KR20230089777A - Bone Conduction Type Piezoelctric Earphone - Google Patents

Abstract

The bone conduction piezoelectric earphone according to the present invention improves the frequency response characteristics of the mid/low tone band and reduces the risk of physical damage to the piezoelectric vibration driver, and includes a piezoelectric vibration driver that generates vibration according to an input electrical signal; a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front; a hard core part, the rear end of which contacts the front surface of the piezoelectric vibration driver, passes through the hole and extends to the front end exposed to the outside of the housing, and transfers the vibration generated by the piezoelectric vibration driver to the outside of the housing; a soft diaphragm formed of a soft rubber material having a hardness lower than that of the hard core, in the form of a film thinly extending in a circumferential direction from the circumference of the hard core in the inner space of the housing; and a rear elastic member formed of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver, wherein an edge portion of the piezoelectric vibration driver and the rear surface of the piezoelectric vibration driver A gap may be formed between the housing and the periphery of the soft diaphragm so that the edge portion vibrates in the forward and backward directions.

Description

Bone Conduction Type Piezoelectric Earphone {Bone Conduction Type Piezoelectric Earphone}

The present invention relates to a bone conduction piezoelectric earphone that transmits sound through a bone conduction path, and more particularly, to bone conduction that transmits vibration generated from a piezoelectric vibration driver to the skull and inner ear bone of the human body so that it can be detected as sound. It relates to a type of piezoelectric earphone.

In general, there are two methods for how a person feels sound according to the path, one is air conduction method and the other is bone conduction method. In the bone conduction method, vibrations are transmitted to the cochlea through the cranial bone and inner ear bone, and then to the brain via the auditory nerve. The process of passing through the dog's bones was omitted. The sound transmission method through bone conduction has the advantage of being able to hear the sound relatively clearly through bone conduction even when it is difficult to identify the sound through air conduction due to severe ambient noise. The bone conduction method can also be applied to hearing aids for people with hearing loss who have abnormalities in the eardrum or ossicles.

When constructing a bone conduction type earphone, a piezoelectric vibration driver that uses the inverse piezoelectric effect as a driver that generates vibration according to an electrical signal can be manufactured with a thin thickness, which is advantageous for miniaturization, and consumes less power. In terms of being advantageous for high-pitched sound reproduction, it has many advantages over coil-type dynamic drivers applied to general earphones. However, the piezoelectric vibration driver has a problem in that it has poor bass characteristics compared to the dynamic driver and is easily damaged by physical force applied to the vibration transmission system because it uses a ceramic material.

Republic of Korea Patent No. 10-1614380

The present invention is to provide a bone conduction piezoelectric earphone that improves the frequency response characteristics of the mid/low tone band and reduces the risk of physical damage to the piezoelectric vibration driver in constructing a bone conduction type earphone using a piezoelectric vibration driver. has its purpose.

In order to solve the above problems, a piezoelectric vibration earphone according to the present invention includes a piezoelectric vibration driver generating vibration according to an input electrical signal; a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front; a vibration transmitting body that transfers vibration generated from the piezoelectric vibration driver to the outside of the housing through the hole; and a rear elastic member formed of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver, wherein the vibration transmitter includes a rear end portion of the piezoelectric vibration driver. a hard core portion that contacts the front surface of the vibration driver and extends through the hole to a front end exposed to the outside of the housing; and a soft diaphragm formed of a soft rubber material having a hardness lower than that of the hard core, in the form of a film extending thinly from the circumference of the hard core in a circumferential direction in the inner space of the housing. It is configured as a hybrid vibration transmission body comprising a.

The soft diaphragm has a center portion fixed to the circumference of the hard core portion and a periphery portion thereof fixed to the housing to regulate the hard core portion to be positioned at the center portion of the piezoelectric vibration driver, and at the same time extend the hard core portion in its longitudinal direction. It may be configured to be elastically supported so as to be movable.

In this case, the soft diaphragm may include a curved portion convexly formed in a forward or backward direction between the central portion and the peripheral portion. In addition, the soft diaphragm may include a sleeve in the center portion, and the hard core portion may be fitted and coupled into the sleeve.

