CN112653956B

CN112653956B - Earphone box, earphone device, mobile terminal and charging method of wireless earphone

Info

Publication number: CN112653956B
Application number: CN201910964473.6A
Authority: CN
Inventors: 刘绍斌
Original assignee: Guangdong Oppo Mobile Telecommunications Corp Ltd
Current assignee: Guangdong Oppo Mobile Telecommunications Corp Ltd
Priority date: 2019-10-11
Filing date: 2019-10-11
Publication date: 2023-07-14
Anticipated expiration: 2039-10-11
Also published as: CN112653956A

Abstract

The embodiment of the application provides an earphone box, an earphone device, a mobile terminal and a wireless earphone charging method, wherein the earphone box is used for accommodating the wireless earphone and comprises a box body, a first sound receiver and a first processor, and the box body is provided with an accommodating groove for accommodating the wireless earphone; the first sound receiver is arranged on the box body and is used for receiving a first preset sound signal sent by the wireless earphone; the first processor is arranged on the box body and is electrically connected with the first sound receiver, and the first processor is used for judging whether the first sound receiver receives a first preset sound signal sent by the wireless earphone or not; if the first sound receiver receives the first preset sound signal, the wireless earphone is determined to be accommodated in the accommodating groove. According to the embodiment of the application, whether the wireless earphone is contained in the earphone box or not can be detected without arranging an additional sensor on the wireless earphone.

Description

Earphone box, earphone device, mobile terminal and charging method of wireless earphone

Technical Field

The present disclosure relates to the field of electronic technologies, and in particular, to a headset case, a headset device, a mobile terminal, and a method for charging a wireless headset.

Background

With the rapid development of earphone technology, wireless earphone is gaining favor of more and more users because it completely eliminates the inconvenience and trouble of transmission line and is more free to use and carry. The power consumption of the wireless earphone is generally large, an earphone box for storing, protecting and charging the wireless earphone appears in the current market, and the wireless earphone can be stored in the earphone box when not used.

In the related art, a first sensor is generally provided in the earphone and a second sensor is provided in the earphone box, and whether the earphone is housed in the earphone box is determined by communication between the first sensor and the second sensor. However, the earphone itself has limited space, and the provision of the first sensor may take up space of the earphone.

Disclosure of Invention

The embodiment of the application provides an earphone box, an earphone device, a mobile terminal and a wireless earphone charging method, which can detect whether the wireless earphone is contained in the earphone box or not without setting an additional sensor on the wireless earphone.

An embodiment of the present application provides an earphone box for accomodate wireless earphone, earphone box includes:

the box body is provided with a storage groove for storing the wireless earphone;

The first sound receiver is arranged on the box body and is used for receiving a first preset sound signal sent by the wireless earphone; and

the first processor is arranged on the box body and is electrically connected with the first sound receiver, and the first processor is used for:

judging whether the first sound receiver receives a first preset sound signal sent by the wireless earphone or not;

and if the first sound receiver receives the first preset sound signal, determining that the wireless earphone is contained in the containing groove.

The embodiment of the application also provides an earphone device, which comprises:

the wireless earphone is provided with a loudspeaker, and the loudspeaker is used for emitting a first preset sound signal; and

and the earphone box is provided with the wireless earphone which can be accommodated in the earphone box, and the earphone box is the earphone box.

The embodiment of the application also provides a mobile terminal, which comprises a third processor, wherein the third processor is used for:

when the wireless earphone is installed in an earphone box, the connection and disconnection between the mobile terminal and the wireless earphone are controlled, and the earphone box is the earphone box;

And when the wireless earphone is taken out from the earphone box, controlling the mobile terminal to establish connection with the wireless earphone.

when a wireless earphone in the earphone device is installed in an earphone box, controlling the connection and disconnection of the mobile terminal and the wireless earphone, wherein the earphone device is an earphone device as described above;

The embodiment of the application also provides a charging method of the wireless earphone, which is applied to an earphone box, wherein the earphone box comprises:

the first sound receiver is arranged on the box body and is used for receiving a first preset sound signal and a second preset sound signal sent by the wireless earphone; and

the power supply is arranged on the box body and is used for providing electric signals for the wireless earphone;

the method comprises the following steps:

If the first sound receiver receives the first preset sound signal, determining that the wireless earphone is contained in the containing groove, and judging whether the first sound receiver receives a second preset sound signal sent by the wireless earphone or not;

and if the first sound receiver receives the second preset sound signal, controlling the power supply to charge the wireless earphone.

According to the wireless earphone receiving device, the first sound receiver is arranged on the earphone box to receive the first preset sound signal sent by the wireless earphone, whether the wireless earphone is contained in the containing groove is determined by whether the first sound receiver receives the first preset sound signal, and for the prior art, the wireless earphone receiving device can achieve box entering detection of the wireless earphone without additionally arranging other sensors in the wireless earphone.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings that are required to be used in the description of the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained from these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an earphone device according to an embodiment of the present application.

Fig. 2 is a schematic diagram of a first structure of an earphone box in the earphone device shown in fig. 1.

Fig. 3 is a schematic diagram of a second structure of the earphone box in the earphone device shown in fig. 1.

Fig. 4 is a schematic diagram of a third structure of the earphone box in the earphone device shown in fig. 1.

Fig. 5 is a schematic diagram of a fourth structure of the earphone box in the earphone device of fig. 1.

Fig. 6 is a schematic view of a fifth structure of the earphone box in the earphone device of fig. 1.

Fig. 7 is a schematic structural diagram of a wireless earphone in the earphone device shown in fig. 1.

Fig. 8 is a communication application scenario diagram of an earphone box, a wireless earphone and a mobile terminal provided in an embodiment of the present application.

Fig. 9 is a flowchart of a charging method of a wireless headset according to an embodiment of the present application.

