CN114631676B - Storage device and electronic device - Google Patents

Abstract

The application provides a storage device and electronic equipment, wherein the storage device comprises a shell, a first bin body, a second bin body and a driving assembly, wherein the driving assembly is arranged in the shell and used for driving the first bin body and the second bin body to move, and particularly, the first bin body is provided with a first accommodating groove, and the second bin body is provided with a second accommodating groove; the driving component can drive the first bin body and the second bin body to move to be close to each other and far away from each other. When the two chambers are close to each other, the first accommodating groove on the first chamber body and the second accommodating groove on the second chamber body are matched with each other, and the two chambers are buckled together to form a single accommodating chamber. When the first accommodation groove and the second accommodation groove are separated from each other.

Description

Storage device and electronic device

Technical Field

The application belongs to the technical field of electronic equipment, and particularly relates to a storage device and electronic equipment.

Background

In the related art, the earphone bin of the wireless bluetooth earphone is usually in an inserting earphone bin of the earphone separation of the left ear and the right ear, and the earphone of the left ear and the right ear and the respective earphone bin are in one-to-one correspondence, if the wrong insertion occurs, the earphone bin needs to be pulled out and replaced to be reinserted in another earphone bin, and the operation is repeated in this way, so that the storage side wall of the earphone bin is also scratched by redundant when the working efficiency and the user experience are influenced, and the service life of the wireless bluetooth earphone is influenced.

Disclosure of Invention

The application aims to provide a storage device and electronic equipment, and one of the technical problems that when the storage device is used for storing earphones, the left ear and the right ear are easy to be reversely assembled in the related art can be solved.

In order to solve the technical problems, the application is realized as follows:

in a first aspect, the present application provides a storage device comprising:

a housing;

the first bin body comprises a first accommodating groove;

the second bin body comprises a second accommodating groove;

the driving assembly is arranged on the shell and used for driving the first bin body and the second bin body to move relatively so that the first accommodating groove and the second accommodating groove are matched to form a single accommodating cavity or the first accommodating groove and the second accommodating groove are separated.

In a second aspect, the present application provides an electronic device, comprising:

an earphone;

the storage device as set forth in the first aspect.

In the embodiment of the application, storage device includes casing, first storehouse body, the second storehouse body and drive assembly, and drive assembly sets up in the casing to, drive assembly is used for driving the motion of first storehouse body and the second storehouse body, specifically, has first holding tank on the first storehouse body, has the second holding tank on the second storehouse body, and drive assembly can drive the motion of first storehouse body and second storehouse body to be close to mutually and keep away from mutually.

When being close to each other, the first holding groove on the first bin body and the second holding groove on the second bin body are mutually matched, and the first holding groove and the second holding groove are buckled together to form a single holding cavity.

When keeping away from mutually, first holding tank and second holding tank separation, and then first holding tank and second holding tank can place an earphone respectively, specifically, after placing an earphone in storage device, drive assembly can drive first storehouse body and second storehouse body motion to keep away from mutually to first holding tank and second holding tank separation form two storage locations, thereby can place another earphone in storage device.

As above, this application is through the drive assembly to the drive of the first storehouse body and the second storehouse body for whole storage device can appear having the state of a storage position and two storage positions, and then when accomodating the earphone, only one storage position has reduced left ear earphone and right ear earphone misplaced the possibility of position, realizes blind effect, has reduced storage device and earphone and has received frictional influence, has promoted earphone and storage device's life.

Additional aspects and advantages of the application will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the application.

Drawings

The foregoing and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, wherein:

FIG. 1 illustrates a schematic view of a receiving device provided in one embodiment of the present application;

FIG. 2 shows an exploded view of a first cartridge, a first guard, and a first power element in a storage device according to one embodiment of the present disclosure;

FIG. 3 illustrates an exploded view of a second cartridge, a second protective member, and a second power member in a receiving device provided in one embodiment of the present application;

FIG. 4 shows a cross-sectional view of a second drive mechanism and a second cartridge in a receiving device provided in one embodiment of the present application;

FIG. 5 is a schematic view showing the first receiving groove and the second receiving groove of the receiving device according to one embodiment of the present application;

FIG. 6 shows a cross-sectional view of the receiving device A-A shown in FIG. 5;

FIG. 7 is a schematic view showing the first receiving groove and the second receiving groove of the receiving device according to one embodiment of the present application;

FIG. 8 is a schematic view showing the receiving device provided in one embodiment of the present application in a first receiving slot and a second receiving slot mated and the earphone mated;

fig. 9 is a schematic view showing that the accommodating device provided in one embodiment of the present application cooperates with the first main body of the earphone in the case that the first accommodating groove and the second accommodating groove cooperate, and the first bin is located at an edge side;

FIG. 10 is a schematic view showing the storage device provided in one embodiment of the present application cooperating with the first body of the earphone in a situation where the first receiving slot and the second receiving slot cooperate, and the first driving mechanism and the first moving mechanism are both on the side, and the first protection member and the first mounting slot form a first receiving cavity;

FIG. 11 is a schematic view showing a storage device provided in an embodiment of the present application cooperating with a first body of an earphone in a situation where a first receiving groove and a second receiving groove cooperate, and a first driving mechanism and a first moving mechanism are both on an edge side, and a first protection member and a first mounting groove form a first receiving cavity, and a second protection member and a second mounting groove form a second receiving cavity;

FIG. 12 is a schematic view showing a receiving device provided in an embodiment of the present application being mated with an earphone in a case where a first receiving groove and a second receiving groove are separated, and a first protecting member and a first mounting groove form a first receiving cavity, and a second protecting member and a second mounting groove form a second receiving cavity;

FIG. 13 is a schematic view showing a storage device provided in an embodiment of the present application cooperating with a second body of an earphone in a situation where a first receiving groove and a second receiving groove cooperate, and a first driving mechanism and a first moving mechanism are both on an edge side, and a first protection member and a first mounting groove form a first receiving cavity, and a second protection member and a second mounting groove form a second receiving cavity;

FIG. 14 is a schematic view of a first positioning assembly of a housing device according to an embodiment of the present disclosure mated with a first body of an earphone;

FIG. 15 is a schematic view of a second positioning assembly in a receiving device according to an embodiment of the present disclosure mated with a second body of an earphone;

FIG. 16 shows a schematic diagram of an electronic device provided in one embodiment of the present application;

fig. 17 is a schematic operation flow diagram of the storage device according to an embodiment of the present application when the earphone is inserted:

fig. 18 is a schematic diagram illustrating an operation flow of the storage device provided in an embodiment of the present application when the earphone is taken out.

