JP2003032789A - Speaker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the thickness of a speaker at least by the thickness of a damper as compared with speakers with a damper installed above a magnetic circuit. SOLUTION: The speaker is provided with a frame; a magnetic circuit fixed on the frame; a diaphragm fixed on the frame so that the diaphragm can vibrate in a specified direction; a driving force transmitting member joined with the diaphragm; and a damper which supports the driving force transmitting member. The magnetic circuit is placed between a first flat face and a second flat face. One end of the damper is joined with the driving force transmitting member in a position between the first flat face and the second flat face, and the other end of the damper is joined with the frame in a position between the first flat face and the second flat face.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a speaker.

[0002]

2. Description of the Related Art When a speaker is installed in a personal computer, a multimedia portable device or the like, the speaker is installed in a narrow area such as both sides or a lower part of a video screen of the personal computer or the multimedia portable device. Therefore, it is desirable that the speaker has an elongated shape such as a rectangle or an ellipse.

For example, a conventional speaker 1200 is described in Japanese Patent Application Laid-Open No. 10-191494. Below, a conventional speaker 1200 is shown in FIGS.
It will be described with reference to b.

FIG. 12a shows the top surface of a conventional speaker 1200. FIG. 12B shows a conventional speaker 1200 A-.
A section in A'is shown.

The speaker 1200 has a frame 1201.
And a magnetic circuit 1206 fixed to the frame 1201.
And a diaphragm 1203 fixed to the frame so that it can vibrate in the direction of arrow P shown in FIG.
3 includes a driving force transmitting member 1204 and a damper 1205 supporting the driving force transmitting member 1204. The outer peripheral portion of the diaphragm 1203 is fixed to the frame 1201 via the edge 1202.

One end of the damper 1205 has a magnetic circuit 120.
6 is coupled to the driving force transmission member 1204 above,
The other end of the damper 1205 is coupled to the frame 1201 above the magnetic circuit 1206.

The driving force transmission member 1204 has a region where the voice coil 1207 is formed. Voice coil 12
When a drive current flows through 07, the drive current and the magnetic circuit 1
By the action of the magnetic flux provided by 206, FIG.
A driving force is generated in the direction of arrow P shown in b. The driving force transmission member 1204 is configured to transmit this driving force to the diaphragm 1203. This driving force causes the diaphragm 1203 to vibrate in the direction of arrow P. As a result, sound is generated.

[0008]

However, according to the conventional speaker 1200, the thickness of the speaker 1200 is at least the thickness of the magnetic circuit 1206 and the damper 1205.
And the thickness of the diaphragm 1203 are required. This is because the damper is provided above the magnetic circuit.

The present invention has been made in view of the above problems, and is a speaker that is thinner than at least the damper provided above the magnetic circuit by at least the thickness of the damper. The purpose is to provide.

It is another object of the present invention to provide a magnetic circuit having a high speaker driving efficiency.

[0011]

A speaker according to the present invention includes a frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to vibrate in a predetermined direction, and the diaphragm. A drive force transmitting member coupled to the drive force transmitting member, and a damper supporting the drive force transmitting member,
The magnetic circuit is arranged between a first plane and a second plane, and the first plane is a plane parallel to the diaphragm, and at least a part of the magnetic circuit contacts. Is defined as a plane, the second plane is a plane parallel to the diaphragm, and is defined as a plane in which at least a part of the magnetic circuit is in contact, and the driving force transmitting member is a voice coil. Has an area where
The driving force transmission member is configured to transmit the driving force in the predetermined direction generated by the action of the current flowing through the voice coil and the magnetic flux provided by the magnetic circuit to the diaphragm. One end of the damper is the first
Is coupled to the driving force transmission member at a position between the first plane and the second plane, and the other end of the damper is at a position between the first plane and the second plane. It is connected to the frame, which achieves the above object.

The magnetic circuit may be arranged inside the frame.

The diaphragm may have a recess, and the driving force transmitting member may be coupled to the recess of the diaphragm.

The frame may have a recess, and at least a part of the magnetic circuit may be embedded in the recess of the frame.

The magnetic circuit may have a protrusion, and the frame may have a portion that is coupled to the protrusion.

The magnetic circuit includes a first magnetic circuit portion, a second magnetic circuit portion, and the first magnetic circuit portion, and the frame includes a first frame plate to which the first magnetic circuit portion is fixed, A second frame plate to which the second magnetic circuit unit is fixed, a third frame plate, and a fourth frame plate. One end of the third frame plate is connected to one end of the first frame plate. , The other end of the third frame plate is coupled to one end of the second frame plate, and one end of the fourth frame plate is coupled to the other end of the first frame plate,
The other end of the fourth frame plate may be coupled to the other end of the second frame plate.

The frame may further include a bottom plate.

The driving force transmitting member may have at least one through hole in a region other than the region where the voice coil is formed.

The driving force transmitting member may be formed by laminating a core member having at least one through hole and a surface member having a region where the voice coil is formed.

The magnetic circuit includes a first magnetic circuit section and a second magnetic circuit section.
A magnetic circuit portion; and a magnetic gap defined by the first magnetic circuit portion and the second magnetic circuit portion, wherein the first magnetic circuit portion is composed of a rectangular parallelepiped first magnet and a first magnet. The second magnetic circuit unit includes a first plate fixed to an upper surface and a second plate fixed to a lower surface of the first magnet, and the second magnetic circuit unit includes a rectangular parallelepiped second magnet and a second magnet. A third plate fixed to an upper surface and a fourth plate fixed to a lower surface of the second magnet, wherein one end of the first magnetic circuit unit is coupled to the frame; and the second magnetic circuit unit. One end of which is coupled to the frame, the first magnet and the second magnet face each other with opposite polarities, and the magnetic gap is defined by the first plate and the third plate. A first magnetic gap, the first magnetic gap being
A first magnetic air gap through which the magnetic flux generated from the magnet and the second magnet pass, and a second magnetic air gap defined by the second plate and the fourth plate, It may include a first magnet and a second magnetic air gap through which the magnetic flux generated from the second magnet passes.