Detailed Description

As shown in fig. 1, fig. 1 is a schematic structural diagram of an earphone device according to an embodiment of the present application. The present embodiments provide a headset device such as headset device 10, the headset device 10 may include a headset case such as headset case 20 and a wireless headset such as wireless headset 40, wherein the headset case 20 may be configured as a headset case that houses the wireless headset 40. The wireless headset 40 refers to a very small headset designed to fit directly into the user's ear. The wireless headset 40 may be referred to as an ear-mounted headset or an ear-bud headset, which includes a small-sized headset that fits inside the user's outer ear without being inserted into the ear canal, and an in-ear headset that is inserted into the ear canal itself, sometimes referred to as an ear canal headset. The wireless headset 40 may be a bluetooth headset, which may establish a connection with the mobile terminal through a bluetooth communication signal to transmit sound signals of the mobile terminal. It should be noted that the wireless headset 40 is not limited to a bluetooth headset, but may be any other type of headset.

The wireless headset 40 is provided with a speaker such as the speaker 41, and the speaker 41 can emit sound signals through a sound emitting end such as the sound emitting end 411. The earphone case 20 may be used to receive the sound signal and perform a corresponding operation, such as a case-in detection operation, a case-out detection operation, a charging operation, etc., according to the type of the sound signal.

As shown in fig. 2 and 3, fig. 2 is a first structural schematic view of the earphone box in the earphone device shown in fig. 1, and fig. 3 is a second structural schematic view of the earphone box in the earphone device shown in fig. 1. The earphone pod 20 includes a pod, such as pod 100, and the pod 100 may be formed of plastic, ceramic, fiber composite, other suitable materials, or a combination of any two or more of these materials. The cartridge 100 may be formed using a unitary configuration in which some or all of the cartridge 100 is machined or molded as a single structure, or may be formed using multiple structures (e.g., an inner frame structure, one or more structures forming an outer housing surface, etc.). The case 100 may serve as a carrier for the earphone case 20 and may carry components of the earphone case 20, such as a processor, a power supply, and the like.

The case 100 may be provided with one or more receiving slots 120, and the receiving slots 120 may be used to receive the wireless headset 40. The size and shape of the receiving slot 120 may be designed to match the size and shape of the wireless headset 40. The receiving groove 120 may have a regular shape, such as a cylindrical structure or a rectangular parallelepiped structure, and the receiving groove 120 may have an irregular shape.

For example, the case 100 may be provided with two receiving slots 120, a first receiving slot that may be used to receive one of the pair of wireless headphones 40, such as a left ear headphone, and a second receiving slot that may be used to receive the other of the pair of wireless headphones 40, such as a right ear headphone, respectively. The size and shape of the first storage groove are matched with those of the left ear earphone, and the size and shape of the second storage groove can be matched with those of the right ear earphone.

The earphone case 20 may further include a first sound receiver such as the first sound receiver 200, and the first sound receiver 200 may be used to receive a first preset sound signal emitted from the wireless earphone 40. The first sound receiver 200 may be a microphone or other sound receiving device. The first sound receiver 200 may be provided on the case 100, for example, the first sound receiver 200 may be provided on a surface of the case 100 or provided inside the case 100. For example, the case 100 may be provided with a mounting groove, and the first sound receiver 200 may be disposed in the mounting groove, and then the mounting groove is covered by the mounting plate, so that the first sound receiver 200 is not visible from the outside of the case 100. In some embodiments, when the first sound receiver 200 is disposed inside the box body 100, a sound receiving hole may be formed on the surface of the box body 100, so that a first preset sound signal emitted by the wireless earphone 40 may be transmitted to the first sound receiver 200 through the sound receiving hole, so as to improve the sound receiving effect of the first sound receiver 200.

The earphone case 20 may further include a first processor such as the first processor 300, the first processor 300 being used as a control center of the earphone case 20 to control devices inside the earphone case 20. The first processor 300 may be disposed on the case 100, for example, the first processor 300 may be disposed on a surface of the case 100 or inside the case 100. The first processor 300 is electrically connected to the first sound receiver 200, and the first processor 300 may be configured to determine whether the first sound receiver 200 receives a first preset sound signal, and determine that the wireless headset 40 is received in the receiving slot 120 when the first sound receiver 200 receives the first preset sound signal, so as to implement the box-in detection of the wireless headset 40.

For example, when the user opens the cover of the earphone case 20, the first processor 300 may control the first sound receiver 200 to be in an operating state, and the first sound receiver 200 may be used to receive a preset sound signal, such as a first preset sound signal, emitted from the wireless earphone 40 when in the operating state. The first processor 300 determines the sound signal receiving condition of the first sound receiver 200 to determine whether the first sound receiver 200 receives the first preset sound signal, and performs different operations according to the determination result. The first preset sound signal sent by the wireless headset 40 may be sent automatically by the wireless headset 40, or may be sent by the wireless headset 40 under control of a user, for example, when the wireless headset 40 is connected to the mobile terminal, the user may operate the wireless headset 40 by operating on the mobile terminal.

When the first sound receiver 200 receives the first preset sound signal as a result of the determination, it is determined that the wireless headset 40 has been put into the receiving groove 120. In some embodiments, the first processor 300 may be further configured to control the earphone box 20 to send out a box-in prompt message after determining that the wireless earphone 40 has been placed in the receiving slot 120, so as to indicate to the user that the wireless earphone 40 has been successfully placed in the receiving slot 120. For example, the first processor 300 may control the earphone box 20 to emit a first alert sound for reminding the user that the wireless earphone 40 is placed in the earphone box 20, and after receiving the first alert sound, the user may close the cover of the earphone box 20 to seal the wireless earphone 40 in the box 100.

When the first sound receiver 200 does not receive the first preset sound signal as a result of the determination, there may be various cases. For example, the wireless headset 40 is not placed in the receiving slot 120, or the wireless headset 40 is not placed in the preset position of the receiving slot 120, such as that the left ear headset is placed in the second receiving slot or the sound emitting end 411 of the wireless headset 40 is not placed corresponding to the first sound receiver 200, so that the first sound receiver 200 does not receive the first preset sound signal, or the first sound receiver 200 may be damaged, such that the first preset sound signal cannot be received. The above is merely an example of a case where the first sound receiver 200 does not receive the first preset sound signal, and is not to be construed as limiting the possible case where the first sound receiver 200 does not receive the first preset sound signal.

