JP6024340B2 - headphone - Google Patents

Description

  The present invention relates to headphones.

  Various so-called inner ear type headphones that are used with the main body part mounted in the auricle have been proposed for reproducing the bass sound better. For example, bass reflex type headphones described in Patent Document 1 are proposed. There is.

JP 2006-287664 A

The headphone described in Patent Document 1 has a duct for guiding the sound emitted from the back side of the speaker unit to be synthesized with the sound emitted from the front side by phase inversion. This structure is called a so-called bass reflex type, and is an inner ear type headphone that uses a relatively small-diameter speaker unit, and is capable of relatively easily realizing the rich bass reproduction expected from the market.
In this structure, since the back pressure applied to the diaphragm of the speaker unit is determined by the duct specifications (duct diameter and length), etc., changing the shape of the duct for sound quality adjustment will affect the vibration of the diaphragm. The sound quality of the sound emitted to the front side also changes.
Therefore, it is relatively easy to enhance the low sound range, but it takes a long time to determine the quality of the reproduced sound as headphones.
That is, in the design process, since the sound quality adjustment work for adjusting and determining the sound quality of a product takes a long time, a headphone that can perform the sound quality adjustment work in a short time has been desired.

  Also, as shown in FIG. 2 and FIG. 7 of Patent Document 1, since the duct has a shape that protrudes greatly outward from the main body, it is easy to attach the main body to the auricle when using headphones. Improvements have been desired in that compactness is not easy.

  Therefore, the problem to be solved by the present invention is to provide a headphone that allows easy sound quality adjustment work and enables rich bass reproduction.

In order to solve the above problems, the present invention has the following configuration 1 ) .
A headphone having 1) release sound port released to the outside sound,
A first speaker unit to emit sound toward Ke said sound emitting port,
A dynamic second speaker unit;
A unit cover that forms a front cavity with the sound emitting surface of the second speaker unit;
One end side has a tube hole communicating with the front cavity, and the sound emitted from the second speaker unit to the front cavity enters from the one end side of the tube hole and is directed from the other end side to the sound emission port. A tube arranged to discharge,
With
The unit cover is formed in a stepped pan shape having a large diameter part accommodating the sound emitting surface side of the second speaker unit, and a small diameter part smaller in diameter than the large diameter part,
The tube according to claim 1, wherein the tube has an arc portion arranged in an arc shape outside the small diameter portion of the unit cover .

  According to the present invention, it is possible to obtain an effect that the sound quality adjustment work is easy and rich bass reproduction is possible.

It is a perspective view which shows the external appearance of the headphones of Example 1 of this invention. It is an exploded view for demonstrating the headphones of Example 1 of this invention. It is principal part sectional drawing for demonstrating the headphones of Example 1 of this invention. It is the perspective view which made L cover unillustrated in order to explain the headphones of Example 1 of the present invention. It is sectional drawing which made R cover unillustrated in order to demonstrate the headphones of Example 1 of this invention. It is a three-view figure for demonstrating the tube in the headphones of Example 1 of this invention. It is the perspective view which extracted the principal part in order to demonstrate the headphones of Example 1 of this invention. It is the perspective view which made the unit cover unillustrated in FIG. It is typical sectional drawing for demonstrating the headphones of Example 1 of this invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view in which an F cover is not shown in order to explain the headphones of Example 1 of the present invention. It is a schematic diagram for demonstrating arrangement | positioning of the principal part in the headphones of Example 1 of this invention. It is a figure for demonstrating the example of a connection in the headphones of Example 1 of this invention. It is a frequency characteristic figure explaining the characteristic of the output sound in the headphones of Example 1 of the present invention. It is a perspective view which shows the external appearance of the headphones of Example 2 of this invention. It is an exploded view for demonstrating the headphones of Example 2 of this invention. It is the perspective view which extracted the principal part in order to demonstrate the headphones of Example 2 of this invention. It is a longitudinal cross-sectional view for demonstrating the modification in Example 1 of this invention. It is a front view for demonstrating the modification in Example 1 of this invention. It is a perspective view which shows the cord bush 73 used for the modification in Example 1 of this invention. It is a schematic diagram for demonstrating the modification in Example 1 of this invention. It is a fragmentary perspective view for demonstrating the principal part of the modification in Example 1 of this invention. It is a perspective view which shows the cord bush 73 which has the cushion member 74 used for the modification in Example 1 of this invention. It is a figure for demonstrating the other modification in Example 1, 2 of this invention.

  A headphone according to an embodiment of the present invention will be described with reference to FIGS.

<Example 1>
FIG. 1 is a perspective view illustrating an appearance of the headphone HP1 according to the first embodiment, and FIG. 2 is a perspective exploded view of the headphone HP1. In the following description, the up / down / left / right and front / back directions are defined by the directions shown in FIG.
The headphone HP1 is a so-called earplug type headphone that can be fitted with an earpiece to be inserted into the ear canal among headphones classified as an inner ear type.
In appearance, the headphone HP 1 is visually recognized by the main body 1, the cylindrical sound tube portion 2 and the cord bush 3 protruding from the main body 1, and the cord 4 pulled out from the tip of the cord bush 3. .
An earpiece 5 is detachably attached to the sound tube portion 2. The earpiece 5 is made of a low-rigidity material (rubber, elastomer, etc.) having flexibility. When the headphone HP1 is used, the earpiece 5 is inserted into the ear canal together with the sound tube portion 2, and is deformed flexibly so as to be in close contact with the inner surface of the ear canal It is supposed to be.
Sounds output from speaker units 7 to 9 to be described later are supplied into the external auditory canal via the sound outlet 2a of the sound tube unit 2. That is, the sound tube portion 2 functions as a sound emitting portion.

