CN214101727U - Storage module and earphone assembly - Google Patents

Abstract

The present disclosure relates to a accomodate module and earphone subassembly, include: a first housing having a receiving compartment; the accommodating cabin is used for accommodating a target object with a first magnet; the second shell is positioned outside the first shell; a linkage module; the linkage module includes: a second magnet having: the first magnetic pole of the second magnet faces the first position when the accommodating cabin and the second magnetic pole of the second magnet faces the second position when the accommodating cabin; the first component is connected with the second magnet and drives the second magnet to switch between the first position and the second position along the first direction along with external force; wherein the first direction is parallel to the distribution direction of the first magnetic pole and the second magnetic pole. When the magnetic poles of the second magnet and the first magnet which are aligned are the same, the second magnet has repulsive force to the first magnet, the target object with the first magnet can be bounced by utilizing the repulsive force, the size which can be clamped by a user to the target object is increased, and the target object is convenient to take out.

Description

Storage module and earphone assembly

Technical Field

The present disclosure relates to the field of electronic devices, and in particular, to a storage module and an earphone assembly.

Background

With the development of wireless bluetooth technology, wireless headsets are gradually replacing traditional wired headsets to occupy the mainstream headset market, and the market proportion is gradually accelerated. And with the development of microelectronic technology, the volume of the earphone is smaller and smaller. The wireless earphones in the current market are various in types, and the shapes of the containing modules for containing the earphones are different. However, the volume of the earphone head is small, so that when the earphone is taken out, the earphone head can be clamped by hands in a small space, and the wireless earphone is inconvenient to take out from the accommodating cabin.

SUMMERY OF THE UTILITY MODEL

The present disclosure provides a storage module and an earphone assembly.

According to a first aspect of the embodiments of the present disclosure, there is provided a storage module, including:

a first housing having a receiving compartment; the accommodating cabin is used for accommodating a target object with a first magnet;

a second housing located outside the first housing;

the linkage module is positioned between the first shell and the second shell; the linkage module includes:

a second magnet having, relative to the containment compartment: a first position in which a first magnetic pole of the second magnet faces the housing compartment, and a second position in which a second magnetic pole of the second magnet faces the housing compartment;

a first assembly coupled to the second magnet;

the first component drives the second magnet to switch between the first position and the second position along a first direction along with an external force; wherein the first direction is parallel to a distribution direction of the first magnetic pole and the second magnetic pole.

In some embodiments, the linkage module further comprises:

the second assembly is vertically distributed with the first assembly;

when the second magnet is in the first position, the first component is in contact with a first surface of the second component, and the second component is limited to move along a second direction along with the first component, wherein the second direction is perpendicular to the first direction;

when the second magnet is in the second position, a second surface of the second component is in contact with the first component, and the first component is limited from moving along the first direction; wherein the second surface is an adjacent surface to the second surface.

In some embodiments, the second magnet is in the first position, the second magnet being mutually attractive with the first magnet;

the second magnet is in the second position, the second magnet is mutually repulsive with the first magnet; and the top end of the second component is higher than the top surface of the first shell and/or the second shell.

In some embodiments, the third component comprises:

moving the column;

a self-locking member connected to the moving post and having the first surface and the second surface;

the storage module further comprises: the two ends of the first elastic piece are respectively connected with the self-locking piece and the second shell;

the first assembly includes:

a base portion connected to the second magnet and located between the self-locking member and the first housing;

a stopper portion connected to the base portion, protruding toward the second component;

the second magnet is in the first position, the limiting part is parallel to the self-locking piece in the second direction, the limiting part is in contact with the first surface, and the first elastic piece is in an elastic deformation state for storing elastic force;

the second magnet is in the second position, the limiting part is parallel to the self-locking piece in the first direction, the limiting part is aligned with the second surface of the self-locking piece and contacts with the second surface, and the first elastic piece restores elastic deformation.

In some embodiments, the first assembly further comprises:

the key is connected with the base part and has a gap with the limiting part, at least part of the key is positioned outside the second shell, and the key is used for receiving the external force;

the second magnet is in the second position and the self-locking member is located in the space between the key and the retainer portion.

In some embodiments, the second housing has: avoiding holes;

the key penetrates through the avoiding hole.

In some embodiments, the storage module further comprises:

the two limiting pieces are provided with through holes and connected with the second shell;

the moving column penetrates through the through hole;

the self-locking piece is located between two locating parts, and the first elastic piece is located between the self-locking piece and one locating part.