Fig. 1 to 16 reference numerals:

100 receiving means, 110 housing, 112 first guide, 114 second guide, 120 first bin, 122 first receiving slot, 124 first slide, 130 second bin, 132 second receiving slot, 134 second slide, 140 drive assembly, 142 first drive mechanism, 1422 first power member, 1424 first screw, 144 second drive mechanism, 1442 second power member, 1444 second screw, 152 first guard, 154 first movement mechanism, 156 first slider, 162 second guard, 164 second movement mechanism, 166 second slider, 172 first positioning assembly, 174 second positioning assembly, 182 single receiving cavity, 184 first receiving cavity, 186 second receiving cavity, 200 electronic device, 210 first body, 220 second body, 232 third positioning assembly, 234 fourth positioning assembly.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functionality throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of explaining the present application and are not to be construed as limiting the present application. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

The features of the terms "first", "second", and the like in the description and in the claims of this application may be used for descriptive or implicit inclusion of one or more such features. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more. Furthermore, in the description and claims, "and/or" means at least one of the connected objects, and the character "/", generally means that the associated object is an "or" relationship.

In the description of the present application, it should be understood that the terms "upper," "inner," and the like indicate an orientation or a positional relationship based on that shown in the drawings, and are merely for convenience of description and simplification of the description, and do not indicate or imply that the apparatus 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 description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

A storage apparatus and an electronic apparatus 200 according to an embodiment of the present application are described below with reference to fig. 1 to 18.

As shown in fig. 1, a storage device 100 according to an embodiment of the present application includes: a housing 110; a first cartridge 120, the first cartridge 120 including a first receiving slot 122; a second cartridge body 130, the second cartridge body 130 including a second receiving groove 132; the driving assembly 140 is disposed on the housing 110, and the driving assembly 140 is used for driving the first bin 120 and the second bin 130 to move relatively, so that the first accommodating groove 122 and the second accommodating groove 132 cooperate to form a single accommodating cavity 182, or the first accommodating groove 122 and the second accommodating groove 132 are separated.

In the embodiment of the present application, the storage device 100 includes a housing 110, a first bin 120, a second bin 130, and a driving assembly 140, where the housing 110 has a mounting groove, the driving assembly 140 is disposed in the mounting groove, a part or all of the first bin 120 is located in the mounting groove, and a part or all of the second bin 130 is located in the mounting groove.

The driving component 140 is connected with at least one of the first bin 120 and the second bin 130, so that the driving component 140 can drive the first bin 120 and the second bin 130 to perform relative motion, wherein the first bin 120 is provided with a first accommodating groove 122, the second bin 130 is provided with a second accommodating groove 132, as shown in fig. 5, the first bin 120 and the second bin 130 can be abutted against each other under the action of the driving component 140, the first accommodating groove 122 of the first bin 120 and the second accommodating groove 132 of the second bin 130 can be matched, that is, the notch of the second accommodating groove 132 is opposite to the notch of the second accommodating groove 132, so as to form a single accommodating cavity 182, the single accommodating cavity 182 is provided with an opening, the first main body 210 or the second main body 220 of the earphone can be placed in the single accommodating cavity 182 through the opening, and, as long as the first accommodating groove 122 and the second accommodating groove 132 form the single accommodating cavity 182, the first bin 120 and the second bin 130 can abut against each other, and the first accommodating groove 120 and the second bin 130 can be inserted into the single accommodating cavity 210 or the second main body 220 can not be separated from the single accommodating cavity 182 as long as the gap is reserved between the first main body and the second main body. The movement modes of the first bin 120 and the second bin 130 can be translation or rotation.

Specifically, the drive assembly 140 can drive the first cartridge 120 and the second cartridge 130 to move toward and away from each other.

When the two housings are close to each other, the first accommodating groove 122 on the first housing 120 and the second accommodating groove 132 on the second housing 130 are matched with each other, and are buckled together to form a single accommodating cavity 182, in such a state, the whole accommodating device 100 only has the single accommodating cavity 182, and when the earphone is placed, the earphone can only be placed in the single accommodating cavity 182, so that the accommodating position of the accommodating device 100 and the matching state of the earphone are not required.

When moving away from each other, the first accommodating groove 122 and the second accommodating groove 132 are separated, and thus the first accommodating groove 122 and the second accommodating groove 132 can respectively place one earphone, specifically, after one earphone is placed in the accommodating device 100, the driving assembly 140 can drive the first bin 120 and the second bin 130 to move away from each other, so that the first accommodating groove 122 and the second accommodating groove 132 are separated to form two accommodating positions, and thus the other earphone can be placed in the accommodating device 100.

As above, this application is through the drive assembly 140 to the drive of the first storehouse body 120 and the second storehouse body 130 for whole storage device 100 can present the state that has a storage position and two storage positions, and then when accomodating the earphone, only one storage position has reduced left ear earphone and right ear earphone misplacement's possibility, has reduced storage device 100 and earphone and has received the influence of friction, has promoted the life of earphone and storage device 100.

Specifically, the first bin 120 and the second bin 130 are disposed side by side, and one ends of the first bin 120 and the second bin 130 are disposed toward the bottom side of the housing 110, and the other sides of the first bin 120 and the second bin 130 are exposed at the notch of the mounting groove of the housing 110, so that the opening of the single accommodating cavity 182 is exposed at the notch of the mounting groove of the housing 110, wherein the notch of the first accommodating groove 122 is toward the second bin 130, and the notch of the second accommodating groove 132 is toward the first bin 120. Wherein the first bin 120 is movable relative to the housing 110, and the second bin 130 is movable relative to the housing 110.

Wherein the single receiving cavity 182 is provided corresponding to the stem of the first body 210 or the second body 220 of the earphone.

As shown in fig. 1, 2 and 3, as a possible embodiment, the storage device 100 further includes: a protection member movably provided on at least one of the first and second cartridges 120 and 130; the movement mechanism is arranged on at least one of the first bin 120 and the second bin 130 and is connected with the protection piece so as to enable the protection piece to be matched with or be unmated with at least one of the first accommodating groove 122 and the second accommodating groove 132. The protection piece is disposed on the first bin 120, or disposed on the second bin 130, or disposed on the first bin 120 and the second bin 130.

The movement mechanism is disposed on the first bin 120, the protection member is disposed on the movement mechanism, and the movement mechanism can drive the protection member to move, so as to be matched with the first accommodating groove 122, to form the first accommodating cavity 184, that is, the protection member forms part of the side wall of the first accommodating cavity 184, the side wall of the first accommodating groove 122 forms part of the side wall of the first accommodating cavity 184, so as to form the first accommodating cavity 184, the opening of the first accommodating cavity 184 is exposed at the notch of the mounting groove of the housing 110, and the first main body 210 of the earphone can be placed in the first accommodating cavity 184 through the opening.

Similarly, the movement mechanism is disposed on the second bin 130, the protection member is disposed on the movement mechanism, and the movement mechanism can drive the protection member to move, so as to cooperate with the second accommodating groove 132 to form the second accommodating cavity 186, that is, the protection member forms part of the side wall of the second accommodating cavity 186, the side wall of the second accommodating groove 132 forms part of the side wall of the second accommodating cavity 186, so as to form the second accommodating cavity 186, the opening of the second accommodating cavity 186 is exposed at the notch of the mounting groove of the housing 110, and then the second main body 220 of the earphone can be placed in the second accommodating cavity 186 through the opening.