The main body 1 is formed by combining an L cover 1a, an R cover 1b, and an F cover 1c, which are three covers divided into a left side, a right side, and a front side. The cord bush 3 is sandwiched and held between the L cover 1a and the R cover 1b.
The cord bush 3 is formed of a low rigidity material such as rubber or elastomer. A specific material example is silicone rubber.
The sound tube portion 2 is formed integrally with the F cover 1c. A ring-shaped ornament 1d is attached to the L cover 1a.
The L cover 1a, R cover 1b, and F cover 1c are formed of, for example, a thermoplastic resin. Examples of the thermoplastic resin used include ABS (acrylonitrile butadiene styrene) and PC (polycarbonate).

A unit holder 6 is housed inside the F cover 1c. The unit holder 6 is formed in an oval shape with, for example, a metal material (brass or the like) or a hard resin material, and the two speaker units 7 and 8 are rearward in parallel in the vertical direction with the upper side being the speaker unit 7. Housing holes 6a and 6b, and through-holes 6c connected to the ends of the tubes 11 to be described later. That is, the unit holder 6 supports the two speaker units 7 and 8 and the end portion of the tube 11.
With the speaker units 7 and 8 housed in the housing holes 6a and 6b of the unit holder 6, the drive axes CL7 and CL8 of the diaphragms (not shown) are parallel to each other.

The two speaker units 7 and 8 have the same specifications in this example, and are dynamic types in which the outer diameter of the case is 5.8 mm and the outer diameter of the diaphragm (the outer diameter of the movable part including the edge) is 5.55 mm. This is an electroacoustic transducer.
One end side of the cord 4 is electrically connected to the speaker units 7 and 8, and an audio signal from a playback device (not shown) connected to the other end side of the cord 4 is converted into sound and output. In FIG. 2, drawing on both ends of the code 4 is omitted.

A speaker unit 9 is accommodated at the rear side of the main body 1, that is, at a position away from the speaker units 7 and 8 with respect to the sound tube unit 2. The speaker unit 9 is a dynamic electroacoustic transducer in which the outer diameter of the case is 8.8 mm and the outer diameter Dc (outer diameter of the movable part including the edge) of the diaphragm 9s (see FIG. 3) is 7.8 mm. .
The speaker unit 9 is accommodated so as to be sandwiched between the R cover 1b and the unit cover 10 in a posture in which the sound emitting surface 9a which is the front surface faces the left side (the front side in FIG. 1). Note that the unit cover 10 and the speaker unit 9 are in a sealed state so that the sound emitted from the diaphragm direction does not wrap around the back space, that is, the 1b side.
The electrical connection between the speaker units 7 to 9 and the cord 4 will be described later.

FIG. 3 is a cross section taken along line S1-S1 in FIG. 1, and shows a state in which a portion where the R cover 1b and the unit cover 10 are combined is cut along a plane generally defined by the upper, lower, left, and right sides.
The unit cover 10 has an upper surface portion 10e, an open portion on the lower surface side is a large-diameter portion 10d, a ring-shaped portion standing from the upper surface portion 10e is a small-diameter portion 10b, and a ring-shaped portion is formed from the bottom surface of the small-diameter portion 10b. It is a stepped pan-like member having a stepped portion 10a. The unit cover 10 is formed of, for example, a thermoplastic resin material such as ABS or PC, or a metal material such as brass or aluminum.

The speaker unit 9 is accommodated with respect to the unit cover 10 at a position where the periphery of the sound emitting surface 9a abuts against the stepped portion 10a with almost no gap inside the large diameter portion 10d.
The sound emitting surface 9a and the unit cover 10 form a front cavity V1 as a space between them. An opening 10c is formed at one location on the surface portion 10b1 on the inner surface side of the small diameter portion 10b facing the front cavity V1.
The front cavity V1 is almost sealed except for the opening 10c.
The back surface 9b side of the speaker unit 9 is covered with an R cover 1b, and a back cavity V2 is formed as a space between the back surface 9b and the R cover 1b. The back cavity V2 is substantially sealed.

  The orientation of the speaker unit 9 in the main body 1 is set such that, for example, the drive axis CL9 intersects (for example, intersects with) the drive axis CL7, 8 of the speaker units 7, 8.

FIG. 4 is a view of the L cover 1a of the main body 1 as seen from the left rear obliquely lower side with the outer surface of the unit cover 10 exposed, not shown.
FIG. 5 is a cross-sectional view taken along a plane generally defined by the front, rear, top and bottom with the R cover 1 b of the main body 1 not shown, with the inner surface of the unit cover 10 exposed.
As shown in FIGS. 3 to 5, one end 11 a side of the tube 11 is inserted into the opening 10 c from the outside.
The tube 11 has a tube hole 11h that communicates with both ends, and one end of the tube hole 11h is connected to the front cavity V1 so that the space inside the tube hole 11h and the front cavity V1 communicate with each other. It is installed.

Here, the tube 11 will be described in detail.
6A and 6B are three views of the tube 11. FIG. 6A is a top view, FIG. 6B is a right side view, and FIG. 6C is a front view.
FIG. 7 is a view in which the L cover 1a, the R cover 1b, the cord bushing 3, and the cord 4 are not shown in order to explain the relationship between the tube 11, the unit cover 10, and the unit holder 6.

The tube 11 is a thin tube having a tube hole 11h that communicates between one end and the other end. A material is not limited, For example, what was formed in the tubular shape using metal materials (iron, aluminum, copper, etc.) and resin materials (polyethylene etc.) can be used.
As shown in FIG. 6, the tube 11 is formed in a substantially straight shape on the side of the end portion 11a inserted into the front cavity V1 and in a substantially straight shape on the side of the other end portion 11e. A straight portion 11d, and an arc portion 11c formed with a predetermined inner diameter Da between the straight portion 11b and the straight portion 11d.
This shape is maintained in a natural state when the tube 11 is formed of a high-rigidity material such as metal, and is thus assembled in the main body 1 in that state when the headphone HP1 is assembled.
Further, when formed of a low-rigidity material such as soft polyethylene, it is difficult to maintain in a natural state. Therefore, it is formed into this shape by a jig or an automatic machine and assembled in the unit cover 10 during assembly work.