According to the embodiment of the application, the first sound receiver 200 is arranged on the earphone box 20 to receive the first preset sound signal sent by the wireless earphone 40, whether the wireless earphone 40 is contained in the containing groove 120 is determined by whether the first sound receiver 200 receives the first preset sound signal, and compared with the prior art, the embodiment of the application can realize the box-in detection of the wireless earphone 40 without additionally arranging other sensors in the wireless earphone 40.

In some embodiments, the first processor 300 may control the first sound receiver 200 to switch between an active state and an off state, where the off state refers to a non-active state, such as may be a standby state. The first processor 300 may control the first sound receiver 200 to switch from the operating state to the off state when it is determined that the wireless headset 40 has been put into the receiving groove 120 or when it is determined that the wireless headset 40 has left the receiving groove, so as to save power consumption of the headset case 20.

In some embodiments, to prevent the first preset sound signal from being confused with other sound signals emitted by the wireless headset 40, the wireless headset 40 may encode the first preset sound according to a preset encoding rule before emitting the first preset sound signal, so as to distinguish the first preset sound signal from the other sound signals. The first processor 300 may be further configured to parse the first preset sound signal to determine whether the sound signal received by the first sound receiver 200 is the first preset sound signal. The earphone box 20 may further include a parsing module, such as a digital signal processor (digital signal processor, DSP), for parsing or decoding the sound signal received by the first sound receiver 200.

With continued reference to fig. 2 and 3, the earphone case 20 is further provided with a power source such as a power source 400 for providing an electrical signal, the power source 400 may be provided on the case 100, for example, the power source 400 may be provided on a surface of the case 100, such as a surface of a bottom wall for forming the receiving groove 120, the wireless earphone 40 is provided with a charging port, and when the wireless earphone 40 is placed in the receiving groove 120, the power source 400 may be electrically connected with the charging port and charge the wireless earphone 40 through the charging port. For another example, the power supply 400 may be disposed inside the case 100, for example, the power supply 400 may be disposed in a bottom wall for forming the receiving groove 120 or in a side wall for forming the receiving groove 120, and one or more power supply ports may be disposed on a surface of the case 100 and electrically connected with the charging port through the power supply ports to charge the wireless earphone 40.

The power supply 400 is further electrically connected to the first processor 300, and the first processor 300 can control the power supply 400. The first sound receiver 200 may be further configured to receive a second preset sound signal sent by the wireless headset 40, and the first processor 300 may be further configured to determine whether the first sound receiver 200 receives the second preset sound signal sent by the wireless headset 40; if the first sound receiver 200 receives the second preset sound signal, the power supply 400 is controlled to charge the wireless headset 40.

For example, the first processor 300 may control the first sound receiver 200 to be in an operating state for receiving the second preset sound signal when it is determined that the wireless headset 40 has been put into the receiving groove 120. The second preset sound signal may be used as a prompting signal indicating that the wireless headset 40 is successfully electrically connected to the power supply 400. The first processor 300 obtains the sound signal receiving condition of the first sound receiver 200, determines whether the first sound receiver 200 receives the second preset sound signal, and if it is determined that the first sound receiver 200 receives the second preset sound signal, it indicates that the charging port of the wireless headset 40 is successfully electrically connected to the power supply port of the power supply 400, and at this time, the first processor 300 may control the power supply 400 to output an electrical signal to charge the wireless headset 40. If it is determined that the first sound receiver 200 does not receive the second preset sound signal, the charging operation is not performed.

The first sound receiver 200 may be further configured to receive a third preset sound signal sent by the wireless headset 40, and the first processor 300 may be further configured to determine whether the first sound receiver 200 receives the third preset sound signal sent by the wireless headset 40; if the first sound receiver 200 receives the third preset sound signal, the power supply 400 is controlled to adjust the rate of charging the wireless headset 40.

For example, when the power supply 400 charges the wireless headset 40, to adjust the charging rate of the power supply 400 for the wireless headset 40, the wireless headset 40 may send out a third preset sound signal, which may be sent out automatically for the wireless headset 40, or may be sent out for the user to control the wireless headset 40, for example, when the user needs to use the wireless headset 40 urgently and the electric quantity of the wireless headset 40 is low, the user may control the wireless headset 40 to send out the third preset sound signal, and when the first sound receiver 200 receives the third preset sound signal, the first processor 300 may control the power supply 400 to increase the charging rate of the wireless headset 40 so as to charge the wireless headset 40 quickly.

Of course, when the first sound receiver 200 receives the third preset sound signal, the first processor 300 may also decrease the rate at which the power supply 400 charges the wireless headset 40, or the first processor 300 may also increase the rate at which the power supply 400 charges the wireless headset 40, and then decrease the rate at which the power supply 400 charges the wireless headset 40, or the first processor 300 may first decrease the rate at which the power supply 400 charges the wireless headset 40, and then increase the rate at which the power supply 400 charges the wireless headset 40. For example, the first processor 300 may first reduce the rate at which the power supply 400 charges the wireless headset 40, and determine whether the electrical signal output by the power supply 400 is successfully input into the wireless headset 40, and increase the rate at which the power supply 400 charges the wireless headset 40 when it is determined that the wireless headset 40 can be charged normally. It should be noted that, the charging rate of the wireless headset 40 by the power supply 400 is not limited to this, and may be adjusted according to practical situations, for example, increasing the charging rate, decreasing the charging rate, and then increasing the charging rate.

As shown in fig. 3, the case 100 may also be provided with one or more indicators, such as indicator 500, the indicator 500 may be provided on an outer surface of the case 100, wherein the outer surface refers to a surface of the case 100 that is visible from the outside when viewed from the outside of the case 100. The indicator 500 may be used to indicate the power status of the power supply 400 and/or the wireless headset 40 so that a user may intuitively know the power status of the power supply 400 and/or the wireless headset 40 at the outer surface of the case 100. For example, the case 100 may include three indicators 500, one indicator 500 for indicating the power status of the power supply 400 and two other indicators 500 for indicating the power status of the wireless headset 40. One of the indicators 500 may include a plurality of indicator lights (e.g., four indicator lights), one of which is in a light-up state and the other three of which are in a light-down state when the power of the power supply 400 or the wireless headset 40 is 0% -25%; when the electric quantity of the power supply 400 or the wireless earphone 40 is 25% -50%, two of the four indicator lamps are in a light-on state, and the other two indicator lamps are in a light-off state; when the electric quantity of the power supply 400 or the wireless earphone 40 is 50% -75%, three of the four indicator lights are in a light-on state, and the other indicator lights are in a light-off state; when the power supply 400 or the wireless headset 40 has 75% -100% of the power, all the four indicator lamps are in the lighted state. For another example, an indicator may include only one indicator light, which may display different colors to indicate several different power states of the power supply 400 or the wireless headset 40.

