阅读说明：本技术 耳塞及使用耳塞的耳机 (Earplug and earphone using same ) 是由 三瓶秀昭 于 2019-01-22 设计创作，主要内容包括：在现有的耳塞中,由于是从耳塞的声道孔直接听取驱动器生成的声音的结构,因此,存在难以改善头部内定位的常态化的问题。在本发明的耳塞(10)中,塞体部(15)安装在中央筒部(13)的声道空间(13A),在塞体部(15)形成有沿其长边方向贯通的声道长孔(15B)和沿其短边方向贯通的声道短孔(15G)。通过这种结构,从支柱部(12)传递来的声音的一部分经由开口(15A)直接传递到鼓膜,但是从支柱部(12)传递来的大部分声音经由内部空间(20)直接传递到鼓膜。并且,使用者将上述迂回的声音识别为伴随着来自自身前方的时间差的间接声音,通过得到声音的头部外定位和声音的扩展感,能够得到前方的方向感和临场感。(In the conventional earplug, since the sound generated by the driver is directly heard through the sound channel hole of the earplug, there is a problem that it is difficult to improve normalization of positioning in the head. In the earplug (10), a plug part (15) is attached to a sound channel space (13A) of a center tube part (13), and a long sound channel hole (15B) penetrating in the longitudinal direction and a short sound channel hole (15G) penetrating in the short side direction are formed in the plug part (15). With this structure, a part of the sound transmitted from the pillar portion (12) is directly transmitted to the eardrum via the opening (15A), but most of the sound transmitted from the pillar portion (12) is directly transmitted to the eardrum via the internal space (20). The user recognizes the detouring sound as an indirect sound with a time difference from the front of the user, and obtains the sense of direction and presence in the front by obtaining the out-of-head localization of the sound and the sense of expansion of the sound.)

1. An earplug detachably attached to an attachment/detachment groove of a stem portion of an earphone, comprising:

a center tube portion having one end side attached to the pillar portion and having an acoustic channel space therein;

a cup portion that is provided so as to surround the central cylindrical portion, and that has one end side integrally formed with one end side of the central cylindrical portion and the other end side serving as a free end;

a plug portion having one end inserted into the acoustic channel space from the other end side of the central cylindrical portion,

an acoustic channel hole for communicating the acoustic channel space with an internal space inside the cup portion is formed in the central cylindrical portion,

at least one cup hole is formed in the cup portion, and the cup hole communicates the internal space with an external space outside the cup portion in the vicinity of the support portion.

2. The earplug of claim 1,

the stopper portion has: a sound channel long hole penetrating through the inside of the sound channel long hole along the long side direction; a sound channel short hole communicating with the sound channel long hole and formed in a short side direction thereof,

the sound channel hole, the sound channel long hole, and the sound channel short hole are communicated with each other in a state where the plug portion is inserted into the sound channel space.

3. The earplug of claim 2,

the stopper portion is exposed from the other end side of the central cylinder portion, and the exposed portion of the stopper portion has a spherical shape,

the width of the opening formed in the spherical body by the acoustic channel long hole is narrower than the width of the acoustic channel long hole located in the central tube portion.

4. The earplug according to any of claims 1-3,

a cup hole adjusting plate disposed in contact with an outer surface of the cup,

the cup hole adjustment plate includes:

a locking part locked with the loading and unloading groove;

a plate portion formed integrally with the locking portion and having at least the outer surface covering an area up to a placement area of the plurality of cup holes,

the plate portion is formed with a cutout portion that exposes the plurality of cup holes, and the cutout portion has a width that exposes all of the plurality of cup holes.

5. The earplug of claim 4,

either the cup or the cup hole adjustment plate is rotatable with respect to the support portion, whereby the number of the plurality of cup holes exposed from the cutout portion can be adjusted.

6. The earplug of claim 4 or 5,

a locking protrusion part is formed on the other end side of the central cylinder part, and a part of the locking protrusion part protrudes to the sound channel space,

an engaging portion that engages with the locking protrusion is formed on the outer side surface of the plug portion,

in a state where the plug portion is inserted into the acoustic channel space, the engaging portion is located closer to the pillar portion side than the locking protrusion.

7. An earphone equipped with the earplug of any one of claims 1 to 6,

comprising: a vibrating plate vibrating in response to an electric signal, a case in which the vibrating plate is disposed, a post portion formed at one end side of the case and to which the earplug is attached,

at least one hole is provided in a side surface of the case between an end portion on the other end side of the case and the vibration plate,

the hole of the housing and the cup hole of the ear plug face toward a tragus portion side of the ear of the user in a state where the earphone is mounted on the ear of the user.

8. An earphone equipped with the earplug of any one of claims 1 to 6,

comprising: a vibrating plate vibrating in response to an electric signal, a case in which the vibrating plate is disposed, a post portion formed at one end side of the case and to which the earplug is attached,

a plurality of holes are provided in a side surface of the case between an end portion on the other end side of the case and the vibration plate, and a slide ring is provided to adjust the number of the holes exposed from the side surface of the case,

the hole of the housing and the cup hole of the ear plug face toward a tragus portion side of the ear of the user in a state where the earphone is mounted on the ear of the user.

Technical Field

The present invention relates to an earplug in which a sound passage hole and a cup portion are provided, and a sound generated in the earplug reaches an eardrum with a time difference from the front, thereby achieving front localization and also allowing an external sound to be heard, and an earphone using the earplug.

Background

After the popularization of cellular phones and smart phones, the chances of listening to music and interesting sound sources are increasing, and many earphones and headphones have been developed according to the purpose. In addition, the opportunity of listening indoors and outdoors is increased, and the use of earphones and headphones is often seen when the earphone is used in public transportation such as a train and a bus.

In particular, in the earphone, in order to achieve high sound quality, it becomes difficult to hear, for example, a broadcast in a vehicle of a public transportation or a broadcast in a field, in order to cut off surrounding noise, and this is an obstacle to prediction of danger. In order to eliminate the above-mentioned hindrance to risk prediction, an earphone capable of listening to external sound with high sound quality is required.