The hard core part may include a first part contacting the piezoelectric vibration driver; and a second part exposed to the outside of the housing. Including, the first part and the second part may be assembled to each other such that the central portion of the soft diaphragm is inserted and fixed therebetween.

In the soft diaphragm, a center portion fixed to the periphery of the hard core portion is closer to the piezoelectric vibration driver than a periphery portion fixed to the housing, and an inverted dome shape between the center portion and the periphery portion is convex in an edge direction of the piezoelectric vibration driver. can

Meanwhile, the bone conduction piezoelectric earphone is disposed between the soft diaphragm and the housing located on the front side of the soft diaphragm and is made of a soft foam material to elastically press the vibration transmitter toward the piezoelectric vibration driver. It may be configured to further include a member.

Meanwhile, the bone conduction piezoelectric earphone according to the present invention includes a piezoelectric vibration driver generating vibration according to an input electrical signal; a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front; a hard core part, the rear end of which contacts the front surface of the piezoelectric vibration driver, passes through the hole and extends to the front end exposed to the outside of the housing, and transfers the vibration generated by the piezoelectric vibration driver to the outside of the housing; a soft diaphragm formed of a soft rubber material having a hardness lower than that of the hard core, in the form of a film thinly extending in a circumferential direction from the circumference of the hard core in the inner space of the housing; and a rear elastic member formed of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver, wherein an edge portion of the piezoelectric vibration driver and the rear surface of the piezoelectric vibration driver A gap may be formed between the housing and the periphery of the soft diaphragm so that the edge portion vibrates in the forward and backward directions.

The edge portion of the piezoelectric vibration driver may be arranged to have a gap between it and the housing in a rearward direction, and to have a predetermined gap between the periphery of the soft diaphragm in a frontward direction.

At this time, the center of the soft diaphragm is fixed to the circumference of the hard core part and its periphery is fixed to the housing, so that the hard core part is positioned at the center of the piezoelectric vibration driver and at the same time the length of the hard core part is fixed. It may be configured to elastically support so as to be movable in a direction.

Meanwhile, a bone conduction earphone according to an aspect of the present invention includes a piezoelectric vibration driver generating vibration according to an input electrical signal; a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front; a core portion having a rear end contacting the front surface of the piezoelectric vibration driver and extending through the hole to a front end exposed to the outside of the housing to transfer vibration generated from the piezoelectric vibration driver to the outside of the housing; a diaphragm formed in the form of a film thinly extending in a circumferential direction from the circumference of the core part in the inner space of the housing; and a rear elastic member formed of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver, wherein an edge portion of the piezoelectric vibration driver and the rear surface of the piezoelectric vibration driver A gap may be formed between the housing and the periphery of the diaphragm so that the edge portion can vibrate in the forward and backward directions.

According to the present invention, in a bone conduction type earphone using a piezoelectric vibration driver, a solid conduction piezoelectric earphone configured to improve frequency response characteristics in a mid/low tone band and reduce the risk of physical damage to the piezoelectric vibration driver. Provided. According to the present invention, there is an effect of improving the sound quality and durability of the bone conduction type earphone.

1 shows the appearance of a bone conduction piezoelectric earphone according to an embodiment of the present invention.
FIG. 2 shows a central axis cross section of the bone conduction piezoelectric earphone according to the embodiment of FIG. 1 .
FIG. 3 is an enlarged view of an edge portion of the piezoelectric vibration driver in FIG. 2 .
FIG. 4 shows frequency response characteristics between bone conduction piezoelectric earphones A and Comparative Example B according to the embodiment of FIG. 1 .
FIG. 5 shows frequency response characteristics between bone conduction piezoelectric earphones A and Comparative Example C according to the embodiment of FIG. 1 .
6 shows an example of a hybrid type vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.
7 shows an example of a hybrid vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.
8 shows an example of a hybrid vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.
9 shows a central axis cross section of a bone conduction piezoelectric earphone according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments described below may be modified in various forms, and the scope of the present invention is not limited to the following embodiments. Embodiments of the present invention are provided to convey the technical idea of the invention to those skilled in the art, and details obvious to those skilled in the art may be omitted.

