JP2003163981A - Electric/mechanical/acoustic transducer and portable terminal equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric/mechanical/acoustic transducer capable of obtaining a stable and sufficiently large mechanical vibrating force even when a use condition is changed. <P>SOLUTION: The electric/mechanical/acoustic transducer is provided with a diaphragm, a movable section, a driving section for generating a driving force for vibrating the diaphragm and the movable section, and a suppressing means for suppressing the sharpness of a vibrating force to be obtained by the vibration of the movable section. Also, this portable terminal equipment is provided with a case body and an electric/mechanical/acoustic transducer installed in the case body. The case body is formed with a sound hole so that a sound to be generated by the electric/mechanical/acoustic transducer can be emitted. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electro-mechanical-acoustic transducer that performs mechanical vibration or sound generation by an electric signal, and a portable terminal device equipped with the same.

[0002]

2. Description of the Related Art Conventionally, as means for notifying an incoming call, a portable telephone has been equipped with a sounding body which produces a bell or melody tone and a micromotor which produces mechanical vibration. Furthermore, it is necessary to mount a receiving speaker (that is, a receiver) for reproducing the receiving sound.

Therefore, in order to reduce the size and weight of a mobile terminal device such as a mobile phone and reduce the number of parts, two functions of sound generation and mechanical vibration are realized by one electric-mechanical-acoustic transducer. A mechanism was devised (Saikaihei 5-8519
No. 2).

Such an electro-mechanical-acoustic transducer 500
0 is shown in FIG. In the electro-mechanical-acoustic transducer 5000, the outer peripheral portion of the circular diaphragm 1 is attached to the case 2. The case 2 is provided with a bottom plate 5, and the yoke 3
Is fixed to the bottom plate 5. The suspension 6 is supported by the case 2, and the magnet 4 is the suspension 6.
Supported by.

The voice coil 7 is inserted into a magnetic gap formed between the inner peripheral surface of the yoke 3 and the outer peripheral surface of the magnet 4, and one end thereof is fixed to the diaphragm 1. York 3
And the magnet 4 form a magnetic circuit, and the suspension 6 and the magnet 4 form a mechanical vibration system.

[0006]

In the above-mentioned electro-mechanical-acoustic transducer 5000, when an electric signal is applied to the voice coil 7, the voice coil 7 and the magnetic circuit are connected to each other.
The action / reaction force works. If the force acting on the voice coil 7 is assumed to be the action force, the force causes the voice coil 7 to move.
The diaphragm 1 to which is attached vibrates to generate sound.

Further, the reaction force acting on the magnetic circuit causes the magnet 4 supported by the suspension 6 to vibrate, and the vibration is transmitted to the case 2 via the suspension 6, so that the case 2 vibrates.

However, since the suspension 6 is made of a material such as a leaf spring having a small internal loss, the sharpness of the mechanical vibration force at the resonance frequency becomes large. FIG. 11 shows a frequency characteristic of a mechanical vibration force generated by the vibration of the magnet 4 by a chain line 300.

If the resonance frequency of the mechanical vibration system is f ₀ and the frequencies for generating the mechanical vibration force of 3 dB lower than the value of the mechanical vibration force at the resonance frequency f ₀ are f ₁ and f ₂ , the sharpness Qf _{0 is obtained.} Is represented by formula (1).

Qf ₀ = f ₀ / (f ₂ −f ₁ ) (1) In the electro-mechanical-acoustic transducer 5000, the sharpness of the mechanical vibration force at the resonance frequency of the mechanical vibration system becomes large. Therefore, there is a problem that the resonance frequency of the mechanical vibration system changes due to a change in usage conditions, and if the frequency of the input signal deviates from the resonance frequency even a little, the mechanical vibration force becomes small and sufficient vibration cannot be obtained. Therefore, there is a method of always tracking the resonance frequency and adding a circuit for changing the frequency of the input signal, but there is a problem that the system becomes large.

In order to solve the above-mentioned problems, an object of the present invention is to provide an electro-mechanical-acoustic transducer which can obtain a stable and sufficiently large mechanical vibration force even when the use condition changes. And

[0012]

The electro-mechanical-acoustic transducer of the present invention comprises a diaphragm, a movable part, a drive part for generating a driving force for vibrating the diaphragm and the movable part, and the movable part. And a suppressing unit that suppresses the sharpness of the vibration force obtained by vibrating.

The movable part may have a magnetic circuit for supplying a magnetic flux to the drive part.

The movable portion may further include a weight integrally formed with the magnetic circuit.

The movable part may be arranged so as to face the diaphragm, and the suppressing means may be an elastic body provided on the opposite side of the movable part from the diaphragm.

The elastic body may be a sponge material.

The elastic body may be a spring material.

The vibrating plate is further provided with a supporting portion, and the suppressing means includes a first magnet provided at a position opposite to the vibrating plate of the movable portion, which is provided so as to face the vibrating plate, and a first magnet. The second magnet magnetized in the opposite direction to the first magnet provided on the support portion so as to face the magnet may be provided.

