CN219812240U - Bone conduction earphone - Google Patents

Abstract

The utility model relates to a bone conduction earphone which comprises a shell and a bone conduction module arranged on the shell, wherein the shell is provided with a back skin wall and a near skin wall which are arranged in a back-to-back mode, and two side walls which are respectively connected with the two sides of the back skin wall and the near skin wall, the output end of the bone conduction module is arranged on the near skin wall, the back skin wall is provided with a hanging groove which penetrates through the two side walls and is used for hanging the shell on the glasses leg of the glasses, so that the bone conduction earphone is required to be hung on the glasses leg from the side of the back skin wall when the bone conduction earphone is arranged, the bone conduction earphone is required to be taken off from the glasses leg from the opposite direction when the bone conduction earphone is dismounted, and the bone conduction earphone is limited by the head of a user when in use and is difficult to take off the bone conduction earphone under the condition of not taking off the glasses.

Description

Bone conduction earphone

Technical Field

The utility model relates to the field of earphones, in particular to a bone conduction earphone.

Background

In order to facilitate the user to use the bone conduction earphone while wearing the glasses, bone conduction earphone capable of being hung on the glasses leg of the glasses appears on the market, and although the difficulty of wearing the bone conduction earphone while wearing the glasses is solved, the bone conduction earphone is easy to fall off from the glasses leg under the influence of external force when in use.

Disclosure of Invention

The technical problem to be solved by the embodiment of the utility model is to provide the bone conduction earphone, so that the problem that the bone conduction earphone hung on the glasses leg is easily affected by external force to fall off from the glasses leg when in use in the prior art is solved.

The bone conduction earphone provided by the embodiment of the utility model comprises: the skin-care device comprises a shell, a pair of glasses leg and a pair of glasses leg, wherein the shell is provided with a skin-back wall, a skin-near wall and two side walls, the skin-back wall and the skin-near wall are arranged in a back-to-back mode, the two side walls are respectively connected to two sides of the skin-back wall and the skin-near wall, the skin-back wall is provided with a hanging groove penetrating through the two side walls, and the hanging groove is used for hanging the shell on the glasses leg; and the bone conduction module is arranged on the shell, and the output end of the bone conduction module is connected with the skin-approaching wall so as to transmit sound vibration by utilizing the skin-approaching wall.

Further, the hanging groove includes: the first groove section is arranged on the back skin wall and extends towards the direction close to the skin-approaching wall; the second groove section is communicated with one side of the first groove section, which is close to the skin-approaching wall, and is bent and extended in a direction away from the gravity direction.

Further, an included angle between the extending direction of the first groove section and the extending direction of the second groove section is an obtuse angle.

Further, the extending direction of the second groove section is arranged at an obtuse angle with the gravity direction.

Further, a protruding portion is arranged on the skin-approaching wall, and the output end of the bone conduction module is connected with the protruding portion, so that the bone conduction module can transmit sound vibration by using the protruding portion.

Further, the groove wall of the second groove section is made of an elastic material.

Further, a plurality of anti-slip bulges are arranged on the groove wall of the second groove section.

Further, a chamfer is arranged at the connection position of the hanging groove and the back skin wall.

Further, the chamfer is a first rounded corner.

Further, the edge of the shell is provided with a second round angle.

Compared with the prior art, the bone conduction earphone provided by the embodiment of the utility model has the beneficial effects that: the bone conduction earphone provided by the embodiment of the utility model comprises a shell and a bone conduction module arranged on the shell, wherein the shell is provided with a back skin wall and a near skin wall which are arranged in a back-to-back manner, and two side walls which are respectively connected with the two sides of the back skin wall and the near skin wall, the output end of the bone conduction module is arranged on the near skin wall, and particularly, the back skin wall is provided with a hanging groove which penetrates through the two side walls and is used for hanging the shell on the glasses leg of the glasses.

Drawings

The utility model will now be described in further detail with reference to the accompanying drawings and examples, in which:

fig. 1 is a schematic perspective view of a bone conduction headset according to an embodiment of the present utility model;

fig. 2 is a schematic perspective view of the bone conduction headset shown in fig. 1 at another angle;

fig. 3 is a schematic perspective view of glasses and a bone conduction headset according to an embodiment of the present utility model;

fig. 4 is a schematic plan view of the bone conduction headset shown in fig. 1;

FIG. 5 is a schematic view of a cleat according to an embodiment of the present utility model;

FIG. 6 is a schematic view of a cleat according to another embodiment of the present utility model.