In some embodiments, the storage module further comprises:

the cover body is connected with the second shell;

a cover magnet connected to the cover body;

a third magnet coupled to the first assembly;

a first pole of the third magnet is aligned with the cover magnet when the second magnet is in the first position;

the second pole of the third magnet is aligned with the cover magnet when the second magnet is in the second position.

In some embodiments, the storage module further comprises:

the two ends of the second elastic piece are respectively connected with the first assembly and the second shell;

when the second magnet is located at the second position, the first assembly drives the second elastic piece to be in a deformation state of storing elastic force.

In some embodiments, the storage module further comprises:

the limiting rod is connected with the second shell, and a channel is formed between the limiting rod and the first shell;

the channel receives the first component.

In some embodiments, the storage module further comprises:

and the charging device is positioned between the first shell and the second shell and is used for charging the target object.

According to a second aspect of embodiments of the present disclosure, there is provided a headset assembly comprising:

the storage module of any of the above embodiments;

an earphone is positioned in the accommodating cabin and provided with a first magnet.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects:

according to the embodiment, when the first component of the present disclosure drives the second magnet to switch between the first position and the second position under the action of an external force, the magnetic pole of the second magnet facing the accommodating compartment is also switched accordingly. When the magnetic poles of the second magnet and the first magnet which are aligned are the same, the second magnet has repulsive force to the first magnet, the target object with the first magnet can be bounced by utilizing the repulsive force, the size which can be clamped by a user to the target object is increased, and the target object is convenient to take out.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is one of schematic structural views of a storage module according to an exemplary embodiment;

fig. 2 is a second schematic structural view of a storage module according to an exemplary embodiment;

fig. 3 is a third schematic view of a storage module according to an exemplary embodiment;

FIG. 4 is a fourth schematic diagram illustrating a structure of a storage module according to an exemplary embodiment;

FIG. 5 is a fifth exemplary diagram illustrating a structure of a storage module according to one embodiment;

FIG. 6 is one of the schematic diagrams showing the relative positional relationship of a first magnet and a second magnet, according to one exemplary embodiment;

FIG. 7 is a second schematic diagram illustrating the relative positional relationship of the first magnet and the second magnet, in accordance with an exemplary embodiment;

FIG. 8 is a third schematic diagram illustrating the relative positional relationship of the first magnet and the second magnet, in accordance with an exemplary embodiment;

fig. 9 is a fourth schematic diagram illustrating a relative positional relationship of the first magnet and the second magnet according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of devices consistent with certain aspects of the present disclosure, as detailed in the appended claims.

In the description of the present disclosure, it should be understood that the terms "center", "upper", "lower", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientation or positional relationship of a user when using the storage module.

The embodiment of the present disclosure provides a storage module, include:

a first housing 111 having a receiving compartment 113; wherein the receiving chamber 113 is configured to receive a target object having a first magnet 300;

a second housing 112 located outside the first housing 111;

a linkage module located between the first housing 111 and the second housing 112; the linkage module includes:

a second magnet 120, the second magnet 120 having, with respect to the accommodation compartment 113: a first position in which a first magnetic pole of the second magnet 120 faces the accommodation compartment 113, and a second position in which a second magnetic pole of the second magnet 120 faces the accommodation compartment 113;

a first assembly 140 coupled to the second magnet 120;

the first component 140 drives the second magnet 120 to switch between the first position and the second position along a first direction with an external force; wherein the first direction is parallel to a distribution direction of the first magnetic pole and the second magnetic pole.

Fig. 1 and 2 exemplarily show that the object is an audio output module, such as a headphone. The object in the embodiment of the present disclosure is not limited to the earphone, but may be a mobile phone, a battery, a microphone (e.g., a wireless microphone), or other items having the first magnet 300.

The number of the accommodating cabins is at least one. Generally, in order to reduce the shaking of the object in the accommodation chamber, the stability of the center of gravity of the storage module after the object is accommodated is improved. The shape of the accommodation chamber may be the same as that of the object, and the volume of the accommodation chamber may be equal to or slightly larger than that of the object. As shown in fig. 1 and 2, when the target is an earphone, the housing 110 may have two accommodation compartments 113, wherein one accommodation compartment 113 accommodates a left-ear earphone and the other accommodation compartment 113 accommodates a right-ear earphone. The shape of the accommodating chamber 113 for accommodating the left ear earphone is the same as that of the left ear earphone, and the outer wall of the left ear earphone is close to the inner wall of the accommodating chamber 113 for accommodating the left ear earphone; likewise, the receiving compartment 113 for receiving the earphone of the right ear has the same shape as the earphone of the right ear, and the outer wall of the earphone of the right ear is close to the inner wall of the corresponding receiving compartment 113.

Without limitation, the second magnet includes: a permanent magnet or an electromagnet. Compared with an electromagnet, the permanent magnet does not need a coil, a control circuit and the like to control magnetism, and the permanent magnet is simpler and more convenient to use.

The first position indicates: the second magnet 120 is located when the first magnetic pole of the second magnet 120 faces the accommodation chamber 113. If the object is placed in the accommodation chamber 113, the second position of the second magnet 120 is: the first pole of the second magnet 120 is aligned with the first magnet 300. The second position indicates: the second magnet 120 is located when the second magnetic pole of the second magnet 120 faces the accommodation chamber 113. If the object is placed in the accommodation chamber 113, the second position of the second magnet 120 is: the second magnetic pole of the second magnet 120 is aligned with the first magnet 300.

In some embodiments, if the second pole of the first magnet 300 faces the second magnet 120; the second magnet 120 is located at the first position, the first magnetic pole of the second magnet 120 is aligned with the second magnetic pole of the first magnet 300, the second magnet 120 and the first magnet 300 attract each other, and the first magnet 300 can drive the target object to be fixed in the accommodating compartment 113, that is, the target object can be kept in the accommodating compartment 113 under the action of the attraction force of the second magnet 120, so that the risk of the target object being separated from the accommodating compartment 113 is reduced, and the target object is convenient to accommodate. The second magnet 120 is located at the second position, the second magnetic pole of the second magnet 120 is aligned with the second magnetic pole of the first magnet 300, the second magnet 120 and the first magnet repel each other, the first magnet 300 can drive the target object to be bounced, the bounced target object can increase the size that a user can clamp the target object, and the target object can be taken out conveniently. Similarly, if the first magnetic pole of the first magnet 300 faces the second magnet, the second magnet 120 is in the first position, the second magnet and the first magnet 300 repel each other, and the first magnet 300 can bring the target object to be bounced. The second magnet 120 is in the second position, the second magnet 120 and the first magnet 300 are attracted to each other, and the first magnet 300 can drive the target object to be fixed in the accommodating chamber 113. Fig. 1 exemplarily shows a partial structural view of the receiving module when the second magnet 120 is in the first position. When the target object needs to be taken out, the first assembly 140 is moved along the solid line direction in fig. 1 by using an external force, and the first assembly 140 drives the second magnet 120 to move to the second position, so that the target object is ejected out, and the target object is convenient to take out. When the target is not needed, the first assembly 140 is moved along the direction of the dotted line in fig. 1, and the first assembly 140 drives the second magnet 120 to return to the first position.

When the first magnetic pole is an N pole, the second magnetic pole is an S pole; when the first magnetic pole is S pole, the second magnetic pole is N pole.

In the disclosed embodiment, the target can be suspended in the accommodation chamber 113. The height of the object ejection may be controlled by adjusting the distance between the second magnet 120 and the first magnet 300. Generally, the smaller the distance between the second magnet 120 and the first magnet 300, the higher the target ejection height. Alternatively, the height of the object ejection may be controlled by adjusting the strength of the magnetic force of the first magnet 300 and/or the second magnet 120. For example: on the premise that the distance between the first magnet 300 and the second magnet 120 is equal, the second magnet 120 is made of a material with higher magnetic strength, and the ejection height of the target is higher.

The second shell forms the outer surface of the containing module, reduces damage to the target object caused by external force and has a protection effect on the target object. Without limitation, the storage module further includes a cover or filler located between the first housing 111 and the second housing 112 to cover the linkage assembly.

The end of the second magnet 120 facing the receiving compartment 113 may have only two poles or more than two poles.

In some embodiments, the second magnet 120 includes: two magnet units, the first magnetic poles of which are respectively located at opposite ends of the second magnet 120. At this time, the end of the second magnet 120 facing the receiving compartment 113 has only two poles. As shown in fig. 6 to 8, two magnet units are arranged side by side, the shaded portion represents the N pole, and the unshaded portion represents the S pole, and it can be seen that the N poles of the two magnet units are oppositely oriented.