The suppressing means is a suspension that supports the movable part, and the material of the suspension has an internal loss coefficient of 0.
It may be a material of 01 or more.

The suppressing means is a suspension that supports the movable part, and the material of the suspension may be a composite material containing a high-viscosity polymer material.

The suppressing means is a suspension that supports the movable portion, and the material of the suspension may be a dislocation type damping alloy.

The suppressing means is a suspension for supporting the movable part, and the material of the suspension may be a laminated material of at least two kinds of materials having different internal loss coefficients.

The material of the suspension may be a damping steel plate which is a laminated material of metal and resin.

The material of the suspension may be a damping alloy which is a laminated material of at least two kinds of metals.

A supporting part for supporting the vibrating plate is further provided, and a space is formed between the supporting part and the vibrating plate. The dividing part is connected to the movable part and the supporting part and divides the space into two. At least one air hole that communicates the space formed between the split portion and the support portion with the external space is formed in the support portion, and the suppressing means may include the split portion, the support portion, and the at least one air hole. Good.

The portable terminal device of the present invention comprises a casing and an electro-mechanical-acoustic transducer provided in the casing,
The mechanical-acoustic transducer includes a diaphragm, a movable section, a drive section that generates a driving force for vibrating the diaphragm and the movable section,
The movable part is provided with a suppressing means for suppressing the sharpness of the vibration force obtained by vibrating, and a sound hole is formed in the housing so that the sound generated from the electro-mechanical-acoustic transducer is radiated. Therefore, the above object is achieved.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIGS. 1 and 2 show an electro-mechanical-acoustic transducer 1000 according to Embodiment 1 of the present invention. 1 is a plan view of the electro-mechanical-acoustic transducer 1000 taken along the alternate long and short dash line CD shown in FIG. 2, and FIG. 2 is an electrical-mechanical-acoustic transducer taken along the alternate long and short dash line AB shown in FIG. Bowl 1
000 is a sectional view.

The electro-mechanical-acoustic transducer 1000 includes a vibrating plate 108, a movable part 118 arranged to face the vibrating plate 108, and a suspension 11 for supporting the movable part 118.
4, the support portion 109 that supports the vibrating plate 108 and the peripheral portion of the suspension 114, the voice coil 117 that generates a driving force for vibrating the vibrating plate 108 and the movable portion 118, and the vibrating movable portion 118. The suppressing means 200 for suppressing the sharpness of the generated mechanical vibration force.

The circular diaphragm 108 has, for example, a thickness of 10 μm.
It is formed of a resin material such as titanium material or polycarbonate which is a non-magnetic material and has a thickness of about m to 50 μm. The bowl-shaped support portion 109 is formed of a resin material such as plastic. The support 109 may be composed of two or more parts for sandwiching the suspension 114.
The support unit 109 is fixed to a housing 119 such as a mobile terminal device.

The movable part 118 includes the magnetic circuit 116 and the weight 11.
3 and operate relative to the support unit 109.
The magnetic circuit 116 includes a yoke 110 and a magnet 111.
And a plate 112. Bowl-shaped yoke 110
Is formed of a ferromagnetic material such as soft iron. The columnar magnet 111 is made of, for example, rare earth (Nd-F).
It is a permanent magnet of e-B). Cylindrical plate 112
Is formed of a ferromagnetic material such as soft iron, and is provided on the surface of the magnet 111 on the diaphragm 108 side. A magnetic gap 115 is formed between the inner peripheral surface of the yoke 110 and the outer peripheral surface of the plate 112. The weight 113 may be integrally formed with the yoke 110. Weight 1 on the yoke 110
By adding 13 to increase the mass of the movable portion 118, a larger mechanical vibration force can be obtained. The yoke 110 and the magnet 111 are fixed to each other with an adhesive, for example. Also,
The magnet 111 and the plate 112 are also fixed to each other with an adhesive, for example. Suspension 114 and movable part 1
18 forms a mechanical vibration system 120.

The suppressing means 200 is an elastic body such as a columnar sponge material or a spring material. The suppressing means 200 is provided on the movable portion 118 on the side opposite to the diaphragm 108. In the present embodiment shown in FIG. 1, the suppressing means 20
0 is provided on the yoke 110 of the magnetic circuit 116, and the suppressing means 200 vibrates together with the movable portion 118.

A cylindrical voice coil 117 is inserted into the magnetic gap 115, and one end of the voice coil 117 is attached to the diaphragm 108. The magnetic circuit 116 supplies a magnetic flux to the voice coil 117. Voice coil 11
Reference numeral 7 is connected to the drive circuit 101 and functions as a drive unit that generates a drive force for vibrating the diaphragm 108 and the movable unit 118.

The suspension 114 has a shape in which three arcuate arms 114c, 114d and 114e are extended in the circumferential direction, one end 114a of each arm is fixed to the yoke 110 and the weight 113, and the other end 114b is a supporting portion. 109
It is fixed to. The number of arms of the suspension 114 may be two or more, but in order to prevent the magnetic circuit 116 from rolling, three or more arms are desirable. Suspension 114
For example, stainless steel is used as the material of the above in consideration of the spring property.