The reference numerals in the drawings are as follows:

1000. bone conduction headphones;

100. a housing; 110. a skin-backing wall; 120. a skin proximal wall; 121. a boss; 130. a sidewall; 140. a hanging groove; 141. a first trough section; 142. a second trough section; 1421. a slip preventing protrusion; 150. chamfering; 151. a first rounded corner; 160. a second rounded corner;

9000. glasses; 9100. a glasses leg.

Detailed Description

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other. Preferred embodiments of the present utility model will now be described in detail with reference to the accompanying drawings.

An embodiment of the present utility model provides a bone conduction headset 1000, as shown in fig. 1-3, the bone conduction headset 1000 includes a housing 100 and a bone conduction module (not shown). The shell 100 has a back skin wall 110, a near skin wall 120, and two side walls 130, the back skin wall 110 and the near skin wall 120 are disposed opposite to each other, the two side walls 130 are respectively connected to two sides of the back skin wall 110 and the near skin wall 120, the back skin wall 110 is provided with a hanging slot 140 penetrating the two side walls 130, and the hanging slot 140 is used for hanging the shell 100 on the temple 9100. The bone conduction module is mounted on the housing 100, and an output end of the bone conduction module is connected with the skin-proximal wall 120, so as to transmit sound vibration by using the skin-proximal wall 120.

It should be noted that, the skin-proximal wall 120 is just one side of the bone conduction earphone 1000 facing the head of the user in use, and the output end of the bone conduction module is connected to the skin-proximal wall 120, so as to transmit sound information to the user by using the skin-proximal wall 120, and the back skin wall 110 is just one side of the bone conduction earphone 1000 facing away from the head of the user in use.

By implementing the present embodiment, the hanging groove 140 is provided on the skin-backing wall 110 of the housing 100, and the hanging groove 140 penetrates through the two side walls 130, so that the bone conduction earphone 1000 can be hung on the glasses leg 9100 of the glasses 9000 on one side of the skin-backing wall 110, and the bone conduction earphone 1000 is only required to be removed from the glasses leg 9100 from the opposite direction when the bone conduction earphone 1000 is detached. Referring to the bone conduction headphones 1000 on the left in fig. 3, since the hanging groove 140 is provided on the back skin wall 110, when the bone conduction headphones 1000 on the left in fig. 3 are mounted on the temples 9100 of the glasses 9000, it is necessary to move in the X direction in fig. 3, and when the bone conduction headphones 1000 are detached from the temples 9100 of the glasses 9000, it is necessary to move in the Y direction in fig. 3, but when the bone conduction headphones 1000 are worn by the user, the bone conduction headphones 1000 are abutted against the head of the user in the Y direction, and at this time, the bone conduction headphones 1000 cannot move in the Y direction due to the restriction of the head of the user, that is, it is difficult to remove the bone conduction headphones 1000 without removing the glasses 9000. As can be seen, the bone conduction headset 1000 of the present embodiment is stable in use and is not subject to external forces from falling off the temple 9100 of the glasses 9000.

Referring to fig. 1-4, in a specific embodiment, the hanging groove 140 includes a first groove section 141 and a second groove section 142, where the first groove section 141 is opened on the back skin wall 110 and extends toward a direction (Z direction in fig. 4) close to the skin proximal wall 120, and the second groove section 142 is communicated with one side of the first groove section 141 close to the skin proximal wall 120 and bends and extends toward a direction away from the gravity direction (T direction in fig. 4).

It should be noted that, the gravity direction of the present embodiment refers to the vertical direction of the bone conduction headset in the upright state as shown in fig. 4. The second groove section 142 is bent and extended in a direction far away from the gravity direction, so that when the bone conduction headset is hung on the glasses leg 900, the glasses leg is located above the connection position of the first groove section 141 and the second groove section 142.