1 shows the appearance of a bone conduction piezoelectric earphone according to an embodiment of the present invention.

The bone conduction piezoelectric earphone 100 according to the present embodiment includes a front housing 11 and a rear housing 12 accommodating a piezoelectric vibration driver (not shown) therein, and transmitting vibration of the piezoelectric vibration driver to the outside. It is configured to include a vibration transmitter 30 whose part (hereinafter, referred to as 'outer side') is exposed to the outside through a hole formed in the front housing 11. The outer portion of the vibration transmission body 30 may be formed in a small size so as to be inserted into the user's ear. An ear tip 34 made of a soft material such as silicone rubber is coupled to the outer portion to prevent pain in the user's ear. The vibration transmission body 30 and the ear tip 34 transfer the vibration of the piezoelectric vibration driver to the user's ear, that is, to the inner wall of the ear canal, thereby transmitting sound to the user's ear through bone conduction.

In the embodiment of this drawing, the housing for accommodating the piezoelectric vibration driver (not shown) is divided into front and rear parts and consists of a front housing 11 and a rear housing 12, but unlike this, various forms such as divided into left and right sides are divided. can be made into a shape. In this specification, 'housing' refers to the entire case structure of an earphone that provides a space for accommodating a piezoelectric vibration driver, etc., and exposes a portion of the vibration transmitter 30 toward the front, and is a structure according to a specific division form. Not limited. However, hereinafter, description will be made based on an embodiment in which the housing is divided into front and rear housings. Here, the front refers to a direction in which the device is inserted into the user's ear, and the rear refers to the opposite direction.

FIG. 2 shows a central axis cross section of the bone conduction piezoelectric earphone according to the embodiment of FIG. 1 . As shown, in the inner space formed by the front housing 11 and the rear housing 12, the rear elastic member 42, the piezoelectric vibration driver 20 and the vibration transmitter 30 from the side of the rear housing 12 is placed

The rear elastic member 42 is supported by a lip structure inside the rear housing 12 and is elastically supported by contacting the rear surface of the piezoelectric vibration driver 20 on the opposite side. The rear elastic member 42 may be made of a soft foam material such as a sponge. The rear elastic member 42 protects the piezoelectric vibration driver 20 by elastically buffering the external force on the piezoelectric vibration driver 20 through the vibration transmission body 30, and also the piezoelectric vibration driver ( 20) to prevent noise from being transmitted to the outside.

On the front side of the piezoelectric vibration driver 20 , the hard core part 32 of the vibration transmitter 30 is disposed to contact the front center of the piezoelectric vibration driver 20 . The vibration transmitter 30 extends from the inside of the housing to the outside along the direction of the central axis of the bone conduction piezoelectric earphone 100, and the hard core part 32 extends from the circumference of the hard core part 32 to the circumferential direction. It is configured to include a thinly expanded soft diaphragm 50 . The hard core part 32 is formed of a hard plastic material and is configured to transfer the vibration of the piezoelectric vibration driver 20 to the head part 31 outside the housings 11 and 12 without loss in the direction of the central axis. An ear tip 34 is coupled to the head part 31 .

The soft diaphragm 50 helps the vibration transmitter 30 including the hard core part 32 to transmit the vibration generated by the piezoelectric vibration driver 20 without loss, and the position of the vibration transmitter 30 and serves to prevent dust or moisture from entering the piezoelectric vibration driver 20 from the outside. Functions of each part of the vibration transmitter 30 will be described in more detail later.

The soft diaphragm 50 is formed in the form of a thin film of a soft material having a relatively lower hardness than the hard core part 32 . The periphery of the soft diaphragm 50 is supported by a housing, for example by the front housing 11 . A protrusion 52 may be formed on at least a portion of the periphery to fit into a groove formed in the front housing 11 . In addition, a sleeve 51 extending along the longitudinal direction of the hard core part 32 is formed at the center of the soft diaphragm 50 so that the hard core part 32 is coupled to the inside of the sleeve 51. can be configured. As described above, the configuration of the vibration transmission body 30 including the hard core portion 32 and the soft diaphragm 50 extending in the circumferential direction is proposed through the present invention, and will be referred to as a 'hybrid vibration transmission body' hereinafter. do.

In the hybrid vibration transmitter 30, the hard core part 32 serves to transmit the vibration of the piezoelectric vibration driver 20 to the ear tip 34 inserted into the user's ear, and the soft diaphragm 50 regulates the position of the hard core part 32 so that it is located at the center of the piezoelectric vibration driver 20, and the rear end of the hard core part 32 is in contact with the piezoelectric vibration driver 20 It serves to elastically support the hard core part 32 between the front housing 11 and the piezoelectric vibration driver 20 so as to be maintained. A forward and/or rearward convex bent portion is formed between the sleeve 51 at the center of the soft diaphragm 50 and the periphery, so that the hard core portion 32 is formed in its longitudinal direction, that is, in the direction of the central axis of the earphone. can help you move more freely.

The structure of the hybrid type vibration transmitter 30 allows the hard core part 32 to substantially transmit vibrations to be made of a material with higher hardness compared to the conventional bone conduction earphone vibration transmitter formed integrally. This point is helpful in improving frequency response characteristics. The fact that the soft diaphragm 50 flexibly and resiliently supports the hard core part 32 also contributes to improving frequency response characteristics. In addition, by preventing damage to the piezoelectric vibration driver 20, it contributes to improving the durability of the bone conduction piezoelectric earphone 100.

Meanwhile, the piezoelectric vibration driver 20 has its periphery, that is, an edge portion 22, which is not directly fixed to either of the housings 11 and 12 and the vibration transmitter 30. In particular, its position is not fixed in the forward/backward direction. Therefore, the piezoelectric vibration driver 20 has its edge portion ( 22) is arranged to vibrate freely in the forward/backward direction within a predetermined range.

FIG. 3 is an enlarged view of an edge portion of the piezoelectric vibration driver in FIG. 2 .

In the case of the present embodiment, as shown, the edge portion 22 of the piezoelectric vibration driver 20 has a gap with the periphery of the soft diaphragm 50 in the front, and the rear housing ( 11) and spaced apart. It is preferable that no member other than air intervenes in these gaps. However, if a member is made of a material that is softer than any of the soft diaphragm 50, the front housing 11, the rear housing 12, and the rear elastic member 42 and is easily deformable, the possibility of intervention is completely prevented. It is not excluded.

FIG. 4 shows frequency response characteristics between bone conduction piezoelectric earphones A and Comparative Example B according to the embodiment of FIG. 1 .

Example A of the bone conduction piezoelectric earphone according to the present invention was configured as described above with reference to FIGS. 2 and 3 . As a hybrid vibration transmission body 30 is applied, the hard core part 32 is made of a hard plastic material, and the soft diaphragm 50 is made of a soft silicon rubber material. In addition, the edge portion 22 of the piezoelectric vibration driver 20 is arranged so that its position is not fixed in the front/rear direction.

In Comparative Example B, an integrated vibration transmission body was applied like the conventional bone conduction earphone, and a part corresponding to the vibration transmission body 30 in the embodiment of FIG. 2 was integrally formed of a hard silicon rubber material. Even in the case of Comparative Example B, the edge portion 22 of the piezoelectric vibration driver 20 was arranged so that its position was not fixed in the front/rear direction.

As represented by the graph, it can be seen that the frequency response characteristics of Example A are improved compared to Comparative Example B. Specifically, at 1 kHz, Comparative Example B was 67.1 dB (re. 1 μN), whereas Example A was confirmed to be 74 dB (re. 1 μN). Overall, it can be confirmed that Example A has a structure that is relatively advantageous in transmitting vibration compared to Comparative Example B in most frequency bands.

FIG. 5 shows frequency response characteristics between bone conduction piezoelectric earphones A and Comparative Example C according to the embodiment of FIG. 1 .

The configuration of Example A of the bone conduction piezoelectric earphone according to the present invention is as described above, and Comparative Example C has a structure in which the edge portion of the piezoelectric vibration driver is fixed so as not to move in the forward/rear direction, as in the existing bone conduction earphone. was applied. As the vibration transmission body of Comparative Example C, a hybrid vibration transmission body was applied as in Example A described above, and an experiment was configured to confirm the effect of whether or not the edge portion of the piezoelectric vibration driver was fixed.

As a result, as shown in the graph, it can be seen that the frequency response characteristics of Example A are superior to those of Comparative Example C. Specifically, at 500 Hz, Example A was found to be 74.4 dB (re. 1 μN) compared to 69.2 dB (re. 1 μN) in Comparative Example C, and Example A was significantly superior to Comparative Example C in the low and mid-range. It can be confirmed that it has excellent response characteristics. It is interpreted that the non-fixed structure in which the edge portion of the piezoelectric vibration driver is not fixed in the front/rear direction contributed to the improvement of response characteristics in the mid/low frequency band.

Meanwhile, in constructing the bone conduction piezoelectric earphone according to the present invention, the above-described hybrid vibration transmission body is not limited to the above-described form and may be configured in various forms.

6 shows an example of a hybrid type vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.

In the hybrid vibration transmission body 301 according to the present embodiment, the soft diaphragm 50R extending in the circumferential direction from the circumference of the hard core part 32 may be formed to form an inverted dome shape convex to the rear side. In this structure, when the vibration transmitter 301 is pressed toward the piezoelectric vibration driver by an external force, the inverted dome-shaped soft diaphragm 50R suppresses the hard core part 32 from moving backward to protect the piezoelectric vibration driver, thereby improving durability. is helpful to A sleeve 51 may also be provided at the center of the soft diaphragm 50R.

7 shows an example of a hybrid vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.

The hybrid vibration transmission body 302 according to the present embodiment is composed of two parts, the first part 321 in which the hard core part contacts the piezoelectric vibration driver and the second part 322 extending outside the housing. and a part of the soft diaphragm 50 may be fitted between the first part 321 and the second part 322 . The coupling part 320 between the first part 321 and the second part 322 may be assembled to each other by means of adhesion, screwing, or interference fit.

8 shows an example of a hybrid vibration transmitter applicable to the bone conduction piezoelectric earphone according to the present invention.

Like the embodiment of FIG. 7 , the hybrid vibration transmission body 303 according to this embodiment is also assembled with its hard core composed of two parts, the first part 321 and the second part 322, A part of the soft diaphragm 50R having an inverted dome shape similar to the embodiment of FIG. 6 may be inserted between the first part 321 and the second part 322 . In this case the sleeve may be omitted.

9 shows a central axis cross section of a bone conduction piezoelectric earphone according to an embodiment of the present invention.

The bone conduction piezoelectric earphone 101 according to this embodiment may include the configuration of the above-described embodiment of FIG. 2 as it is, and may additionally include a front elastic member 43. The front elastic member 43 is disposed in front of the piezoelectric vibration driver 20 and is configured to serve to bring the vibration transmitter 30 into close contact with the piezoelectric vibration driver 20 . The front elastic member 43 may be disposed in a donut shape disposed between the soft diaphragm 50 and the front housing 11 and may be formed of a soft foam material.

100, 101: bone conduction piezoelectric earphone
20: piezoelectric vibration driver 22: edge portion of piezoelectric vibration driver
30: vibration transmission body 32: hard core part
42: rear elastic member 43: front elastic member
50: soft diaphragm 51: sleeve

Claims (11)

a piezoelectric vibration driver generating vibration according to an input electrical signal;
a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front;
a vibration transmitting body that transfers vibration generated from the piezoelectric vibration driver to the outside of the housing through the hole; and
A rear elastic member made of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver;
The vibration transmission body,
a hard core having a rear end in contact with the front surface of the piezoelectric vibration driver and extending through the hole to a front end exposed to the outside of the housing; and
a soft diaphragm formed of a soft rubber material having a hardness lower than that of the hard core, in the form of a film thinly extending in a circumferential direction from the circumference of the hard core in the inner space of the housing; A hybrid vibration transmission chain comprising a,
Bone conduction piezoelectric earphone. According to claim 1,
The soft diaphragm has a center portion fixed to the circumference of the hard core portion and a periphery portion fixed to the housing to regulate the hard core portion to be positioned at the center portion of the piezoelectric vibration driver, and to move the hard core portion in its longitudinal direction. elastically supported,
Bone conduction piezoelectric earphone. According to claim 2,
The soft diaphragm includes a bent portion formed convexly forward or backward between the center and the periphery,
Bone conduction piezoelectric earphone. According to claim 2,
The soft diaphragm includes a sleeve in the center,
The hard core part is fitted and coupled into the sleeve,
Bone conduction piezoelectric earphone. According to claim 1,
The hard core part may include a first part contacting the piezoelectric vibration driver; and
a second part exposed to the outside of the housing; including,
The first part and the second part are assembled to each other such that the center of the soft diaphragm is fitted and fixed therebetween.
Bone conduction piezoelectric earphone. According to claim 1 or 5,
In the soft diaphragm, the center portion fixed to the periphery of the hard core is disposed closer to the piezoelectric vibration driver than the periphery portion fixed to the housing, and the center portion and the periphery have an inverted dome shape convex in an edge direction of the piezoelectric vibration driver. formed,
Bone conduction piezoelectric earphone. According to claim 1,
A front elastic member disposed between the soft diaphragm and the housing located at a front side of the soft diaphragm, made of a soft foam material, and elastically pressing the vibration transmitter toward the piezoelectric vibration driver,
Bone conduction piezoelectric earphone. a piezoelectric vibration driver generating vibration according to an input electrical signal;
a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front;
a hard core part having a rear end contacting the front surface of the piezoelectric vibration driver and extending through the hole to a front end exposed to the outside of the housing to transfer vibration generated from the piezoelectric vibration driver to the outside of the housing;
a soft diaphragm formed of a soft rubber material having a hardness lower than that of the hard core, in the form of a film thinly extending in a circumferential direction from the circumference of the hard core in the inner space of the housing; and
A rear elastic member made of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver;
Consisting of a non-fixed structure so that the edge portion can vibrate in the forward and backward directions by leaving a gap between the edge portion of the piezoelectric vibration driver and the periphery of the housing and the soft diaphragm,
Bone conduction piezoelectric earphone. According to claim 8,
The edge portion of the piezoelectric vibration driver is arranged so as to have a gap from the housing rearward and a predetermined gap from the periphery of the soft diaphragm forward.
Bone conduction piezoelectric earphone. According to claim 8,
The soft diaphragm has a center portion fixed to the circumference of the hard core portion and a periphery portion thereof fixed to the housing to regulate the hard core portion to be positioned at the center portion of the piezoelectric vibration driver, and at the same time extend the hard core portion in its longitudinal direction. elastic support for movement,
Bone conduction piezoelectric earphone. a piezoelectric vibration driver generating vibration according to an input electrical signal;
a housing accommodating the piezoelectric vibration driver in an inner space and having a hole formed from the inner space toward the front;
a core portion having a rear end contacting the front surface of the piezoelectric vibration driver and extending through the hole to a front end exposed to the outside of the housing to transfer vibration generated from the piezoelectric vibration driver to the outside of the housing;
a diaphragm formed in the form of a film thinly extending in a circumferential direction from the circumference of the core part in the inner space of the housing; and
A rear elastic member made of a soft foam material, disposed between the housing and the rear surface of the piezoelectric vibration driver, and elastically supporting the rear surface of the piezoelectric vibration driver;
Consisting of a non-fixed structure so that the edge portion can vibrate in the forward and backward directions by leaving a gap between the edge portion of the piezoelectric vibration driver and the periphery of the housing and the diaphragm,
Bone conduction piezoelectric earphone.

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