In some embodiments, the second magnet 120 includes: four magnet units; the first end 125 and the second end 126 of the second magnet 120 each have a magnet unit, wherein the second end 126 is opposite to the first end 125; two of the magnet units are provided between the first end 125 and the second end 126; when the second magnet 120 is between the first position and the second position, the first magnet 300 is simultaneously aligned with the two magnet units 123 and 124 located between the first end 125 and the second end 126, and the two magnet units 123 and 124 located between the first end 125 and the second end 126 have different magnetic poles toward the ends of the first magnet 300. At this time, the end of the second magnet 120 facing the accommodation chamber 113 has four magnetic poles, two S poles and two N poles, respectively. As shown in fig. 9, the first magnetic pole is an N pole, the second magnetic pole is an S pole, and the S pole of the first magnetic pole faces the second magnetic pole 120. The two magnet units 121 and 122 located at both ends are arranged side by side in a first direction, and the two magnet units 123 and 124 located between the first end 125 and the second end 126 are arranged side by side in a second direction perpendicular to the first direction. When the second magnet 120 is at the first position, an attractive force is generated between the magnet unit 121 at the first end 125 and the first magnet 300; when the second magnet 120 is at the second position, a repulsive force is generated between the magnet unit 122 at the second end 126 and the first magnet 300; when the second magnet 120 is located between the first position and the second position, since one of the two magnet units 124 and 123 facing the accommodation chamber 113 has the same magnetic pole as the magnetic pole adjacent to the first magnet 300, and the other magnet unit 124 facing the accommodation chamber 113 has a different magnetic pole from the magnetic pole adjacent to the first magnet 300, the acting force between the first magnet 300 and the second magnet 120 is weak, that is, at this position, the second magnet 120 has neither significant repulsive force nor significant attractive force to the first magnet 300, and the acting force between the second magnet 120 and the first magnet 300 can be approximately zero. Thus, the middle two magnet units 123 and 124 provide a transition position for the second magnet 120 between the first position and the second position. In practical application, the transition position further deepens the feeling of the user between the fixed state and the popup state of the target object, and enriches the perception state of the user in the adjustment process.

As can be seen from the above embodiments, when the first assembly 140 of the present disclosure drives the second magnet 120 to switch between the first position and the second position under the action of an external force, the magnetic pole of the second magnet 120 facing the accommodating chamber 113 is also switched accordingly. When the magnetic poles of the second magnet 120 aligned with the first magnet 300 are the same, the second magnet 120 has a repulsive force to the first magnet 300, and the target object with the first magnet 300 can be bounced by the repulsive force, so that the size of the target object which can be clamped by a user is increased, and the target object can be conveniently taken out.

In other optional embodiments, the linkage module further comprises:

a second assembly 150 vertically disposed with the first assembly 140;

when the second magnet 120 is located at the first position, the first component 140 contacts a first surface of the second component 150, and the second component 150 is restricted from following the first component 140 to move along a second direction, wherein the second direction is perpendicular to the first direction;

when the second magnet 120 is in the second position, a second surface of the second component 150 contacts the first component 140, restricting the first component 140 from moving in the first direction; wherein the second surface is an adjacent surface to the second surface; wherein the second surface is an adjacent surface to the second surface.

In the embodiment of the present disclosure, the moving direction of the first assembly 140 is perpendicular to the moving direction of the second assembly 150. As shown in fig. 1, when the second magnet 120 is in the first position, the second assembly 150 does not restrict movement of the first assembly 140 in the first direction, but the first assembly 140 restricts movement of the second assembly 150 in the second direction. When the first assembly 140 moves in the first direction under the action of an external force and drives the second magnet 120 to move to the second position, the first assembly 140 does not limit the movement of the second assembly 150 in the second direction, but the second assembly 150 limits the movement of the first assembly 140 in the first direction, and under the limit action of the second assembly 150, the first assembly 140 can drive the second magnet 120 to maintain the second position. Thus, with the second assembly 150, the second magnet 120 may be maintained in the second position.

In other alternative embodiments, the second magnet 120 is in the first position, the second magnet 120 and the first magnet 300 are attracted to each other;

the second magnet 120 is in the second position, the second magnet 120 and the first magnet 300 are repulsive to each other; and the top end of the second assembly 150 is higher than the top surface of the first housing 111 and/or the second housing.