Specifically, when the bone conduction earphone 1000 of the present embodiment is hung on the temple 9100 of the glasses 9000, the temple 9100 will sequentially pass through the first slot section 141 and the second slot section 142, so when the bone conduction earphone 1000 is detached from the temple 9100 of the glasses 9000, the temple 9100 will be retracted from the second slot section 142 to the first slot section 141, and then moved along the first slot section 141 to the detachment hanging slot 140, since the extending directions of the first slot section 141 and the second slot section 142 are different, and the second slot section 142 is bent and extended in a direction far from the gravity direction, even if the bone conduction earphone 1000 is affected by an external force in a single direction, the bone conduction earphone 1000 will not be detached from the temple 9100 of the glasses 9000. Thus, the bone conduction headset 1000 does not easily come off the temple 9100 of the glasses 9000, even if the user is wearing the glasses 9000 or is taking the glasses 9000 aside.

Referring to fig. 1-4, in a specific embodiment, the groove wall of the second groove section 142 is made of an elastic material, so that not only can the elastic deformation adapt to the temples 9100 with different shape and size, but also the elastic deformation can be used to clamp the temples 9100, further preventing the bone conduction earphone 1000 from falling off from the temples 9100 under the influence of external force, and the user experience is excellent.

There are many specific examples of elastic materials, and those skilled in the art can adapt this, and two kinds of elastic materials are listed below for reference. In one embodiment, the elastic material is a silicone elastic material. In another embodiment, the elastic material is a rubber elastic material.

Referring to fig. 1-6, in an embodiment, the groove wall of the second groove section 142 is provided with a protrusion 1421, and the protrusion 1421 can further increase the friction between the elastic material and the temple 9100, so as to further prevent the bone conduction headset 1000 from falling off from the temple 9100 due to external force, and the user experience is excellent.

There are many specific examples of stud 1421, which can be adapted by a person skilled in the art, and two elastic materials are listed below for reference. In one embodiment, the stud 1421 is a striped stud disposed parallel to one another, as is the stud 1421 shown in fig. 5, and in another embodiment, the stud 1421 is a matrix arrangement of spot-like studs, as is the stud 1421 shown in fig. 6.

Referring to fig. 1-4, in one embodiment, the angle between the extending direction of the first slot segment 141 (Z direction in fig. 4) and the extending direction of the second slot segment 142 (T direction in fig. 4) is an obtuse angle. For a relatively wide temple 9100, when the temple 9100 enters the second channel segment 142 from the first channel segment 141 or exits from the second channel segment 142 to the first channel segment 141, the temple 9100 needs to turn, and compared with the technical scheme that the extending direction of the first channel segment 141 is perpendicular to the extending direction of the second channel segment 142, the obtuse angle technical scheme can provide a larger turning radius, which is beneficial for the temple 9100 to enter the second channel segment 142 from the first channel segment 141 or exit from the second channel segment 142 to the first channel segment 141.

In a specific embodiment, the extending direction of the second groove section 142 is disposed at an obtuse angle to the gravitational direction.

Specifically, if the extending direction of the second slot segment 142 is set at a flat angle with respect to the gravity direction, the lower edge of the temple 9100 will not contact with the slot wall of the second slot segment 142, and the friction will be relatively small, so that the temple 9100 will easily move up and down in the second slot segment 142, and when the glasses 9000 are taken off and placed on the desktop, the temple 9100 will easily slide down to the vicinity of the first slot segment 141 due to the lack of constraint of the lower edge of the temple 9100, and the risk that the bone conduction headset 1000 falls off from the temple 9100 is increased. In the obtuse angle solution, the groove wall of the second groove section 142 contacts the lower edge of the temple 9100, so the above technical problem can be solved.

In one embodiment, the output end of the bone conduction module protrudes out of the skin proximal wall 120 so that the output end can better contact the user's skin, thereby better transmitting acoustic vibrations.

Referring to fig. 1-4, in one embodiment, the attachment location of the hanging groove 140 to the backing wall 110 is provided with a chamfer 150.

In particular, the chamfer 150 may act as a guide when the temple 9100 enters the hanging groove 140, making it easier for the temple 9100 to enter the hanging groove 140. By implementing the present embodiment, the bone conduction headset 1000 can be more easily assembled.

In a specific embodiment, the chamfer 150 is the first fillet 151, so that a sharp edge is avoided at the connection position of the hanging groove 140 and the skin-backing wall 110, so that the temple 9100 is not scratched by the sharp edge during the assembly process, and in addition, the first fillet 151 can also avoid the user from being scratched by the sharp edge.

In an embodiment, the second rounded corner 160 is provided on the edge of the housing 100, so that the user is prevented from being scratched by the sharp edge, and the comfort of wearing the bone conduction headset 1000 by the user is improved.

Referring to fig. 1-4, in a specific embodiment, the bone conduction earphone 1000 is symmetrically designed, that is, the shape of the bone conduction earphone 1000 on the left side in fig. 3 is identical to that of the bone conduction earphone 1000 on the right side, unlike the existing earphone, the bone conduction earphone 1000 used on the left side and the bone conduction earphone 1000 used on the right side in this embodiment can share a mold, so that the mold opening cost can be effectively reduced, and the production cost of the bone conduction earphone 1000 can be further reduced.

The embodiment of the utility model shows a bone conduction earphone 1000, as shown in fig. 1-3, the bone conduction earphone 1000 includes a housing 100 and a bone conduction module mounted on the housing 100, the housing 100 has a back skin wall 110 and a near skin wall 120 which are disposed opposite to each other, and two side walls 130 which are respectively connected to two sides of the back skin wall 110 and the near skin wall 120, an output end of the bone conduction module is disposed on the near skin wall 120, specifically, the back skin wall 110 is provided with a hanging groove 140 penetrating the two side walls 130, the hanging groove 140 is used for hanging the housing 100 on a temple 9100 of an eyeglass 9000, therefore, when the bone conduction earphone 1000 needs to be mounted on the temple 9100 from the side of the back skin wall 110, when the bone conduction earphone 1000 needs to be dismounted, the bone conduction earphone 1000 needs to be dismounted from the temple 9100 from the opposite directions, and the bone conduction earphone 1000 is limited by the head of a user when in use, and the bone conduction earphone 1000 is difficult to be dismounted from the temple 9100 under the condition of not being dismounted, thus the bone conduction earphone 1000 is not influenced by external force when the embodiment of the utility model is provided from the temple 9100.

It should be understood that the foregoing embodiments are merely illustrative of the technical solutions of the present utility model, and not limiting thereof, and that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art; all such modifications and substitutions are intended to be included within the scope of this disclosure as defined in the following claims.

Claims (10)

1. A bone conduction headset for mounting on a temple of eyeglasses, the bone conduction headset characterized by comprising:

the skin-care device comprises a shell, a pair of glasses leg and a pair of glasses leg, wherein the shell is provided with a skin-back wall, a skin-near wall and two side walls, the skin-back wall and the skin-near wall are arranged in a back-to-back mode, the two side walls are respectively connected to two sides of the skin-back wall and the skin-near wall, the skin-back wall is provided with a hanging groove penetrating through the two side walls, and the hanging groove is used for hanging the shell on the glasses leg;

and the bone conduction module is arranged on the shell, and the output end of the bone conduction module is connected with the skin-approaching wall so as to transmit sound vibration by utilizing the skin-approaching wall.

2. The bone conduction headset of claim 1, wherein the hanging slot comprises:

the first groove section is arranged on the back skin wall and extends towards the direction close to the skin-approaching wall;

the second groove section is communicated with one side of the first groove section, which is close to the skin-approaching wall, and is bent and extended in a direction away from the gravity direction.

3. The bone conduction headset of claim 2, wherein the angle between the direction of extension of the first slot segment and the direction of extension of the second slot segment is an obtuse angle.

4. The bone conduction headset of claim 3, wherein the direction of extension of the second slot segment is disposed at an obtuse angle to the direction of gravity.

5. The bone conduction headset of claim 1, wherein the skin proximal wall is provided with a boss, and the output end of the bone conduction module is connected to the boss, so that the bone conduction module can transmit sound vibration by using the boss.

6. The bone conduction headset of any one of claims 2-4, wherein the groove wall of the second groove section is made of an elastic material.

7. The bone conduction headset of claim 6, wherein a plurality of cleats are provided on a wall of the second channel segment.

8. The bone conduction headset of any one of claims 1-4, wherein the attachment location of the hanging groove to the skin-backing wall is provided with a chamfer.

9. The bone conduction headset of claim 8, wherein the chamfer is a first rounded corner.

10. The bone conduction headset of claim 9, wherein the edge of the housing is provided with a second rounded corner.