Next, the operation of the electro-mechanical-acoustic transducer 1000 will be described.

The drive circuit 101 is, for example, a reception signal processing circuit of a mobile terminal device, and when an AC electric signal is applied from the drive circuit 101 to the voice coil 117, an action / reaction occurs between the voice coil 117 and the magnetic circuit 116. Power works. If the force acting on the magnetic circuit 116 is a reaction force, this reaction force is applied to the movable portion 118 supported by the suspension 114, and the movable portion 118 vibrates. For example, when the resonance frequency of the mechanical vibration system 120 composed of the suspension 114 and the movable portion 118 is 150 Hz, the movable portion 118 vibrates and a mechanical vibration force is generated if the electric signal includes a frequency of 200 Hz or less. If the above frequencies are included, the diaphragm 108 vibrates and a sound is generated. In particular, when the frequency of the electric signal applied to the voice coil 117 matches the resonance frequency of the mechanical vibration system 120, a large mechanical vibration force is generated. The mechanical vibration force generated in the movable portion 118 is transmitted to the support portion 109 via the suspension 114, and the support portion 109 and the housing 119 to which the support portion 109 is fixed vibrate. Electric-mechanical-acoustic transducer 1000
Has both mechanical vibration and sound generation functions.

The suppressing means 200 is present between the support 109 and the magnetic circuit 116. Therefore, when the amplitude of the movable portion 118 is large, for example, when the frequency of the electric signal matches the resonance frequency of the mechanical vibration system 120, the suppressing unit 200 is provided.
Is compressed between the support portion 109 and the magnetic circuit 116 to suppress mechanical vibration force.

FIG. 3 shows the frequency characteristic of the mechanical vibration force generated by the vibration of the movable portion 118. The larger the mechanical vibration force is, the larger the movable portion 118 vibrates. The frequency characteristic of the mechanical vibration force when the electro-mechanical-acoustic converter 1000 includes the suppressing means 200 is shown by a solid line 310, and the frequency of the mechanical vibration force when the electro-mechanical-acoustic converter 1000 does not include the suppressing means 200. The characteristic is shown by the dotted line 320. Figure 1
The frequency characteristic of the mechanical vibration force in the conventional electro-mechanical-acoustic converter 5000 shown in FIG.

When the electro-mechanical-acoustic transducer 1000 does not include the suppressing means 200, the sharpness of the mechanical vibration force at the resonance frequency f ₀ becomes large as shown in FIG. On the other hand, the electro-mechanical-acoustic transducer 1000 has the suppressing means 200.
When the movable portion 118 has a large amplitude, the suppressing means 2
00 suppresses the vibration of the movable portion 118. Therefore, the sharpness of the mechanical vibration force at the resonance frequency f ₀ is suppressed by the suppressing means 20.
It is suppressed by 0, and the sharpness becomes small. As the sharpness decreases, the rate of change of the mechanical vibration force with respect to the frequency decreases.
_{It is} possible to reduce the variation of the mechanical vibration force due to the change of ₀ .

The maximum value of the mechanical vibration force when the electro-mechanical-acoustic transducer 1000 includes the suppressing means 200 is
It becomes smaller than the maximum value of the mechanical vibration force when the suppressing means 200 is not provided. Therefore, in order to obtain a sufficient mechanical vibration force, the current value of the electric signal applied from the drive circuit 101 to the voice coil 117 is applied to the voice coil 7 (FIG. 10) of the conventional electro-mechanical-acoustic converter 5000. It is desirable that the current value be larger than the current value of the electric signal. By increasing the current value of the electric signal applied to the voice coil 117, it is possible to obtain the mechanical vibration force having a desired strength even in a state where the sharpness of the mechanical vibration force is suppressed by the suppressing means 200. For example, as shown in FIG. 3, the maximum value of the mechanical vibration force when the electric-mechanical-acoustic converter 1000 includes the suppressing means 200 is the maximum value of the mechanical vibration force in the conventional electric-mechanical-acoustic converter 5000. By setting the current value of the electric signal so as to match with, it is possible to obtain a mechanical vibration force of a desired magnitude.

As described above, since the suppressing means 200 reduces the sharpness of the mechanical vibration force, the movable portion 118 vibrates and the frequency band in which a sufficient mechanical vibration force can be obtained can be expanded. As a result, even when the resonance frequency of the movable portion 118 changes depending on the usage conditions (that is, when the frequency of the electric signal does not match the resonance frequency of the mechanical vibration system 120), a stable and sufficient mechanical vibration force can be obtained. it can.

In the electro-mechanical-acoustic transducer 1000, the sharpness of the mechanical vibration force can be reduced by adding the suppressing means 200.

Further, the means 20 for suppressing the impact such as a drop is also provided.
Since 0 serves as a relaxation agent, damage to the movable portion 118 can be prevented. In addition, the movable portion 11 can be used when the amplitude is large.
8 can be prevented from hitting the support portion 109.

In this embodiment, the suppressing means 200
Is fixed on the magnetic circuit 116, the same effect can be obtained by fixing it on the surface of the supporting portion 109 facing the magnetic circuit 116.