The inner diameter Da of the arc portion 11c is set slightly larger than the outer diameter Db (see FIGS. 4 and 7) of the small diameter portion 10b of the unit cover 10. Further, the outer diameter of the tube 11 is set to be smaller than half of the outer diameter difference between the small diameter portion 10b and the large diameter portion 10d.
As a result, as shown in FIGS. 3, 4, and 7, the arc portion 11c extends radially from the maximum outer shape of the unit cover 10 (the outer shape of the large diameter portion 10d) outside the small diameter portion 10b of the unit cover 10. It is arranged so as to fit in the step of the step portion 10a without protruding outward.

Moreover, by providing the arc part 11c in the tube 11, the full length of the tube hole 11h can be ensured with a desired length by effectively utilizing the empty space in the main body part 1.
Further, the tube 11 is disposed such that the arc portion 11 c forms an arc around the drive axis CL 9 of the speaker unit 9. That is, it is formed so that the drive axis CL9 is positioned within the arc of the arc portion 11c. For example, it is an arc centered on the drive axis CL9. As a result, the dimension in the direction along the drive axis CL9 is reduced in the space occupied by the arc portion 11c of the tube 11, so that the main body portion 1 can be formed with an extremely compact design.
That is, the circular arc part 11c functions as a path extension part for obtaining the entire length (path) of the tube hole 11h longer in the occupied space formed by the compact L cover 1a and R cover 1b.

The opening 10c through which one end portion 11a of the tube 11 is passed is sealed with a sealing material BD such as a bond at the gap with the tube 11 (see FIG. 4). As a result, the front cavity V1 is in communication with the external space only at the tube hole 11h of the tube 11.
On the other hand, the distal end side of the straight portion 11 d of the tube 11 is inserted into a through hole 6 c provided in the unit holder 6, and the other end of the tube hole 11 h is open to the front space of the unit holder 6.
That is, the tube hole 11h is a ventilation path that communicates between the front space VF (see FIG. 5) of the unit holder 6 and the front cavity V1 with a predetermined length.

As shown in FIG. 5, an intermediate portion 11M that bridges the unit holder 6 and the unit cover 10 of the tube 11, for example, a portion near the arc portion 11c in the straight portion 11d is formed in the L cover 1a. The groove portion 1a1 may be engaged and supported.
In this case, when the tube 11 is formed of a low-rigidity material, the posture of the tube 11 is stably and satisfactorily maintained.
Further, when the tube 11 is formed of a highly rigid material, the vibration of the tube 11 itself is satisfactorily suppressed, so that unnecessary internal vibration that affects the reproduced sound of the headphone HP1 is prevented.
When the tube 11 is formed of a highly rigid material, the tube 11 may be disposed so as not to contact the unit cover 10 except for the opening 10c to which the tube 11 is connected.
In this case, a gap is formed between the tube 11 and the stepped portion 10a of the unit cover 10 as exemplified by the part PT in FIG.
By forming this gap, even if the tube 11 vibrates, contact (collision) with the unit cover 10 other than the opening 10c is unlikely to occur, so that a tapping sound is generated by the tube 11 and the unit cover 10. This can be prevented more reliably.

FIG. 8 is a view in which the unit cover 10 in FIG. 7 is not shown, and is a view for explaining the positional relationship (arrangement state) between the speaker unit 9 and each member related thereto.
As shown in FIG. 8, in the vertical direction, the drive axis CL9 of the speaker unit 9 is located between the drive axis CL7 of the speaker unit 7 and the drive axis CL8 of the speaker unit 8.
Further, as described above, the drive axis CL9 is non-parallel (intersects) with the drive axis CL7 and the drive axis CL8 that are parallel to each other, and is set to be orthogonal in this example. Has been.
In the left-right direction, the speaker unit 9 is installed such that the sound emitting surface 9a is on or near a virtual plane SF defined as a plane including the drive axis CL7 and the drive axis CL8. Is set.
FIG. 9 is a cross-sectional view seen from the rear side in the extending direction of the virtual plane SF, and is a schematic view cut at a position where the speaker unit 9 is crossed. In the example of this figure, the speaker unit 9 is disposed such that the sound emitting surface 9a is positioned closest to the left side with respect to the virtual plane SF.
Further, as shown in FIG. 9, it is better that the front cavity V1 and the back cavity V2 are formed on one side and the other side across the virtual plane SF.

With these arrangement states, the speaker unit 9 and the front cavity V1 and the back cavity V2 having the configuration related to the speaker unit 9 can be distributed to the speaker units 7 and 8 approximately equally in the vertical and horizontal directions. it can.
Therefore, the shape of the main body 1 of the headphone HP1 can be formed in a compact and well-balanced manner as a whole with few protruding portions.

This merit is also apparent in the example shown in FIG.
FIG. 10 is a view of the state in which the unit holder 6 is exposed with the F cover 1c of the main body 1 not shown, as viewed from the front side.
In this example, the cord bush 3 is arranged so that the center line thereof is located on the virtual plane SF.
In addition, the outline line is set so that the distance to the left maximum protrusion portion (left protrusion amount) WL with respect to the virtual plane SF and the distance to the right maximum protrusion portion (right protrusion amount) WR are not significantly different. . In addition, there is no portion that projects locally in the outer shape line, and the main body 1 is extremely compact in design.

In FIG. 10, the speaker unit 7, the speaker unit 8, and the tube hole 11 h of the tube 11 are opened in the front surface portion 6 d of the unit holder 6.
In other words, the layout is equivalent to providing three speaker units on the front surface portion 6d.

FIG. 11 is a schematic diagram for explaining the relationship between the speaker units 7 to 9 and the tube 11, and shows a state viewed from the left side of the main body 1.
As is clear from FIG. 11, the sound units AD8 and AD8 (see white arrows) are output from the speaker units 7 and 8 to the sound tube unit 2, respectively, and the tube holes 11h are directed to the sound tube unit 2. The sound AD9 (see black arrow) output from the speaker unit 9 is output.
The voices AD7 to AD9 are all output in the same direction (forward) from the front surface portion 6d which is the same surface, and emitted from the tip of the sound tube portion 2 into the user's ear canal when the headphone HP1 is used.
Thus, the headphones HP1 have the same direction (directions parallel to each other) in which the output direction of the voices AD7 and AD8 and the output direction of the voice AD9 added to the voices AD7 and AD8 are directed to the sound tube unit 2 as the sound emitting unit. It is preferable that As a result, unnecessary waveform interference or the like that may occur when the voice AD9 is added from a direction different from the voices AD7 and AD8 (crossing direction) does not occur and is better for the user. Can provide a simple output sound.

  FIG. 12 is a connection diagram illustrating an example of electrical connection between the cord 4 and the speaker units 7 to 9. For example, the cord 4 has two cores, and external audio signals are connected to the speaker units 7 to 9 in parallel. For this connection, auxiliary circuits such as an impedance adjustment unit for adjusting impedance and a sound quality adjustment unit for adjusting sound quality may be added as necessary.

According to the configuration described in detail above, the sound AD9 output from the speaker unit 9 can be added to the user's listening sound without affecting the sound AD7, AD8 itself output from the speaker units 7, 8. it can.
Here, since the sound AD9 from the speaker unit 9 is sound emitted from the front surface part 6d via the tube hole 11h, the specification of the tube hole 11h is set so that the sound AD9 has a desired frequency characteristic. (Tuning) can be added to the voices AD7 and AD8.
For example, by making the tube hole 11h smaller in diameter and making the entire length of the tube 11 longer, in the frequency characteristic of the voice AD9, the sound range having a high sound pressure level is shifted to the low sound side, and the sound pressure level is made higher. be able to.

More specifically, when the tube 11 has an inner diameter of the tube hole 11h as p, and the tube hole length L in the state where the entire tube 11 is linearly expanded, the vibration of the speaker unit 9 will be described. It is preferable that the relationship with the outer diameter Dc of the movable part including the plate 9s is set so as to satisfy the following formulas, because a rich bass reproduction is possible in general inner-ear headphones.
That is, 3 × Dc ≦ L (Expression 1) and 22xp ≦ Dc (Expression 2)
It is.
An additional example of the voice AD9 will be described with reference to FIG.

FIG. 13 is a diagram showing frequency characteristics of 10 kHz or less, where the horizontal axis is frequency (Hz) and the vertical axis is sound pressure level (dB).
The headphones HP1 having the characteristics shown in FIG. 13 have Dc = 7.8 mm, p = 0.35 mm, and L = 30 mm.
The characteristic A (dashed line) is the frequency characteristic of the sound AD9 output from the tube hole 11h by driving only the speaker unit 9 without driving the speaker units 7 and 8, and the characteristic B (dashed line) is the speaker unit. 9 is a frequency characteristic related to the sound AD7 and the sound AD8 obtained by driving only the speaker units 7 and 8 without driving 9.
A characteristic C (solid line) is a characteristic of the sound obtained by driving all the speaker units 7 to 9, and is obtained by adding the sound AD9 to the sound AD7 and the sound AD8. The user listens to the sound having the characteristic C.

As shown by the characteristic A, the sound AD9 has a high sound pressure level particularly in a low sound range of 100 Hz or less. In other words, the sound path from the speaker unit 9 to the front surface portion 6d functions as a low-pass filter.
As shown in the characteristic A, the sound AD9 does not have a high sound pressure level in the middle and high sound range (a range exceeding approximately 100 Hz), so that the sound AD9 hardly affects the characteristics B of the sound AD7 and the sound AD8.
Therefore, the characteristic C is the same as the characteristic B in this mid-high range.
On the other hand, since the sound AD9 has a particularly high sound pressure level in the low sound range (approximately 100 Hz or less), the sound AD9 affects the characteristics B of the sound AD7 and the sound AD8.
Therefore, in this low sound range, the characteristic C has a higher sound pressure level than the characteristic B.

Thus, the headphone HP1 can add the sound AD9 that is output from the speaker unit 9 and that depends only on the sound path that passes through the tube hole 11h without affecting the output sound itself of the speaker units 7 and 8. .
Therefore, the user can listen by setting (tuning) the voice AD9 to have a desired characteristic (for example, the characteristic A in which only the low frequency range is enhanced as described above) by the speaker unit 9 and the tube 11. The output sound of the headphone HP1 can be easily set to a desired characteristic.
For this reason, the sound quality adjustment work in the design process is shortened, the product development cycle is shortened, the market demand can be met at an early stage, and the design cost can be reduced.

When (Formula 1) is not satisfied, that is, when the total length of the tube hole 11h is short, or when (Formula 2) is not satisfied, that is, when the inner diameter of the tube hole 11h is large, the characteristic A is in the middle range. The sound pressure level near 100 to 1000 Hz is also increased. Therefore, the characteristic C becomes a characteristic in which the sound pressure level is enhanced not only in the low sound range but also in the middle sound range, and the entire frequency may need to be readjusted.
Originally, only the speaker units 7 and 8 are driven, and at least the mid-range and high-range sound quality adjustments are well adjusted, and the bass enhancement, which is an improvement of the inner-ear type headphones, is desired. Since it is required to be realized in a short time with characteristics, it is expected that only the low frequency range can be enhanced without affecting the adjusted middle / high frequency range. Therefore, in the headphone HP1, it is more desirable that each dimension is set so as to satisfy (Expression 1) and (Expression 2).

<Example 2>
The headphone HP1 described above is a speaker unit 9 for adding characteristics disposed so that the drive axis intersects (non-parallel) with respect to the speaker units 7 and 8 that control basic characteristics (characteristic A). there were.
On the other hand, the headphone HP2 according to the second embodiment is arranged such that the drive axes of the speaker units are parallel to each other.

