CN116962933A - Bone conduction earphone - Google Patents

Abstract

The application relates to the technical field of bone conduction equipment, in particular to a bone conduction earphone, which comprises a clamping arm, a detection unit, detection pieces and a control board, wherein the clamping arm is firstly worn on the head of a main user, the skull and cheekbone of the main user can eject the two detection pieces in each containing shell by a certain angle, the control board can record relevant data of the main user, when the main user wears the bone conduction earphone by other people, because the protruding degree of the skull and cheekbone of each person is different, the ejected angles of the two detection pieces in the containing shell are different, the control board can control whether a sounding body vibrates according to the data of a detection block, and prevent strangers from wearing privacy of the snoop main user; meanwhile, when no person wears the device, the two detection pieces in the accommodating shell are coplanar, and the control board can also control whether the sounding body vibrates or not, so that the sounding body can be automatically closed when no person wears the device, the electric quantity is saved, and the endurance time is prolonged.

Description

Bone conduction earphone

Technical Field

The application relates to the technical field of bone conduction equipment, in particular to a bone conduction earphone.

Background

The bone conduction earphone converts sound into mechanical vibration with different frequencies, sound waves are transmitted through skull, bone labyrinth, inner ear lymph fluid, a cote device, an auditory nerve and an auditory center of a person, nerve impulse is generated along with the auditory nerve and transmitted to the auditory center, after comprehensive analysis of cerebral cortex, the sound is finally heard, and the problem that the tympanic membrane is damaged due to long-term wearing of the traditional earphone is effectively avoided by the appearance of the bone conduction earphone.

At present, the existing bone conduction earphone does not have the function of wearing detection, and can not automatically stop playing when not worn, so that the power consumption is high. In addition, the existing bone conduction earphone does not have a main user identification function, and can not automatically stop playing when being worn by strangers, so that privacy of the main user is not protected.

Disclosure of Invention

The application provides a bone conduction earphone to solve the problem that the existing bone conduction earphone cannot effectively protect privacy of a main user.

The bone conduction earphone adopts the following technical scheme:

the bone conduction earphone comprises a clamping arm, a detection unit, a detection piece and a control board.

The clamping arm can be worn on the head, the clamping arm is provided with a first end and a second end which are opposite, the first end and the second end of the clamping arm are respectively provided with a containing shell, the side walls of the two containing shells, which are close to each other, are respectively provided with a containing groove, and the openings of the containing grooves are oppositely arranged; each accommodating groove is internally provided with a detection block and two detection pieces, the two detection pieces are rotationally connected with the accommodating shell, in an initial state, the two detection pieces have a first preset angle, when the clamping arm is worn on the head, the accommodating grooves are attached to the cheekbone of a user, and the cheekbone can eject the two detection pieces by an included angle; the detection unit is arranged on the detection pieces and can detect the included angle between the two detection pieces; each detection piece is provided with a sounding body; the control panel can control sounding body vibration according to the data that the detection piece detected.

Further, two rotating shafts are arranged in each accommodating groove, and each rotating shaft is connected with one detection piece; the detecting unit is an internal hollow detecting block, a sensor capable of acquiring the rotation angle of the detecting piece is arranged in the detecting block, and when the detecting piece deflects at different angles in the accommodating shell, the sensor in the detecting block sends out different signals.

Further, each detecting piece is provided with a first elastic piece, and the first elastic pieces are used for maintaining the two detecting pieces to automatically restore to an initial state.

Further, an opening end of the accommodating groove is provided with an anti-collision ring.

Further, a cross-ear arc rod is arranged between each end of the clamping arm and one containing shell.

Further, the arm lock includes two arc poles, connects through adjusting part between the two arc poles, and adjusting part can adjust the opening size of arm lock.

Further, the adjusting assembly comprises an adjusting knob and two hinging blocks, the two hinging blocks are respectively fixedly connected with the arc-shaped rod, and the two hinging blocks are mutually hinged; one of the hinge blocks is provided with a mounting hole, the adjusting knob is in threaded transmission fit with the mounting hole, an adjusting spring is connected between the adjusting knob and the other hinge block, and the adjusting spring is always in a stretching state.