Wherein the guard includes a first guard 152 and/or a second guard 162 and the movement mechanism includes a first movement mechanism 154 and/or a second movement mechanism 164. The first protection piece 152 is movably arranged on the first bin 120; the first moving mechanism 154 is disposed on the first bin 120 and connected to the first protection element 152, so that the first protection element 152 and the first accommodating groove 122 cooperate to form a first accommodating cavity 184, or the first protection element 152 and the first accommodating groove 122 are disengaged; and/or a second protection member 162 movably disposed on the second bin 130; the second moving mechanism 164 is disposed on the second bin 130 and connected to the second protecting member 162, so that the second protecting member 162 and the second accommodating groove 132 cooperate to form a second accommodating cavity 186, or the second protecting member 162 and the second accommodating groove 132 are disengaged.

Specifically, the storage device 100 may include the first protection member 152 and the first movement mechanism 154, or the storage device 100 may include the second protection member 162 and the second movement mechanism 164, or the storage device 100 may include the first protection member 152, the first movement mechanism 154, the second protection member 162, and the second movement mechanism 164.

The first moving mechanism 154 is disposed on the first housing body 120, the first protection member 152 is disposed on the first moving mechanism 154, and the first moving mechanism 154 can drive the first protection member 152 to move so as to cooperate with the first accommodating groove 122 to form the first accommodating chamber 184, that is, the first protection member 152 forms a part of the sidewall of the first accommodating chamber 184, the sidewall of the first accommodating groove 122 forms a part of the sidewall of the first accommodating chamber 184 to form the first accommodating chamber 184, the opening of the first accommodating chamber 184 is exposed to the notch of the mounting groove of the housing 110, and the first main body 210 of the earphone can be placed in the first accommodating chamber 184 through the opening.

Specifically, the first housing 120 and the second housing 130 are separated, and after the first accommodating groove 122 and the second accommodating groove 132 are separated, the first moving mechanism 154 can drive the first protection member 152 to move, so as to protect the first main body 210 of the earphone, and improve the stability of the first main body 210 when placed in the first housing 120.

The second moving mechanism 164 is disposed on the second housing 130, the second protection member 162 is disposed on the second moving mechanism 164, and the second moving mechanism 164 can drive the second protection member 162 to move so as to cooperate with the second receiving groove 132 to form the second receiving chamber 186, that is, the second protection member 162 forms a part of the sidewall of the second receiving chamber 186, and the sidewall of the second receiving groove 132 forms a part of the sidewall of the second receiving chamber 186 to form the second receiving chamber 186, the opening of the second receiving chamber 186 is exposed to the notch of the mounting groove of the housing 110, and the second body 220 of the earphone can be placed in the second receiving chamber 186 through the opening.

Specifically, the first and second housings 120 and 130 are separated, and after the first and second receiving grooves 122 and 132 are separated, the second moving mechanism 164 may drive the second protecting member 162 to move, thereby protecting the second body 220 of the earphone, and improving the stability of the second body 220 when it is placed in the second housing 130.

As shown in fig. 1, 2 and 3, as a possible embodiment, the movement mechanism is a rotation member for driving the protection member to rotate so as to screw in or out at least one of the first receiving groove and the second receiving groove.

Specifically, the movement mechanism employs a rotating member, and thus the protecting member can rotate relative to the first housing 120, wherein the movement mechanism can rotate the protecting member to open the first receiving slot 122 toward the side of the second housing 130, and the movement mechanism can also rotate the protecting member to close the side of the first receiving slot 122 toward the second housing 130, where the closing can be a complete closing or a partial closing.

Similarly, the movement mechanism adopts a rotating member, and thus the protecting member can rotate relative to the second bin 130, wherein the movement mechanism can rotate the protecting member to open the second accommodating groove 132 towards one side of the first bin 120, and the movement mechanism can also rotate the protecting member to close the second accommodating groove 132 towards one side of the first bin 120, and the closing can be completely closing or partially closing.

Specifically, the first movement mechanism 154 is a first rotating member; and/or the second motion mechanism 164 is a second rotational member.

Specifically, the first motion mechanism 154 is a first rotating member, or the second motion mechanism 164 is a second rotating member, or the first motion mechanism 154 is a first rotating member and the second motion mechanism 164 is a second rotating member. Wherein the first motion mechanism 154 is a motor and the second motion mechanism 164 is a motor.

Specifically, the first moving mechanism 154 adopts a first rotating member, and the first protection member 152 can rotate relative to the first bin body 120, where the first moving mechanism 154 can rotate the first protection member 152 into the first accommodating groove 122, so that the first accommodating groove 122 is opened towards one side of the second bin body 130, and the first moving mechanism 154 can also rotate the first protection member 152 out of the first accommodating groove 122, so as to block the notch of the first accommodating groove 122, so that the first accommodating groove 122 is closed towards one side of the second bin body 130, and the closure can be completely closed or partially closed.

The rotating movement mode can make the first protection piece 152 occupy smaller space in the movement process, and reduce the volume of the storage device 100.

The second moving mechanism 164 adopts a second rotating member, and further, the second protecting member 162 can rotate relative to the second bin body 130, where the second moving mechanism 164 can rotate the second protecting member 162 into the second accommodating groove 132, so that the second accommodating groove 132 is opened towards one side of the first bin body 120, and the second moving mechanism 164 can also rotate the second protecting member 162 out of the second accommodating groove 132, so as to cover the notch of the second accommodating groove 132, so that the second accommodating groove 132 is closed towards one side of the first bin body 120, and the closure can be completely closed or partially closed.

The rotating movement mode can make the second protection piece 162 occupy smaller space in the movement process, and reduce the volume of the storage device 100.

As a possible embodiment, as shown in fig. 2 and 3, the sidewall of at least one of the first receiving groove and the second receiving groove may have a curved surface, and the protector may follow the curved surface.

Specifically, the protection member has a semicircular arc structure, and the first accommodating groove 122 has a semicircular arc structure, and when the movement mechanism drives the protection member to move, the protection member can rotate on one side of the side wall of the first accommodating groove 122, and the protection member can rotate to the first accommodating groove 122, so that the protection member and the side wall of the first accommodating groove 122 are stacked together, and the protection member can also be opposite to the side wall of the first accommodating groove 122, thereby forming the first accommodating cavity 184.

Similarly, the protection member has a semicircular arc structure, the second accommodating groove 132 has a semicircular arc structure, and when the movement mechanism drives the protection member to move, the protection member can rotate on one side of the side wall of the second accommodating groove 132, and the protection member can rotate to the second accommodating groove 132, so that the protection member and the side wall of the second accommodating groove 132 are stacked together, and the protection member can also be opposite to the side wall of the second accommodating groove 132, thereby forming the second accommodating cavity 186.