FIG. 14 is a perspective view illustrating an appearance of the headphone HP2 according to the second embodiment, and FIG. 15 is a perspective exploded view of the headphone HP2. In the following description, the up / down / left / right and front / back directions are defined by the directions shown in FIG.
The headphone HP2 is a so-called earplug type headphone that can be fitted with an earpiece to be inserted into the ear canal among the inner ear types.
In appearance, the headphone HP 2 is visually recognized with a main body 21, a cylindrical sound tube portion 22 and a cord bush 23 projecting from the main body portion 21, and a cord 24 drawn out from the tip of the cord bush 23. .
An earpiece 25 is detachably attached to the sound tube portion 22. The earpiece 25 is made of a flexible material (such as rubber or elastomer), and is inserted into the ear canal together with the sound tube portion 22 when the headphone HP2 is used, and is deformed flexibly so as to be in close contact with the inner surface of the ear canal. It has become.
Sound output from speaker units 27 to 29 described later is supplied into the ear canal via the sound emission port 22 a of the sound tube portion 22. That is, the sound tube portion 22 functions as a sound emitting portion.

The main body 21 is formed by combining a front cover 21a, an intermediate cover 21b, a ring cover 21c, and a back cover 21d, which are four covers divided in the front-rear direction.
The sound tube portion 22 is formed integrally with the front cover 21a. The cord bush 23 is formed integrally with the ring cover 21c.
The front cover 21a, the intermediate cover 21b, and the back cover 21d are made of, for example, a thermoplastic resin. Examples of the thermoplastic resin include ABS and PC.
The ring cover 21c in which the cord bush 23 is integrated is formed of, for example, an elastomer material.

A unit holder 26 is housed inside the front cover 21a. The unit holder 26 is formed in a disk shape with, for example, a metal material (brass, etc.), and the two speaker units 27 and 28 can be accommodated from the front side in the vertical direction with the upper side being the speaker unit 27, respectively. And a through hole 26c connected to one end 31a of the tube 31 to be described later. That is, the unit holder 6 supports the two speaker units 27 and 28 and the end 31 a side of the tube 31.
With the speaker units 27 and 28 accommodated in the accommodation holes 26a and 26b of the unit holder 26, the drive axes CL27 and CL28 of the diaphragms (not shown) are parallel to each other.

The two speaker units 27 and 28 are the same in this example, the outer diameter of the case is 5.8 mm, and the outer diameter of the diaphragm (not shown) (the outer diameter of the movable part including the edge) is 5.55 mm. This is a dynamic electroacoustic transducer.
One end of the cord 24 is electrically connected to the speaker units 27 and 28, and an audio signal from a playback device (not shown) connected to the other end of the cord 24 is converted into sound and output. In FIG. 15, drawing on both ends of the code 24 is omitted.

The intermediate cover 21b has a boundary wall 21b1 at an intermediate portion in the front-rear direction, and the tube 31 is accommodated in a cylindrical space V3 on the front side of the boundary wall 21b1.
In addition, on the rear side of the boundary wall 21b1, an accommodation portion 21b2 that is a recess in which the sound emitting surface 29a of the speaker unit 29 is accommodated without a gap is formed, and a recess 21b3. The recess 21b3 is a front portion of a back cavity V4 (described later) of the speaker unit 29.
The speaker unit 29 is accommodated in the accommodating portion 21b2. That is, the speaker unit 29 is disposed at a position farther from the speaker units 27 and 28 with respect to the sound tube portion 22.
A through-hole 21b4 is formed in a portion of the boundary wall 21b1 that becomes the bottom of the accommodating portion 21b2, and the other end 31b of the tube 31 is inserted therethrough.
The rear side of the intermediate cover 21b is closed with a back cover 21d via a ring cover 21c. Therefore, the back cavity V4 of the speaker unit 29 is formed by the back surface 29b of the speaker unit 29, the ring cover 21c, the back cover 21d, and the recess 21b3. The back cavity V4 is substantially sealed.

  FIG. 16 shows a state in which the intermediate cover 21b, the ring cover 21c, and the back cover 21d are not shown in FIG.

The tube 31 includes a straight portion 31c on the one end portion 31a side, a straight portion 31d on the other end portion 31b side, and a spiral portion that spirally connects the straight portion 31c and the straight portion 31d. 31e.
Moreover, it has the tube hole 31h which connects the edge part 31a and the edge part 31b, and opens at both ends 31a and 31b.
The curvature and the arrangement position are determined so that the outer shape of the spiral portion 31 e is located inside the outer shape of the unit holder 26. The spiral portion 31e is formed in a spiral shape with the drive axis CL29 on the inside. For example, the drive axis CL29 is the center of the spiral.
The spiral part 31e functions as a path extension part for obtaining the full length (path) of the tube hole 31h longer in a compact occupied space.
A speaker unit 27, a speaker unit 28, and a tube hole 31h are opened in the front surface portion 26d of the unit holder 26.
In other words, the layout is equivalent to providing three speaker units on the front surface portion 26d.
In the headphone HP2, the output direction of the voices AD27 and AD28 and the output direction of the voice AD29 added to the voices AD27 and AD28 are in the same direction (directions parallel to each other) toward the sound tube unit 22 that is a sound emitting unit. Preferably it is. As a result, unnecessary waveform interference or the like that may occur when the voice AD29 is added from a direction (crossing direction) different from the voices AD27 and AD28 does not occur, and is better for the user. Can provide a simple output sound.

The configuration of the headphone HP2 is such that the orientation of the speaker unit 29 corresponding to the speaker unit 9 with respect to the headphone HP1 of the first embodiment is such that the drive axis CL29 is parallel to the drive axes CL27 and CL28 of the other speaker units 27 and 28. The tube 31 is spirally formed around the drive axis CL29 to secure the entire length of the tube hole 31h while making the shape of the tube 31 compact.
That is, by providing the spiral portion 31e, the entire length of the tube hole 31h can be secured longer by effectively using the space in the main body portion 21. Further, the tube 31 is disposed such that the spiral portion 31 e draws a spiral around the drive axis CL 29 of the speaker unit 29. For example, it is a spiral centered on the drive axis CL29. Thereby, since the dimension of the direction in alignment with drive axis line CL29 in the arrangement | positioning space of the tube 31 becomes small, the main-body part 21 can be formed with a very compact design. The spiral includes a spiral.
The acoustic effect in this configuration is the same as that of the headphone HP1. In FIG. 11, reference numerals corresponding to the headphones HP2 are shown in parentheses.