In this embodiment, the movable portion 118 is provided with the magnetic circuit 116 and the weight 113. However, when mechanical vibration force can be sufficiently obtained from the magnetic circuit 116, the movable portion 1
The weight 113 may be omitted from 18.

(Embodiment 2) FIG. 4 shows an electro-mechanical-acoustic transducer 2000 according to Embodiment 2 of the present invention.
FIG. 4 is a sectional view of the electro-mechanical-acoustic transducer 2000. The electro-mechanical-acoustic transducer 2000 comprises the suppressing means 20.
The point that the suppression means 220 is provided instead of 0 is electro-mechanical-
It differs from the acoustic transducer 1000 (FIGS. 1 and 2). The suppressing unit 220 includes a first magnet 201 and a second magnet 202. Electric-mechanical-acoustic transducer 2000
The other components of the electro-mechanical-acoustic transducer 10 are
The same as 00.

The first magnet 201 has a movable portion 118.
Is provided on the opposite side of the diaphragm 108. In the present embodiment, the first magnet 201 is provided above the yoke 110. The second magnet 202 is provided on the surface of the support 109 that faces the first magnet 201. First magnet 201 and second magnet 20
2 is magnetized in the opposite direction so as to repel each other.
5A and 5B are plan views of the first magnet 201 and the second magnet 202. The first magnet 201 and the second magnet 202 are, for example, rare earth (Nd-Fe-B) permanent magnets and have a columnar shape.

Next, the operation of the electro-mechanical-acoustic transducer 2000 will be described.

When an alternating electric signal is applied from the drive circuit 101 to the voice coil 117, an action / reaction force acts between the voice coil 117 and the magnetic circuit 116. The reaction force acting on the magnetic circuit 116 is applied to the movable portion 118 supported by the suspension 114, and the operation of vibrating the movable portion 118 is performed by the electro-mechanical-acoustic transducer 10 of the first embodiment.
The same as 00. Similar to the electro-mechanical-acoustic transducer 1000, when the frequency of the electric signal applied to the voice coil 117 matches the resonance frequency of the mechanical vibration system 120 including the suspension 114 and the movable portion 118,
The movable part 118 vibrates greatly.

The electro-mechanical-acoustic transducer 2000 differs from the electro-mechanical-acoustic transducer 1000 in that the suppressing means 200 is replaced by a suppressing means 220. Suppressing means 220
Since the first magnet 201 and the second magnet 202 included in are magnetized in opposite directions, a force that always repels each other is generated. For example, when the amplitude of the movable portion 118 is large, such as when the frequency of the electric signal and the resonance frequency of the mechanical vibration system 120 match, the distance between the first magnet 201 and the second magnet 202 becomes short, so that the distance between them becomes short. The repulsive force generated at the position increases to suppress the vibration of the movable portion 118. That is, the sharpness of the mechanical vibration force is suppressed by the suppressing means 220, and the sharpness can be reduced. Since the movable portion 118 vibrates and the frequency band in which a sufficient mechanical vibration force can be obtained can be expanded, even if the resonance frequency of the movable portion 118 changes depending on the use conditions, a stable machine of a sufficient size can be obtained. Vibration force can be obtained.

Although the rare earth material is used as the first magnet 201 and the second magnet 202 in the second embodiment, other materials such as ferrite may be used as long as the same effect can be obtained. . The first magnet 201 and the second magnet 202 are cylindrical in shape, but if a sufficient repulsive force can be obtained,
The shape is not particularly limited, and may be a ring type, a rectangular parallelepiped or the like. Further, the shapes do not have to be the same as shown in FIGS. 5A and 5B.

Although the second magnet 202 is provided on the support portion 109 in the second embodiment, it may be provided so as to be embedded in the support portion 109. Similarly, the first magnet 2
01 may also be embedded in the yoke 110.

(Embodiment 3) FIG. 6 shows an electro-mechanical-acoustic transducer 3000 according to Embodiment 3 of the present invention.
FIG. 6 is a sectional view of the electro-mechanical-acoustic transducer 3000.

The electro-mechanical-acoustic transducer 3000 is different from the electro-mechanical-acoustic transducer 1000 (FIGS. 1 and 2) in that a suspension 124 is provided instead of the suspension 114, and that the suppressing means 200 is omitted. different. The suspension 124 supports the movable portion 118 and also functions as a suppressing unit that suppresses the sharpness of the mechanical vibration force generated by the vibration of the movable portion 118. The suspension 124 and the movable part 118 are the mechanical vibration system 12
5 is formed. The other components of the electro-mechanical-acoustic converter 3000 are the same as those of the electro-mechanical-acoustic converter 1000.

The suspension 124 supports the movable portion 118. The suspension 124 is formed of a composite material containing a high-viscosity polymer material (for example, rubber). The suspension 124 has, for example, a three-layer structure of aluminum-rubber-aluminum. As the material of the suspension 124, a material having a high internal loss with respect to the vibration of the mechanical vibration system 125 and damping the vibration is used. The shape of the suspension 124 is the same as that of the suspension 114 (FIGS. 1 and 2) of the first embodiment.

Next, the operation of the electro-mechanical-acoustic converter 3000 will be described.

When an alternating electric signal is applied from the drive circuit 101 to the voice coil 117, an action / reaction force acts between the voice coil 117 and the magnetic circuit 116. The reaction force acting on the magnetic circuit 116 is applied to the movable portion 118 supported by the suspension 124, and the operation of vibrating the movable portion 118 is performed by the electro-mechanical-acoustic transducer 100 of the first embodiment.
The same as 0. Similar to the electro-mechanical-acoustic transducer 1000, when the frequency of the electric signal applied to the voice coil 117 matches the resonance frequency of the mechanical vibration system 125, the movable portion 118 vibrates greatly.

The electro-mechanical-acoustic transducer 3000 is different from the electro-mechanical-acoustic transducer 1000 (FIGS. 1 and 2) in that the suspension 124 is provided instead of the suspension 114 and that the suppressing means 200 is omitted. different. The material of the suspension 124 supporting the movable portion 118 has a high internal loss with respect to the vibration of the mechanical vibration system 125,
A vibration damping material is used. Therefore, when the movable portion 118 has a large amplitude, for example, when the frequency of the electric signal matches the resonance frequency of the mechanical vibration system 125, the suspension 124 having high internal loss suppresses the vibration of the movable portion 118. The sharpness of the mechanical vibration force is suppressed by the suspension 124, and the sharpness can be reduced.

As a result, the suppressing means 200 (elastic body or the like) and the suppressing means 22 as shown in the first and second embodiments.
0 (first magnet 201 and second magnet 2
It is possible to expand the frequency band in which the movable portion 118 vibrates and a sufficient mechanical vibration force can be obtained without adding 02). As a result, the movable part 1 is
Even if the resonance frequency of 18 is changed, a stable and sufficient mechanical vibration force can be obtained.

Since aluminum, which is a metal, is used as the base material of the suspension 124, the suspension 1
An elastic force for 24 to function as a support system can also be secured.

In the above description of the present embodiment, a composite material (aluminum-rubber-aluminum three-layer structure) containing a highly viscous polymer material is used as the material of the suspension 124, but the same effect can be obtained. If possible, a three-layer structure of aluminum-epoxy-aluminum, a three-layer structure of aluminum-acryl-aluminum, or the like may be used. Further, as a material of the suspension 124, polyether sargon (poly) is used.
Materials with high internal loss factors such as ether sulphone and polyarylate may be used. The material of the suspension 124 is preferably a material having an internal loss coefficient of 0.01 or more. Further, as the material of the suspension 124, magnesium or a dislocation type damping alloy (for example, magnesium-zirconium alloy) that absorbs vibration due to dislocation motion inside the metal may be used. Further, as the material of the suspension 124, a laminated material containing at least two kinds of materials (for example, a laminated material of two layers of aluminum-copper alloy and aluminum-alloy composite material) may be used. By absorbing the mechanical vibration by friction, the sharpness of the mechanical vibration force can be suppressed. The materials of the laminated materials used as the materials of the suspension 124 have different internal loss coefficients. Further, a damping steel plate which is a laminated material of metal and resin may be used as the material of the suspension 124. Further, as a material of the suspension 124, a damping alloy which is a laminated material of at least two kinds of metals may be used.

The material of the suspension 124 is not limited to the laminated material, and for example, a material obtained by applying a vibration damping material such as SBR (styrene butadiene rubber) on a stainless steel base material may be used.

(Embodiment 4) FIG. 7 shows an electro-mechanical-acoustic transducer 4000 according to Embodiment 4 of the present invention.
FIG. 7 is a sectional view of the electro-mechanical-acoustic transducer 4000.

The electro-mechanical-acoustic transducer 4000 includes a vibrating plate 108, a movable part 228 arranged to face the vibrating plate 108, and a suspension 13 for supporting the movable part 228.
3, a support portion 139 that supports the peripheral portion of the diaphragm 108 and the suspension 133, a voice coil 117,
The divider plate 1 connected to the movable portion 228 and the support portion 139.
And 34.

The movable portion 228 includes the magnetic circuit 216 and the weight 12
3, and operates relative to the support portion 139.
The magnetic circuit 216 includes a bowl-shaped yoke 210, a magnet 111, and a plate 112. A magnetic gap 215 is formed between the inner peripheral surface of the ferromagnetic yoke 210 and the outer peripheral surface of the plate 112. The weight 123 may be integrally formed with the yoke 210. Suspension 133
The movable part 228 forms the mechanical vibration system 121. The material and shape of the suspension 133 are similar to those of the suspension 114 of the first embodiment. Voice coil 11
7 generates a driving force for vibrating the diaphragm 108 and the movable portion 228. The bowl-shaped support portion 139 may be composed of three or more parts for sandwiching the suspension 133 and the partition plate 134.

The dividing plate 134 functions as a dividing portion which divides the space formed between the supporting portion 139 and the diaphragm 108 into two. The divider plate 134 has a substantially roll-shaped cross-sectional shape obtained by deforming an arc shape.