On the other hand, as seen in vr (visual reality), the headphone is normalized for positioning use within the head in the present situation where images are 3d (three dimensions). In addition, by improving the normalization of the head positioning, the VR device can be listened to with less discomfort, and the matching of the 3D image and the sound can be realized.

As a conventional earphone, a structure shown in fig. 8 is known. Fig. 8 is a sectional view illustrating the structure of a conventional earphone 100.

As shown in fig. 8, the headphone 100 mainly includes a front case 101, a rear case 102, a cable case 103, and a drive unit 104 disposed in the cases 101 to 103. A tubular first sound channel 105 is provided as a sound outlet in the front case 101, and an earplug 106 made of silicone rubber or the like is attached to a front end of the first sound channel 105. Further, a sound channel attenuating material 107 is provided near the center of the first sound channel 105, and attenuates the frequency range (near 6 kHz) of the peak value caused by the external auditory meatus occlusion effect.

Further, a second channel 108 is provided in the front case 101, and a part of the sound on the back side of the drive unit 104 joins the sound (direct sound) passing through the first channel 105 in a state of having a predetermined delay time as a spatially reflected sound (reflected sound or reverberation sound). In order to adjust the phase and the sound pressure level of the reflected sound, a reflected component attenuating material 109 is provided in the second channel 108.

With the above configuration, when the sound generated by the drive unit 104 is output as a direct sound from the first sound channel 105 to the external acoustic meatus, the sound generated by the drive unit 104 is transmitted through the second sound channel 108 of a path different from the first sound channel 105, and is merged with the direct sound of the first sound channel 105 in a delayed state, thereby becoming a state in which a spatially reflected sound is simulatively added to the direct sound from the drive unit 104. As a result, the driving unit 104 does not need a signal processing circuit, and the headphone 100 alone can realize the off-head audio-video localization (forward localization) (see, for example, patent document 1)

In addition, a structure shown in fig. 9 is known as a conventional ear canal earphone. Fig. 9 a is a sectional view showing the structure of a conventional in-canal earphone 120 (hereinafter referred to as "earphone 120"). Fig. 9(B) is a top view of the ear bud 124 mounted on the conventional earphone 120.

As shown in fig. 9(a), the headphone 120 mainly includes a driver 121, a housing 122 for housing the driver 121, a tube portion 123 protruding from the housing 122, and an ear plug 124 attached to the front end of the tube portion 123. When the earphone 120 is attached to the ear, the ear plug 124 is inserted into the external auditory canal 125, and the outer peripheral portion of the ear plug 124 is in close contact with the inner wall 126 of the external auditory canal 125, thereby preventing the earphone 120 from falling off the ear.

As shown in fig. 9(B), a channel hole 127 is penetratingly formed on the center of the ear plug 124 and transmits the sound generated by the driver 121 to the eardrum. Four through holes 128 are formed around the sound channel hole 127 of the earplug 124. The through hole 128 allows air pressure in the external auditory canal 125 blocked by the ear plug 124 to leak to the outside when the earphone 120 is attached to the ear, thereby reducing a sense of pressure on the eardrum and guiding external sound into the external auditory canal 125, thereby allowing the user of the earphone 120 to hear the external sound (see, for example, patent document 2).

Prior patent literature

Patent document

Patent document 1: japanese patent No. 5666797

Patent document 2: japanese laid-open patent publication No. 2012-244350

As described above, in the headphone 100 shown in fig. 8, the first channel 105 and the second channel 108 are formed in the front housing 101, and a part of the sound on the back side of the drive unit 104 is merged with the sound (direct sound) passing through the first channel 105 in a state of having a predetermined delay time as a spatial reflected sound (reflected sound or reverberation sound) via the second channel 108, thereby realizing the localization of the sound image outside the head of the headphone 100 alone.

However, in order to realize the above-described off-head sound image localization, the first channel 105 and the second channel 108 are formed in the front case 101, and an opening portion or the like is formed in another open end, so that the structure of the headphone 100 becomes complicated, and there is a problem that it is difficult to reduce the manufacturing cost.

When the headphone 100 is attached to the ear, a sound channel attenuating material 107 is provided near the center of the first sound channel 105 so as to attenuate a frequency region (near 6 kHz) of a peak caused by the external auditory canal occlusion effect in order to substantially occlude the external auditory canal by the ear plug 106. In order to adjust the phase and the sound pressure level of the reflected sound, a reflection component attenuation material 109 is provided in the second channel 108. Therefore, not only the structure of the earphone 100 becomes complicated, but also the number of parts increases, and there is a problem that it is difficult to reduce the manufacturing cost.

Further, when the earphone 100 is attached to the ear, since the ear plug 106 actually blocks the external auditory meatus, it is difficult to guide external sound into the external auditory meatus and let the user of the earphone 100 hear it, which may hinder the user from predicting the danger to the surrounding environment.

On the other hand, in the earphone 120 shown in fig. 9(a) and 9(B), the structure of the earphone 120 is simple, and the ear plug 124 is provided with 4 through holes 128, so that external sound is guided into the external auditory canal 125, and it is possible to prevent the risk prediction of the surrounding environment from being obstructed by the user.

However, since the user directly listens to the sound generated by the driver 121 through the sound channel hole 127, there is a problem that normalization of the head positioning cannot be improved.

The earplug 124 has an umbrella-open shape, and when the earplug 124 is attached to the ear, the tip center thereof is inserted into the inner side (tympanic membrane side) of the external auditory canal 125. Therefore, although the degree of insertion varies depending on the user, the earplug 124 generally tends to be in close contact with the inner wall 126 of the external auditory meatus 125 on the front end side. Further, the tip end side of the earplug 124 is not structurally a free end, and is hardly deformed along the concave-convex structure of the inner wall 126 of the external auditory meatus 125 at the time of insertion, so that a gap is easily generated between the earplug 124 and the inner wall 126 of the external auditory meatus 125, and there is a problem that it is difficult to achieve high sound quality due to sound leakage or the like.