With continued reference to fig. 2, the earphone case 20 may further include a cover, such as cover 600, and the cover 600 may be coupled to the case 100. For example, the cover 600 may be detachably connected to the case. When the user needs to take out the wireless headset 40, the cover 600 is separated from the case 100 so that the wireless headset 40 received in the receiving groove 120 is exposed to the outside, and the user can take out the wireless headset 40 exposed to the outside from the receiving groove 120. When the user needs to hide the wireless headset 40 in the headset case 20, the cover 600 may be connected to the case 100, and the cover 600 may enclose the wireless headset 40 inside the headset case 20.

The cover 600 is provided with a cover sensor such as cover sensor 620, and the cover sensor 620 may be used to detect when the cover 600 is in an open state and when the cover 600 is in a closed state. The cover sensor 620 may be electrically connected with the first processor 300 such that the first processor 300 may receive signals from the cover sensor 620 indicating when the cover 600 is in the open state and when it is in the closed state. For example, the cover sensor 620 may generate and transmit an open signal to the first processor 300 upon detecting when the cover 600 is in the open state. The first processor 300 may be configured to communicate with the wireless headset 40 to trigger the wireless headset 40 to turn on its wireless communication device, such as a bluetooth communication device, when the first processor 300 receives the turn-on signal, so that it may automatically establish a connection with the mobile terminal for use by the user. The cover sensor 620 may generate and transmit a closing signal to the first processor 300 upon detecting when the cover 600 is in a closed state. The first processor 300 may trigger the wireless headset 40 to be turned off when receiving the close signal to save the power of the wireless headset 40. Wherein the lid sensor 620 may be any type of mechanical or electronic switch including, but not limited to, a momentary switch, a capacitive sensor, a magnetic sensor, an optical sensor, or the like.

The first processor 300 may be further configured to determine, when a detection signal (such as the opening signal or the closing signal described above) is received, whether the first sound receiver 200 receives a fourth preset sound signal, and if the first sound receiver 200 does not receive the fourth preset sound signal, determine whether the wireless headset 40 is taken out from the receiving slot 120 according to the number of times the first sound receiver does not receive the fourth preset sound signal.

For example, when the first processor 300 receives the on signal, the first processor 300 detects the sound signal received by the first sound receiver 200 during the preset time period, determines whether the sound signal received by the first sound receiver 200 during the preset time period is a fourth preset sound signal, and when the determination result is that the fourth preset sound signal is not received by the first sound receiver 200, the first processor 300 may further determine whether the number of times the fourth preset sound signal is not received by the first sound receiver 200 is greater than a preset number of times, and if the number of times the fourth preset sound signal is not received by the first sound receiver 200 is greater than the preset number of times, determines that the wireless headset 40 has been taken out of the receiving slot 120, and if the number of times the fourth preset sound signal is not received by the first sound receiver 200 is less than or equal to the preset number of times, determines that the wireless headset 40 has not been taken out of the receiving slot 120. For example, the wireless headset 40 may intermittently emit a fourth predetermined sound signal within a predetermined time, and when the first sound receiver 200 exceeds a predetermined number of times (e.g., three times), it is determined that the wireless headset 40 has left the receiving slot 120. By the embodiment of the application, the box-out detection of the wireless earphone 40 can be realized.

As shown in fig. 4, fig. 4 is a schematic view of a third structure of the earphone box in the earphone device shown in fig. 1. The cover 600 of the present embodiment may be rotatably connected with the case 100 so that the cover 600 may be switched between a closed state and an open state, where the open state of the cover 600 refers to a state in which the storage slot 120 is exposed, and the closed state refers to a state in which the storage slot 120 is enclosed in the case 100. It will be appreciated that when the cover 600 is in the closed position, in the closed position of the cover 600 and the case 100, the cover 600 is aligned over the one or more receiving slots 120, thereby enclosing the wireless headset 40 placed within the receiving slots 120 within the case; when the cover 600 is in the opened state, the receiving groove 120 is exposed to the outside so that the user can take out or replace the wireless headset 40 in the receiving groove 120.

The earphone pod 20 may further include one or more second sound receivers such as a second sound receiver 700, the second sound receiver 700 may be configured to receive a preset sound signal, such as a second sound receiver may be configured to receive a first preset sound signal, a second preset sound signal, a third preset sound signal, and/or a fourth preset sound signal. The second sound receiver 700 is spaced apart from the first sound receiver 200, the second sound receiver 700 is electrically connected to the first processor 300, and the first processor 300 can control the second sound receiver 700 to be in an operating state or an off state.

The first processor 300 may be configured to activate one or more second sound receivers 700 to receive the first preset sound signal in conjunction with the first sound receiver 200 when the first sound receiver 200 does not receive the first preset sound signal. The first processor 300 may also be configured to turn off the first sound receiver 200 and activate one or more of the second sound receivers 700 to receive the first preset sound signal when the first sound receiver 200 does not receive the first preset sound signal.

For example, the first sound receiver 200 may send an instruction to the first processor 300 that the first preset sound signal is not received when the first preset sound signal is not received, and the first processor 300 may control one or more second sound receivers 700 to be activated when the first processor 300 receives the instruction that the first preset sound signal is not received, and the second sound receiver 700 may receive the first preset sound signal after being activated. By starting other sound receivers to receive the first preset sound signal, the embodiment of the present application prevents the situation that the first sound receiver 200 cannot receive the first preset sound signal because the sound transmitting end 411 of the wireless headset 40 is not placed corresponding to the first sound receiver 200. For another example, the first processor 300 may also control the second sound receiver 700 to be started when any instruction of the first sound receiver 200 is not received within a preset time period, so as to prevent the first sound receiver 200 from being damaged, which results in that the first preset sound signal cannot be received, and the instruction cannot be sent to the first processor 300. Of course, the first processor 300 may also control the first sound receiver 200 to be in the off state when the second sound receiver 700 is started, so as to prevent the first sound receiver 200 from being in the working state all the time and consuming the power of the power source 400, and prolong the power use time of the power source 400.