The support portion 139 is provided with an air hole 135 which connects the support portion 139, the space formed between the cutout plate 134 and the yoke 210, and the external space of the electro-mechanical-acoustic transducer 4000. There is. As the air holes 135, for example, a plurality of circular holes are formed in the support portion 139. The divider plate 134, the air hole 135, and the support portion 139 function as a suppressing unit that suppresses the sharpness of the mechanical vibration force generated by the vibration of the movable portion 228.

Next, the operation of the electro-mechanical-acoustic converter 4000 will be described.

When an alternating electric signal is applied from the drive circuit 101 to the voice coil 117, an action / reaction force acts between the voice coil 117 and the magnetic circuit 216. The reaction force acting on the magnetic circuit 216 is applied to the movable portion 228 supported by the suspension 133, and the movable portion 228 vibrates. The operation of the electro-mechanical-acoustic transducer 10 of the first embodiment is performed.
The same as 00. Similar to the electro-mechanical-acoustic transducer 1000, when the frequency of the electric signal applied to the voice coil 117 matches the resonance frequency of the mechanical vibration system 121, the movable portion 228 vibrates greatly.

The electro-mechanical-acoustic transducer 4000 is different from the electro-mechanical-acoustic transducer 1000 in that it has the dividing plate 134 and that the suppressing means 200 is omitted. When the movable portion 228 vibrates, the diaphragm plate 134 also vibrates, and the air in the space between the diaphragm plate 134 and the support portion 139 is compressed. The compressed air is discharged to the outside through the air hole 135. At this time, the acoustic resistance generated by the movement of the air inside the air hole 135 suppresses the vibration of the movable portion 228. This acoustic resistance suppresses the mechanical vibration force generated by the vibration of the movable portion 228, and the sharpness of the mechanical vibration force can be reduced.

As a result, the movable portion 228 vibrates, and the frequency band in which a sufficient mechanical vibration force can be obtained can be expanded. Therefore, even if the resonance frequency of the movable portion 228 changes depending on the use conditions, it is stable. A sufficient amount of mechanical vibration force can be obtained. Further, since the movable part 228 is supported by the two components of the suspension 133 and the cut-off plate 134, the effect that the movable part 228 is less likely to roll is also obtained.

In the present embodiment, the shape of the divider plate 134 is a substantially roll type, but the space is cut off and the movable portion 2 is cut off.
A wave shape or the like may be used as long as it can ensure the amplitude margin of 28.

Although the air holes 135 have a cylindrical shape in the present embodiment, the size, shape and number are not limited to the above if similar acoustic resistance can be obtained. Since the ratio of suppressing the vibration of the movable portion 228 changes depending on the shape and number of the air holes 135, the movable portion 228 vibrates, and the frequency band in which a sufficient mechanical vibration force can be obtained can be adjusted. .

In addition, an air hole may be formed in the support portion 139 to connect the space on the back side of the diaphragm 108 and the external space.

(Fifth Embodiment) As a fifth embodiment of the present invention, a mobile phone 61 which is a mobile terminal equipped with the electro-mechanical-acoustic converter of the present invention will be described with reference to FIGS. 8 and 9. To do.

FIG. 8 is a partially cutaway perspective view of mobile phone 61 according to the fifth embodiment of the present invention. FIG. 9 shows a block diagram of the inside of the mobile phone 61.

The mobile phone 61 includes a housing 62 and a housing 62.
And a sound hole 63 provided in the electro-mechanical-acoustic transducer 64.
With. Electricity provided in the mobile phone 61-Machine-
The acoustic transducer 64 includes the first, second, and third embodiments of the present invention.
An electro-mechanical-acoustic transducer 1000 shown at 3 and 4,
Any of 2000, 3000 and 4000 apply. An electro-mechanical-acoustic transducer 64 inside the housing 62.
Is provided so that the diaphragm 108 faces the sound hole 63.

As shown in FIG. 9, the mobile phone 61 further includes an antenna 150, a transmission / reception circuit 160, a calling signal generation circuit 161, and a microphone 152. The transmission / reception circuit 160 also includes a demodulation unit 160 a and a modulation unit 16 a.
0b, a signal switching unit 160c, and an absence recording unit 160d.

The antenna 150 is used for receiving radio waves output from the nearest base station and transmitting radio waves to the base station. The demodulation unit 160a decodes the modulated wave input from the antenna 150, converts it into a reception signal, and outputs the reception signal to the signal switching unit 160c. The signal switching unit 160c is a circuit that switches signal processing according to the content of the received signal. When the received signal is an incoming signal, it is output to the ringing signal generation circuit 161, when it is a voice signal, it is output to the electro-mechanical-acoustic converter 64, and when it is a voice signal of voice recording, it is output to the voice recording unit 160d. It The absence recording section 160d is, for example, a semiconductor memory. The message recording message when the power is turned on is stored in the message recording section 160d, but when the mobile phone 61 is out of the service area or when the power is off, the message recording is stored in the storage device of the base station. The call signal generation circuit 161 generates a call signal and outputs it to the electro-mechanical-acoustic transducer 64.