The headphone HP2 can make the outer shape of the main body 21 compact, and the sound output from the speaker unit 29 in the user's listening sound without affecting the sound AD27, AD28 itself output from the speaker units 27, 28. AD29 can be added.
Therefore, by setting the sound AD29 having a desired characteristic (for example, a characteristic in which only the low frequency range is enhanced) by the speaker unit 29 and the tube 31, the output sound of the headphone HP2 can be easily set to the desired characteristic. be able to.
For this reason, the sound quality adjustment work in the design process is shortened, the product development cycle is shortened, the market demand can be met at an early stage, and the design cost can be reduced.

  It goes without saying that the embodiment of the present invention is not limited to the above-described configuration, and may be further modified without departing from the gist of the present invention.

The tube 11 in the first embodiment is supported at both ends by the unit holder 6 and the unit cover 10, and an intermediate portion 11M that is a portion of the tube 11 between the unit holder 6 and the unit cover 10 is related to the L cover 1a. It may be supported together.
In addition, the tube 31 in the second embodiment is supported at both ends by the through hole 26c of the unit holder 26 and the through hole 21b4 of the intermediate cover 21b, and for example, the spiral portion 31e included in the intermediate portion 11M is the same as the tube 11, It may be engaged and supported by the intermediate cover 21b.

  The vibration of the tubes 11 and 31 in this structure will be described with the tube 11 of the headphone HP1 of the first embodiment as a representative.

In the headphone HP1, the tube 11 is supported at both ends.
Moreover, the speaker unit 9 is equipped with a relatively large-diameter diaphragm as a so-called inner-ear type headphone, and can output a sound with a large volume.
When a sound is output from the speaker unit 9 at a large volume, the tube 11 is not a small amount of vibration because a large amplitude air vibration is transmitted through the tube hole 11h. The tube 11 can also be induced to vibrate by resonance according to the inner diameter and length of the tube hole 11h. And the amplitude of those vibrations becomes large especially in the middle part 11M of the tube 11, especially near the center. The vicinity of the center means the vicinity of a position that is half (center) of the extension length of the intermediate portion 11M.
Therefore, even if the intermediate portion 11M is engaged and supported by the L cover 1a, the tube 11 is loosely supported when the amplitude of the induced vibration is large, and the L cover 1a is hit by the tube 11 even slightly. There is a risk of becoming.

Here, when the tube 11 is formed of a high rigidity material such as metal and the L cover 1a is formed of a thermoplastic resin such as ABS or PC, the thermoplastic resin is a flexible low rigidity material such as rubber or elastomer. Since it is much more rigid, it is an engagement support between members having relatively high rigidity.
The hitting sound generated by hitting in this case becomes a hard sound with a medium and high sound quality and is easily heard as annoying noise.
In addition, a hard hitting sound in the middle / high range affects the reproduction sound of the headphone HP1 even at a small volume, and causes a deterioration in sound quality expressed as "turbidity" or "miscellaneous taste" as a user's feeling.
Further, since the engagement between the intermediate portion 11M and the L cover 1a does not return to the original state once loosened, the hitting phenomenon is more likely to occur as the usage time becomes longer.
Therefore, it is preferable to have a structure in which the generation of a tapping sound is more effectively suppressed and the suppression is maintained for a long period of time, and a modified example described below corresponds to the structure.

A modified headphone HP71 is obtained by replacing the cord bush 3 with the cord bush 73 in the headphone HP1 of the first embodiment. The headphone HP 71 will be described first with reference mainly to FIGS.
FIG. 17 is a longitudinal sectional view of the headphone HP 71, and the F cover 1c, the speaker units 7 and 8, the unit holder 6 and the cord 4 are omitted.
FIG. 18 is a front view of the headphone HP 71 with the F cover 1c, the speaker units 7 and 8, the unit holder 6 and the cord 4 removed.
FIG. 19 is a perspective view showing the cord bush 73.

The cord bush 73 is housed inside the main body 1 and has a vertically long annular base 73k whose longitudinal direction is the vertical direction in FIG. 18 and an insertion hole 73h extending from the base 73k downward in FIG. And a cord lead-out portion 73a that protrudes from the main body 1 in a cylindrical shape.
The cord bush 73 is made of a flexible low rigidity material. For example, rubber and elastomer are used, and a specific example is silicone rubber.

The base 73k includes a pair of opposing wall portions 73kL and 73kR, a pair of arc-shaped portions 73kb and 73kb that connect the upper and lower ends of the wall portions 73kL and 73kR in FIG. 18 in an arc shape, and a pair of wall portions 73kL and 73kR. And a connecting wall portion 73kc for connecting the two. A notch 73kc1 is formed at the center of the connecting wall 73kc.
The inner side of the annular base 73k is partitioned into two through spaces SP1 and SP2 by the connecting wall 73kc. The two penetrating spaces SP1 and SP2 are used to divide the path of the lead wire connected between the three speaker units 7 to 9 and the cord 4 and to improve the fit of the lead wire.

On one wall 73kR, a recess 73b that is recessed in a shape corresponding to the outer shape of the tube 11 is formed as a groove extending in the front-rear direction.
When the tube 11 is a circular tube, the recess 73b has a substantially arc-shaped cross section, and the range in contact with the outer peripheral surface of the tube 11 is formed in an arc shape with a central angle of, for example, about 90 ° or more. A specific example of the central angle is 180 °.