As shown in fig. 5, fig. 5 is a schematic view of a fourth structure of the earphone box in the earphone device shown in fig. 1. The earphone case 20 may further include a rotating member such as the rotating member 810 and a first driving mechanism such as the first driving mechanism 910, the rotating member 810 being disposed in the receiving groove 120, for example, the rotating member 810 may be disposed on a bottom wall for forming the receiving groove 120. The rotating member 810 is rotatably connected to the case 100, for example, the rotating member 810 may be rotatably connected to the case 100 through a first connecting member, and the first driving mechanism 910 may drive the rotating member 810 to rotate around the first connecting member, so that the wireless earphone 40 placed in the receiving slot 120 follows the rotating member 810 to rotate. The first driving mechanism 910 is further electrically connected to the first processor 300, and the first processor 300 can be used to control the first driving structure 810 to drive the rotating member 810 to rotate.

The rotator 810 is provided with a positioning structure that can be used to position whether the sound emitting end 411 of the wireless headset 40 corresponds to the first sound receiver 200, the positioning structure can be a mechanical structure or an electronic structure, such as a positioning post formed on the rotator 810, and the positioning structure can be a sensor, such as an optical sensor, which can be used to emit an optical signal. The first processor 300 may be further configured to detect whether the positioning structure is located at a preset position when the wireless headset 40 is received in the receiving slot 120 and the first sound receiver 200 does not receive the first preset sound signal; if the positioning structure is not located at the preset position, the first driving mechanism 910 is controlled to drive the rotating member 810 to rotate so as to rotate the positioning structure to the preset position, and further the sound emitting end 411 of the wireless headset 40 corresponds to the first sound receiver 200.

For example, the earphone box 20 may be provided with a detector electrically connected to the first processor 300, the detector may be configured to detect whether the positioning structure is located at a preset position, and when the detector detects that the positioning structure is not located at the preset position, a first instruction may be sent to the first processor 300, and after the first processor 300 receives the first instruction, the first driving mechanism 910 is controlled to drive the rotating member 810 to rotate to the preset position. For example, during the rotation of the first driving mechanism 910, the detector may detect the position of the positioning structure in real time, and when detecting that the positioning structure has rotated to the preset position, the detector may send a second instruction to the first processor 300, and after the first processor 300 receives the second instruction, control the first driving mechanism 910 to stop working so as to stop the rotation of the rotating member 810. At this time, the positioning structure is located at the preset position, and the sound receiving end of the wireless headset 40 corresponds to the first sound receiver 200, so as to reduce the distance between the sound receiving end of the wireless headset 40 and the first sound receiver 200, and improve the accuracy of detecting the wireless headset 40.

The first processor 300 may further control the first driving mechanism 910 to drive the rotating member 810 to rotate when the positioning structure is located at the preset position and the first sound receiver 200 still does not receive the first preset sound signal, so that the positioning structure is located at other preset positions, and the sound emitting end 411 of the wireless headset 40 corresponds to other sound receivers such as the second sound receiver 700.

As shown in fig. 6, fig. 6 is a schematic view of a fifth structure of the earphone box in the earphone device shown in fig. 1. The earphone case 20 in the above-mentioned application embodiment may also be provided with no rotating member 810 and no first driving mechanism 910, alternatively, the earphone case 20 may be provided with a moving member 820 and a second driving mechanism 920, the moving member 820 may be disposed on the case 100 and movably connected with the case 100, the first sound receiver 200 is disposed on the moving member 820, and the second driving mechanism 920 may be used to drive the moving member 820 to rotate so as to change the position of the first sound receiver 200 on the case 100. For example, the case 100 may be provided with a sliding groove, the sliding groove may be surrounded around the storage groove 120, the moving member 820 may be movably connected with the sliding groove, the second driving mechanism 920 may drive the moving member 820 to move in the sliding groove, and change the position of the moving member 820 in the sliding groove, and further change the position of the first sound receiver 200 on the case 100, so that the first sound receiver 200 corresponds to the sound emitting end 411 of the wireless earphone 40.

The second driving mechanism 920 is electrically connected to the first processor 300, and the first processor 300 is further configured to control the second driving mechanism 920 to drive the moving member 820 to move so that the first sound receiver 200 corresponds to the sound emitting end 411 of the wireless headset 40 when the wireless headset 40 is received in the receiving slot 120 and the first sound receiver 200 does not receive the first preset sound signal.

For example, when the wireless earphone 40 is received in the receiving slot 120 and the first sound receiver 200 does not receive the first preset sound signal, an instruction that the first preset sound signal is not received may be sent to the first processor 300, after the first processor 300 receives the instruction sent by the first sound receiver 200, the second driving mechanism 920 is controlled to drive the moving member 820 to move, so that the position of the first sound receiver 200 is changed, the first sound receiver 200 searches for the first preset sound signal in real time during the position change, and when the first sound receiver 200 receives the first preset sound signal, an instruction that the first preset sound signal is received is sent to the first processor 300, and after the first processor 300 receives the instruction that the first preset sound signal is received, the second driving mechanism 920 is controlled to stop working, so that the moving member 820 stops moving.

In some embodiments, during the process that the moving member 820 moves from the initial moving position and returns to the initial moving position, the first sound receiver 200 still does not receive the first preset sound signal, the first sound receiver 200 may send an instruction to the first processor 300 that the first preset sound signal cannot be received, after receiving the related instruction by the first processor 300, the first sound receiver 200 may be controlled to be turned off, and the second sound receiver 700 is started to receive the first preset sound signal, if the second sound receiver 700 cannot receive the first preset sound signal all the time, the first processor 300 may send a fault indication message to indicate that the first sound receiver 200 or the second sound receiver 700 may have a fault. It should be noted that, the prompting function of the fault prompting information is not limited thereto, and for example, the fault prompting information may also be used to prompt that the wireless earphone 40 may have a fault, so that the first preset sound signal cannot be emitted.