Wherein, the side wall of the first accommodating groove 122 is curved, and the first protecting member 152 can rotate along the side wall of the first accommodating groove 122; and/or the sidewall of the second receiving groove 132 may be curved, and the second protection member 162 may rotate along the sidewall of the second receiving groove 132.

Specifically, the first protector 152 may rotate along the curved side wall of the first receiving groove 122, or the second protector 162 may rotate along the curved side wall of the second receiving groove 132, or the first protector 152 may rotate along the curved side wall of the first receiving groove 122, and the second protector 162 may rotate along the curved side wall of the second receiving groove 132.

The side wall of the first accommodating groove 122 is an arc surface, specifically a semi-arc structure, and the side wall of the second accommodating groove 132 is an arc surface, specifically a semi-arc structure.

Specifically, the first protection member 152 has a semicircular arc structure, the side wall of the first receiving groove 122 has the same semicircular arc structure, and when the first movement mechanism 154 drives the first protection member 152 to move, the first protection member 152 can rotate on one side of the side wall of the first receiving groove 122, and the first protection member 152 can rotate into the first receiving groove 122, so that the first protection member 152 and the side wall of the first receiving groove 122 are stacked together, and the first protection member 152 can also be opposite to the side wall of the first receiving groove 122, thereby forming the first receiving cavity 184.

Further, the first moving mechanism 154 may be rotated by q degrees at a time so that the first protection member 152 and the side wall of the first receiving groove 122 are laminated or so that the first protection member 152 and the side wall of the first receiving groove 122 are opposite, and q takes a value of 90 to 270 degrees. The first movement mechanism 154 drives the first protection member 152 to move in two adjacent ways, which may be a reciprocating movement or a same direction movement.

The second protection member 162 has a semicircular arc structure, and the side wall of the second accommodating groove 132 has the same semicircular arc structure, and when the second movement mechanism 164 drives the second protection member 162 to move, the second protection member 162 can rotate on one side of the side wall of the second accommodating groove 132, and the second protection member 162 can rotate into the second accommodating groove 132, so that the second protection member 162 and the side wall of the second accommodating groove 132 are stacked together, and the second protection member 162 can also be opposite to the side wall of the second accommodating groove 132, thereby forming the second accommodating cavity 186.

Further, the second moving mechanism 164 may be rotated by q degrees at a time, thereby laminating the second protection member 162 and the side wall of the second receiving groove 132, or making the second protection member 162 and the side wall of the second receiving groove 132 opposite, and q takes a value of 90 to 270 degrees. The second movement mechanism 164 drives the second protection member 162 to move in two adjacent ways, which may be a reciprocating movement or a same direction movement.

Further, a first slide 124 is provided on a side wall of the first accommodating groove 122, a first slider 156 is provided on the first protection member 152, the first slider 156 slides in the first slide 124, specifically, an edge of a side of the first protection member 152 facing away from the first movement mechanism 154 forms a folded edge toward a side of the first protection member 152 protruding, the first slider 156 is provided on the folded edge, and the first slide 124 is in an "L" shape structure, so that the first slider 156 can be inserted into the first slide 124 to form a sliding connection. Specifically, the first slider 156 and the first protector 152 form a flared structure.

The second slide 134 is disposed on a side wall of the second accommodating groove 132, the second protecting member 162 is disposed with the second slider 166, the second slider 166 slides in the second slide 134, specifically, an edge of a side of the second protecting member 162 facing away from the second moving mechanism 164 forms a folded edge toward a side of the second protecting member 162 protruding, the second slider 166 is disposed on the folded edge, and the second slide 134 is in an "L" shape structure, so that the second slider 166 can be inserted into the second slide 134 to form a sliding connection. Specifically, the second slider 166 and the second protector 162 form a flared structure.

As shown in fig. 1, 4 and 6, as one possible embodiment, the driving assembly 140 includes: the first driving mechanism 142 is arranged on the shell 110 and connected with the first bin 120, and is used for driving the first bin 120 to move; the second driving mechanism 144 is disposed on the housing 110 and connected to the second bin 130, and is used for driving the second bin 130 to move.

Specifically, the driving assembly 140 includes a first driving mechanism 142 and a second driving mechanism 144, where the first driving mechanism 142 and the second driving mechanism 144 are both installed in the installation slot of the housing 110, and the first driving mechanism 142 is used for driving the first bin 120, and the second driving mechanism 144 is used for driving the second bin 130, so that the first bin 120 and the second bin 130 can move in opposite directions or move in opposite directions, and the first bin 120 and the second bin 130 can both be used, so that the separate strokes of the first bin 120 or the second bin 130 are reduced, and the overall movement process is quicker.

Moreover, the first driving mechanism 142 and the second driving mechanism 144 can be independently operated, so that the reliability of the whole system is improved, the first driving mechanism 142 can drive the first bin 120 to move to the side position and the middle position, the second driving mechanism 144 can drive the second bin 130 to move to the side position and the middle position, and therefore the first bin 120 and the second bin 130 can form three states, and the first state is that: the first bin 120 and the second bin 130 are in the middle position, i.e. the first bin 120 and the second bin 130 are close to each other, and the first accommodating groove 122 and the second accommodating groove 132 are matched to form a single accommodating cavity 182; second state: one of the first and second cartridge bodies 120 and 130 is at a middle position and the other is at an edge position such that the first and second receiving grooves 122 and 132 are in a separated state to a small extent; third state: the first cartridge body 120 and the second cartridge body 130 are both in the side positions such that the first receiving groove 122 and the second receiving groove 132 are in a completely separated state.

Specifically, the specific process of housing the earphone in the housing device 100 is as follows, if no earphone is in the housing device 100, at this time, as shown in fig. 7, the first housing 120 and the second housing 130 are in the first state, as shown in fig. 8, then the first main body 210 of the earphone may be inserted into the single accommodating cavity 182 and engaged with the first housing 120, then, as shown in fig. 9, the first driving mechanism 142 operates, the first housing 120 and the second housing 130 are in the second state, then, as shown in fig. 10, the first moving mechanism 154 drives the first protection member 152 and the first accommodating groove 122 to engage, thereby protecting the first main body 210 of the earphone, then, as shown in fig. 11, the second housing 130 moves, thereby enabling the first housing 120 and the second housing 130 to be in the third state, and the second moving mechanism 164 drives the second protection member 162 and the second accommodating groove 132 to engage, then, as shown in fig. 9, the second main body 220 of the earphone may be inserted into the second accommodating cavity 186, thereby keeping only one jack of the housing device 100 available for blind insertion.

If the first main body 210 of the earphone is disposed in the storage device 100, as shown in fig. 11, the first bin 120 and the second bin 130 are in the third state, and the second protection member 162 is matched with the second accommodating groove 132, so that only one available jack of the second accommodating cavity 186 is reserved, as shown in fig. 12, the second main body 220 of the earphone can be inserted into the second accommodating cavity 186, and thus only one jack on the storage device 100 is available, and blind insertion of the earphone is realized.