Disclosure of Invention

The present invention has been made in view of the above circumstances, and provides an ear plug and an earphone using the same, in which a sound duct hole and a cup hole are provided in the ear plug, and a sound generated by the earphone reaches an eardrum with a time difference from the front, thereby realizing front localization and allowing an external sound to be heard.

The earplug according to the present invention is a removable channel to be removably attached to a post portion of an earphone, the earplug including: a center tube portion having one end side attached to the pillar portion and having an acoustic channel space therein; a cup portion that is provided so as to surround the central cylindrical portion, and that has one end side integrally formed with one end side of the central cylindrical portion and the other end side serving as a free end; and a plug portion having one end inserted into the acoustic channel space from the other end side of the central cylindrical portion, wherein the central cylindrical portion is formed with an acoustic channel hole that communicates the acoustic channel space with an internal space inside the cup portion, and the cup portion is formed with at least one or more cup portion holes that communicate the internal space with an external space outside the cup portion in the vicinity of the support portion.

In addition, in the earplug according to the present invention, the plug body portion includes: a sound channel long hole penetrating through the inside of the sound channel long hole along the long side direction; and a sound channel short hole formed in a short side direction thereof in communication with the sound channel long hole, the sound channel long hole, and the sound channel short hole being in communication with each other in a state where the plug portion is inserted into the sound channel space.

In the earplug according to the present invention, the plug portion is exposed from the other end side of the central tube portion, and the exposed portion of the plug portion is shaped like a sphere, and the width of the opening formed in the sphere by the channel long hole is smaller than the width of the channel long hole located in the central tube portion.

In addition, the earplug according to the present invention is characterized by comprising a cup hole adjustment plate disposed in contact with an outer surface of the cup, the cup hole adjustment plate comprising: a locking part locked with the loading and unloading groove; and a plate portion that is formed integrally with the locking portion and has the outer surface covering at least up to an arrangement region of the plurality of cup holes, wherein a cutout portion that exposes the plurality of cup holes is formed in the plate portion, and the cutout portion has a width that exposes all of the plurality of cup holes.

In the earplug according to the present invention, the number of the plurality of cup holes exposed from the cutout portion can be adjusted by rotating either the cup portion or the cup hole adjustment plate with respect to the support portion.

In the earplug according to the present invention, a locking protrusion is formed on the other end side of the central tube, a part of the locking protrusion protrudes into the acoustic channel space, an engaging portion that engages with the locking protrusion is formed on the outer side surface of the plug portion, and the engaging portion is located closer to the strut portion side than the locking protrusion in a state where the plug portion is inserted into the acoustic channel space.

In addition, the earphone of the present invention is equipped with the above-described earplug, and is characterized by including: the earphone includes a vibrating plate that vibrates in response to an electric signal, a case in which the vibrating plate is disposed, and a post portion that is formed on one end side of the case and to which the ear plug is attached, at least one hole being provided in a side surface of the case between an end portion on the other end side of the case and the vibrating plate, and the hole of the case and the hole of the cup portion of the ear plug face an tragus portion side of an ear of a user in a state in which the earphone is attached to the ear of the user.

In addition, the earphone of the present invention is an earphone equipped with the above-described earplug, including: the earphone includes a vibrating plate that vibrates in response to an electric signal, a case in which the vibrating plate is disposed, and a post portion that is formed on one end side of the case and to which the ear plug is attached, wherein a plurality of holes are provided in a side surface of the case between an end portion on the other end side of the case and the vibrating plate, and a slide ring that adjusts the number of the holes exposed from the side surface of the case is provided, and the holes of the case and the hole of the cup portion of the ear plug face an tragus portion side of the ear of a user in a state in which the earphone is attached to the ear of the user.

ADVANTAGEOUS EFFECTS OF INVENTION

In the earplug according to the present invention, the sound transmitted from the pillar portion is transmitted to the internal space between the central tube portion and the cup portion via the plug portion, and a part of the transmitted sound is released to the external space of the earplug via the cup hole of the cup portion and then returns to the internal space again. With this configuration, the user can recognize the direct sound and the indirect sound by combining them via the cup hole, and by obtaining the outside-of-the-head localization of the sound and the feeling of extension of the sound, the sense of direction and the feeling of presence in front can be obtained.

In the earplug according to the present invention, the earplug body attached to the central tube portion includes the long channel hole penetrating in the longitudinal direction in the interior thereof and the short channel hole communicating with the long channel hole and penetrating in the short side direction thereof. With this configuration, a part of the sound transmitted from the pillar portion is directly transmitted to the eardrum through the opening of the vocal tract long hole of the plug portion, and the user can obtain the sense of direction and presence in front.

In the earplug according to the present invention, the width of the opening formed by the acoustic channel long hole of the spherical body of the plug portion is narrower than the width of the acoustic channel long hole. With this configuration, most of the sound transmitted from the pillar portion is transmitted to the eardrum through the internal space, and the user can obtain the sense of direction and presence in front.

In the earplug according to the present invention, the plurality of cup holes are formed in the plate portion of the cup hole adjustment plate, and the plurality of cup holes are exposed to the outside of the cup. With this configuration, the user can adjust the number of cup holes exposed from the cutout portion, and can hear the sound of the surrounding environment of the user, and therefore, the risk prediction can be performed on the surrounding environment.

In the earplug according to the present invention, the user can easily adjust the number of the cup holes exposed from the cut portion by rotating one of the cup portion and the cup hole adjustment plate with respect to the support portion.

In the earplug according to the present invention, the locking protrusion protruding toward the vocal tract space side is formed on the other end side of the central tube portion, and the engaging portion engaging with the locking protrusion is formed on the outer side surface of the plug portion. With this configuration, before the plug portion is pulled out from the central cylindrical portion, the locking protrusion of the central cylindrical portion is fitted to the engagement portion of the plug portion. As a result, the stopper portion is prevented from falling off the central cylindrical portion, and the stopper portion is prevented from remaining in the external auditory meatus of the user.