Referring to fig. 1, fig. 3, and fig. 7, fig. 7 is a schematic structural diagram of a wireless earphone in the earphone device shown in fig. 1. The earphone case 20 may further include a first wireless communication module such as the first wireless communication module 1000, and the first wireless communication module 1000 may be a close range communication module such as a bluetooth communication module or a wireless fidelity communication module. The earphone box 20 may establish a connection with the wireless earphone 40 through the first wireless communication module 1000, so as to implement communication between the earphone box 20 and the wireless earphone 40, and the earphone box 20 may also communicate with other electronic devices through the first wireless communication module, and send the current state of the earphone box 20 or the wireless earphone 40 to the other electronic devices. For example, the earphone box 20 may establish communication with an electronic device such as a smart phone, and send the current power condition of the earphone box 20 to the smart phone (for example, may send that the current power of the earphone box 20 is low or the current power is sufficient, etc.); when the wireless headset 40 is placed in the headset box 20 for charging, the headset box 20 may also send the current charging status of the wireless headset 40 to the smart phone (e.g., may send that the current power of the wireless headset 40 is less than 25% or that the current power is 100%, etc.).

The wireless headset 40 may further include a second processor, such as a second processor 42, and the speaker 41 is electrically connected to the second processor 42, where the second processor 42 may control the speaker 41 to emit different types of preset sound signals under different conditions.

For example, when the wireless headset 40 is received in the receiving slot 120, the second processor 42 controls the speaker 41 to emit a first preset sound signal, which may be transmitted outward through the sound emitting end 411, so that the first preset sound signal may be transmitted into a sound receiver of the headset case 20, such as the first sound receiver 200 or the second sound receiver 700.

When the wireless headset 40 leaves the receiving slot 120, the second processor 42 may control the speaker 41 to intermittently emit the fourth preset sound signal, for example, the second processor 42 may control the speaker 41 to intermittently emit the fourth preset sound signal in a preset time period, and when the number of times the first sound receiver 200 does not receive the fourth preset sound signal exceeds the preset number of times, it is determined that the wireless headset 40 is taken out of the receiving slot 120, and the method for detecting the output of the headset case 20 is specifically described above and will not be described herein.

When the power of the wireless headset 40 is too low or the charging port of the wireless headset 40 is electrically connected to the power supply port of the headset box 20, the second processor 42 may control the wireless headset 40 to emit a second preset sound signal to trigger the headset box 20 to charge the wireless headset 40. When the wireless headset 40 needs to increase or decrease the charging rate of the headset box 20 for charging the wireless headset 40, the second processor 42 can control the wireless headset 40 to emit a third preset sound signal, and after the headset box 20 receives the third preset sound signal, the charging rate can be adjusted accordingly according to the actual situation.

The second processor 42 may be further configured to control the speaker 41 to adjust the intensity of the first preset sound signal when the first sound receiver 200 does not receive the first preset sound signal. For example, when the first sound receiver 200 does not receive the first preset sound signal, the first sound receiver 200 sends, to the wireless headset 40, information that the first sound receiver 200 does not receive the first preset sound signal through communication between the wireless headset 40 and the headset case 20 (for example, the headset case 20 communicates with the wireless headset 40 through the first wireless communication module 1000), and the second processor 42 may perform a corresponding operation, such as increasing the intensity of the first preset sound signal sent by the speaker 41 and increasing the loudness of the first preset sound signal, when the information is received.

When the wireless earphone 40 is worn in the ear of the user to play other sound signals, such as music or video, if the wireless earphone 40 emits a preset sound signal (such as the first preset sound signal or the second preset sound signal), the playing of the other sound signals will be interfered, so as to affect the listening experience of the user.

With continued reference to fig. 7, the wireless headset 40 may further include a wear detector such as wear detector 43, where the wear detector 43 may be used to detect whether the wireless headset 40 is in a worn state, which refers to a state in which the wireless headset 40 is worn in a user's ear. The wear detector 43 may be a capacitive detector or a light sensitive detector (such as a proximity sensor).

The wearing detector 43 is electrically connected to the second processor 42 to obtain detection information of the wearing detector 43, and the second processor 42 is configured to control the speaker 41 to emit a preset sound signal (e.g., a first preset sound signal) according to a preset condition when the wireless headset 40 is in an unworn state or in an unworn state, where the preset condition refers to any one of the above conditions. For example, when the user wears the wireless headset 40 on the ear, the wearing detector 43 detects that the wireless headset 40 is in the wearing state, then sends a first detection instruction to the second processor 42, where the first detection instruction is an instruction that the wireless headset 40 is in the wearing state, and after receiving the first detection instruction, the second processor 42 controls the speaker 41 not to send any preset sound signal; when the user does not wear the wireless headset 40 on the ear, the wear detector 43 detects that the wireless headset is not in a worn state, and sends a second detection instruction to the second processor 42, where the second detection instruction is an instruction that is not in a worn state, and after the second processor 42 receives the second detection instruction, the speaker 41 may be controlled to send a corresponding preset sound signal (such as a first preset sound signal, a second preset sound signal, a third preset sound signal, or a fourth preset sound signal) under a preset condition.

As shown in fig. 7, the wireless headset 40 is further provided with a third sound receiver, such as the third sound receiver 44, and the third sound receiver 44 may be used to receive sound signals emitted by the user, for example, the third sound receiver 44 may be a microphone, and the user may record sound through the third sound receiver 44 or talk with other users, etc.

Fig. 8 is a communication application scenario diagram of an earphone box, a wireless earphone and a mobile terminal provided in an embodiment of the present application, as shown in fig. 7 and fig. 8. The wireless headset 40 is further provided with a wireless communication module such as a second wireless communication module 45, the second wireless communication module 45 being operable for wireless communication with other devices, e.g. the wireless headset 40 may establish a connection with the first wireless communication module 1000 of the headset case 20 via the second wireless communication module 45, such that the wireless headset 40 and the headset case 20 may communicate or with a mobile terminal such as the mobile terminal 60. The second wireless communication module 45 may be a bluetooth module, a wireless fidelity communication module, or the like. The mobile terminal 60 may be an electronic device such as a smart phone, a tablet computer, a palm computer (PDA, personal Digital Assistant), etc.