For the specific process of taking out the storage device 100, if the storage device 100 has the first main body 210 of the earphone, as shown in fig. 11, the first housing 120 and the second housing 130 are in the third state, and the second protecting member 162 and the second accommodating groove 132 cooperate to only reserve one available jack of the second accommodating cavity 186, and after taking out the first main body 210, if the earphone is inserted within the preset time period, as shown in fig. 7, the first housing 120 and the second housing 130 can move to the first state.

If the first body 210 and the second body 220 of the earphone are provided in the storage device 100, at this time, as shown in fig. 12, the first housing 120 and the second housing 130 are in the third state, after the first body 210 of the earphone is taken out, as shown in fig. 13, the first housing 120 and the second housing 130 are in the third state, and the first protection member 152 and the first receiving groove 122 cooperate to only reserve one available jack of the first receiving cavity 184, and if the second body 220 of the earphone is taken out again and the earphone is inserted in the preset time period, as shown in fig. 7, the first housing 120 and the second housing 130 can move to the first state.

As shown in fig. 1 and 4, as a possible embodiment, the first driving mechanism 142 includes: a first power component 1422 disposed on the housing 110; a first screw 1424, which is connected to the first power element 1422 and is screwed to the first bin 120; and/or the second drive mechanism 144 includes: a second power element 1442 provided in the housing 110; the second screw 1444 is connected with the second power element 1442 and is screwed with the second bin 130. Wherein, the first power component 1422 is a motor, and the second power component 1442 is a motor.

Specifically, the first drive mechanism 142 includes a first power member 1422 and a first screw 1424, or the second drive mechanism 144 includes a second power member 1442 and a second screw 1444, or the first drive mechanism 142 includes a first power member 1422 and a first screw 1424, and the second drive mechanism 144 includes a second power member 1442 and a second screw 1444.

Specifically, the first power component 1422 can drive the first screw rod 1424 to rotate, and the first bin body 120 is in threaded connection with the first screw rod 1424, so that under the constraint of the drive of the first screw rod 1424 and the shell 110, the first bin body 120 can realize translation, wherein the first power component 1422 can drive the first screw rod 1424 to rotate bidirectionally, so that the first bin body 120 can translate towards two directions, and the mode that the first screw rod 1424 drives the first bin body 120 can enable the movement process of the first bin body 120 to be more stable. Wherein, the first screw 1424 has an external thread, and the first bin 120 is provided with an internal thread.

Moreover, the structure can realize self-locking, so that the whole first bin 120 is stable in movement and stable state.

The second power component 1442 can drive the second screw 1444 to rotate, and the second bin body 130 is in threaded connection with the second screw 1444, so that under the constraint of the drive of the second screw 1444 and the shell 110, the second bin body 130 can realize translation, wherein the second power component 1442 can drive the second screw 1444 to rotate bidirectionally, so that the second bin body 130 can translate towards two directions, and the mode that the second screw 1444 drives the second bin body 130 can enable the movement process of the second bin body 130 to be more stable. Wherein, the second screw 1444 has an external thread, and the second bin 130 is provided with an internal thread.

And, this structure can realize the auto-lock for and then whole second storehouse body 130 removes and steady state all steadily.

In other embodiments of the present application, the first drive mechanism 142 includes a first gear set, or the first drive mechanism 142 includes a first worm gear and a first worm, or the first drive mechanism 142 includes a first electromagnetic component, thereby effecting an electromagnetic transmission. The second drive mechanism 144 includes a second gear set, or the second drive mechanism 144 includes a second worm gear and a second worm, or the second drive mechanism 144 includes a second electromagnetic component, thereby effecting electromagnetic transmission.

As shown in fig. 6, as a possible embodiment, the housing 110 includes a first guide 112 and a second guide 114, the first cartridge 120 is mated with the first guide 112, and the second cartridge 130 is mated with the second guide 114.

Specifically, the first guide portion 112 and the second guide portion 114 are disposed in the mounting groove of the housing 110 in a protruding manner, so that the first bin 120 has a first guide groove, and the first guide groove and the first guide portion 112 are matched, so that when the first driving mechanism 142 drives the first bin 120 to move, the first bin 120 moves along the first guide portion 112, so that the movement of the first bin 120 is smoother.

The first guide part 112 and the second guide part 114 are arranged in the mounting groove of the shell 110 in a protruding manner, so that the second bin 130 is provided with a second guide groove, the second guide groove is matched with the second guide part 114, and when the second driving mechanism 144 drives the second bin 130 to move, the second bin 130 moves along the second guide part 114, so that the second bin 130 moves more stably.

As shown in fig. 14 and 15, as a possible embodiment, the storage device 100 further includes: the first positioning component 172 is arranged on the first bin 120; the second positioning assembly 174 is disposed in the second bin 130.

Specifically, the storage device 100 further includes a first positioning component 172 and a second positioning component 174, where the first positioning component 172 is disposed on the first bin 120 and is capable of positioning the first main body 210 of the earphone, and the second positioning component 174 is disposed on the second bin 130 and is capable of positioning the second main body 220 of the earphone, specifically, when the first main body 210 of the earphone is stored in the first bin 120, the first positioning component 172 is matched with the first main body 210 of the earphone, so that the first main body 210 of the earphone is stably placed in the first bin 120, and when the second main body 220 of the earphone is stored in the second bin 130, the second positioning component 174 is matched with the second main body 220 of the earphone, so that the second main body 220 of the earphone is stably placed in the second bin 130.

Wherein the first positioning assembly 172 may be disposed corresponding to the head of the first body 210 of the headset and the second positioning assembly 174 may be disposed corresponding to the head of the second body 220 of the headset.

The first body 210 of the earphone is provided with a third positioning component 232, the second body 220 of the earphone is provided with a fourth positioning component 234, and thus the third positioning component 232 can be matched with the first positioning component 172, and the fourth positioning component 234 can be matched with the second positioning component 174.

As one possible implementation, the first positioning component 172 includes a first magnetic or magnetizable component; the second positioning assembly 174 includes a second magnetic or magnetizable member. Wherein the first magnetic member is a magnet or a magnetite, and the first magnetic ring member is a material that can be magnetized by a material such as a magnet or a magnetite, for example: iron or an alloy of iron. The second magnetic member is a magnet or a magnet, and the second magnetically permeable ring member is a material that can be magnetized by a material such as a magnet or a magnet, for example: iron or an alloy of iron.

Specifically, the first positioning component 172 includes a first magnetic element or a first magnetizable element, and the third positioning component 232 on the first main body 210 of the earphone is also provided with a third magnetic element or a third magnetizable element corresponding to the first positioning component 172, so that when the first main body 210 of the earphone is placed in the first bin 120, the first magnetic element or the first magnetizable element on the first bin 120 can form an attraction fit with the third magnetic element or the third magnetizable element on the first main body 210 of the earphone, thereby improving the stability of the first main body 210 of the earphone stored in the first bin 120.