In the earphone according to the present invention, at least one hole is provided in a side surface of the case between the end portion of the case on the other end side of the case of the earphone body and the diaphragm, and the hole of the case and the cup hole of the ear plug face the tragus portion side of the ear of the user in a state where the earphone is attached to the ear of the user. With this structure, a part of the sound emitted from the housing returns to the internal space of the earplug via the cup hole, and the user can obtain the above-described sense of direction and presence in the front.

In the earphone according to the present invention, a plurality of holes penetrating the inside of the case are provided in the case body on the side surface on the tragus side, and a slide ring for adjusting the number of holes exposed from the side surface of the case is provided. With this structure, the user can appropriately adjust the number of cup holes exposed from the tragus-side of the earplug and the number of holes exposed from the side of the housing. Thus, the excess or deficiency of the bass region caused by the strength of the front localization and the width of the introduction of the external sound can be adjusted.

Drawings

Fig. 1 is a perspective view (a) and a perspective view (B) illustrating an earplug according to an embodiment of the present invention.

Fig. 2 is a perspective view, (B) a sectional view, (C) a plan view, and (D) a bottom view of a plug portion of an earplug according to an embodiment of the present invention.

Fig. 3 is a sectional view (a) and a sectional view (B) of an earplug according to an embodiment of the present invention.

Fig. 4 is a sectional view illustrating a modification of the earplug according to the embodiment of the present invention.

Fig. 5 is a cross-sectional view illustrating an earplug according to an embodiment of the invention.

Fig. 6 is a sectional view (a) and a perspective view (B) illustrating an earphone according to another embodiment of the present invention.

Fig. 7 is a perspective view illustrating a modified example of the headphone according to another embodiment of the present invention.

Fig. 8 is a sectional view illustrating the structure of a conventional earphone.

Fig. 9 is a sectional view (a) and a plan view (B) illustrating the structure of a conventional in-canal earphone.

Detailed Description

Hereinafter, an earplug according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the description of the present embodiment, the same reference numerals are used for the same members in principle, and redundant description is omitted.

Fig. 1(a) and 1(B) are perspective views illustrating an earplug 10 of the present embodiment. Fig. 2(a) is a perspective view illustrating the plug portion 15 of the earplug 10 according to the present embodiment. Fig. 2(B) is a diagram illustrating the plug portion 15 of the earplug 10 according to the present embodiment, and is a cross-sectional view taken along line B-B in fig. 2 (a). Fig. 2(C) is a plan view of the plug portion 15 of the earplug 10 according to the present embodiment as viewed from the distal end side. Fig. 2(D) is a bottom view of the plug portion 15 of the earplug 10 according to the present embodiment as viewed from the rear end side. Fig. 3(a) and 3(B) are views for explaining the earplug 10 of the present embodiment, and are cross-sectional views taken along line a-a of fig. 1 (a). In the description of fig. 1 to 3, the front-back direction represents the long side direction of the earplug 10, and the left-right direction and the up-down direction represent the short side direction of the earplug 10.

As shown in fig. 1(a), the earplug 10 is detachably attached to the stem portion 12 of the earphone 11, and is configured for the purpose of improving the head positioning peculiar to the earphone 11 and changing to the front positioning. The earplug 10 is composed of a plurality of members, and mainly includes: a central cylindrical portion 13 (see fig. 3a), a cup portion 14 formed integrally with the central cylindrical portion 13, a plug portion 15 detachably attached to the central cylindrical portion 13, and a cup hole adjustment plate 16 disposed in a state of being in contact with an outer peripheral surface of the cup portion 14.

The central tube portion 13 and the cup portion 14 of the earplug 10 are integrally formed of, for example, a rubber material having a hardness of a45 degrees to a50 degrees. As the rubber material, for example, silicon rubber is used, and when the earplug 10 is inserted into the external auditory meatus 32 (see fig. 5), it is appropriately deformed in accordance with the shape of the inner wall 34 (see fig. 5) of the external auditory meatus 32, thereby improving the close contact of the earplug 10 with the inner wall 34 of the external auditory meatus 32, and preventing the leakage of sound more than necessary from the ear. As will be described in detail later, the front end side of the cup portion 14 of the earplug 10 inserted into the back side of the external auditory canal 32 becomes a free end, so that the shape of the inner wall 34 is easily deformed due to the unevenness, and the adhesiveness is improved.

The stopper portion 15 is detachably attached to a central tube portion 13 formed inside the cup portion 14. The stopper portion 15 is formed by processing a material having a specific gravity different from that of silicone rubber, such as surgical stainless steel, surgical titanium, silver, acrylic resin, natural material, semi-precious stone, or the like. Further, by attaching the plug portion 15 made of a material having a different specific gravity to the central tube portion 13, the resonance frequency of the earplug 10 due to sound is corrected, and the amount of noise generated by resonance of the earplug 10 is greatly reduced.

An acoustic channel long hole 15B (see fig. 2B) penetrating the plug portion 15 in the longitudinal direction (front-rear direction of the drawing) is formed in the plug portion 15, and an opening 15A opened by the acoustic channel long hole 15B is formed in the center of a spherical portion 15D (see fig. 2 a) on the front end side of the plug portion 15. Part of the sound transmitted from the pillar portion 12 is transmitted directly from the opening 15A to the external auditory meatus 32 through the vocal tract long hole 15B.

As shown in fig. 1(B), 5 cup holes 17 are formed uniformly at a constant interval, for example, in the vicinity of the support portion 12 on one end side of the cup portion 14. The cup hole 17 is a hole communicating the space inside and outside the cup 14, and is formed, for example, in a size of 0.1mm to 2.0mm in diameter. The 5 cup holes 17 are disposed in a region of approximately 1/3 degrees with respect to the periphery of the cup 14. The number of the cup holes 17 may be changed as appropriate.