As in the conventional mobile phone, the mobile phone 6
1 includes a small microphone 15 as an electroacoustic transducer.
Two are provided. The modulation unit 160b modulates the dial signal and the audio signal converted by the microphone 152, and outputs the modulated signal to the antenna 150.

The operation of the mobile phone 61 as such a mobile terminal device will be described.

Radio waves output from the base station are transmitted to the antenna 15
0 is received and demodulated by the demodulator 160a into a baseband received signal. When the signal switching circuit 160c detects that the received signal is an incoming signal, the incoming signal is received by the mobile phone 6
In order to notify the No. 1 user, an incoming signal is output to the calling signal generation circuit 161.

Upon receiving such an incoming signal, calling signal generating circuit 161 outputs a calling signal. When the call setting is in the manner mode, the call signal is input as an electric signal including a frequency component close to the resonance frequency of the mechanical vibration system of the electro-mechanical-acoustic transducer 64. As a result, the largest vibration is obtained from the mechanical vibration system, and the support portion vibrates greatly. Due to the vibration of the supporting portion, the casing 62 of the mobile phone is vibrated, and the mobile phone main body 61 vibrates. In this way, the user can know the incoming call by vibrating the mobile phone main body 61. On the other hand, when the ringing setting is in the standard mode, the ringing signal includes a signal of a pure tone in the audible band or a complex tone thereof, and when this ringing signal is input to the electro-mechanical-acoustic converter 64, the electro-mechanical-acoustic conversion is performed. The vibrating plate of the container 64 vibrates to generate a ring tone. This ring tone is output to the outside through the sound hole 63 to notify the user of the incoming call.

When the user enters the listening state, the signal switching unit 1
After adjusting the level of the received signal, 60c directly outputs the received audio signal to the electro-mechanical-acoustic transducer 64. The electro-mechanical-acoustic transducer 64 operates as a receiver or a speaker and reproduces an audio signal.

The voice of the user is detected by the microphone 152, converted into a voice signal and input to the modulator 160b. The audio signal is modulated by the modulator 160b, converted into a predetermined carrier wave, and output from the antenna 150.

When the user of the mobile phone 61 sets the voice recording to the voice recording state with the power turned on, the contents of the transmitted voice are stored in the voice recording section 160d. In addition, the mobile phone 61
When the power of the user is off, the transmitted content is temporarily stored in the base station. Then, when the user requests the reproduction of the recorded message by key operation, the signal switching unit 160c receives the request and acquires the recorded message from the recorded message recording unit 160d or the base station. Then, the audio signal is adjusted to a loud level and output to the electro-mechanical-acoustic transducer 64. At this time, the electro-mechanical-acoustic transducer 64 operates as a receiver or a speaker and outputs a message.

As described above, it is possible to reduce the number of acoustic components incorporated in the conventional mobile phone. In addition, the resonance frequency of the mechanical vibration system changes due to changes in usage conditions such as how to hold and place the mobile phone. However, since the sharpness of the mechanical vibration force of the electro-mechanical-acoustic transducer of the present invention is small, the vibration force felt by the user can be made almost constant at all times.

Sensitivity of vibration varies depending on the frequency band, and sensitivity is high in a low frequency band of 200 Hz or less. In particular, since the sensitivity of frequencies near 130 Hz is high, it is desirable to design the resonance frequency of the mechanical vibration system to be around 130 Hz. When reproducing a voice or music signal, it is desirable that the reproduction band is 200 Hz or higher.

In the portable telephone 61, the electric-mechanical-
Although the acoustic transducer 64 is directly attached to the housing 62, the acoustic transducer 64 may be attached to a substrate built in the mobile phone 61.
Further, the electro-mechanical-acoustic transducer 64 may be attached so as to face the sound hole 63 via an acoustic port. Also, the same operation and effect can be obtained even if the electro-mechanical-acoustic transducer 64 is attached to another mobile terminal.

8 and 9 show a mobile phone as an example of a mobile terminal, the present invention is not limited to this, and pagers (registered trademark), notebook computers, PDAs, wristwatches, etc. The present invention is applied to a mobile terminal equipped with an acoustic transducer.

[0091]

According to the present invention, there is provided an electro-mechanical-acoustic transducer having a suppressing means for suppressing the sharpness of mechanical vibration force generated by the vibration of a movable part. When the suppressing unit reduces the sharpness of the vibration force, the movable portion vibrates, and the frequency band in which a sufficient mechanical vibration force can be obtained can be expanded. As a result, a stable and sufficient mechanical vibration force can be obtained even when the resonance frequency of the movable portion changes depending on the usage conditions.

Further, since the movable part and the diaphragm are vibrated by the drive part, both mechanical vibration and sound can be generated.

The portable terminal device of the present invention comprises the electro-mechanical-acoustic transducer of the present invention. As a result, it is possible to realize a mobile terminal device having a function of notifying a user of an incoming call by mechanical vibration, a function of notifying an incoming call by sound, and a function of playing a received sound such as voice. The mobile terminal device of the present invention includes the electro-mechanical-acoustic transducer of the present invention, so that a mobile terminal device that generates mechanical vibration and sound can be realized with only one unit.