In the state in which the headphone HP71 is assembled, the tube 11 is configured such that the intermediate portion 11M and the recess 73b are engaged with each other and come into contact with each other. In this modification, the intermediate part 11M of the tube 11 in contact is a straight part 11d.
Here, since the cord bush 73 is formed of a flexible low-rigidity material, the concave portion 73b is formed so that the curvature of the cross-sectional shape thereof and the curvature of the outer peripheral surface of the tube 11 substantially coincide with each other. Can be satisfactorily adhered to the recess 73b.
Further, if the tube 11 is disposed so as to be urged against the concave portion 73b of the cord bush 73, the contact or close contact between both members is more surely accompanied by pressing. In this case, the degree of contact or close contact is hardly changed by an external impact or induced vibration.

As described above, in the headphone HP 71, the tube 11 is brought into contact with only a contact member formed of a flexible material having a rigidity lower than that of the material of the tube 11 in the intermediate portion 11M. This structure is shown in FIG. 20 as a schematic diagram.
As shown in FIG. 20, the contact member that comes into contact with the intermediate portion 1M of the tube 11 is, for example, the above-described cord bush 73. Otherwise, for example, the flexible member attached to the inner surface of the L cover 1a by pasting or bonding This is a cushion member 74 made of a low rigidity material.

FIG. 21A is a partial perspective view illustrating the recess 73 b of the cord bush 73. As shown in FIG. 19, the edge 73b1 on the opening side of the recess 73b may be filleted so as to be gentle, and is formed in a shape along the shape of the tube 11 as shown in FIG. It may be formed.
FIG. 21B is a view for explaining the cushion member 74 fixed to the wall portion 73kR of the cord bush 73 with an adhesive or the like, and is a partial perspective view corresponding to FIG. FIG. 22 is an overall perspective view of the cord bush 73 to which the cushion member 74 is fixed.
The cushion member 74 has a recess 74b corresponding to the recess 73b.
In the case of the structure in which the cushion member 74 is provided, the degree of flexibility between the cord bush 73 and the cushion member 74 can be different.
For example, when a material having a relatively high rigidity is designated as a material of the cord bush 73, only a portion in contact with the tube 11 is a contact member formed of a more flexible material. Optimization is possible.

The tube 11 is not limited to the one that comes into contact with the low-rigidity member at only one place, and may have a structure that comes into contact at a plurality of places.
In addition, it is preferable that the contact position includes at least the vicinity of the center of the intermediate portion 11M, which easily generates the maximum amplitude, because vibration can be suppressed satisfactorily.
Further, the tube 11 may be covered with a low-rigidity member while being substantially in contact with the entire circumference. In this case, a tube insertion hole through which the tube 11 is inserted in contact with the entire circumference is formed in the low-rigidity member in contact. The tube insertion hole has a cross-sectional shape that substantially corresponds to the cross-sectional shape of the tube 11.
The tube insertion hole may not be a hole closed by the peripheral wall, and a radial cut connecting the outside and the tube insertion hole may be provided in a part of the peripheral wall.

With this contact structure, even if a hit occurs between the tube 11 and the contact member (code bush 73, cushion member 74), it is difficult to generate a hit sound.
Even if the vibration of the tube 11 has a large amplitude, the volume of the generated tapping sound is small and a soft sound in the low frequency range in the audible band, so that it is difficult to hear as annoying noise.
In addition, the soft sound in the low frequency range mixed in the reproduction sound has little influence on the reproduction sound for the sake of hearing, so that the sound quality of the reproduction sound is prevented from being deteriorated.
Further, by disposing the tube 11 so that the intermediate portion 11M biases the recess 73b, the engagement becomes difficult to loosen, and the occurrence of the hitting phenomenon is less likely to occur even in long-term use.
Further, if the contact member that contacts the intermediate portion 11M of the tube 11 is not a separate member but a cord bush 73, the number of parts and the number of assembly steps are reduced.

  Of course, the above-described structure may be applied to the headphone HP2 of the second embodiment. Specifically, for example, the intermediate portion 11M (for example, the spiral portion 31e) of the tube 31 is configured to be brought into contact with or pressed against a cushion member made of a flexible low-rigid material attached to the intermediate cover 21b. .

Other modifications will be described below.
In the headphone HP1 of the first embodiment, the speaker units that control the basic characteristics of the reproduced sound, other than the speaker unit 9 for adding characteristics (for enhancing bass), are not limited to the two speaker units 7 and 8, but one Or it is good also as three or more. In addition, when there are a plurality of speaker units that control basic characteristics, the speaker units may have different specifications. The same applies to the headphones HP2 of the second embodiment.

  The headphones HP1, HP2, and HP71 of the first and second embodiments and the modified examples are not limited to the earplug type. The present invention can also be favorably applied as an inner ear type headphone that is used by mounting the main body portions 1 and 21 in the auricle without using the earpieces 5 and 25. In this case, the sound emission part is not a sound tube part but a sound emission hole group formed of a plurality of small sound emission holes normally formed in the main body part.

The aspects of the speaker unit 9 and the tube 11 and the speaker unit 29 and the tube 31 are not limited to the above-described first and second embodiments.
For example, the same effect can be obtained as various modified embodiments schematically shown in FIG.

In FIG. 23A, speaker units 51 and 52 that control basic characteristics are arranged so that the drive axes CL51 and CL52 are parallel to each other, and the speaker unit 53 for adding characteristics is connected to the drive axes CL53 that are CL51 and CL52. It is the example arrange | positioned so that it may cross | intersect in parallel.
Similarly to the second embodiment, the tube 54 is formed in a spiral shape around the drive axis CL53, and is accommodated between the speaker units 51 and 52 and the speaker unit 53, and is opened to the front surface 55a together with the speaker units 51 and 52. Yes. Thereby, the whole shape can be made compact.

  In FIG. 23B, speaker units 51 and 52 that control basic characteristics are arranged so that the drive axes CL51 and CL52 are parallel to each other, and a speaker unit 53 for adding characteristics is disposed on the rear side of the speaker units 51 and 52. Is arranged in a posture in which the drive axis CL53 is parallel to CL51 and CL52, and the tube 54 is spirally formed around the drive axis CL53 and is exposed to the outside along the outer surface of the main body 55. (Headphone HP3).