The cup hole adjusting plate 16 has: an annular locking portion 16A attached to an attachment/detachment groove 12B (see fig. 3a) provided on the column portion 12 side; a cup-shaped plate portion 16B formed integrally with the locking portion 16A and abutting against the outer surface of the cup portion 14. The cup hole adjustment plate 16 is formed of, for example, a silicone rubber material, which is the same material as the cup portion 14 of the earplug 10 described above. The hardness of the silicone rubber material forming the cup hole adjustment plate 16 may be changed as appropriate.

The plate portion 16B is disposed so as to cover the cup hole 17 formed in the cup 14, and has a length of about 4.0mm to 4.5mm from the locking portion 16A, for example. As shown in the drawing, the plate portion 16B is formed with a notch portion 16C having a width in which the 5 cup holes 17 are simultaneously exposed. As described above, the cut-out portion 16C has a width of approximately about 1/3 around the cup 14 with respect to the arrangement region of the cup hole 17.

The engaging portion 13D (see fig. 3a) of the central cylindrical portion 13 is also attached to the attaching/detaching groove 12B of the support portion 12, and the plate portion 16B of the cup hole adjustment plate 16 is in a state of abutting against the outer peripheral surface of the cup portion 14. When the earplug 10 is used, the cup portion 14 and the cup hole adjustment plate 16 are brought into close contact with each other and fixed in accordance with the contact state.

On the other hand, before the earplug 10 is used, the user can remove the above-described abutment state between the cup portion 14 and the cup hole adjustment plate 16 by, for example, grasping the cup portion 14 with fingers, and rotate the cup portion 14 relative to the support portion 12. With this configuration, the user can adjust the number of cup holes 17 exposed from the cutout portion 16C of the cup hole adjustment plate 16. As will be described in detail later, as the number of the cup holes 17 exposed from the cut-out portion 16C increases, the amount of the sound generated by the earphone 11 as indirect sound reaching the eardrum with a time difference increases, and the sense of front positioning is easily achieved. In addition, the external sound easily reaches the eardrum through the cup hole 17, and the user can easily predict the risk of the surrounding environment even in the state of using the earplug 10. Alternatively, the cup hole adjustment plate 16 may be rotated relative to the support portion 12 after the cup portion 14 is gripped and the abutment state is removed.

As shown in fig. 2(a), the stopper portion 15 has a substantially cylindrical portion 15C extending in the front-rear direction thereof and a spherical portion 15D integrally formed on the distal end side of the cylindrical portion 15C. Then, an engagement portion 15F having an annular concave shape is formed on the rear end side of the outer surface 15E of the cylindrical portion 15C. The outer surface 15E of the engaging portion 15F is formed with 4 openings 15H opened by the vocal tract short holes 15G.

As shown in fig. 2B, a long vocal tract hole 15B penetrating the plug portion 15 in the longitudinal direction (front-rear direction of the drawing) and a short vocal tract hole 15G penetrating the plug portion in the short direction (left-right direction of the drawing, front-rear direction of the drawing) are formed in the plug portion 15. Most of the long acoustic channel hole 15B is formed as a cylindrical hole of, for example, Φ 2.0 to 2.5mm, the hole width is gradually narrowed at the tip end portion of the long acoustic channel hole 15B, and the opening portion 15A is formed with, for example, an opening area of Φ 0.3 to 1.0 mm.

Further, 4 acoustic short holes 15G are formed so as to be opened in the formation region of the engaging portion 15F. The 4 channel short holes 15G are formed at intervals of 90 degrees in the circumferential direction, and communicate with the channel long hole 15B at the center of the plug portion 15. The acoustic duct short hole 15G is formed as a cylindrical hole of Φ 1.0 to 1.5mm, for example, and 4 openings 15H are formed at 90-degree intervals on the outer surface 15E of the engaging portion 15F.

As shown in fig. 2(C), an opening 15A opened at the center by an acoustic channel long hole 15B is formed at the tip of the spherical portion 15D. As shown in fig. 2(D), an opening 15I opened by the vocal tract long hole 15B is formed at the rear end of the cylindrical portion 15C.

As shown in fig. 3(a), the central tube portion 13 is disposed in the center of the earplug 10, and is formed in a substantially cylindrical shape centered on a center axis CL indicated by a chain line. A sound channel space 13A penetrating in the longitudinal direction (front-rear direction of the drawing) is formed inside the center tube 13, and openings 13B and 13C are formed at both ends of the center tube 13. Then, the stem portion 12 is inserted into the vocal tract space 13A on the opening portion 13B side of the central tube portion 13, and the earplug 10 is attached to the headphone 11.

Here, the column part 12 is formed in a substantially cylindrical shape about the center axis CL, and an attaching and detaching groove 12B in the form of an annular concave portion is formed on the outer surface 12A thereof, similarly to the central cylindrical part 13. An annular locking portion 13D protruding toward the acoustic channel space 13A is formed near the opening 13B of the center tube portion 13. When the earplug 10 is attached to the headphone 11, the locking portion 13D is fitted into the attaching/detaching groove 12B of the support portion 12, whereby the earplug 10 is configured to be difficult to be pulled out from the support portion 12.

On the other hand, the plug portion 15 is inserted into the acoustic channel space 13A on the opening portion 13C side of the center tube portion 13, and the acoustic channel space 13A is closed by the plug portion 15. As described above, the elongated acoustic channel hole 15B is formed in the plug portion 15 along the longitudinal direction thereof. With this configuration, even in a state where the opening 13C of the central cylindrical portion 13 is blocked by the plug portion 15, the sound transmitted from the pillar portion 12 is transmitted to the vocal tract long hole 15B of the plug portion 15 inside the vocal tract space 13A. Then, a part of the sound transmitted from the pillar portion 12 is directly transmitted to the external auditory meatus 32 via the opening 15A of the stopper portion 15 (see fig. 5).