[Brief description of drawings]

FIG. 1 is a plan view of an electro-mechanical-acoustic transducer according to a first embodiment of the present invention.

FIG. 2 is a sectional view of the electro-mechanical-acoustic transducer according to the first embodiment of the present invention.

FIG. 3 is a diagram showing frequency characteristics of mechanical vibration force according to the first embodiment of the present invention.

FIG. 4 is a sectional view of an electro-mechanical-acoustic transducer according to a second embodiment of the present invention.

FIG. 5A is a plan view of a first magnet according to the second embodiment of the present invention.

FIG. 5B is a plan view of the second magnet according to the second embodiment of the present invention.

FIG. 6 is a sectional view of an electro-mechanical-acoustic transducer according to a third embodiment of the present invention.

FIG. 7 is a sectional view of an electro-mechanical-acoustic transducer according to a fourth embodiment of the present invention.

FIG. 8 is a partial cutaway view of a mobile phone according to a fifth embodiment of the present invention.

FIG. 9 is a block diagram showing a mobile phone according to a fifth embodiment of the present invention.

FIG. 10 is a sectional view of a conventional electro-mechanical-acoustic transducer.

FIG. 11 is a diagram showing frequency characteristics of mechanical vibration force.

[Explanation of symbols]

108 diaphragm 109 Support 110 York 111 magnet 112 plates 113 weight 114 suspension 115 magnetic gap 116 Magnetic circuit 117 voice coil 118 Moving part 200 Control means

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04R 9/00 H04R 9/00 B 9/02 102 9/02 102E F term (reference) 5D012 AA02 CA02 CA09 FA06 5D017 AA11 5D107 AA05 BB08 CC08 CC10 DD12 DE02 5K023 AA07 EE07 HH01 HH11

Claims (15)

[Claims] 1. A vibrating plate, a movable part, a driving part that generates a driving force for vibrating the vibrating plate and the movable part, and a sharpness of a vibrating force obtained by vibrating the movable part. An electro-mechanical-acoustic transducer comprising a suppressing means for suppressing. 2. The electro-mechanical-acoustic transducer according to claim 1, wherein the movable part has a magnetic circuit for supplying a magnetic flux to the drive part. 3. The electric device according to claim 2, wherein the movable portion further comprises a weight integrally formed with the magnetic circuit.
Mechanical-acoustic transducer. 4. The movable section is arranged so as to face the diaphragm, and the suppressing means is an elastic body provided on the opposite side of the movable section from the diaphragm. The electro-mechanical-acoustic transducer described. 5. The electro-mechanical-acoustic transducer according to claim 4, wherein the elastic body is a sponge material. 6. The electro-mechanical-acoustic transducer according to claim 4, wherein the elastic body is a spring material. 7. A support section for supporting the diaphragm is further provided, wherein the suppressing means is provided at a position opposite to the diaphragm of the movable section provided facing the diaphragm. The electric machine according to claim 1, further comprising: a first magnet; and a second magnet that faces the first magnet and that is provided in the support portion and is magnetized in a direction opposite to the first magnet. -Machine-
Acoustic transducer. 8. The electro-mechanical-acoustic transducer according to claim 1, wherein the suppressing means is a suspension that supports the movable portion, and a material of the suspension is a material having an internal loss coefficient of 0.01 or more. . 9. The electro-mechanical-acoustic transducer according to claim 1, wherein the suppressing means is a suspension that supports the movable portion, and the material of the suspension is a composite material including a high-viscosity polymer material. . 10. The electro-mechanical-acoustic transducer according to claim 1, wherein the suppressing means is a suspension that supports the movable portion, and the material of the suspension is a dislocation-type damping alloy. 11. The electric-mechanical machine according to claim 1, wherein the suppressing means is a suspension that supports the movable portion, and the material of the suspension is a laminated material of at least two kinds of materials having different internal loss coefficients. Acoustic transducer. 12. The electro-mechanical-acoustic transducer according to claim 11, wherein the material of the suspension is a damping steel plate which is a laminated material of metal and resin. 13. The electro-mechanical-acoustic transducer according to claim 11, wherein the material of the suspension is a damping alloy which is a laminated material of at least two kinds of metals. 14. A support part for supporting the vibration plate is further provided, a space is formed between the support part and the vibration plate, the space is connected to the movable part and the support part, and two spaces are provided. Further comprising a dividing section, wherein at least one air hole communicating the space formed between the dividing section and the supporting section with an external space is formed in the supporting section, and the suppressing unit is the dividing section. An electro-mechanical-acoustic transducer according to claim 1 including a section, the support and the at least one air hole. 15. A housing, and an electro-mechanical-acoustic converter provided in the housing, wherein the electro-mechanical-acoustic converter includes a diaphragm, a movable portion, the diaphragm, and the diaphragm. A drive unit that generates a drive force for vibrating the movable unit, and a suppressing unit that suppresses the sharpness of the vibration force obtained by vibrating the movable unit are provided. A mobile terminal device, in which a sound hole is formed so that a sound generated from an acoustic transducer is radiated.