Wherein, when the first positioning component 172 includes only the first magnetic element, a third magnetic element or a third magnetizable element may be disposed on the first main body 210 of the earphone, and when the first positioning component 172 includes only the first magnetizable element, a third magnetic element is disposed on the first main body 210 of the earphone.

The second positioning component 174 includes a second magnetic element or a second magnetizable element, and the fourth positioning component 234 of the second main body 220 of the earphone is also provided with a fourth magnetic element or a fourth magnetizable element corresponding to the second positioning component 174, so that when the second main body 220 of the earphone is placed in the second bin 130, the second magnetic element or the second magnetizable element on the second bin 130 can form an attraction fit with the fourth magnetic element or the fourth magnetizable element on the second main body 220 of the earphone, thereby improving the stability of the second main body 220 of the earphone stored in the second bin 130.

Wherein, when the second positioning assembly 174 includes only the second magnetic element, a fourth magnetic element or a fourth magnetizable element may be disposed on the second main body 220 of the earphone, and when the second positioning assembly 174 includes only the second magnetizable element, a fourth magnetic element is disposed on the second main body 220 of the earphone.

Moreover, based on the design of magnetic force positioning, when the first bin 120 and the second bin 130 are close to each other, and the first accommodating groove 122 and the second accommodating groove 132 form the single accommodating cavity 182, when the first main body 210 of the earphone is put into the single accommodating cavity 182, the first positioning component 172 can guide the first main body 210 of the earphone to slide into a position matched with the first bin 120, and when the second main body 220 of the earphone is put into the single accommodating cavity 182, the second positioning component 174 can guide the second main body 220 of the earphone to slide into a position matched with the second bin 130, so that the risk of misplug of the earphone is further reduced.

As one possible embodiment, the storage device 100 further includes: the control component is arranged on the shell 110 and is electrically connected with the driving component 140; the first detection component is arranged in the first bin body 120 and is electrically connected with the control component and is used for detecting whether headphones are placed in the first bin body 120 or not; the second detection component is arranged on the second bin 130 and is electrically connected with the control component and is used for detecting whether the earphone is placed in the second bin 130, wherein the control component controls the driving component 140 according to the detection results of the first detection component and the second detection component. The first detection component is disposed on the first bin 120, and the second detection component is disposed on the second bin 130.

Specifically, the storage device 100 further includes a control component, a first detection component, and a second detection component, where the first detection component, the second detection component, and the driving component 140 are all electrically connected with the control component, the first detection component can detect whether the first bin 120 is placed on the first main body 210 of the earphone, the second detection component can detect whether the second bin 130 is placed on the second main body 220 of the earphone, and the first detection component and the second detection component feed back a detection result to the control component, and the control component controls the driving component 140 to move based on the detection result, specifically, the control component controls the first driving mechanism 142 and the second driving mechanism 144 to work based on the detection result.

Further, through control of the control component, automatic movement of the first bin 120 and the second bin 130 in the storage device 100 can be achieved, so that storage of the earphone by the storage device 100 is more convenient.

The first detecting component may detect the magnetic field of the first positioning component 172, so as to determine whether the first main body 210 of the earphone is placed on the first housing 120, and specifically, the first positioning component 172 and the first detecting component may be two independent components or may be integrated together. The second detecting component may detect the magnetic field of the second positioning component 174, so as to determine whether the second main body 220 of the earphone is placed in the second housing 130, and specifically, the second positioning component 174 and the second detecting component may be two independent components or may be integrated together.

As one possible embodiment, the storage device 100 further includes: a cover body provided on the housing 110; the third detecting component is disposed on the housing 110 and electrically connected to the control component, and is configured to detect whether the cover and the housing 110 are closed, and the control component controls the driving component 140 according to the detection results of the first detecting component, the second detecting component and the third detecting component.

Specifically, the housing 110 is provided with a cover body, the cover body can be covered and buckled on the housing 110 to close the mounting groove of the housing 110, so as to protect the earphone, wherein the storage device 100 includes a control component, a first detection component, a second detection component and a third detection component, wherein the first detection component, the second detection component, the third detection component and the driving component 140 are all electrically connected with the control component, the first detection component can detect whether the first bin 120 is used for placing the first main body 210 of the earphone, the second detection component can detect whether the second bin 130 is used for placing the second main body 220 of the earphone, the third detection component can detect whether the cover body and the housing 110 are closed, and the first detection component, the second detection component and the third detection component feed back detection results to the control component, the control component controls the driving component 140 to move based on the detection results, and then the movement of the first bin 120 and the second bin 130 can be performed in different states of the cover body and the housing 110, for example: in the case that the cover and the housing 110 are closed, corresponding actions are performed, so that unnecessary movement time can be saved, and the risk that sundries or users block the movement of the first bin 120 or the second bin 130 is reduced.

Specifically, as shown in fig. 17, the flow of the operation of the storage device in inserting the earphone is as follows:

step 1702: a single earphone is inserted.

Specifically, the first body 210 or the second body 220 of the earphone is inserted into the storage device 100.

Step 1704: judging whether a single earphone exists in the storage device or not; if the determination result is yes, step 1706 is executed, and if the determination result is no, step 1714 is executed.

Specifically, after the first body 210 or the second body 220 of the earphone is inserted into the storage device 100, it is determined whether the first body 210 or the second body 220 of the earphone is present in the storage device 100 before the first body 210 or the second body 220 is not inserted.

Step 1706: a single earphone is inserted into the corresponding position.

Specifically, based on the case where one of the first body 210 and the first body 210 of the earphone already has in the storage device 100, the other is inserted to the corresponding position.

Step 1708: judging whether to take out the other earphone; if the determination result is yes, step 1710 is executed, and if the determination result is no, step 1712 is executed.

Specifically, it is determined whether the first body 210 or the second body 220 of the earphone is taken out within a preset period of time.

Step 1710: the first bin body and the second bin body are in a third state, and a single earphone is accommodated.

Specifically, based on the fact that the first body 210 or the second body 220 of the earphone is not taken out within the preset time period, the first and second housings 120 and 130 are maintained in the third state, and the first body 210 and the first housing 120 of the earphone are engaged, and the second body 220 and the second housing 130 of the earphone are engaged.

Step 1712: the first bin body and the second bin body are in a third state, and two earphones are accommodated.

Specifically, based on the first body 210 or the second body 220 of the earphone being taken out for a preset period of time, the first and second housings 120 and 130 are maintained in the third state, and the first body 210 and the first housing 120 of the earphone are engaged, the second housing 130 is not engaged with the second body 220 of the earphone, or the second body 220 and the second housing 130 of the earphone are engaged, and the first housing 120 is not engaged with the first body 210 of the earphone.

Step 1714: the driving component drives the unilateral bin body to move, and the corresponding movement mechanism drives the protection piece to move.

Specifically, if the first body 210 of the earphone is inserted in the storage device 100 without the first body 210 and the second body 220 of the earphone, the first body 210 and the first housing 120 are engaged, and thus the first driving mechanism 142 is operated, the first housing 120 is moved to the side, and the first moving mechanism 154 is operated, so that the first protector 152 is moved to engage with the first receiving groove 122, thereby protecting the first body 210 of the earphone.

If the second main body 220 of the earphone is inserted, the second main body 220 is matched with the second bin 130, so that the second driving mechanism 144 works, the second bin 130 moves to the side, and the second moving mechanism 164 works, so that the second protecting piece 162 moves to be matched with the second accommodating groove 132, and the second main body 220 of the earphone is protected.

Step 1716: judging whether another earphone is inserted; if the determination result is yes, step 1724 is executed, and if the determination result is no, step 1718 is executed.

Specifically, it is determined whether to insert the second body 220 of the earphone when the first body 210 of the earphone has been inserted, or whether to insert the first body 210 of the earphone when the second body 220 of the earphone has been inserted.

Step 1718: and detecting whether the cover body and the shell are closed.

Specifically, when the first body 210 of the earphone has been inserted, without the second body 220 of the earphone inserted, it is detected whether the cover and the housing 110 are closed.

When the second body 220 of the earphone has been inserted, without the first body 210 of the earphone inserted, it is detected whether the cover and the housing 110 are closed.

Step 1720: based on the closing of the cover body and the shell, the bin body without the single earphone is moved, and the corresponding movement mechanism drives the protection piece to move.

Specifically, when the first body 210 of the earphone has been inserted, without the second body 220 of the earphone inserted, the second driving mechanism 144 operates based on the case 110 and the cover having been closed, such that the second cartridge 130 moves to the side, such that the first and second cartridges 120 and 130 are in the third state, and the second moving mechanism 164 operates such that the second protection member 162 and the second receiving groove 132 cooperate, forming the second receiving chamber 186.

When the second body 220 of the earphone has been inserted, without the first body 210 of the earphone inserted, the first driving mechanism 142 operates such that the first cartridge 120 moves to the side based on the case 110 and the cover having been closed, such that the first cartridge 120 and the second cartridge 130 are in the third state, and the first moving mechanism 154 operates such that the first protector 152 and the first receiving groove 122 are engaged to form the first receiving chamber 184.

Step 1722: the first bin body and the second bin body are in a third state, and a single earphone is accommodated.

Specifically, the first and second housings 120 and 130 are in the third state, and receive the first or second body 210 or 220 of the earphone.

Step 1724: the first bin body and the second bin body are in a third state, and two earphones are accommodated.

Specifically, when the first body 210 of the earphone has been inserted, and the second body 220 of the earphone has been inserted, the second driving mechanism 144 operates to move the second housing 130 to the side, so that the first housing 120 and the second housing 130 are in the third state, and then the second moving mechanism 164 operates to cooperate with the second protection member 162 and the second receiving groove 132 to protect the second body 220 of the earphone.

When the second body 220 of the earphone has been inserted, and the first body 210 of the earphone has been inserted, the first driving mechanism 142 operates such that the first housing 120 moves to the side, such that the first housing 120 and the second housing 130 are in the third state, and then the first moving mechanism 154 operates such that the first protector 152 cooperates with the first receiving groove 122 to protect the first body 210 of the earphone.

At this time, the first and second housings 120 and 130 are in the third state, and the first and second bodies 210 and 220 of the earphone are received.

Specifically, as shown in fig. 18, the flow of the operation of the storage device in taking out the earphone is as follows:

step 1802: if it is determined that there is a single earphone in the storage device, step 1810 is executed if the determination result is yes, and if the determination result is no, step 1804 is executed.

Specifically, it is determined whether the first body 210 or the second body 220 of the earphone is already present in the storage device 100.

Step 1804: the single earphone is taken out.

Specifically, based on the case where the first body 210 and the second body 220 of the earphone are provided in the storage device 100, one of the first body 210 and the second body 220 of the earphone is taken out.

Step 1806: whether or not another earphone is taken out is determined, and if the determination result is yes, step 1810 is executed, and if the determination result is no, step 1808 is executed.

Specifically, it is determined whether the other of the first body 210 and the second body 220 of the earphone is taken out.

Step 1808: the first bin body and the second bin body are in a third state, and a single earphone is accommodated.

Specifically, in the case where the first body 210 or the second body 220 of the earphone is provided in the storage device 100, the first and second housings 120 and 130 are in the third state, and the first body 210 or the second body 220 of the earphone is stored.

Step 1810: the single earphone is taken out.

Specifically, based on the case where only the first body 210 or the second body 220 of the earphone is in the storage device 100, the first body 210 or the second body 220 of the earphone is taken out.

Step 1812: whether or not a single earphone is inserted is determined, and if the determination is yes, step 1808 is executed, and if the determination is no, step 1814 is executed.

Specifically, it is determined whether the first body 210 or the second body 220 of the earphone is inserted within a preset period of time.

Step 1814: and detecting whether the cover body and the shell are closed.

Specifically, based on the case where the first body 210 or the second body 220 of the earphone is not inserted for a preset period of time, it is detected whether the cover and the housing 110 are closed.

Step 1816: based on the closure of the cover and the housing, the cartridge body moves, and the first receiving groove and the second receiving groove form a single receiving chamber.

Specifically, in the case where the cover and the housing 110 are closed, the first moving mechanism 154 drives the first protection member 152 to move so that the first protection member 152 is transferred into the first receiving groove 122, the second moving mechanism 164 drives the second protection member 162 to move so that the second protection member 162 is transferred into the second receiving groove 132, and the first driving mechanism 142 drives the first cartridge body 120 to move, and the second driving mechanism 144 drives the second cartridge body 130 to move so that the first cartridge body 120 and the second cartridge body 130 are in the intermediate position, and the first receiving groove 122 and the second receiving groove 132 form the single receiving chamber 182.

Step 1818: the first bin body and the second bin body are in a first state, and the earphone is not contained.

Specifically, the first and second housings 120 and 130 are in the first state and do not house headphones.

As one possible embodiment, the first cartridge body 120 and the second cartridge body 130 are symmetrical in structure, the first drive mechanism 142 and the second drive mechanism 144 are symmetrical, the first motion mechanism 154 and the second motion mechanism 164 are symmetrical, the first guard 152 and the second guard 162 are symmetrical, and the first positioning assembly 172 and the second positioning assembly 174 are symmetrical.

As shown in fig. 16, an electronic device 200 according to an embodiment of the present application includes: an earphone; the storage device 100 provided in any of the embodiments described above.

Specifically, the earphone may be housed in the housing device 100.

As shown in fig. 14, 15 and 16, as a possible embodiment, the earphone includes: a first body 210, the first body 210 including a third positioning assembly 232; the second body 220, the second body 220 includes a fourth positioning assembly 234.

Wherein the third positioning assembly 232 includes a third magnetic member or third magnetizable member and the fourth positioning assembly 234 includes a fourth magnetic member or fourth magnetizable member.

Wherein the third magnetic member is a magnet or a magnetite, and the third magnetic ring member is a material that can be magnetized by a material such as a magnet or a magnetite, for example: iron or an alloy of iron. The fourth magnetic member is a magnet or a magnet, and the fourth magnetically permeable ring member is a material that can be magnetized by a material such as a magnet or a magnet, for example: iron or an alloy of iron.

Specifically, the earphone includes a first main body 210 and a second main body 220, a third positioning component 232 is disposed on the first main body 210, a fourth positioning component 234 is disposed on the second main body 220, the third positioning component 232 includes a third magnetic component or a third magnetizable component, and the first positioning component 172 of the storage device 100 is also disposed with a first magnetic component or a first magnetizable component corresponding to the third positioning component 232, so that when the first main body 210 of the earphone is placed in the first bin 120, the first magnetic component or the first magnetizable component on the first bin 120 can form an attractive fit with the third magnetic component or the third magnetizable component on the first main body 210 of the earphone, thereby improving the stability of the first main body 210 of the earphone stored in the first bin 120.

Wherein the first positioning component 172 comprises a first magnetic component or first magnetizable component when the third positioning component 232 comprises only a third magnetic component, and the first positioning component 172 comprises a first magnetic component when the third positioning component 232 comprises only a third magnetizable component.

The fourth positioning component 234 includes a fourth magnetic element or a fourth magnetizable element, and the second positioning component 174 of the storage device 100 is also provided with a second magnetic element or a second magnetizable element corresponding to the fourth positioning component 234, so that when the second main body 220 of the earphone is placed on the second bin 130, the second magnetic element or the second magnetizable element on the second bin 130 can form an attraction fit with the fourth magnetic element or the fourth magnetizable element on the second main body 220 of the earphone, thereby improving the stability of the second main body 220 of the earphone stored in the second bin 130.

Wherein the second positioning assembly 174 includes a fourth magnetic member or a fourth magnetizable member when the fourth positioning assembly 234 includes only the fourth magnetic member, and the second positioning assembly 174 includes a second magnetic member when the fourth positioning assembly 234 includes only the fourth magnetizable member.

Moreover, based on the design of magnetic force positioning, when the first bin 120 and the second bin 130 are close to each other, and the first accommodating groove 122 and the second accommodating groove 132 form the single accommodating cavity 182, when the first main body 210 of the earphone is put into the single accommodating cavity 182, the first positioning component 172 and the third positioning component 232 can guide the first main body 210 of the earphone to be matched with the first bin 120, and when the second main body 220 of the earphone is put into the single accommodating cavity 182, the second positioning component 174 and the fourth positioning component 234 can guide the second main body 220 of the earphone to be matched with the second bin 130, so that the risk of misplug of the earphone is further reduced.

Specifically, the first body 210 and the second body 220 are symmetrical in structure.

Further, the first body 210 includes a first head and a first shank, at least a portion of which mates with the first receiving cavity 184, the first receiving channel 122, or the single receiving channel, and the second body 220 includes a second head and a second shank, at least a portion of which mates with the second receiving cavity 186, the second receiving channel 132, or the single receiving channel.

In the description of the present specification, reference to the term "one embodiment", or "a particular embodiment", etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present application have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the principles and spirit of the application, the scope of which is defined by the claims and their equivalents.

Claims (12)

1. A storage device, comprising:

a housing;

the first bin body comprises a first accommodating groove;

the second bin body comprises a second accommodating groove;

the driving assembly is arranged on the shell and used for driving the first bin body and the second bin body to relatively move so as to enable the first accommodating groove and the second accommodating groove to be matched to form a single accommodating cavity or enable the first accommodating groove and the second accommodating groove to be separated;

The driving assembly can drive the first bin body and the second bin body to move to be close to and far away from each other;

when the two storage devices are close to each other, the first storage groove on the first bin body and the second storage groove on the second bin body are matched with each other and buckled together to form a single storage cavity, and in such a state, the whole storage device is only provided with one single storage cavity and can only be placed in the single storage cavity when the earphone is placed;

when keeping away from mutually, first holding tank with the separation of second holding tank, and then first holding tank with the second holding tank can place an earphone respectively behind the earphone is placed to storage device in, drive assembly can drive first storehouse body with the second storehouse body moves to keeping away from mutually, thereby first holding tank with the separation of second holding tank forms two storage locations, thereby can place another earphone in storage device.

2. The storage device according to claim 1, further comprising:

the protection piece is movably arranged on at least one of the first bin body and the second bin body;

And the movement mechanism is arranged on at least one of the first bin body and the second bin body and is connected with the protection piece so as to enable the protection piece to be matched with or un-matched with at least one of the first accommodating groove and the second accommodating groove.

3. The storage device of claim 2, wherein the housing is configured to receive the container,

the movement mechanism is a rotation piece and is used for driving the protection piece to rotate so that the protection piece can be screwed into or out of at least one of the first accommodating groove and the second accommodating groove.

4. The storage device according to claim 3, wherein,

the side wall of at least one of the first accommodating groove and the second accommodating groove is a curved surface, and the protecting piece can rotate along the curved surface.

5. The storage device of any one of claims 1 to 4, wherein the drive assembly comprises:

the first driving mechanism is arranged on the shell and connected with the first bin body and used for driving the first bin body to move;

the second driving mechanism is arranged on the shell and connected with the second bin body and used for driving the second bin body to move.

6. The storage device of claim 5, wherein the housing is configured to hold the container,

The first driving mechanism includes:

the first power piece is arranged on the shell;

the first screw is connected with the first power piece and is in threaded connection with the first bin body;

and/or

The second driving mechanism includes:

the second power piece is arranged on the shell;

the second screw rod is connected with the second power piece and is in threaded connection with the second bin body.

7. The storage device according to any one of claim 1 to 4, wherein,

the shell comprises a first guide part and a second guide part, the first bin body is matched with the first guide part, and the second bin body is matched with the second guide part.

8. The storage device according to any one of claims 1 to 4, further comprising:

the first positioning assembly is arranged on the first bin body;

the second positioning assembly is arranged on the second bin body.

9. The storage device according to any one of claims 1 to 4, further comprising:

the control assembly is arranged on the shell and is electrically connected with the driving assembly;

the first detection assembly is arranged in the first bin body and is electrically connected with the control assembly and used for detecting whether the earphone is placed in the first bin body or not;

The second detection component is arranged in the second bin body and is electrically connected with the control component for detecting whether the earphone is placed in the second bin body,

the control assembly controls the driving assembly according to detection results of the first detection assembly and the second detection assembly.

10. The storage device of claim 9, further comprising:

the cover body is arranged on the shell;

the third detection assembly is arranged on the shell and is electrically connected with the control assembly and used for detecting whether the cover body and the shell are closed or not, and the control assembly controls the driving assembly according to detection results of the first detection assembly, the second detection assembly and the third detection assembly.

11. An electronic device, comprising:

an earphone;

the storage device of any one of claims 1 to 10.

12. The electronic device of claim 11, wherein the headset comprises:

a first body including a third positioning assembly;

a second body including a fourth positioning assembly.