  In FIG. 23 (c), the basic speaker units 51 and 52 are arranged so that the drive axes CL51 and CL52 are parallel to each other, and the speaker unit 53 for adding characteristics is placed behind them so that the sound emitting surface is behind. The orientation drive axis CL53 is arranged in a posture that is parallel to CL51 and CL52, and the tube 54 is buried inside at an intermediate position of the main body 55 from the rear surface side of the main body 55 through the side surface. 52 is an example (headphone HP4) opened to the front surface portion 55a together with 52.

The headphones HP3 and HP4 can visually recognize the characteristic of the headphones HP3 and HP4 that the tube 54 is visible from the outside and has the tube 54.
By providing the tube 54 so as to be partially embedded in the main body portion 55, for example, a projection corresponding to the radius is sufficient. Since the outer diameter of the tube 54 is sufficiently small in view of the size of the main body 55, it is still possible to make it compact.
23 (b) and 23 (c), the tube 54 is installed so as to be placed over the main body 55, but the tube 54 may of course be installed inside the main body 55.

When the material of the tubes 11 and 54 is a low-rigidity material, unnecessary vibration hardly occurs, and a hitting sound or a so-called tube noise phenomenon hardly occurs. Therefore, the acoustic characteristics are better than those of a high-rigidity material. On the other hand, the ease of assembly work is better with the tubes 11 and 54 formed of a highly rigid material.
Therefore, it is preferable that the materials of the tubes 11 and 54 are appropriately selected according to their priorities by comparing workability and acoustic characteristics.

  As the speaker unit 9 for adding characteristics, it is preferable to use a speaker unit 9 having a larger outer diameter of the movable part including the diaphragm with respect to the speaker units 7 and 8 in order to enhance the bass. The same applies to the second embodiment and the modifications.

The present invention improves the reproduction sound in the low frequency range by enhancing it.
The low frequency range to be enhanced is, for example, a region of 100 Hz or less, and the characteristic A is output from the speaker unit 7 and the speaker unit 8 because the sound pressure level in the region other than the low frequency range is sufficiently smaller than the characteristic B. The phase of the sound and the phase of the sound from the speaker unit 9 output from the tube hole 11h do not have to be strictly controlled. For example, a deviation other than the phase difference (180 °) that completely cancels each other is allowed.

1, 21, 55 Body 1a L cover 1a1 Groove 1b R cover, 1c F cover, 1d ornament 2, 22 Sound tube part (sound emitting part)
2a, 22a Sound outlet 3, 23, 73 Cord bush 4, 24 Cord 5, 25 Earpiece 6, 26 Unit holder 6a, 6b, 26a, 26b Housing hole, 6c, 26c Through hole 6d, 26d, 55a 9, 27 to 29, 51 to 53 Speaker unit 9a, 29a Sound emitting surface, 9b, 29b rear surface, 9s Diaphragm 10 Unit cover 10a Step portion 10b Small diameter portion 10b1 Surface portion 10c Opening portion, 10d Large diameter portion, 10e Upper surface portion 11 , 31,54 Tube (path extension)
11a, 11e, 31a, 31b End portion 11b, 11d, 31c, 31d Straight portion, 11M, 31M Intermediate portion 11c Arc portion, 11h, 31h Tube hole 21a Front cover 21b Intermediate cover 21b1 Boundary wall, 21b2 Housing portion, 21b3 Recessed portion 21b4 Through-hole 21c Ring cover, 21d Back cover, 31e Spiral part 73a Cord lead-out part 73b Recess 73b1 Edge 73h Through-hole 73k Base 73kb Arc-shaped part 73kc Connection wall part, 73kc1 Notch 73kL, 73kR Wall part 74 Cushion member 74b Recessed part AD7 ~ AD9 Audio BD Sealing material CL7 ~ CL9, CL27 ~ CL29 Drive axis Da inner diameter, Db outer diameter, Dc (movable part) outer diameter HP1-HP4, HP71 headphone L tube hole length, p (tube hole) inner diameter PT site, SF provisional Plane V1 front cavity (space), V2, V4 back cavity (space)
V3 space, VF front space WL distance (left side protruding amount), WR distance (right side protruding amount)

Claims (5)

A headphone having a discharge sound port you released to the outside sound,
A first speaker unit to emit sound toward Ke said sound emitting port,
A dynamic second speaker unit;
A unit cover that forms a front cavity with the sound emitting surface of the second speaker unit;
One end side has a tube hole communicating with the front cavity, and the sound emitted from the second speaker unit to the front cavity enters from the one end side of the tube hole and is directed from the other end side to the sound emission port. A tube arranged to discharge,
With
The unit cover is formed in a stepped pan shape having a large diameter part accommodating the sound emitting surface side of the second speaker unit, and a small diameter part smaller in diameter than the large diameter part,
The headphone according to claim 1, wherein the tube has an arc portion disposed in an arc shape outside the small diameter portion of the unit cover . The outer diameter of the tube is set to be smaller than half of an outer diameter difference between the large diameter portion and the small diameter portion in the unit cover, and the arc portion protrudes radially outward from the outer shape of the large diameter portion. The headphone according to claim 1, wherein the headphone is arranged so as not to exist . The first speaker unit and the tube are arranged so that the sound emitted from the first speaker unit and the sound emitted from the other end of the tube hole in the tube are emitted in the same direction. The headphone according to claim 1, further comprising a holder for supporting the headphone. The second speaker unit has a cover that forms a back cavity between the opposite side of the sound emitting surface and the back surface of the second speaker unit, and the first speaker unit is a dynamic type so that the drive axes are parallel to each other. Prepared,
The said front cavity and the said back cavity are formed in the one side and the other side on both sides of the virtual plane containing each drive-axis line of two said 1st speaker units. Headphones given in any 1 paragraph. The headphone according to any one of claims 1 to 4, wherein the tube acts as a low-pass filter for sound emitted from the second speaker unit.

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