The wireless headset 40 may wirelessly communicate with the mobile terminal 60 through the second wireless communication module 45, wherein a wireless communication operation of the wireless headset 40 may be initiated by the headset box 20, and the headset box 20 may indicate whether the wireless headset 40 establishes a connection with the mobile terminal 60 according to a state of the wireless headset 40. For example, in the case where the first wireless communication module 1000 of the earphone box 20 and the second wireless communication module 45 of the wireless earphone 40 establish a communication connection, when the wireless earphone 40 is taken out from the earphone box 20, the earphone box 20 may send an instruction for establishing the communication connection between the wireless earphone 40 and the mobile terminal 60 to the second processor 42, and after receiving the instruction, the second processor 42 controls the second wireless communication module 45 to be in an operating state and initiates a wireless pairing to the mobile terminal 60, and after receiving the wireless pairing, the mobile terminal 60 may establish a wireless communication connection with the wireless earphone 40, so as to implement wireless communication between the mobile terminal 60 and the wireless earphone 40, and further implement a function of answering a phone call or listening to music of the mobile terminal 60 through the wireless earphone 40. When the wireless headset 40 is installed in the headset box 20, the headset box 20 may send an instruction to disconnect the communication between the wireless headset 40 and the mobile terminal 60 to the second processor 42, and after receiving the instruction, the second processor 42 controls the second wireless communication module 45 to be in a closed state to disconnect the wireless headset 40 and the mobile terminal 60, so as to save power consumption of the wireless headset 40.

In other embodiments, the connection state between the mobile terminal 60 and the wireless headset 40 may alternatively be operated by the mobile terminal 60. For example, the mobile terminal 60 may include a third processor that may be used to operate the wireless connection state of the mobile terminal 60. For example, in the case where the mobile terminal 60 establishes a communication connection with the first wireless communication module 1000 of the earphone box 20 or the second wireless communication module 45 of the wireless earphone 40, when the wireless earphone 40 is installed in the earphone box 20, the wireless earphone 40 or the earphone box 20 may send an instruction that the wireless earphone 40 is already in the box to the third processor, and after receiving the instruction that the wireless earphone 40 is already in the box, the third processor controls the mobile terminal 60 to disconnect from the wireless earphone 40, for example, directly disconnect the mobile terminal 60 from the wireless earphone 40 or directly close a wireless connection switch (such as a bluetooth switch) of the mobile terminal 60. When the wireless headset 40 is removed from the headset box 20, the wireless headset 40 or the headset box 20 may send an instruction that the wireless headset 40 has been taken out of the box to the third processor, and after the third processor receives the instruction that the wireless headset 40 has been taken out of the box, the third processor controls the mobile terminal 60 to establish a connection with the wireless headset 40, such as establishing a bluetooth communication connection, and the like.

Fig. 9 is a schematic flow chart of a charging method of a wireless headset according to an embodiment of the present disclosure, as shown in fig. 9. The embodiment of the present application further provides a charging method of a wireless earphone, where the charging method of the wireless earphone is applied to the earphone box 20 shown in any one of fig. 1 to 8, and the structure of the earphone box 20 is as described above and will not be described herein. The charging method of the wireless earphone comprises the following steps:

101, determining whether the first sound receiver receives a first preset sound signal sent by the wireless earphone, where the structure of the wireless earphone is shown in fig. 1 and fig. 7, and will not be described herein.

For example, when the user puts the wireless headset 40 into the headset box 20, the wireless headset 40 emits a first preset sound signal, and when the first sound receiver 200 in the headset box 20 receives the first preset sound signal, an instruction of "having received the first preset sound signal" may be transmitted to the first processor 300, and the instruction of "having received the first preset sound signal" may be used to indicate that the first sound receiver 200 has received the first preset sound signal. The first processor 300 may determine whether the first sound receiver receives the first preset sound signal sent by the wireless earphone according to the instruction of whether to receive the "the first preset sound signal has been received".

102, if the first sound receiver receives the first preset sound signal, determining that the wireless earphone is stored in the storage groove, and judging whether the first sound receiver receives a second preset sound signal sent by the wireless earphone.

For example, when the first sound receiver 200 receives the first preset sound signal, the first sound receiver 200 sends an instruction of "the first preset sound signal has been received" to the first processor 300, and the second processor 300 determines that the wireless headset 40 has been received in the receiving slot 120 after receiving the instruction of "the first preset sound signal has been received". The first processor 300 acquires the sound signal reception condition of the first sound receiver 200 after determining that the wireless headset 40 has been received in the receiving slot 120, and determines whether the first sound receiver 200 receives a second preset sound signal. The second preset sound signal may be used as a prompting signal indicating that the wireless headset 40 is successfully electrically connected to the power supply 400.

103, if the first sound receiver receives the second preset sound signal, controlling the power supply to charge the wireless earphone.

For example, when the first sound receiver 200 receives the second preset sound signal, the first sound receiver 200 sends an instruction of "the second preset sound signal has been received" to the first processor 300, and after the second processor 300 receives the instruction of "the second preset sound signal has been received", it is determined that the wireless headset 40 has been successfully electrically connected to the power supply 400, and controls the power supply 400 to output an electrical signal to charge the wireless headset 40.

In some embodiments, at 103, after controlling the power supply to charge the wireless earphone if the first sound receiver receives the second preset sound signal, the method may further include:

judging whether the first sound receiver receives a third preset sound signal sent by the wireless earphone or not;

and if the first sound receiver receives the third preset sound signal, adjusting the rate of charging the wireless earphone by the power supply.

For example, when the first sound receiver 200 receives the third preset sound signal, the first sound receiver 200 sends an instruction of "the third preset sound signal has been received" to the first processor 300, and the second processor 300 determines to adjust the charging rate of the power supply 400 for charging the wireless headset 40 after receiving the instruction of "the third preset sound signal has been received". For example, the first processor 300 may control the power supply 400 to increase the charge rate of the wireless headset 40 to rapidly charge the wireless headset 40. For another example, the first processor 300 may decrease the rate at which the power supply 400 charges the wireless headset 40, or the first processor 300 may increase the rate at which the power supply 400 charges the wireless headset 40, and decrease the rate at which the power supply 400 charges the wireless headset 40, or the first processor 300 may decrease the rate at which the power supply 400 charges the wireless headset 40, and increase the rate at which the power supply 400 charges the wireless headset 40.