Further, a dust screen is arranged at the opening of the accommodating groove.

Further, a control program is provided on the control board, and the control program includes: defining a reference signal sent by a sensor inside the detection block; if the sensor in the detection block stops sending out signals, stopping the sound generating body from vibrating; if the signal sent by the sensor in the detection block is different from the reference signal, the sounding body stops vibrating.

Further, a power supply is arranged on the clamping arm, and the power supply can provide electric energy for the control panel, the sensor in the detection block and the sounding body.

The beneficial effects of the application are as follows: the application relates to a bone conduction earphone, which comprises a clamping arm, a detection unit, detection pieces and a control board, wherein the clamping arm is firstly worn on the head of a main user, the two detection pieces in each containing shell can be ejected out of an included angle by a skull and cheek bow of the main user, the control board can record relevant data of the main user, when the bone conduction earphone is worn by other people, the angles of the ejected included angles of the two detection pieces in the containing shell are inconsistent as the protruding degree of the skull and cheek bow of each person is different, and the control board can control the vibration of a sounding body according to the data of a detection block so as to prevent strangers from wearing privacy of the main user; meanwhile, when no person wears the device, the two detection pieces in the accommodating shell are restored to the first preset angle, the control board controls the sounding body to stop vibrating, automatic closing can be ensured when no person wears the device, electric quantity is saved, and accordingly the endurance time is prolonged.

Drawings

In order to more clearly illustrate the embodiments of the application or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the application, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a bone conduction headset according to a first embodiment of the present application;

fig. 2 is an exploded view of a bone conduction headset according to a first embodiment of the present application;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is a partial enlarged view at B in FIG. 2;

fig. 5 is a top view of a bone conduction headset according to a first embodiment of the application;

FIG. 6 is a cross-sectional view taken along the direction C-C in FIG. 5;

FIG. 7 is a partial enlarged view at D in FIG. 6;

fig. 8 is a schematic structural diagram of a detecting member, a detecting block and a first spring in a bone conduction headset according to a first embodiment of the present application.

In the figure: 110. a clamp arm; 111. an arc-shaped rod; 120. an adjustment knob; 130. a hinge block; 131. a mounting hole; 140. an adjusting spring; 210. an ear-spanning arc rod; 220. a housing case; 221. a receiving groove; 230. anti-punch rings; 310. a detection block; 320. a detecting member; 330. a rotating shaft; 340. a first spring; 350. placing the hole; 360. a sounding body; 370. and a power supply.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

The numbering of components herein, such as "first," "second," etc., is used merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "coupled" as used herein includes both direct and indirect coupling (coupling), unless otherwise indicated. In the description of the present application, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the present application, unless expressly stated or limited otherwise, a first feature "up" or "down" a second feature may be the first and second features in direct contact, or the first and second features in indirect contact via an intervening medium. Moreover, a first feature "above," "over" and "on" a second feature may be a first feature directly above or obliquely above the second feature, or simply indicate that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

As shown in fig. 1 to 8, the bone conduction headset provided in the first embodiment of the present application includes a clip arm 110, a detection unit, a detection member 320, and a control board.

The clip arm 110 is slightly U-shaped in shape, the clip arm 110 has opposite first and second ends, and the clip arm 110 is capable of being worn on the head. Specifically, the clamping arm 110 includes two arc-shaped rods 111, the two arc-shaped rods 111 are connected through an adjusting assembly, and the adjusting assembly can adjust the opening size of the clamping arm 110. The adjusting assembly comprises an adjusting knob 120 and two hinging blocks 130, the two hinging blocks 130 are respectively and fixedly connected with the arc-shaped rod 111, the two hinging blocks 130 are all in hollowed-out arrangement, the two hinging blocks 130 are mutually hinged, and the two hinging blocks 130 are connected through a hinging shaft. One of them is provided with mounting hole 131 on the articulated piece 130, and the axis of mounting hole 131 sets up perpendicularly with the lateral wall that is close to each other of two articulated pieces 130, and mounting hole 131 inside wall is provided with the screw thread, and adjust knob 120 installs in mounting hole 131, and adjust knob 120 periphery wall is provided with the screw thread, and screw thread on adjust knob 120 can mutually support with the screw thread on the interior periphery wall of mounting hole 131, then when adjust knob 120 rotates, adjust knob 120 can follow the axis direction slip of mounting hole 131. An adjusting spring 140 is connected between the adjusting knob 120 and the other hinge block 130, the adjusting spring 140 is always in a stretched state, and the restoring force of the adjusting spring 140 can pull the arc rods 111 to be close to each other, so that the opening of the U-shaped clamping arm 110 formed by the two arc rods 111 is reduced, and wearing comfort can be improved by rotating the adjusting knob 120 when the novel multifunctional electric bicycle is worn.