The magnetic circuit includes a first magnetic circuit section and a second magnetic circuit section.
A first magnetic circuit section, and a magnetic gap defined by the first magnetic circuit section and the second magnetic circuit section, wherein the first magnetic circuit section is fixed to a rectangular parallelepiped magnet and an upper surface of the magnet. One plate and a second plate fixed to the lower surface of the magnet, the second magnetic circuit unit includes a yoke, and one end of the first magnetic circuit unit is coupled to the frame, One end of the magnetic circuit unit is coupled to the frame, the magnet and the yoke face each other, and the magnetic gap is a first magnetic gap defined by the first plate and the yoke. A first magnetic air gap through which the magnetic flux generated from the magnet passes, and a second magnetic air gap defined by the second plate and the yoke that passes through the magnetic flux generated from the magnet. With 2 magnetic air gaps It may also include a. At least a part of the first plate may be in contact with the facing yoke, and at least a part of the second plate may be in contact with the facing yoke.

The magnetic circuit includes a first magnetic circuit section and a second magnetic circuit section.
A magnetic circuit portion, and a magnetic gap defined by the first magnetic circuit portion and the second magnetic circuit portion, wherein the first magnetic circuit portion includes a rectangular parallelepiped first magnet and a rectangular parallelepiped second magnet. A magnet, a first plate, and a second plate; the second magnetic circuit unit includes a yoke; one end of the first plate is coupled to the frame; and the other of the first plate. An end is coupled to the first magnet, one end of the second plate is coupled to the frame, the other end of the second plate is coupled to the second magnet, and the first magnet and the The yoke is opposed to each other, the second magnet and the yoke are opposed to each other, and the first magnet and the second magnet are opposed to each other.
Magnets are arranged and fixed in a direction opposite to each other in the predetermined direction, and the magnetic gap is a first magnetic gap defined by the first plate and the yoke. A first magnetic air gap through which the magnetic flux generated from the magnet passes, and a second magnetic air gap defined by the second plate and the yoke, wherein the magnetic flux generated from the second magnet is And a second magnetic air gap passing therethrough.

The speaker of the present invention includes a frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to be vibrable in a predetermined direction, and a driving force coupled to the diaphragm. The magnetic circuit includes a transmission member and a damper that supports the driving force transmission member, the magnetic circuit is disposed between a first plane and a second plane, and the first plane is the diaphragm. Is defined as a plane parallel to the at least a part of the magnetic circuit,
The second plane is a plane parallel to the diaphragm,
It is defined as a plane in which at least a part of the magnetic circuit is in contact, the driving force transmission member has a region in which a voice coil is formed, and the driving force transmission member is a current flowing through the voice coil. It is configured to transmit the driving force in the predetermined direction generated by the action of the magnetic flux provided by the magnetic circuit to the diaphragm,
The magnetic circuit includes a first magnetic circuit unit, a second magnetic circuit unit, and a magnetic gap defined by the first magnetic circuit unit and the second magnetic circuit unit, and the first magnetic circuit unit is A rectangular parallelepiped magnet, a first plate fixed to an upper surface of the magnet, and a second plate fixed to a lower surface of the magnet, the second magnetic circuit unit includes a yoke, and the first magnetic One end of the circuit unit is coupled to the frame, one end of the second magnetic circuit unit is coupled to the frame, the magnet and the yoke are opposed to each other, and the magnetic gap is
A first magnetic air gap defined by the first plate and the yoke, the first magnetic air gap passing the magnetic flux generated from the magnet, and a second magnetic air gap defined by the second plate and the yoke. And a second magnetic air gap through which the magnetic flux generated from the magnet passes, whereby the above object can be achieved.

In the speaker of the present invention, at least a part of the first plate is in contact with the opposing yoke,
At least a part of the second plate may be in contact with the opposing yoke.

The speaker of the present invention includes a frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to be able to vibrate in a predetermined direction, and a driving force coupled to the diaphragm. The magnetic circuit includes a transmission member and a damper that supports the driving force transmission member, the magnetic circuit is disposed between a first plane and a second plane, and the first plane is the diaphragm. Is defined as a plane parallel to the at least a part of the magnetic circuit,
The second plane is a plane parallel to the diaphragm,
It is defined as a plane in which at least a part of the magnetic circuit is in contact, the driving force transmission member has a region in which a voice coil is formed, and the driving force transmission member is a current flowing through the voice coil. It is configured to transmit the driving force in the predetermined direction generated by the action of the magnetic flux provided by the magnetic circuit to the diaphragm,
The magnetic circuit includes a first magnetic circuit unit, a second magnetic circuit unit, and a magnetic gap defined by the first magnetic circuit unit and the second magnetic circuit unit, and the first magnetic circuit unit is A rectangular parallelepiped first magnet, a rectangular parallelepiped second magnet, a first plate, and a second plate, the second magnetic circuit unit includes a yoke, and one end of the first plate Is coupled to the frame, the other end of the first plate is coupled to the first magnet, one end of the second plate is coupled to the frame, and the other end of the second plate is coupled to the first magnet. The first magnet and the yoke are opposed to each other, the second magnet and the yoke are opposed to each other, and the first magnet and the second magnet are opposite to each other. The magnetic gaps are arranged side by side in the predetermined direction and fixed in a polar state. A first magnetic gap defined by the first plate and the yoke, through which the magnetic flux generated from the first magnet passes, the second plate, and the first magnetic gap. And a second magnetic air gap defined by a yoke through which the magnetic flux generated from the second magnet passes, thereby achieving the above object.

[0026]

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

1. Structure of Speaker of the Present Invention FIG. 1a shows the top surface of a speaker 100 of an embodiment of the present invention. FIG. 1b shows a cross section taken along the line AA ′ of the speaker 100 according to the embodiment of the present invention. FIG. 1c shows a cross section taken along the line BB ′ of the speaker 100 according to the embodiment of the present invention.
FIG. 1d shows a perspective view of a speaker 100 according to an embodiment of the invention.

The speaker 100 includes a frame 101, a magnetic circuit 106 fixed to the frame 101, and a frame 101 so that the speaker 100 can vibrate in the direction of arrow P shown in FIG.
The vibration plate 103 is fixed to the vibration plate 103, the driving force transmission member 104 coupled to the vibration plate 103, and the damper 105 that supports the driving force transmission member 104. The outer peripheral portion of the diaphragm 103 is fixed to the frame 101 via the edge 102.

The magnetic circuit 106 is arranged between the first plane and the second plane.

Here, in the present specification, the "first plane" is defined as "a plane parallel to the vibrating plate and in contact with at least a part of the magnetic circuit". The "second plane" is defined as "a plane parallel to the diaphragm and in contact with at least a part of the magnetic circuit".

One end of the damper 105 has a first plane and a second plane.
Is connected to the driving force transmission member 104 at a position between the driving force transmission member 104 and the plane. The other end of the damper 105 has a first plane and a second plane.
Is connected to the frame 101 at a position between the frame 101 and the plane.

For example, as shown in FIG. 1, the magnetic circuit 1
06 is a rectangular parallelepiped, and the upper surface I and the lower surface II of the magnetic circuit 106 are parallel to the diaphragm 103.
When 6 is fixed to the frame 101, the first plane is the upper surface I of the magnetic circuit 106 and the second plane is the lower surface II of the magnetic circuit 106. Thus, the magnetic circuit 10
By arranging 6 and the damper 105, the damper 10
The mounting position of 5 does not exceed or fall below the mounting position of the magnetic circuit 106. As a result, the speaker 100 can be made thinner by at least the thickness of the damper 105 as compared with the conventional speaker in which the damper is provided above the magnetic circuit.

Further, the magnetic circuit 106 is connected to the frame 101.
The speaker 100 can be further thinned by disposing the speaker 100 inside. This is because the mounting position of the magnetic circuit 106 is neither higher than nor lower than the position of the frame 101.

In the example shown in FIG. 1, the magnetic circuit 106
Is configured to include a magnetic circuit unit 106a, a magnetic circuit unit 106b, and a magnetic gap 110 defined by the magnetic circuit unit 106a and the magnetic circuit unit 106b.

The magnetic circuit section 106a includes a rectangular parallelepiped (for example, rectangular bar) magnet 108a, a plate 109a which is a flat surface fixed to the upper surface of the magnet 108a, and a plate 109b which is a flat surface fixed to the lower surface of the magnet 108a. .

The magnetic circuit portion 106b includes a rectangular parallelepiped (for example, rectangular bar) magnet 108b, a plate 109c which is a flat surface fixed to the upper surface of the magnet 108b, and a plate 109d which is a flat surface fixed to the lower surface of the magnet 108b. .

One end of the magnetic circuit portion 106a is connected to the frame 10
It is bonded to one flat surface. One end of the magnetic circuit portion 106b is joined to the flat surface of the frame 101. The magnet 108a and the magnet 108b face each other so that their polarities are opposite to each other.

The magnetic gap 110 includes a magnetic gap 110a and a magnetic gap 110b.

The magnetic gap 110a is defined by the plate 109a and the plate 109c, and is a gap through which the magnetic flux generated from the magnets 108a and 108b passes. The magnetic gap 110b is defined by the plate 109b and the plate 109d, and is a gap through which the magnetic flux generated from the magnets 108a and 108b passes.

FIG. 2 shows a perspective view of the driving force transmission member 104.

The driving force transmitting member 104 is the voice coil 1
07 has an area where it is formed. The region where the voice coil 107 is formed is arranged in the magnetic gap 110,
The driving force transmission member 104 is installed.

The voice coil 107 is, for example, a thin printed coil formed by winding the driving force transmitting member 104 on both sides in a rectangular ring shape.

When a driving current flows through the voice coil 107, a driving force is generated in the direction of arrow P shown in FIG. 1 due to the action of the driving current and the magnetic flux provided by the magnetic circuit 106. The driving force transmission member 104 is configured to transmit the driving force to the diaphragm 103. This driving force causes the diaphragm 103 to vibrate in the direction of arrow P. As a result, sound is generated.

The shape of the magnetic circuit 106 is not limited to a rectangular parallelepiped. The magnetic circuit 106 can have any shape.
Also in this case, by disposing the magnetic circuit 106 and the damper 105 between the first plane and the second plane,
The speaker 100 can be thinned.

With the above configuration, for example, a length of 65 m
m, width 14 mm, height 10 mm thin speaker 100
Can be realized. The diaphragm 103 is, for example, an elongated flat plate (horizontal length 56 mm, vertical length 7 mm).
Is. The driving force transmission member 104 is, for example, a flat plate (thickness: 0.3 mm) made of glass fiber reinforced resin.

Variations of the present invention will be described below.

2. Use of Vibration Plate Having Recesses The shape of the vibration plate 103 is not limited to a flat plate. Diaphragm 10
3 has, for example, a recess, and the driving force transmission member 104 can be coupled to the recess of the diaphragm 103.

FIG. 3a shows the top surface of a speaker 100 utilizing a diaphragm 103a having a recess. FIG. 3b shows an A- of a speaker 100 using a diaphragm 103a having a recess.
A section in A'is shown. FIG. 3c shows a cross section taken along the line BB ′ of the speaker 100 using the diaphragm 103a having the recess.

The cross section of the diaphragm 103a has a corrugated shape.
The diaphragm 103a has a recess, and the driving force transmission member 104 is coupled to the recess of the diaphragm 103a. Diaphragm 1
The driving force transmission member 1
04 is inserted into a fine hole and fixed with an adhesive.

As described above, according to the speaker of the present invention, the driving force transmitting member is connected to the concave portion of the diaphragm.
Therefore, it is possible to provide a speaker in which the adhesive accumulates in the concave portion and the strength of the joint portion is high.

3. Utilization of Frame Having Recesses It is not essential that one end of the magnetic circuit unit 106 is bonded to the flat surface of the frame 101. The frame has a recess, and at least a part of the magnetic circuit may be embedded in the recess of the frame. In addition, the frame 101 is 4
It is not essential that the face frame plate be manufactured in one piece. The frame 101 may be manufactured by assembling four frame plates.

FIG. 4a shows a frame plate 101 having a recess.
The upper surface of the speaker using a and the frame board 101b is shown. FIG. 4b shows a speaker AA ′ that uses the frame plate 101a and the frame plate 101b having a recess.
The cross section in. FIG. 4c shows a perspective view of a speaker using a frame plate 101a and a frame plate 101b having recesses.

The magnetic circuit 106 includes a magnetic circuit portion 106a and a magnetic circuit portion 106b.

The frame 101 includes a frame plate 101a to which a magnetic circuit section 106a is fixed and a magnetic circuit section 106b.
Frame plate 101b to which is fixed, and the frame plate 101
c and a frame plate 101d.

One end of the frame plate 101c is the frame plate 1
01a, and the other end of the frame plate 101c is connected to one end of the frame plate 101b.

One end of the frame plate 101d is the frame plate 1
01a and the other end of the frame plate 101d are connected to the other end of the frame plate 101b.

The frame 101a has a recess, and a part of the magnetic circuit 106a is embedded in the recess of the frame 101a. The frame 101b has a recess,
A part of the magnetic circuit 106b is embedded in the recess of the frame 101b.

Since the magnets 108a and 108b are opposed to each other so that their polarities are opposite to each other, a strong force (adsorption force) is always applied to the magnets 108a and 108b in the adsorbing direction. Further, the speaker 100 may be deformed due to heat change.

As described above, according to the speaker of the present invention, the adhesive area between the magnetic circuit portion 106a and the frame 101a is increased, so that the adhesive strength is improved. Magnetic circuit part 1
Since the bonding area between 06b and the frame 101b is increased, the bonding strength is improved. Therefore, by the adsorption force,
Further, due to heat change, the magnetic circuit unit 106a and the frame 10
The risk of deviation from 1a is greatly reduced. The risk of the magnetic circuit portion 106b and the frame 101b coming off from each other due to the attraction force and heat change is greatly reduced.

Further, as described above, according to the speaker of the present invention, the frame is manufactured by assembling the four frame plates, so that the magnetic circuit can be easily manufactured and assembled.

4. Utilization of Magnetic Circuit Having Protrusions The shapes of the upper surface and the lower surface of the magnetic circuit 106 are not limited to flat surfaces. The upper surface of the magnetic circuit or the lower surface of the magnetic circuit has a protrusion, and the frame may have a portion which is connected to the protrusion of the magnetic circuit.

FIG. 5a shows the top surface of a speaker utilizing a magnetic circuit with protrusions. FIG. 5b shows a cross section at AA 'of a speaker using a magnetic circuit having protrusions. FIG. 5c is a perspective view of a speaker using a magnetic circuit having a protrusion.

The plate 109a fixed to the upper surface of the magnet 108a has a protrusion. Frame 101
Has a portion that is coupled to this protrusion of the plate 109a. The plate 109b fixed to the lower surface of the magnet 108a has a protrusion. Frame 101
Has a portion that is coupled to this protrusion of the plate 109b. The plate 109c fixed to the upper surface of the magnet 108b has a protrusion. Frame 101
Has a portion that is connected to this protrusion of the plate 109c. The plate 109d fixed to the lower surface of the magnet 108b has a protrusion. Frame 101
Has a portion that is connected to this protrusion of the plate 109d.

Since the magnets 108a and 108b are opposed to each other so that their polarities are opposite to each other, a strong force (adsorption force) is always applied to the magnets 108a and 108b in the adsorbing direction. Further, the speaker 100 may be deformed due to heat change.

As described above, according to the speaker of the present invention, the adhesive area between the magnetic circuit portion 106a and the frame 101a is increased, so that the adhesive strength is improved. Magnetic circuit part 1
Since the bonding area between 06b and the frame 101b is increased, the bonding strength is improved. Therefore, by the adsorption force,
Further, due to heat change, the magnetic circuit unit 106a and the frame 10
The risk of deviation from 1a is greatly reduced. The risk of the magnetic circuit portion 106b and the frame 101b coming off from each other due to the attraction force and heat change is greatly reduced.

5. Utilization of Frame Having Bottom Plate The structure of the frame 101 is four (frame plate 101a-
It is not limited to 101d). The frame 101 is the bottom plate 10
It may further have 1e.

FIG. 6a shows a speaker 1 having a bottom plate 101e.
00 shows the upper surface of 00. FIG. 6b shows a cross section taken along the line AA ′ of the speaker 100 having the bottom plate 101e. FIG. 6c is a perspective view of the speaker 100 having the bottom plate 101e.

By assembling the frame 101 with five plates including the bottom plate 101e, the structural strength of the speaker 100 can be further increased.

6. Utilization of Driving Force Transmission Member Having Through Hole The driving force transmission member 104 may have a through hole in a region other than the region where the voice coil 107 is formed.

FIG. 7 shows a driving force transmission member 1 having a through hole.
04a shows a perspective view of 04a.

The driving force transmitting member 104a has a through hole 104.
b and a through hole 104c. The size of each of the through holes 104b and 104c is, for example, 16 m in width.
It is a rectangle with m and a length of 2 mm.

The through hole 104b and the through hole 1 are formed in the driving force transmitting member 104a so as not to reduce the driving force transmitting efficiency.
04c is provided. Since the driving force transmission member 104a is light, the driving efficiency of the speaker is improved.

7. Driving force transmission member composed of composite substrate
The configuration of the driving force transmission member 104a is not limited to a single plate. The driving force transmission member 104a may be composed of a composite substrate.

FIG. 8 shows a perspective view of the driving force transmission member 104a 'made of a composite substrate.

The driving force transmitting member 104a 'has a core member 104d having at least one through hole and a surface member 104e having an area where the voice coil 107 is formed.
And the surface member 104f having a region in which the voice coil 107 is formed are pasted together.

Surface member 104e and surface member 104f
Is a sheet made of glass fiber composite resin, for example.

The driving force transmitting member 104a 'is composed of a composite substrate including a lightweight surface member and a core member having high rigidity. Therefore, as compared with the single plate, it is possible to obtain a driving force transmitting member that is light and has high rigidity.

8. Use of Magnetic Circuit Having One Magnet The configuration of the magnetic circuit is not limited to having two magnets. The number of magnets used in the magnetic circuit may be one.

FIG. 9a shows the top surface of a speaker 100 utilizing a magnetic circuit with one magnet. FIG. 9b shows an A of a speaker 100 using a magnetic circuit having one magnet.
-A 'shows the cross section. FIG. 9c shows a cross section at BB ′ of the speaker 100 utilizing a magnetic circuit with one magnet. FIG. 9d shows a perspective view of a speaker 100 utilizing a magnetic circuit with one magnet.

The magnetic circuit 106 includes a magnetic circuit section 106c.
And a magnetic circuit portion 106d, and a magnetic gap 110 'defined by the magnetic circuit portion 106c and the magnetic circuit portion 106d.
It is configured to include and.

The magnetic circuit portion 106c includes a rectangular parallelepiped (for example, rectangular bar) magnet 108c, a plate 109e fixed to the upper surface of the magnet 108c, and a plate 109f fixed to the lower surface of the magnet 108c.

The magnetic circuit portion 106d includes a yoke 111a.

One end of the magnetic circuit portion 106c has the frame 10
Is bound to 1. One end of the magnetic circuit unit 106d is coupled to the frame 101. Magnet 108c and yoke 1
11a are opposed to each other.

The magnetic gap 110 includes a magnetic gap 110a 'and a magnetic gap 110b'. The magnetic gap 110a 'is
It is an air gap defined by the plate 109e and the yoke 111a, through which the magnetic flux generated from the magnet 108c passes. The magnetic gap 110b 'is defined by the plate 109f and the yoke 111a, and is a gap through which the magnetic flux generated from the magnet 108c passes.

The magnetic flux generated from the magnet 108c enters the yoke 111a via the plate 109e, the magnetic gap 110a ', and the like.

The magnetic circuit 106d includes a yoke 111a instead of one magnet and two plates. Therefore, the cost can be reduced. The position where the damper is attached does not matter. For example, the mounting position of the damper may be higher than the mounting position of the magnetic circuit. The mounting position of the damper may be lower than the mounting position of the magnetic circuit. If the magnetic circuit 106d includes the yoke 111a instead of one magnet and two plates, the cost can be reduced.

A part of the plate 109e may be in contact with the opposing yoke 111a. Also, plate 1
A part of 09f may be in contact with the opposing yoke 111a.

FIG. 10a shows the top surface of a speaker utilizing a plate where a portion of the plate contacts the opposing yoke. FIG. 10b shows a cross section taken along the line AA ′ of the speaker using a plate in which a part of the plate is in contact with the opposing yoke. FIG. 10c shows a cross-section at BB 'of a loudspeaker that utilizes plates in which a portion of the plate contacts the opposing yoke.

The plate 109g fixed to the upper surface of the magnet 108c has a convex portion 109g 'and a convex portion 109g''which are in contact with the yoke 111a. The plate 109h fixed to the lower surface of the magnet 108c has a convex portion 109h ′ and a convex portion 109h ″ that are in contact with the yoke 111a. The cross-sectional areas of the convex portions 109g ′, 109g ″, 109h ′ and 109h ″ are wide enough to saturate the magnetic flux. Therefore, from the plate 109g to the convex portion 109
There is almost no magnetic flux passing through the yoke 111a via g'and 109g ''. The decrease in the magnetic flux density of the magnetic gap is reduced, and the magnetic gap can be stably held.

The position of mounting the damper does not matter.
For example, the mounting position of the damper may be higher than the mounting position of the magnetic circuit. The mounting position of the damper may be lower than the mounting position of the magnetic circuit. Plate 109
When a part of e is in contact with the opposing yoke 111a,
In addition, the yoke 111 in which a part of the plate 109f faces
When it is in contact with a, the decrease in the magnetic flux density of the magnetic gap is reduced and the magnetic gap can be stably held.

9. It has a magnetic circuit part with magnets lined up and down
Use of magnetic circuit The magnetic circuit is not limited to the configuration in which two magnets are opposed to each other. The configuration of the magnetic circuit may be a configuration in which two magnets are arranged vertically.

FIG. 11a shows the upper surface of a speaker using a magnetic circuit having a magnetic circuit section in which magnets are arranged vertically.
FIG. 11b shows a cross section taken along the line AA ′ of a speaker using a magnetic circuit having a magnetic circuit section in which magnets are arranged vertically. FIG. 11c shows a cross section taken along the line BB ′ of a speaker using a magnetic circuit having a magnetic circuit section in which magnets are arranged vertically.

The magnetic circuit 106 has a magnetic circuit section 106e.
And a magnetic gap 110 defined by the magnetic circuit portion 106e and the magnetic circuit portion 106f.

The magnetic circuit section 106e is a rectangular parallelepiped magnet 10
8d, a rectangular parallelepiped magnet 108e, and a plate 109i
And a plate 109j. Magnetic circuit unit 106f
Includes a yoke 111b.

One end of the plate 109i is the frame 101
And the other end of the plate 109i is coupled to the magnet 108d. One end of the plate 109j is the frame 1
01, and the other end of the plate 109j is connected to the magnet 108.
bound to e.

The magnet 108d and the yoke 111b face each other, and the magnet 108e and the yoke 111b face each other.

The magnets 108d and 108e are vertically arranged and fixed in a state where they have opposite polarities.

The magnetic gap 110 includes a magnetic gap 110c and a magnetic gap 110d.

The magnetic gap 110c is defined by the plate 109i and the yoke 111b and is a gap through which the magnetic flux generated from the magnet 108d passes. Magnetic air gap 110
d is an air gap defined by the plate 109j and the yoke 111b, through which the magnetic flux generated from the magnet 108e passes.

Between the magnet 108d and the magnet 108e,
An aluminum plate spacer 112, which is a non-magnetic material, is arranged. Spacers 112 reduce short circuits in the magnetic flux.

The magnetic flux generated from the N pole of the magnet 108d passes through the magnetic gap 110c, and the opposing yoke 111b.
to go into. From the lower part of the yoke 111b, through the magnetic gap 110d, it enters the S pole of the magnet 108e which faces it. Further, from the N pole of the magnet 108e to the plate 109j and the plate 10
Through 9i, a closed loop of magnetic flux reaching the S pole of the magnet 108d is formed. Therefore, the magnetic flux direction is
At 0c, the direction is from the magnet 108d to the yoke 111b. In the magnetic gap 110d, the magnetic flux direction is the yoke 111b.
To the magnet 108e.

By arranging the magnets 108d and 108e vertically in the same manner as the vibration direction of the diaphragm, the portion having a high magnetic flux density becomes wider in the vertical direction of the magnetic gap 110. Therefore, the change in magnetic flux density when the voice coil 107 vibrates vertically is reduced. Therefore, the change in driving force is reduced. It is possible to realize a speaker with good linearity in the input-to-play sound pressure characteristic, excellent reproduction in the low-pitched sound range, and less distortion of the sound.

The position of mounting the damper does not matter.
For example, the mounting position of the damper may be higher than the mounting position of the magnetic circuit. The mounting position of the damper may be lower than the mounting position of the magnetic circuit. If the magnets 108d and 108e are arranged vertically as in the vibration direction of the diaphragm, a speaker with good linearity of input-to-playback sound pressure characteristics, excellent bass reproduction, and less distortion of sound can be provided. Can be realized.

[0104]

According to the speaker of the present invention, the magnetic circuit is disposed between the first plane parallel to the diaphragm and the second plane parallel to the diaphragm, and one end of the damper is the first plane. Is coupled to the driving force transmitting member at a position between the first plane and the second plane, and the other end of the damper is coupled to the frame at a position between the first plane and the second plane. ing. As a result, the mounting position of the damper does not exceed or fall below the mounting position of the magnetic circuit. As a result, it is possible to provide a speaker that is thinner than the conventional speaker in which the damper is provided above the magnetic circuit by at least the thickness of the damper.

[Brief description of drawings]

FIG. 1a is a diagram showing a top surface of a speaker 100 according to an embodiment of the present invention.

FIG. 1b shows an A- of a speaker 100 according to an embodiment of the present invention.
Diagram showing a cross section at A ′

FIG. 1c is a B- of the speaker 100 according to the embodiment of the present invention.
The figure which shows the cross section in B '

FIG. 1d is a perspective view of a speaker 100 according to an embodiment of the present invention.

FIG. 2 is a perspective view of a driving force transmission member 104.

FIG. 3a is a diagram showing a top surface of a speaker 100 using a diaphragm 103a having a recess.

FIG. 3b is a view showing a cross section taken along the line AA ′ of the speaker 100 using the diaphragm 103a having a recess.

FIG. 3c is a diagram showing a cross section taken along the line BB ′ of the speaker 100 using the diaphragm 103a having a recess.

FIG. 4a is a diagram showing an upper surface of a speaker using a frame plate 101a and a frame plate 101b having recesses.

FIG. 4b is a view showing a cross section taken along the line AA ′ of the speaker using the frame plate 101a and the frame plate 101b having the concave portions.

FIG. 4c is a perspective view of a speaker using a frame plate 101a and a frame plate 101b having recesses.

FIG. 5a is a diagram showing a top surface of a speaker using a magnetic circuit having a protrusion.

FIG. 5b is a view showing a cross section taken along line AA ′ of a speaker using a magnetic circuit having a protrusion.

FIG. 5c is a perspective view of a speaker using a magnetic circuit having a protrusion.

FIG. 6a is a diagram showing a top surface of a speaker 100 having a bottom plate 101e.

