod 21, and the magnetostrictive rod 21 is bonded to the non-magnetic straining rod 22 at the same time in the cross direction. The central portion is to be firmly coupled to the shaft 10 to be fixed.

In this configuration, as the outer peripheral surfaces of the magnetostrictive bar 21 and the non-magnetic deformation bar 22, which are provided with the vibration means 20 and joined to each other, a coil 30 for forming a magnetic field by power supplied from the outside is provided. Allow winding.

Therefore, as the magnetic field is applied to the coil 30, the vibration member 20 is flexurally deformed in the circumferential direction of the shaft 10 by the deformable property of the magnetostrictive rod 21, as shown in FIG. 10) to cause vibration in the radial direction of the shaft.

Meanwhile, in the present embodiment, the vibrating member 20 may be formed in a structure as shown in FIG. 8, that is, the vibrating member 20 having the above-described configuration may be formed in a plurality of layers with a predetermined height difference on the shaft 10. It is more preferable that the vibration member 20 formed as a double layer has a structure shifted in the cross direction so as not to overlap with each other on a vertical line as shown in FIG. 9.

In this embodiment, as in the first embodiment, both ends of the vibrating member 20 are integrally bonded to the heavy body 50 of the non-heavy material so as to maximize the bending deformation of the vibrating member 20. .

FIG. 10 shows a third embodiment according to the present invention, in which the shaft 10, the coil 30 wound around the vibration member 20, and the cover member 40 are disconnected from the outside. The structure enclosed by) is substantially the same as in the first and second embodiments.

In this embodiment, however, the main member is fixed to the shaft 10 after the vibration member 20 is joined to the rod-shaped magnetostrictive element 21 and the non-magnetic element 22 up and down. to be.

That is, in the first embodiment, the vibration member 20 is eccentrically supported on the shaft 10. However, in the present embodiment, the magnetostrictive element 21 and the non-magnetic deformation element 22 are stacked on top of each other. This center portion is configured to be firmly fixed to the shaft 10 so that the center of gravity in the center.

When a magnetic field is applied to the vibrating member 20 as shown in FIG. 11, both ends of the vibrating member 20 are bent in the up and down directions in which the magnetostrictive elements 21 are positioned, and the shaft 10 is axially disposed. Will cause the vibration of the.

Therefore, when the magnetostrictive element 21 of the vibrating member 20 is joined to the upper portion of the nonmagnetic deformable element 22 as shown in the previous figure, both ends of the vibrating member 20 are upwardly deflected, and vice versa When the element 21 is bonded to the lower portion of the non-magnetic deformation element 22, both ends of the vibrating member 20 has a function of downward bending deformation.

On the other hand, as in the second embodiment, the vibration member 20 in the present embodiment can be formed in multiple layers with a predetermined height difference on the shaft 10. In this case, in particular, the vibration member 20 is deflected up and down. It is more preferable that the vibrating members 20 formed in a plurality of layers so as to be completely excluded from each other when the interference of operation is formed are shifted from each other in the cross direction as shown in FIG. 9.

In addition, in the present embodiment, both ends of the vibrating member 20 are most preferably such that the weight 50 of the high specific gravity material is integrally joined to maximize the bending deformation of the vibrating member 20.

According to the configuration of the present embodiment as described above, the application of the magnetic field is interrupted by the vibration member 20 to transmit the vibration force in the axial direction through the shaft 10 to the cover member 40. Incoming call through the case can be performed smoothly.

FIG. 12 shows a fourth embodiment according to the present invention, in which the shaft 10, the coil 30 and the cover member 40 in the present embodiment are constructed in the first, second and third embodiments. Is the same as

In this embodiment, however, the first vibration member 20a and the second vibration member 20b are provided with a predetermined height difference on the shaft 10, but the first vibration member 20a is a rod-shaped magnetostrictive element 21. ) And the nonmagnetic deforming element 22 are arranged so that the same elements are integrally bonded to each other by being arranged in the cross direction on the same horizontal line, and the second vibration member 20b includes the magnetostrictive element 21 and the nonmagnetic deforming element. It is to be provided in the structure which 22 is joined up and down.

The first vibrating member 20a is fixed to the shaft 10 at a central portion at which one end of each element is simultaneously joined, and the second vibrating member 20b is a magnetostrictive element 21 and a nonmagnetic element that are stacked up and down. The central portion of 22 is fixed to the shaft 10 at the same time.

Therefore, the first vibration member 20a has the same configuration as the vibration member of the second embodiment of the present invention, and the second vibration member 20b has the same configuration as the vibration member of the third embodiment, and in this embodiment, such a second embodiment. The main feature is that the vibration member in the third embodiment and provided on the shaft 10 at the same time.