Further, the ends of the two arc rods 111 are provided with ear-spanning arc rods 210, each ear-spanning arc rod 210 has an arc opening, and when the clip is worn on the head, the arc opening of the ear-spanning arc rod 210 faces downwards, so that the clip arm 110 is convenient to wear on the head.

The first end and the second end of the clamping arm 110 are respectively provided with a containing shell 220, specifically, the containing shells 220 are vertically arranged, the upper ends of the containing shells 220 are fixedly arranged on the ear-spanning arc rods 210, the two containing shells 220 on the two ear-spanning arc rods 210 are oppositely arranged, the side walls, close to each other, of the two containing shells 220 are provided with containing grooves 221, and the openings of the containing grooves 221 are oppositely arranged. The open end of each receiving groove 221 is provided with a tamper ring 230, and the tamper ring 230 is used to improve wearing comfort when the receiving case 220 contacts the skin, and the tamper ring 230 is made of flexible rubber. The opening of the accommodation groove 221 is provided with a dust screen, which can block impurities from entering the accommodation groove 221.

Each of the receiving grooves 221 is provided therein with a sensing block 310 and two sensing pieces 320, and the two sensing pieces 320 are rotatably connected with the receiving case 220 such that the two sensing pieces 320 can rotate in the receiving groove 221. Specifically, two rotating shafts 330 are disposed in each accommodating groove 221, each rotating shaft 330 is disposed horizontally, two rotating shafts 330 in the same accommodating groove 221 are in the same vertical plane, each rotating shaft 330 is connected with one detecting piece 320, and it is ensured that the two detecting pieces 320 can rotate in the accommodating groove 221. In the initial state, the arm lock 110 is not worn on the head, a first preset angle is formed between the two detecting pieces 320, the first preset angle can be 170 degrees or 180 degrees, the two detecting pieces 320 can seal the opening of the accommodating groove 221, when the arm lock 110 is worn on the head, the accommodating groove 221 is attached to the cheekbone arch of the head of a user, the cheekbone arch can eject the two detecting pieces 320 to form an included angle, the protruding degrees of the cheekbone arch of each person are different, and then the angle of the two detecting pieces 320 ejected by the cheekbone arch of the head of each person is different. Specifically, each detecting element 320 is provided with a first elastic element, and the first elastic element is used for maintaining the two detecting elements 320 to automatically restore to an initial state. Further, the first elastic member is a first spring 340, where the first spring 340 is located at an end of the detecting member 320, the rotating shaft 330 is located at a middle of the detecting member 320, and in an initial state, the arm lock 110 is not worn on the head, the first spring 340 is in an original length state, and a length of the first spring 340 is equal to a distance between the middle of the detecting member 320 and an end of the accommodating groove 221, so as to ensure that an included angle between two detecting members 320 in the same accommodating groove 221 is located at a first preset angle in the initial state. Each detecting member 320 is provided with a placement hole 350, and each placement hole 350 is internally provided with a sounding body 360, the sounding body 360 can vibrate, and the vibration of the sounding body 360 can be transmitted to the cochlea through the zygomatic arch of the skull, so that a wearer can hear the sound.