The above describes in detail the earphone box, the earphone device, the mobile terminal and the charging method of the wireless earphone provided in the embodiments of the present application. Specific examples are set forth herein to illustrate the principles and embodiments of the present application, with the description of the examples given above only to assist in understanding the present application. Meanwhile, those skilled in the art will have variations in the specific embodiments and application scope in light of the ideas of the present application, and the present description should not be construed as limiting the present application in view of the above.

Claims

1. An earphone box for receiving a wireless earphone, the earphone box comprising:

2. The earphone pod of claim 1, wherein the first sound receiver is further configured to receive a second preset sound signal emitted by the wireless earphone;

the earphone box is provided with the power that is used for providing the signal of telecommunication, the power with first treater electric connection, first treater still is used for:

judging whether the first sound receiver receives a second preset sound signal sent by the wireless earphone or not;

3. The earphone pod of claim 2, wherein the first sound receiver is further configured to receive a third preset sound signal emitted by the wireless earphone;

the first processor is further configured to:

4. The earphone pod of claim 1, wherein the pod is configured to provide one or more second sound receivers, the second sound receivers being spaced apart from the first sound receiver, the second sound receivers being configured to receive the first predetermined sound signal, the second sound receivers being electrically connected to the first processor, the first processor further configured to:

if the first sound receiver does not receive the first preset sound signal, starting the one or more second sound receivers to receive the first preset sound signal together with the first sound receiver;

or the first processor is further configured to:

if the first sound receiver does not receive the first preset sound signal, the first sound receiver is turned off, and the one or more second sound receivers are turned on to receive the first preset sound signal.

5. The earphone box of claim 1, further comprising a rotating member and a first driving mechanism, wherein the rotating member is provided with a positioning structure for positioning whether the sound emitting end of the wireless earphone corresponds to the first sound receiver, the rotating member is disposed in the receiving slot and is rotatably connected with the box body, the rotating member is electrically connected with the first driving mechanism, and the first driving mechanism is electrically connected with the first processor;

The first processor is further configured to:

when the wireless earphone is accommodated in the accommodating groove and the first sound receiver does not receive the first preset sound signal, detecting whether the positioning structure is positioned at a preset position or not;

if the positioning structure is not located at the preset position, controlling the first driving mechanism to drive the rotating piece to rotate so as to enable the positioning structure to rotate to the preset position;

when the positioning structure rotates to the preset position, the sound emitting end of the wireless earphone corresponds to the first sound receiver.

6. The earphone box of claim 1, further comprising a moving member and a second driving mechanism, wherein the moving member is enclosed around the accommodating groove and is movably connected with the box body, the moving member is connected with the second driving mechanism, the second driving mechanism is electrically connected with the first processor, and the first sound receiver is arranged on the moving member;

the first processor is further configured to:

when the wireless earphone is accommodated in the accommodating groove and the first sound receiver does not receive the first preset sound signal, the second driving mechanism is controlled to drive the moving piece to move so that the first sound receiver corresponds to the sound emitting end of the wireless earphone.

7. The earphone pod of any of claims 1-6, wherein the earphone pod further comprises:

the cover body is connected with the box body and can be switched between a closed state and an open state, the closed state is a state of hiding the wireless earphone in the box body, and the open state is a state of exposing the wireless earphone outside;

the cover sensor is arranged on the cover body and is used for generating a detection signal when the closed state is switched to the open state, and the cover sensor is electrically connected with the first processor;

the first sound receiver is further used for receiving a fourth preset sound signal;

the first processor is configured to:

when the detection signal is received, judging whether the first sound receiver receives the fourth preset sound signal or not;

and if the first sound receiver does not receive the fourth preset sound signal, determining whether the wireless earphone is taken out of the storage groove according to the times that the first sound receiver does not receive the fourth preset sound signal.

8. The earphone box of claim 7, wherein the first preset sound signal is a sound signal formed by encoding according to a preset encoding rule;

The first processor is further configured to parse a first preset sound signal received by the first sound receiver.

9. An earphone device, characterized by comprising:

a headset box in which the wireless headset is receivable, the headset box being as claimed in any one of claims 1 to 8.

10. The earphone device of claim 9, wherein said wireless earphone is provided with a second processor, said second processor being electrically connected to said speaker;

the second processor is used for controlling the loudspeaker to adjust the intensity of the first preset sound signal when the first sound receiver does not receive the first preset sound signal.

11. The earphone device of claim 10, wherein said second processor is further configured to: and when the wireless earphone is taken out from the earphone box, controlling the loudspeaker to emit a fourth preset sound signal at intervals.

12. The earphone device according to claim 10 or 11, wherein the wireless earphone is provided with a wear detector electrically connected to the second processor, the wear detector being configured to detect whether the wireless earphone is in a worn state;

The second processor is used for controlling the loudspeaker to emit a first preset sound signal according to preset conditions when the wireless earphone is not in the wearing state.

13. A mobile terminal comprising a third processor configured to:

controlling the connection and disconnection of the mobile terminal and the wireless earphone when the wireless earphone is installed in an earphone box, wherein the earphone box is an earphone box according to any one of claims 1 to 8;

14. A mobile terminal comprising a third processor configured to:

controlling the connection and disconnection of the mobile terminal and the wireless earphone when the wireless earphone in the earphone device is installed in an earphone box, wherein the earphone device is an earphone device as claimed in any one of claims 9 to 11;

15. A method for charging a wireless earphone, which is applied to an earphone box, characterized in that the earphone box comprises:

the method comprises the following steps:

16. The method for charging a wireless headset of claim 15, wherein the first sound receiving signal is further configured to receive a third preset sound signal sent by the wireless headset;

and if the first sound receiver receives the second preset sound signal, controlling the power supply to charge the wireless earphone, including: