JP6579841B2 - Electroacoustic transducer - Google Patents

Description

  The present invention relates to a driver electroacoustic transducer that is driven by a sound signal and emits sound, and relates to, for example, an electroacoustic transducer suitable for application to an earphone.

In recent years, in mobile audio, earphones are mainly in the canal (ear canal insertion) type.
When an electrical signal is input, a canal type earphone transmits an electroacoustic transducer (driver) that radiates acoustic energy from a diaphragm, a casing that houses the electroacoustic transducer, and acoustic energy radiated from the diaphragm. And an earpiece that holds the acoustic tube in the ear canal. As an example of an electroacoustic transducer, there is a dynamic type composed of a magnetic circuit including a magnet and a yoke, having a magnetic gap, a voice coil arranged in the magnetic gap of the magnetic circuit, and a diaphragm to which the voice coil is attached. is there.

  Electroacoustic transducers and housings are designed according to the performance and application requirements of the product, but the stability of the wearing state and the good sound quality for music appreciation are particularly important. For that purpose, design of the external dimensions of the housing and design of the internal space of the housing, appropriate driving force of the electroacoustic transducer, diaphragm, space of the frame before and after the diaphragm, communication port (air on the back side of the diaphragm) The design of holes for exhausting outside is important.

Conventionally, there are earphones described in Patent Documents 1 and 2 below as earphones that take into consideration sufficient output characteristics and wearability with a canal type. The earphone device described in Patent Document 1 has a housing (housing) as an ear. By adopting a shape that matches the positional relationship between the concha cavity and the external auditory canal, the housing (housing) is accommodated in the concha cavity without downsizing the driver unit (electroacoustic transducer).

  The earphone described in Patent Document 2 secures a diaphragm area by arranging an electroacoustic transducer in a direction perpendicular to the sound conduit radiation direction.

Japanese Patent No. 4709017 JP 2009-55248 A

Both the earphone device described in Patent Document 1 and the earphone described in Patent Document 2 can use a large electroacoustic transducer (driver) by matching the shape with the shape of the mounting portion of the human body.
The earphone device described in Patent Document 1 and the earphone described in Patent Document 2 have the following disadvantages.

(1) The weight increases and it is not suitable for long-time use or use where the head is moving sharply, such as when jogging.
(2) The shape of the left and right cases is different because the shape is matched to the shape of the mounting part of the human body. Therefore, the number of parts and part cost increase, and the management cost of parts and products also increases.

In order to solve the above disadvantages, if the housing of the earphone is miniaturized, even if it is a common housing on the left and right sides, it is possible to achieve good wearability. In that case, the diameter of the electroacoustic transducer (driver) must be reduced, and there are the following problems.
(1) If the electroacoustic transducer (driver) is to be miniaturized, the magnetic circuit must be made smaller, an appropriate driving force cannot be obtained, and the performance is degraded.

The driving force F generated in the voice coil of the electroacoustic transducer is expressed by the following equation.
F = Bg × Ic × I
Bg: Magnetic flux density at the magnetic gap G Ic: Effective length of the coil of the voice coil (the length of the portion of the magnetic gap G where the magnetism acts)
I: Current flowing in the coil In order to increase the driving force F, it is necessary to increase Bg and Ic.

  In order to increase Bg, it is effective to increase the size of the magnet that is a magnetic generation source, in particular, to increase the area of the magnetic pole surface. That is, when the magnet is cylindrical, it is effective to increase the diameter. It is also effective to increase the cross-sectional area of the yoke (magnetic path). If the cross-sectional area is small, the leakage magnetic flux increases, and the operating point of the magnet decreases due to the increase of the magnetic resistance of the magnetic path, so that the ability of the magnet cannot be effectively used in the magnetic gap.

  Ic is better as long as possible, but it is necessary to match the requirements of a predetermined resistance value by matching with the power supply source (amplifier) to be connected, and it is also necessary to consider the effect of mass as a vibration element, so it should be simply increased I can't. However, when the driving force is important, Ic can be increased without increasing the resistance by increasing the diameter of the voice coil and increasing the wire diameter of the coil.

Enlarging the voice coil diameter, increasing the magnet diameter, and increasing the cross-sectional area of the magnetic path of the yoke to increase the driving force generated in the voice coil of the magnetic circuit are all The outer diameter will be increased.
(2) If the back side of the diaphragm of the electroacoustic transducer (driver) is a sealed space, the movement of the diaphragm will be hindered. Therefore, a communication port for exhausting the air in the space on the back side of the diaphragm to the outside is required. If the electroacoustic transducer (driver) is downsized, a space for providing a communication port cannot be secured.

  The present invention has been made in view of the above problems, and an object thereof is to provide an electroacoustic transducer that is small in size, can obtain a large driving force, and can secure a space for providing a communication port.

The electroacoustic transducer of the invention according to claim 1 for solving the problem is:
A magnetic circuit having a magnetic gap;
A voice coil disposed in the magnetic gap of the magnetic circuit;
A diaphragm attached to the voice coil at the center and an outer edge attached to the frame;
A communication port provided in the frame, for exhausting air on the back side of the diaphragm to the outside of the frame;
An electroacoustic transducer having
The magnetic circuit is:
Magnets,
A first bottom portion joined to the bottom surface of the magnet, and a first cylindrical portion having an inner peripheral surface that is connected to the first bottom portion and faces the outer peripheral surface of the magnet through a gap serving as the magnetic gap. A first yoke that forms a bottomed cylindrical shape with one end surface being an open surface, and that is part of the frame;
A second bottom portion joined to the outer surface of the first bottom portion of the first yoke; a second tubular portion provided continuously to the second bottom portion and opposed to an outer peripheral surface of the first tubular portion of the first yoke; A bottomed cylindrical second yoke whose end face is an open surface;
Consists of
The frame is
The first yoke;
A collar portion formed to extend outward from a peripheral portion on the open surface side of the first cylindrical portion of the first yoke, and to which an outer edge portion of the diaphragm is attached;
Consists of
A gap is formed between the end surface on the open surface side of the second cylindrical portion of the second yoke and the collar portion,
The communication port is
It is formed in the said collar part, The end surface by the side of the open surface of a 2nd cylinder part is located on the opening part of the said communicating port, It is characterized by the above-mentioned.

  Other features of the present invention will become more apparent from the following detailed description and accompanying drawings.

According to the electroacoustic transducer of the present invention,
The magnetic circuit is:
Magnets,
A first bottom portion joined to the bottom surface of the magnet, and a first cylindrical portion having an inner peripheral surface that is connected to the first bottom portion and faces the outer peripheral surface of the magnet through a gap serving as the magnetic gap. A first yoke that forms a bottomed cylindrical shape with one end surface being an open surface, and that is part of the frame;
A second bottom portion facing the outer surface of the first bottom portion of the first yoke, and a second tube portion connected to the second bottom portion and facing an outer peripheral surface of the first tube portion of the first yoke, A bottomed cylindrical second yoke whose end face is an open surface;
By consisting of
Since the cross-sectional area of the magnetic path of the magnetic circuit is increased and the magnetic flux density can be increased, a large driving force can be ensured.

By appropriately setting the shape of the second yoke, it is possible to secure a large space for the collar portion of the frame in which the communication port is provided.
Other effects of the present invention will become more apparent from the following detailed description and accompanying drawings.

FIG. 3 is an enlarged view of the electroacoustic transducer of FIG. 2, which is a cross-sectional view of the earphone having the electroacoustic transducer of the first embodiment. It is sectional drawing of the earphone which has the electroacoustic transducer of 1st Embodiment. It is sectional drawing of the electroacoustic transducer of 2nd Embodiment.

<First Embodiment>
A first embodiment will be described with reference to the drawings.
1 is an enlarged view of the electroacoustic transducer of FIG. 2, which is a cross-sectional view of the earphone having the electroacoustic transducer of the first embodiment, and FIG. 2 is a cross section of the earphone having the electroacoustic transducer of the first embodiment. FIG.

First, the overall configuration of the earphone having the electroacoustic transducer of the first embodiment will be described with reference to FIG.
In FIG. 2, the housing 101 of the earphone 102 includes a bowl-shaped front housing 103 having an open surface 103a and a bottom 103b, and a bowl-shaped rear housing 105 having an open surface 105a and a top 105b.

The front housing 103 and the rear housing 105 are assembled so that the open surface 103a and the open surface 105a of each housing overlap, and a space is formed inside.
A driver (electroacoustic transducer) 107 that is driven by a sound signal and emits sound toward the bottom 103 b of the front housing 103 is provided on the bottom 103 b side in the front housing 103.

In the housing 101, a space on the rear housing 103 side of the driver 107 (a back space of the driver 107) is a cavity C for adjusting acoustic characteristics.
The rear housing 105 is formed with a cylindrical cord taking-in part 105c extending in the radial direction from the peripheral surface. A through hole 105d having an opening on the inner wall surface of the rear housing 105 is formed in the cord taking-in portion 105c. The cord 113 is taken into the rear housing 105 from the outside of the earphone 102 through the through hole 105d.

  The cord 113 taken into the rear housing 105 from the outside of the earphone 102 is tied and a ball knotting ball portion 113 a is formed in the rear housing 105. The diameter of the knotted ball portion 113a is larger than the diameter of the through hole 105d, and prevents the cord 113 taken into the rear housing 103 from the cord taking-in portion 105c.

The front housing 103 is formed with a sound conduit 103c extending outward from the bottom 103b. The sound conduit 103 c is formed with a through hole 103 d having an opening on the inner wall surface of the front housing 103.
An earpiece 117 made of urethane resin, silicon rubber, or the like is provided on the outer peripheral surface of the sound conduit 103c.

A screen 119 is provided at the tip of the sound conduit 103c so as to close the opening of the through hole 103d.
Next, the driver (electroacoustic transducer) 107 will be described with reference to FIG.
The driver 107 according to this embodiment includes a magnetic circuit 150, a voice coil 170, and a diaphragm 190.
(Magnetic circuit)
The magnetic circuit 150 includes a magnet 151 having a cylindrical shape whose magnetization direction is the height direction of the cylinder, a first yoke 153, a plate 157, and a second yoke 159.

  The first yoke 153 is made of a ferromagnetic material, and is connected to the first bottom portion 153a joined to the bottom surface of the magnet 151. The first yoke 153 is connected to the first bottom portion 153a via a gap serving as a magnetic gap G with respect to the outer peripheral surface of the magnet 151. It has the 1st cylinder part 153b which comprises the inner peripheral surface which opposes, and has comprised the bottomed cylinder shape by which one end surface became the open surface.

A flange 155 is formed on the first yoke 153 so as to extend outward from the peripheral portion on the open surface side of the first tube portion 153 b, and the first yoke 153 and the flange 155 form a frame 180. Is configured.
The plate 157 is made of a ferromagnetic material and is provided on the top surface of the magnet 151.

  The second yoke 159 is made of a ferromagnetic material, is connected to the outer surface of the first bottom portion 153 a of the first yoke 153, and is connected to the second bottom portion 159 a, and the first tube portion of the first yoke 153 is connected to the second yoke 159. It has the 2nd cylinder part 159b which opposes the outer peripheral surface of 153b through a very small space, and becomes a bottomed cylinder shape by which one end surface became the open surface.

In this embodiment, the frame 180 having the first yoke 153 and the second yoke 159 are formed by press drawing a plate material made of a ferromagnetic material.
(Voice coil, diaphragm)
Generally, a voice coil includes a cylindrical bobbin and a coil wound around the outer peripheral surface of the bobbin, and a coil wound with a wire rod in a cylindrical shape.

The voice coil 170 of the present embodiment is a coil obtained by winding a conductive wire in a cylindrical shape.
One end of the voice coil 170 is attached to the center of the diaphragm 190 so that the voice coil 170 is positioned in the magnetic gap G of the magnetic circuit 150.

A cord 113 is connected to the voice coil 170, and an audio signal is supplied via the cord 113.
An outer edge portion of the diaphragm 190 is attached to a flange portion 155 of the frame 180.
Further, the flange portion 155 of the frame 180 is formed with a communication port 155a for exhausting the air in the space on the back side of the diaphragm 190 (the space surrounded by the diaphragm 190 and the frame 180) to the outside.

In the present embodiment, the end surface 159c on the open surface side of the second cylindrical portion 159b of the second yoke 159 of the magnetic circuit 150 does not contact the collar portion 155, and the end surface 159c of the second yoke 159 and the collar portion 155 are not in contact with each other. A space is formed between them.
Next, the operation of the driver (electroacoustic transducer) 107 having the above configuration will be described.

  A magnetic field is generated in the magnetic gap G of the magnetic circuit 150 including the magnet 151, the first yoke 153, the second yoke 159, and the plate 157. When a voice signal is passed through the cord 113 to the voice coil 170 arranged in the magnetic gap 1G, a driving force (propulsive force) is generated in the voice coil 170 due to Fleming's left-hand rule. 190 vibrates and a sound is emitted.

According to the above configuration, the following effects can be obtained.
(1) The magnetic circuit 150 includes a magnet 151, a first bottom portion 153a that is joined to the bottom surface of the magnet 151, and an outer peripheral surface of the magnet 151 that is connected to the bottom surface of the magnet 151 via a gap serving as a magnetic gap G. The first yoke portion 153b having a first cylindrical portion 153b having inner surfaces facing each other, having a bottomed cylindrical shape with one end surface being an open surface, and a first yoke 153 that is a part of the frame 180, and a first yoke 153 A second bottom part 159a joined to the outer surface of the first bottom part 153a, and a second cylinder connected to the second bottom part 159a and facing the outer peripheral surface of the first cylindrical part 153b of the first yoke 153 via a small space. The bottom end of the first yoke 153 and the second yoke 159 has a cross-sectional area of the magnetic path. Widen, magnetic flux Since the density can be increased, a large driving force can be secured.

In particular, in this embodiment, the weight of the frame 180 can be reduced by setting the thickness of the first yoke 153 that is a part of the frame 180 to a thickness that can ensure the minimum mechanical strength in assembly.
(2) The end surface 159c on the open surface side of the second cylindrical portion 159b of the second yoke 159 of the magnetic circuit 150 does not contact the collar portion 155, and is between the end surface 159c of the second yoke 159 and the collar portion 155. Since a space is formed, a large space can be secured for the collar portion 155 provided with the communication port 155a.

In particular, in the present embodiment, by setting the thickness of the first yoke 153 that is a part of the frame 180 to a thickness that can ensure the minimum mechanical strength in assembling, a larger space for the collar portion 155 can be secured.
An appropriate acoustic impedance can be obtained by appropriately setting the opening area of the communication port 155a provided in the collar portion 155 and the acoustic resistance provided in the communication port 155a.

In the present embodiment, the first yoke 153 and the second yoke 159 need not be fixed by adhesion or the like, but in order to reliably guide the magnetic flux from the magnet 151 to the first yoke 153 and the second yoke 159. In addition, it is desirable that the gap between the first yoke 153 and the second yoke 159 in the vicinity of the bottom of the magnet 151 and in the vicinity of the opening of the second cylindrical portion 159b of the second yoke 159 be eliminated as much as possible.
Second Embodiment
A second embodiment will be described with reference to the drawings. FIG. 3 is a cross-sectional view of the electroacoustic transducer of the second embodiment.

The difference between this embodiment and the first embodiment is the magnetic circuit, more specifically, the second yoke, and the other parts are the same. Accordingly, the same parts are denoted by the same reference numerals, and redundant description is omitted.
The second yoke 259 of the magnetic circuit 250 according to the present embodiment is made of a ferromagnetic material, and is connected to the outer surface of the bottom portion 153a of the first yoke 153, the second bottom portion 259a, and the second bottom portion 259a. It has a bottomed cylindrical shape having an outer peripheral surface of the first cylindrical portion 153b of 153 and a second cylindrical portion 259b facing each other through a minute space, and one end surface is an open surface.

In this embodiment, the frame 180 having the first yoke 153 and the second yoke 259 are formed by press drawing a plate material made of a ferromagnetic material.
In the present embodiment, the end surface 259c on the open surface side of the second cylindrical portion 259b of the second yoke 259 of the magnetic circuit 250 is in contact with the collar portion 155.

And the communication port 155a formed in the collar part 155 is formed outside the outer peripheral surface of the 2nd cylinder part 259b.
According to such a configuration, the following effects can be obtained.
(1) The magnetic circuit 250 includes a magnet 151, a first bottom portion 153a that is joined to the bottom surface of the magnet 151, and an outer peripheral surface of the magnet 151 that is connected to the bottom surface of the magnet 151 via a gap serving as a magnetic gap G. The first yoke portion 153b having a first cylindrical portion 153b having inner surfaces facing each other, having a bottomed cylindrical shape with one end surface being an open surface, and a first yoke 153 that is a part of the frame 180, and a first yoke 153 A second bottom part 259a joined to the outer surface of the first bottom part 153a, and a second cylinder connected to the second bottom part 259a and facing the outer peripheral surface of the first cylindrical part 153b of the first yoke 153 via a small space. A bottom-cylindrical cylindrical second yoke 259 having one end face that is an open surface, so that the cross-sectional area of the magnetic path composed of the first yoke 153 and the second yoke 259 is reduced. Widen, magnetic flux Since the density can be increased, a large driving force can be secured.

In particular, in this embodiment, the weight of the frame 180 can be reduced by setting the thickness of the first yoke 153 that is a part of the frame 180 to a thickness that can ensure the minimum mechanical strength in assembly.
(2) The end surface 259c on the open surface side of the second tube portion 259 of the second yoke 259 of the magnetic circuit 250 is in contact with the flange portion 155, and the communication port 155a formed in the flange portion 155 is the second tube portion 259b. As a result, the opening of the communication port 155a can be reliably secured.

Also in this embodiment, by setting the thickness of the first yoke 153 that is a part of the frame 180 to a thickness that can ensure the minimum mechanical strength in assembly, a large space for the collar portion 155 can be secured.
An appropriate acoustic impedance can be obtained by appropriately setting the opening area of the communication port 155a provided in the collar portion 155 and the acoustic resistance provided in the communication port 155a.

  In the present embodiment, the first yoke 153 and the second yoke 159 may not be fixed by adhesion or the like, but in order to reliably guide the magnetic flux from the magnet 151 to the first yoke 153 and the second yoke 259. In addition, it is desirable that the gap between the first yoke 153 and the second yoke 259 in the vicinity of the bottom of the magnet 151 and in the vicinity of the opening of the second cylindrical portion 259b of the second yoke 259 be eliminated as much as possible.

150 Magnetic circuit 151 Magnet 153 First yoke 153a First bottom 153b First cylinder 155 Collar 159 Second yoke 159a Second bottom 159b Second cylinder 180 Frame

Claims (1)

A magnetic circuit having a magnetic gap;
A voice coil disposed in the magnetic gap of the magnetic circuit;
A diaphragm attached to the voice coil at the center and an outer edge attached to the frame;
A communication port provided in the frame, for exhausting air on the back side of the diaphragm to the outside of the frame;
An electroacoustic transducer having
The magnetic circuit is:
Magnets,
A first bottom portion joined to the bottom surface of the magnet, and a first cylindrical portion having an inner peripheral surface that is connected to the first bottom portion and faces the outer peripheral surface of the magnet through a gap serving as the magnetic gap. A first yoke that forms a bottomed cylindrical shape with one end surface being an open surface, and that is part of the frame;
A second bottom portion joined to the outer surface of the first bottom portion of the first yoke; a second tubular portion provided continuously to the second bottom portion and opposed to an outer peripheral surface of the first tubular portion of the first yoke; A bottomed cylindrical second yoke whose end face is an open surface;
Consists of
The frame is
The first yoke;
A collar portion formed to extend outward from a peripheral portion on the open surface side of the first cylindrical portion of the first yoke, and to which an outer edge portion of the diaphragm is attached;
Consists of
A gap is formed between the end surface on the open surface side of the second cylindrical portion of the second yoke and the collar portion,
The communication port is
An electroacoustic transducer, characterized in that an end surface on the open surface side of the second tube portion is located on the opening portion of the communication port .

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