The detection unit is a hollow detection block 310, the detection block 310 is arranged on the detection piece 320, and the detection block 310 can detect an included angle between the two detection pieces 320. Specifically, the detecting block 310 is hollow, the detecting block 310 is internally provided with a sensor capable of acquiring a rotation angle of the detecting element 320, when the detecting element 320 deflects at different angles in the accommodating case 220, the sensor in the detecting block 310 sends different signals, wherein the sensor in the detecting block 310 is an angular displacement type capacitive sensor, a capacitor is arranged in the angular displacement type capacitive sensor, a polar plate of the capacitor is in a fan shape, and when the detecting element 320 rotates, one polar plate of the capacitor in the angular displacement type capacitive sensor synchronously rotates, so that the opposite areas of two polar plates of the capacitor in the angular displacement type capacitive sensor are changed, and the capacitance of the capacitor in the angular displacement type capacitive sensor is changed, wherein the formula: c=εs/d, where C is the capacitance of the capacitor; epsilon is the dielectric constant, S is the facing area of the two plates in the capacitor, and d is the distance between the two plates in the capacitor.

The control panel is fixed to be set up on arbitrary one detection piece 320, and the control panel can control sounding body 360 vibration according to the data of detecting block 310, is provided with control program on the control panel, and wherein control program includes: defining a reference signal emitted by a sensor inside the detection block 310; if the sensor inside the detection block 310 stops sending out a signal, the sounding body 360 stops vibrating; if the signal from the sensor in the detection block 310 is different from the reference signal, the vibration of the sounding body 360 is stopped. The reference signal is the capacitance transferred to the control board by the angular displacement type capacitive sensor when the main user wears the sensor. The stop of the signal from the angular displacement type capacitive sensor in the detecting block 310 means that the opposite areas of the two polar plates of the capacitor are at the maximum value, and the capacitance at this time is at the maximum value, which indicates that the included angle between the two detecting members 320 is at the first preset angle, and at this time, the detecting member is in a state of being worn by no person, and the sounding body 360 stops vibrating. The fact that the signal sent by the sensor inside the detection block 310 is different from the reference signal means that the user wearing the sound generating body 360 is not the same person as the main user, so that privacy of the main user is ensured, and the control panel controls the sound generating body 360 to stop vibrating.

In this embodiment, the power supply 370 is disposed on the arm 110, and the power supply 370 can provide power for the control board, the sensor in the detection block 310, and the sounding body 360.

In combination with the above embodiments, the working procedure of the bone conduction earphone provided by the embodiment of the present application is as follows:

when the device works, a main user wears the device on the head, the cheekbone arches of the head of the main user ejects the two detection pieces 320 in each containing groove 221 to form an included angle, at the moment, the two detection pieces 320 deflect at a certain angle around the rotating shaft 330, one polar plate of a capacitor in the angular displacement type capacitive sensor arranged in the detection block 310 is driven to synchronously rotate, so that the opposite areas of the two polar plates of the capacitor in the angular displacement type capacitive sensor are changed, the capacitance of the capacitor in the angular displacement type capacitive sensor is changed, data are transmitted to a control board after the capacitance of the capacitor in the angular displacement type capacitive sensor is stable, and the control board records the data at the moment and defines the data as a reference signal.

When a stranger wears, the protruding size of the cheekbone arch of the head of the stranger is inconsistent with the protruding size of the cheekbone arch of the head of the main user, so that the cheekbone arch of the head of the stranger ejects the two detection pieces 320 out of the included angle, at the moment, the included angle between the two detection pieces 320 is inconsistent with the included angle of the main user during wearing, a certain gap exists between the capacitance size sent by the angular displacement type capacitive sensor and the reference signal, and the control board can control the sounding body 360 to stop vibrating so as to prevent the privacy of the main user from being leaked.

When no one wears, because all be provided with first spring 340 on every detection piece 320, first spring 340 can be located the contained angle between two detection pieces 320 and is in first default angle, then the just right area of two polar plates in the condenser is in the maximum value this moment, and the electric capacity size that angular displacement type capacitive sensor sent is in the maximum value this moment, after angular displacement type capacitive sensor's electric capacity size transmission to the control panel, control panel control sounding body 360 stops the vibration, avoids the waste of electric energy to increase whole duration.

The bone conduction headset provided in the second embodiment of the present application is different from the above embodiment in that: the sensor for acquiring the rotation angle of the detection piece in the detection block can also be a gyroscope, the gyroscope is arranged at the joint of the rotating shaft and the detection piece, when a main user wears the sensor, the detection piece rotates by a certain angle, the gyroscope acquires the rotation degree of the detection piece relative to the rotating shaft, and therefore an included angle between the two detection pieces is acquired, and at the moment, the data of the gyroscope are reference signals. When the detection piece is worn by an unmanned person, the detection piece does not rotate, or the detection piece reversely rotates by a certain angle after being worn or is taken down, and the gyroscope acquires the rotating degree of the detection piece relative to the rotating shaft. When the stranger wears the device, the rotation degree of the detection piece relative to the rotating shaft is inconsistent with the rotation degree of the detection piece relative to the rotating shaft, corresponding to the reference signal.

The bone conduction headset provided in the third embodiment of the present application is different from the above embodiment in that: the detecting member can be a plate-like structure, and the angle between the two detecting members is the angle between the two plates.

The bone conduction headset provided in the third embodiment of the present application is different from the above embodiment in that: the detecting member can be a plate-like structure, and the angle between the two detecting members is the angle between the two plates.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the application.

Claims (10)

1. A bone conduction headset, characterized in that: comprising the following steps:

the clamping arm can be worn on the head, the clamping arm is provided with a first end and a second end which are opposite, the first end and the second end of the clamping arm are respectively provided with a containing shell, the side walls of the two containing shells, which are close to each other, are respectively provided with a containing groove, and the openings of the containing grooves are oppositely arranged;

each accommodating groove is internally provided with a detection unit and two detection pieces, the two detection pieces are rotationally connected with the accommodating shell, in an initial state, the two detection pieces have a first preset angle, when the clamping arm is worn on the head, the accommodating grooves are attached to the cheekbone of a user, and the cheekbone can eject the two detection pieces by an included angle; the detection unit is arranged on the detection pieces and can detect the included angle between the two detection pieces; each detection piece is provided with a sounding body;

and the control panel can control the vibration of the sounding body according to the data detected by the detection block.

2. The bone conduction headset of claim 1, wherein: two rotating shafts are arranged in each accommodating groove, and each rotating shaft is connected with one detection piece; the detecting unit is an internal hollow detecting block, a sensor capable of acquiring the rotation angle of the detecting piece is arranged in the detecting block, and when the detecting piece deflects at different angles in the accommodating shell, the sensor in the detecting block sends out different signals.

3. The bone conduction headset of claim 1, wherein: each detection piece is provided with a first elastic piece, and the first elastic piece is used for maintaining the two detection pieces to automatically restore to an initial state.

4. The bone conduction headset of claim 1, wherein: the open end of the holding groove is provided with an anti-punch ring.

5. The bone conduction headset of claim 1, wherein: an ear-spanning arc rod is arranged between each end part of the clamping arm and one containing shell.

6. The bone conduction headset of claim 1, wherein: the arm lock includes two arc poles, connects through adjusting part between two arc poles, and adjusting part can adjust the opening size of arm lock.

7. The bone conduction headset of claim 6, wherein: the adjusting component comprises an adjusting knob and two hinging blocks, the two hinging blocks are respectively fixedly connected with the arc-shaped rod, and the two hinging blocks are mutually hinged; one of the hinge blocks is provided with a mounting hole, the adjusting knob is in threaded transmission fit with the mounting hole, an adjusting spring is connected between the adjusting knob and the other hinge block, and the adjusting spring is always in a stretching state.

8. The bone conduction headset of claim 1, wherein: the opening of the accommodating groove is provided with a dust screen.

9. The bone conduction headset of claim 2, wherein: the control panel is provided with a control program, and the control program comprises: defining a reference signal sent by a sensor inside the detection block; if the sensor in the detection block stops sending out signals, stopping the sound generating body from vibrating; if the signal sent by the sensor in the detection block is different from the reference signal, the sounding body stops vibrating.

10. The bone conduction headset of claim 2, wherein: be provided with the power on the arm lock, the power can provide the electric energy for control panel, sensor and the sounding body in the detection piece.