The action according to the present embodiment is to first apply power to the coils 30 wound around each of the vibration members 20 to form a magnetic field, and as shown in FIG. 13 by forming the magnetic fields on the coils 30. As described above, the first vibration member 20a generates vibration force in the circumferential direction with respect to the shaft 10 to cause incoming vibration in the radial direction of the shaft, and the second vibration member 20b with respect to the shaft 10. Since the vibration force in the vertical direction is generated to cause the incoming vibration in the axial direction, it is possible to induce the omnidirectional vibration by simultaneously operating the first vibration member 20a and the second vibration member 20b.

Meanwhile, in this embodiment, it is most preferable that both ends of the vibrating member 20 are integrally bonded to the heavy body 50 of the high specific gravity so that the bending deformation of the vibrating member 20 is maximized.

As shown in the embodiments of the configuration as described above, the present invention is to cause a vibration by repeatedly bending and restoring the deflection member 20 of the vibration member 20, each coil 30 is a constant voltage Figure 14 Vibration function is to be performed by the power supplied for a predetermined time in the form of a square wave or a sine wave as shown in.

Therefore, while the conventional vibration motor is difficult to manufacture due to structural problems, that is, a complicated configuration, and the manufacturing cost is also expensive, the present invention makes it possible to provide an inexpensive product by simplifying the structure.

In addition, the conventional vibration motor is a configuration that rotates the rotor with respect to the shaft was very disadvantageous in terms of mechanical stability, while the present invention simply bending the vibration member 20 fixed to the shaft 10 in the vertical or circumferential direction Because of the configuration to make it has a stable operating characteristics.

Therefore, the present invention enables the vibration to be generated more simply by using an element that causes magnetic deformation when applying a magnetic field, thereby improving productivity according to the fabrication of the vibration means and the reduction of parts.

In addition, the present invention can completely eliminate the operation noise because the friction at the time of vibration is not involved at all, and in particular, the miniaturization and thinning is easy to facilitate the miniaturization and thinning of the equipment used, and at the same time significantly reduce the production cost. It has a very useful effect.

Claims (13)

A shaft; A vibration member having a rod-shaped magnetostrictive element and a nonmagnetic element deformed to each other so that one end thereof is eccentrically fixed to the shaft; A coil wound around an outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element; And A cover member which covers the shaft, the vibration member and the coil from the outside while fixing the shaft; Vibrator made up of. The method of claim 1, wherein the vibration member A vibrator in which a magnetostrictive element and a nonmagnetic element are joined laterally and bent in a circumferential direction by a magnetic field applied to a coil. The method of claim 1, wherein the vibration member A vibrator in which a magnetostrictive element and a nonmagnetic element are joined up and down and bent up and down by a magnetic field applied to a coil. The method of claim 1, wherein the vibration member A vibrator in which a heavy body of high specific gravity is attached to an outer end corresponding to an end supported by a shaft. A shaft; A vibration member in which a bar-shaped magnetostrictive element and a non-magnetic element are arranged in the cross direction on the same horizontal line so as to be integrally bonded to each other, and a central portion having one end joined at the same time is fixed to the shaft; A coil wound around an outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element; And A cover member which covers the shaft, the vibration member and the coil from the outside while fixing the shaft; Vibrator made up of. The method of claim 5, wherein the vibration member A vibrator provided in a plurality of layers with a predetermined height difference from the shaft. The vibration member of claim 6, wherein Vibrator provided in the cross direction so as not to overlap each other on a vertical line. The method of claim 5, wherein the vibration member Vibrator with high weight heavy material attached to both ends. A shaft; A vibrating member in which a bar-shaped magnetostrictive element and a nonmagnetic element are joined up and down to fix a central portion to the shaft; A coil wound around an outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element; And A cover member which covers the shaft, the vibration member and the coil from the outside while fixing the shaft; Vibrator made up of. The method of claim 9, wherein the vibration member A vibrator provided in a plurality of layers with a predetermined height difference from the shaft. The method of claim 9, wherein the vibration member Vibrator with high weight heavy material attached to both ends. A shaft; The first vibration member in which the bar-shaped magnetostrictive element and the non-magnetic element are arranged in the cross direction on the same horizontal line so as to be integrally bonded to each other, and the central part joined at the end of the movement is fixed to the shaft. And a vibrating member including a second vibrating member fixed to the shaft with a predetermined height difference from the first vibrating member by joining the magnetostrictive element and the nonmagnetic deformable element up and down. A coil wound around an outer circumferential surface of the vibration member to apply a magnetic field to the magnetostrictive element; And A cover member which covers the shaft, the vibration member and the coil from the outside while fixing the shaft; Vibrator made up of. The method of claim 12, wherein the first vibration member and the second vibration member of the vibration member Vibrator with high weight heavy material attached to both ends.