FIG. 6b is an A- of a speaker 100 having a bottom plate 101e.
Diagram showing a cross section at A ′

FIG. 6c is a perspective view of a speaker 100 having a bottom plate 101e.

FIG. 7 is a perspective view of a driving force transmission member 104a having a through hole.

FIG. 8 is a driving force transmission member 104 composed of a composite substrate.
a 'perspective view

FIG. 9a is a diagram showing a top surface of a speaker 100 using a magnetic circuit having one magnet.

FIG. 9b is a diagram showing a cross section taken along the line AA ′ of the speaker 100 using a magnetic circuit having one magnet.

FIG. 9c is a diagram showing a cross section taken along line BB ′ of the speaker 100 using a magnetic circuit having one magnet.

FIG. 9d is a perspective view of a speaker 100 using a magnetic circuit having one magnet.

FIG. 10a is a diagram showing a top surface of a speaker using a plate in which a part of the plate is in contact with an opposing yoke.

FIG. 10b is a diagram showing a cross section taken along the line AA ′ of the speaker using a plate in which a part of the plate is in contact with an opposing yoke.

FIG. 10c is a view showing a cross section taken along line BB ′ of the speaker using a plate in which a part of the plate is in contact with the facing yoke.

FIG. 11a is a diagram showing a top surface of a speaker using a magnetic circuit having a magnetic circuit section in which magnets are arranged vertically.

FIG. 11b is a view showing a cross section taken along the line AA ′ of the speaker using the magnetic circuit having the magnetic circuit section in which magnets are arranged vertically.

FIG. 11c is a diagram showing a cross section taken along line BB ′ of a speaker using a magnetic circuit having a magnetic circuit section in which magnets are arranged vertically.

FIG. 12 a is a diagram showing a top surface of a conventional speaker 1200.

FIG. 12b is a view showing a cross section taken along the line AA ′ of the conventional speaker 1200.

[Explanation of symbols]

100 speaker 101 frame 102 edge 103 diaphragm 104 driving force transmission member 105 damper 106 magnetic circuit 106a 106b magnetic circuit section 107 voice coil 108 magnet 109 109a 109b 109c 109d plate 110 110a 110b magnetic gap

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 5D012 BA03 BA08 BB02 CA07 CA08                       FA00 GA01                 5D016 AA04 AA05 AA15 AA17

Claims (16)

[Claims] 1. A frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to be able to vibrate in a predetermined direction, and a driving force transmission member coupled to the diaphragm. A damper that supports the driving force transmission member, the magnetic circuit is disposed between a first plane and a second plane, and the first plane is a plane parallel to the diaphragm. And the second plane is defined as a plane that is in contact with at least a part of the magnetic circuit, and the second plane is a plane that is parallel to the diaphragm and that is in contact with at least a part of the magnetic circuit. The driving force transmitting member has a region in which a voice coil is formed, and the driving force transmitting member is operated by a current flowing through the voice coil and a magnetic flux provided by the magnetic circuit. Occurrence The driving force transmitting member is configured to transmit the driving force in the predetermined direction to the vibrating plate, and one end of the damper is located between the first plane and the second plane. And the other end of the damper is coupled to the frame at a position between the first plane and the second plane.
Speaker. 2. The speaker according to claim 1, wherein the magnetic circuit is arranged inside the frame. 3. The speaker according to claim 1, wherein the diaphragm has a recess, and the driving force transmitting member is coupled to the recess of the diaphragm. 4. The speaker according to claim 1, wherein the frame has a recess, and at least a part of the magnetic circuit is embedded in the recess of the frame. 5. The speaker according to claim 4, wherein the magnetic circuit has a protrusion, and the frame has a portion that is coupled to the protrusion. 6. The magnetic circuit comprises a first magnetic circuit section and a second magnetic circuit section.
A magnetic circuit unit and a first magnetic circuit unit, and the frame includes a first magnetic circuit unit to which the first magnetic circuit unit is fixed.
A frame plate, a second frame plate to which the second magnetic circuit unit is fixed, a third frame plate, and a fourth frame plate are included, and one end of the third frame plate is connected to one end of the first frame plate. And the other end of the third frame plate is connected to one end of the second frame plate, one end of the fourth frame plate is connected to the other end of the first frame plate, and The speaker according to claim 1, wherein the other end of the fourth frame plate is coupled to the other end of the second frame plate. 7. The speaker according to claim 6, wherein the frame further has a bottom plate. 8. The speaker according to claim 1, wherein the driving force transmission member has at least one through hole in a region other than the region where the voice coil is formed. 9. The driving force transmitting member according to claim 1, wherein the driving force transmitting member is formed by laminating a core member having at least one through hole and a surface member having a region where the voice coil is formed. Speaker. 10. The magnetic circuit includes a first magnetic circuit section,
A second magnetic circuit unit; and a magnetic gap defined by the first magnetic circuit unit and the second magnetic circuit unit, wherein the first magnetic circuit unit is a rectangular parallelepiped first magnet and the first magnetic circuit unit.
A first plate fixed to an upper surface of the magnet and a second plate fixed to a lower surface of the first magnet, wherein the second magnetic circuit unit includes a second magnet of the rectangular parallelepiped and the second magnet.
A third plate fixed to the upper surface of the magnet and a fourth plate fixed to the lower surface of the second magnet, wherein one end of the first magnetic circuit unit is coupled to the frame,
One end of the second magnetic circuit unit is coupled to the frame,
The first magnet and the second magnet face each other so as to have opposite polarities, and the magnetic gap is a first magnetic gap defined by the first plate and the third plate. A first magnetic air gap through which the magnetic flux generated from the first magnet and the second magnet passes, and a second magnetic air gap defined by the second plate and the fourth plate. And a second magnetic air gap through which the magnetic flux generated from the first magnet and the second magnet passes.
The speaker according to claim 1. 11. The magnetic circuit includes a first magnetic circuit section,
A second magnetic circuit unit, and a magnetic gap defined by the first magnetic circuit unit and the second magnetic circuit unit, wherein the first magnetic circuit unit is fixed to a rectangular parallelepiped magnet and an upper surface of the magnet. A first plate and a second plate fixed to a lower surface of the magnet, the second magnetic circuit unit includes a yoke, and one end of the first magnetic circuit unit is coupled to the frame,
One end of the second magnetic circuit unit is coupled to the frame,
The magnet and the yoke are opposed to each other, the magnetic gap is a first magnetic gap defined by the first plate and the yoke, and the magnetic flux generated from the magnet passes therethrough. Magnetic gap and a second defined by the second plate and the yoke
2. The speaker according to claim 1, further comprising a second magnetic gap through which the magnetic flux generated from the magnet passes. 12. The speaker according to claim 11, wherein at least a part of the first plate is in contact with the facing yoke, and at least a part of the second plate is in contact with the facing yoke. . 13. The magnetic circuit includes a first magnetic circuit section,
A second magnetic circuit unit; and a magnetic gap defined by the first magnetic circuit unit and the second magnetic circuit unit, wherein the first magnetic circuit unit includes a rectangular parallelepiped first magnet and a rectangular parallelepiped first magnet. Two magnets, a first plate, and a second plate, the second magnetic circuit unit includes a yoke, and one end of the first plate is coupled to the frame,
The other end of the first plate is coupled to the first magnet, one end of the second plate is coupled to the frame, and the other end of the second plate is coupled to the second magnet, The first magnet and the yoke face each other,
The second magnet and the yoke are opposed to each other, the first magnet and the second magnet are fixed side by side in the predetermined direction with the polarities opposite to each other, and the magnetic gap is A first magnetic gap defined by a first plate and the yoke, through which the magnetic flux generated from the first magnet passes, and the second plate and the yoke. A loudspeaker according to claim 1, comprising a defined second magnetic air gap through which the magnetic flux generated from the second magnet passes. 14. A frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to be able to vibrate in a predetermined direction, and a driving force transmission member coupled to the diaphragm. A damper that supports the driving force transmission member, the magnetic circuit is disposed between a first plane and a second plane, and the first plane is a plane parallel to the diaphragm. And the second plane is defined as a plane that is in contact with at least a part of the magnetic circuit, and the second plane is a plane that is parallel to the diaphragm and that is in contact with at least a part of the magnetic circuit. The driving force transmitting member has a region in which a voice coil is formed, and the driving force transmitting member is operated by a current flowing through the voice coil and a magnetic flux provided by the magnetic circuit. Departure Is configured to transmit the driving force in the predetermined direction to the diaphragm, and the magnetic circuit includes a first magnetic circuit unit, a second magnetic circuit unit, the first magnetic circuit unit, and the first magnetic circuit unit. And a magnetic gap defined by two magnetic circuit units, wherein the first magnetic circuit unit includes a rectangular parallelepiped magnet, a first plate fixed to an upper surface of the magnet, and a second plate fixed to a lower surface of the magnet. A plate, the second magnetic circuit unit includes a yoke, and one end of the first magnetic circuit unit is coupled to the frame.
One end of the second magnetic circuit unit is coupled to the frame,
The magnet and the yoke are opposed to each other, the magnetic gap is a first magnetic gap defined by the first plate and the yoke, and the magnetic flux generated from the magnet passes therethrough. Magnetic gap and a second defined by the second plate and the yoke
A second magnetic air gap through which the magnetic flux generated from the magnet passes. 15. The speaker according to claim 14, wherein at least a part of the first plate is in contact with the facing yoke, and at least a part of the second plate is in contact with the facing yoke. . 16. A frame, a magnetic circuit fixed to the frame, a diaphragm fixed to the frame so as to be able to vibrate in a predetermined direction, and a driving force transmission member coupled to the diaphragm. A damper that supports the driving force transmission member, the magnetic circuit is disposed between a first plane and a second plane, and the first plane is a plane parallel to the diaphragm. And the second plane is defined as a plane that is in contact with at least a part of the magnetic circuit, and the second plane is a plane that is parallel to the diaphragm and that is in contact with at least a part of the magnetic circuit. The driving force transmitting member has a region in which a voice coil is formed, and the driving force transmitting member is operated by a current flowing through the voice coil and a magnetic flux provided by the magnetic circuit. Departure Is configured to transmit the driving force in the predetermined direction to the diaphragm, and the magnetic circuit includes a first magnetic circuit unit, a second magnetic circuit unit, the first magnetic circuit unit, and the first magnetic circuit unit. And a magnetic gap defined by two magnetic circuit parts, wherein the first magnetic circuit part has a rectangular parallelepiped first magnet, a rectangular parallelepiped second magnet, a first plate, and a second plate. The second magnetic circuit unit includes a yoke, and one end of the first plate is coupled to the frame,
The other end of the first plate is coupled to the first magnet, one end of the second plate is coupled to the frame, and the other end of the second plate is coupled to the second magnet, The first magnet and the yoke face each other,
The second magnet and the yoke are opposed to each other, the first magnet and the second magnet are fixed side by side in the predetermined direction with the polarities opposite to each other, and the magnetic gap is A first magnetic gap defined by a first plate and the yoke, through which the magnetic flux generated from the first magnet passes, and the second plate and the yoke. A second magnetic air gap defined by which the magnetic flux generated from the second magnet passes.