In the short side direction (the left-right direction of the paper surface, the front-back direction of the paper surface) of the center cylinder 13, 4 sound channel holes 13E are formed at intervals of 90 degrees in the circumferential direction. The 4 sound channel holes 13E are respectively communicated with the sound channel space 13A, and are formed as cylindrical holes of phi 1.0 to 1.5mm, for example. On the outer surface 13F of the center cylinder portion 13, 4 opening portions 13G are formed at 90-degree intervals by 4 acoustic holes 13E.

When the earplug 10 is mounted on the headphone 11, as shown in the drawing, the rear end portion of the plug portion 15 is in a state of abutting against the pillar portion 12. In a state where the plug portion 15 is inserted into the central cylindrical portion 13, the sound channel hole 13E of the central cylindrical portion 13 and the sound channel short hole 15G of the plug portion 15 are in a communicating state. With this configuration, most of the sound transmitted from the pillar portion 12 is transmitted to the internal space 20 between the central tube portion 13 and the cup member 14 via the vocal tract long hole 15B, the vocal tract short hole 15G, and the vocal tract hole 13E.

The cup portion 14 is formed in an umbrella shape so as to surround the central tube portion 13, and is formed to extend in the longitudinal direction of the central tube portion 13. One end side of the cup 14 is formed integrally with the opening 13B side of the central tube portion 13, and the other end side of the cup 14 is formed as a free end. The cup portion 14 is formed to extend further than the central tube portion 13, and the central tube portion 13 is located inside the cup portion 14. With this structure, an internal space 20 is formed between the cup portion 14 and the central tube portion 13.

As described above, 5 cup holes 17 are formed uniformly at a constant interval in the vicinity of the support portion 12 on one end side of the cup portion 14, for example. The cup hole 17 is a hole connecting the internal space 20 and an external space 21 outside the cup 14.

The cup hole adjustment plate 16 is disposed so as to be positioned outside the cup 14, and the locking portion 16A of the cup hole adjustment plate 16 is fitted into the attachment/detachment groove 12B of the column portion 12. That is, the engaging portion 13D of the central tube portion 13 and the engaging portion 16A of the cup hole adjusting plate 16 are fitted into the attaching/detaching groove 12B, so that the ear portion 10 is hard to be pulled out from the support portion 12

A plate portion 16B of the cup hole adjustment plate 16 is formed with a notch portion 16C having a width in which the 5 cup holes 17 are simultaneously exposed. The number of cup holes 17 exposed from the notch 16C of the plate 16B may be adjusted to 0 to 5.

The spherical portion 15D of the plug portion 15 is disposed so as to be exposed from the distal end side of the central cylindrical portion 13, but the spherical portion 15D is preferably located inside the cup portion 14 without protruding therefrom. With this structure, the spherical portion 15D is less likely to contact the inner wall 34 of the external auditory canal 32 of the user when the earplug 10 is mounted, and the user is less likely to be given a feeling of annoyance when the inner wall 34 contacts the spherical portion 15D.

As shown in fig. 3(B), the earplug 10 is used with the plug portion 15 inserted into the central tube portion 13, but an annular locking protrusion 13H protruding toward the acoustic channel space 13A is formed near the opening 13C of the central tube portion 13. The locking protrusion 13H is shaped to fit into the engagement portion 15F of the plug portion 15. As shown in fig. 3(a), in a state where the plug portion 15 is securely inserted into the central cylindrical portion 13, the central cylindrical portion 13 is slightly deflected outward by the thickness of the locking projection 13H.

With this configuration, for example, when the earplug 10 is pulled out from the external auditory canal 32 (see fig. 5) of the user, even when the plug portion 15 is pulled out in the direction of pulling out from the central tube portion 13, the locking protrusion 13H of the central tube portion 13 fits into the engagement portion 15F of the plug portion 15 before the plug portion 15 is pulled out from the central tube portion 13. As a result, the earplug 10 can be pulled out of the external auditory meatus 32 before the plug portion 15 is pulled out of the central tube portion 13, and the plug portion 15 is prevented from remaining in the external auditory meatus 32 of the user.

Fig. 4 is a sectional view illustrating an earplug 60 according to the present embodiment, and shows a modification of the earplug 10 described with reference to fig. 1 to 3. The cross-sectional view shown in fig. 4 corresponds to the cross-sectional view shown in fig. 3 (a). The earplug 60 shown in fig. 4 differs from the earplug 10 described above primarily in the construction of the engaging portion 62 formed on the body portion 61. Therefore, in describing the earplug 60 of fig. 4, the components different from the earplug 10 described with reference to fig. 1 to 3 will be mainly described, and the description of the other components will be referred to.

As shown in fig. 4, the stem portion 61 of the earplug 60 has two annular engaging portions 15F and 62 formed in the front-rear direction of the stem portion 61. The engagement portion 62 is the base of the spherical portion 15D of the stopper portion 61, and is formed as an annular recess on the outer peripheral surface 15E of the cylindrical portion 15C.

As shown, when the earplug 60 is used, the plug portion 61 is inserted into the central tube portion 13 of the cup portion 14. At this time, the locking projection 13H of the central cylindrical portion 13 is fitted into the engagement portion 62 of the stopper portion 61, and thereby the stopper portion 61 is configured to be difficult to be pulled out from the central cylindrical portion 13 of the cup portion 14.

Further, when the earplug 60 is removed from the external auditory canal 32 (see fig. 5), even if the locking protrusion 13H of the central tube portion 13 is detached from the locking portion 62, the locking protrusion 13H of the central tube portion 13 is fitted into the engagement portion 15F of the plug portion 15 as described with reference to fig. 3 (B). That is, the two ring-shaped engaging portions 15F, 62 are formed in the front-rear direction of the plug portion 61, so that the structure is realized in which the plug portion 15 is less likely to remain in the external auditory canal 32 of the user when the earplug 60 is used or the earplug 60 is removed from the external auditory canal 32.

Fig. 5 is a perspective view for explaining a state in which the earplug 10 of the present embodiment is attached to the external auditory meatus 32 of the user, and fig. 5 shows a state of sound transmission when the cup hole 17 is exposed from the cup hole adjustment plate 16. In fig. 5, the front-back direction indicates the front-back direction of the head of the user, and the left-right direction indicates the left-right direction of the head of the user. In the following description, the left ear 31 of the user will be described, but the same applies to the right ear, and the description thereof will be omitted here.

In fig. 5, a state in which the earplug 10 is mounted in the external auditory meatus 32 of the left ear 31 of the user is shown, but a dotted arrow schematically shows a transmission state of sound. First, the earplug 10 is inserted into the external auditory canal 32 such that the cup hole 17 of the cup portion 14 is opposed to the tragus portion 33 outside the external auditory canal 32 of the left ear 31. That is, the earplug 10 is installed in the user's left ear 31 such that the area of formation of the cup aperture 17 of the cup 14 is toward the front of the user's head.

The long vocal tract hole 15B penetrates the plug portion 15 in the longitudinal direction thereof, but since the opening area of the opening portion 15A on the distal end side is small, most of the sound transmitted from the pillar portion 12 is transmitted to the internal space 20 between the center tube portion 13 and the cup portion 14 via the long vocal tract hole 15B, the short vocal tract hole 15G, and the vocal tract hole 13E. Part of the sound transmitted from the pillar portion 12 is directly transmitted into the external auditory canal 32 through the opening 15A of the plug portion 15.

Most of the sound transmitted to the internal space 20 is reflected and diffused by the central tube portion 13, the cup portion 14, and the like around the internal space 20, and is transmitted into the external auditory canal 32. On the other hand, a part of the sound transmitted to the internal space 20 is transmitted to the external space 21 via the cup hole 17. Then, most of the emitted sound is also reflected to the tragus 33 and its periphery, for example, the concave-convex shape formed inside the left ear 31, and is again transmitted to the internal space 20 via the cup hole 17.

That is, only a part of the sound transmitted from the pillar portion 12 is directly transmitted to the tympanic membrane through the opening 15A, and the other most part is transmitted to the inner space 20 of the earplug 10. Then, the sound transmitted to the internal space 20 is transmitted to the eardrum via the external auditory canal 32 while being diffused in the internal space 20, the surface of the spherical portion 15D exposed from the central cylindrical portion 13, the inner wall 34 of the external auditory canal 32, and the like. At this time, a part of the sound transmitted to the inner space 20 is once released to the outer space 21 of the earplug 10, and returns to the inner space 20 again. According to the transmission state of the sound, the user recognizes the diffused sound as an indirect sound having a time difference from the front of the user along with the direct sound via the opening 15A, and obtains the out-of-head localization of the sound and the feeling of extension of the sound, thereby obtaining the forward sense of direction and the feeling of presence.

Further, by exposing the cup hole 17 from the cut-out portion 16C of the cup hole adjustment plate 16, the sound of the user's surrounding environment is transmitted into the internal space 20 via the cup hole 17, and then transmitted to the eardrum via the external auditory meatus 32. With this configuration, the user can listen to the sound of the user's surrounding environment, such as the guidance sound in the station, while listening to the music or the like transmitted from the pillar portion 12 at a constant volume, for example, so that the risk prediction can be performed for the surrounding environment.

Next, headphones according to other embodiments of the present invention will be described in detail with reference to the drawings. In the description of the present embodiment, since the earplug described with reference to fig. 1 to 5 is used, the same reference numerals are used for the same components in principle, and redundant description is omitted.

Fig. 6(a) is a sectional view illustrating an earphone 11 using the earplug 10 according to the present embodiment. Fig. 6(B) is a perspective view illustrating the earphone 11 using the earplug 10 according to the present embodiment. In the description of the earphone 11, the above-described fig. 1 to 5 and the description thereof should be referred to as appropriate. In fig. 6(a) and 6B, the front-back direction indicates the front-back direction of the head of the user, and the left-right direction indicates the left-right direction of the head of the user. In the following description, the left ear 31 of the user will be described, but the same applies to the right ear, and the description thereof will be omitted here.

As shown in fig. 6(a), the earphone 11 is an insertion-type earphone used by being attached to the external auditory canal 32 of a user, and mainly includes: a case 41 as a main body thereof, a support portion 12 disposed at the front end side of the case 41 and to which the earplug 10 is attached, and a dry drive unit 42 disposed inside the case 41. The earphone 11 is connected to a music terminal such as a portable music player and used, and music input from the music terminal to the earphone 11 is transmitted from the pillar portion 12 by being vibrated by a vibrating plate (not shown) in the drive unit 42 and emitting sound waves.

In the present embodiment, at least one or more holes 44, 45 are formed in the housing 41. The holes 44 and 45 are holes that communicate the internal space 46 of the housing 41 with the external space 21 outside the housing 41, and are formed in the housing 41 so as to surround the internal space 46 between the drive unit 42 and the bottom surface 47 of the housing 41 on the side opposite to the column part 12. Specifically, the hole 44 is a hole that must be formed, and is formed in the side surface 43 between the drive unit 42 and the bottom surface 47 of the housing 41. Further, the hole 45 is formed in the bottom surface 47 of the case 41, and releases the pressure of the internal space 46 when the vibration plate of the driving unit 42 vibrates. Further, by expanding the amplitude width of the diaphragm of the driving unit 42, the bass region of the music can be enhanced.

As shown in the drawing, two annular grooves 48 and 49 are formed in the side surface 43 of the housing 41, and an annular rubber member, for example, an O-ring 50 is disposed in the grooves 48 and 49. By providing the housing 41 with an O-ring 50 on the side 43, the user can use the O-ring 50 as a slip stop and easily hold the housing 41 while installing the earplug 10. Further, the groove 48 is formed to include a formation region of the hole 44, and the O-ring 50 is disposed in the groove 48, whereby the hole 44 is closed by the O-ring 48. Further, the effect of enhancing the bass region of the music described above is reduced due to the clogging of the holes 44, but the sound volume leaking from the cup hole 17 is also reduced in the case where the number of the cup hole 17 exposed from the cutout portion 16B is 0 or 1. That is, by adjusting whether the opening 44 or the closing hole 44 is made by the O-ring 48 according to the number of the cup holes 17 exposed from the cutout portion 16B, it is possible to adjust the sound heard from the earplug 10, for example, to adjust the balance between the treble range and the bass range.

As shown in FIG. 6(B), the earplug 10 is mounted on the user's left ear 31 such that the cup hole 17 is opposite the tragus portion 33 outside the external auditory meatus 32 of the user's left ear 31. Then, the hole 44 formed in the housing 41 is also set to be located on the tragus portion 33 side outside the external auditory meatus 32 of the user's left ear 31. That is, the cup hole 17 and the hole 44 are set to face the front side of the head of the user in the same direction when the earplug 10 is installed.

By arranging the cup hole 17 and the hole 44 in the same direction, a part of the music can thereby be released from the hole 44, but, as indicated by the dashed arrow, a part of the released music returns to the inner space 20 of the earplug 10 via the cup hole 17. The user recognizes the returned music as indirect sound with time difference as described above, and obtains the sense of direction and presence in the front by obtaining the out-of-head localization of the sound and the sense of expansion of the sound.

Fig. 7 is a perspective view illustrating the headphone 70 according to the present embodiment, and shows a modification of the headphone 11 described with reference to fig. 6. In addition, in the earphone 70 shown in fig. 7, an annular groove 48 is formed mainly in the side surface 43 of the housing 41, a plurality of holes 44 are formed in the groove 48, and the number of the holes 44 to be released can be adjusted by a slide ring 71 disposed in the groove 48, which is different from the structure of the earphone 11 described above. Therefore, in describing the earphone 70 of fig. 7, components different from those of the earphone 11 described with reference to fig. 6 will be mainly described, and the description of the other components will be referred to.

As shown in fig. 7, an annular groove 48 is formed in the side surface 43 of the housing 41, and for example, 5 holes 44 are formed at regular intervals in the groove 48. The hole 44 is a hole that communicates the internal space 46 (see fig. 6) of the housing 41 with the external space 21 outside the housing 41. The hole 44 is formed in the housing 41 surrounding an inner space 46 between the drive unit 42 (see fig. 6) and a bottom surface 47 of the housing 41. As described above, the 5 holes 44 are positioned on the tragus portion 33 (see fig. 6B) side of the user when the earplug 10 is attached, similarly to the cup hole 17.

As shown, the slide ring 71 is disposed in the groove 48 of the housing 41. The slide ring 71 is, for example, C-shaped, and can expose the hole 44 from its opening portion. The opening width of the slide ring 71 has a width that simultaneously exposes the 5 holes 44. The slide ring 71 slides while rotating in the groove 48, whereby the number of exposed holes 44 can be changed from 0 to 5.

The hole 44 is exposed from the slide ring 71, thereby releasing the pressure of the internal space 46 when the vibration plate of the driving unit 42 vibrates. Then, by increasing the amplitude width of the vibration plate of the driving unit 42, the bass region of music can be enhanced. In the earphone 70, the number of the exposed holes 44 can be adjusted, and thus the holes 45 of the earphone 11 shown in fig. 6 may not be necessary.

As described above with reference to fig. 1(B), in the earplug 10, by exposing the cup hole 17 from the cut-out portion 16B, the amount of sound transmitted to the external space 21 also increases, and particularly, the decrease of the bass region of music tends to increase. As a countermeasure, by increasing the number of holes 44 exposed from the slip ring 71, the disadvantage in the case of the multi-relief cup hole 17 can be supplemented by increasing the bass region transmitted to the earplug 10 via the pillar portion 12. In addition, as described above, the multi-cup hole 17 can provide a sense of localization of the outside of the head of the sound and a sense of extension of the sound, which is advantageous for obtaining a sense of direction and presence in the front.

That is, the user can adjust the balance between the high pitch range and the low pitch range, for example, by appropriately adjusting the number of exposed cup holes 17 of the earplug 10 and the number of exposed holes 44 of the case 41 according to the preference or the like, and can obtain the outer-head localization of the sound and the feeling of extension of the sound, and also obtain the sense of direction and presence in the front. Further, by adjusting the number of cup holes 17 and holes 44, the sound also intersects between the left and right ears, and the presence feeling can be improved. The same effect can be obtained by using the earplug 60 described in fig. 4.

In the present embodiment, the case where the spherical portion 15D of the stopper portion 15 is exposed to the outside from the central cylindrical portion 13 has been described, but the present invention is not limited to this case. For example, the stopper portion 15 may be constituted only by the cylindrical portion 15C, and the entire stopper portion 15 is inserted into the acoustic channel space 13A of the central cylindrical portion 13. Even in this case, the opening 15A of the stopper portion 15 is provided at the front end of the cylindrical portion 15C, and only a part of the sound transmitted from the pillar portion 12 is directly transmitted to the eardrum in the external auditory meatus 32 via the opening 15A. Further, by housing the plug portion 15 in the central tube portion 13, the plug portion 15 is less likely to contact the external auditory meatus 32 of the user when the earplug 10 is attached, and the user is less likely to be given a feeling of annoyance when the inner wall 34 contacts the plug portion 15. In addition, various modifications may be made without departing from the scope of the present invention.

Description of the symbols

10 earplug

11 earphone

12 column part

12B loading and unloading groove

13 center tube section

13A channel space

13E sound channel hole

13H locking protrusion

14 cup part

15 stopper part

15A opening part

15B sound channel long hole

15C cylindrical part

15D ball portion

15G sound channel short hole

16 cup hole adjusting plate

17 cup hole

20 inner space

21 outer space

31 left ear

32 external auditory canal

33 tragus part

34 inner wall

41 casing

44 holes