In practical applications, the top end of the second assembly 150 is higher than the first housing 111 and the second housing 112, as shown in fig. 5, when the second magnet 120 is at the second position, a portion of the second assembly 150 higher than the top surface of the first housing 111 and/or the second housing 112 is convenient for a user to apply an external force, and the second assembly 150 is controlled to move, so as to release the limit of the second assembly 150 on the first assembly 140, and enable the first assembly 140 to drive the second magnet 120 to return to the first position.

In some embodiments, the storage module further includes a cover 200, wherein when the object is ejected, the cover 200 is in an open state, and when the object is stored in the receiving compartment 113, the cover 200 is in a closed state. In the closing process, the cover 200 may simultaneously apply an external force to a portion of the second assembly 150 higher than the top surface of the first housing 111, so that the second assembly 150 releases the limit on the first assembly 140 while the cover 200 is closed, and the first assembly 140 drives the second magnet 120 to return to the first position.

In other alternative embodiments, the second assembly 150 comprises:

a moving column 151;

a self-locking member 152 connected to the moving column 151, having the first surface 1521 and the second surface 1522;

the storage module further comprises: a first elastic member 160 having both ends connected to the self-locking member 152 and the second housing 112, respectively;

the first component 140 includes:

a base portion 143 connected to the second magnet 120 between the self-locking piece 153 and the first housing 111;

a stopper portion 144 connected to the base portion 143 to protrude toward the second member 150;

the second magnet 120 is at the first position, the stopper portion 144 is parallel to the self-locking member 152 in the second direction, the stopper portion 144 is in contact with the first surface 1521, and the first elastic member 160 is in an elastic deformation state storing an elastic force;

the second magnet 120 is at the second position, the limiting portion 144 is parallel to the self-locking member 152 in the first direction, the limiting portion 144 is aligned with the second surface 1522 of the self-locking member 152 and contacts with the second surface 1522, and the first elastic member 160 is elastically deformed.

Without limitation, the first elastic member 160 includes, but is not limited to: a spring or a leaf spring.

In some embodiments, the first elastic member 160 is a compression spring, and as shown in fig. 1 to 4, the first surface 1521 may be a top surface of the self-locking member 152, and the second surface 1522 may be a side surface of the self-locking member 152. The cooperation of self-locking member 152 with first assembly 140 provides a self-locking function. Specifically, when the second magnet 120 is located at the first position, the bottom surface of the limiting portion 144 abuts against the top surface of the self-locking member 152, so as to limit the self-locking member 152 from driving the moving column 151 to move upward and compress the first elastic member 160. When the second magnet 120 is located at the second position, the position-limiting portion 144 is staggered from the first surface 1521 of the self-locking member 152 along with the movement of the base portion 143, the first elastic member 160 releases the elastic force and drives the self-locking member 152 to move along the second direction, and the moved self-locking member 152 has a position-limiting locking effect on the first component 140 by abutting against the position-limiting portion 143.

As shown in fig. 1 and 2, the second magnet 120 is in the second position, and the top end of the moving column 151 is higher than the top surface of the first housing 111. When the cover is closed, the cover touches the moving column 151 higher than the top surface of the first housing, and drives the second assembly 150 to move, and then the first assembly 140 drives the second magnet 120 to return to the first position.

In other alternative embodiments, the first component 140 further comprises:

a key 130 connected to the base portion 143 and having a space 141 with the limiting portion 144, wherein the key 130 is at least partially located outside the second housing 112, and the key 130 is used for receiving the external force;

the second magnet 120 is in the second position and the self-locking member 152 is located in the space between the button 130 and the retainer portion 144.

As shown in fig. 1 and 2, the key 130 and the base portion 143 are integrated, and when the key 130 is driven by an external force, the key 130 drives the base portion 143 and the position-limiting portion 144 to move in the same direction.

In some embodiments, the key 130 and the base portion 143 may also be a split structure, and when the second magnet 120 is located at the first position, the key 130 and the base portion 143 may be spaced apart from each other, and in this case, the first assembly 140 further includes an elastic member such as a spring, and one end of the elastic member is connected to the key 130. When the key 130 is pressed, the key 130 drives the base portion 143 and the limiting portion 144 to move along the first direction, and then the base portion 143 drives the second magnet 120 to move to the second position, at this time, the key 130 compresses the elastic component to generate deformation, and the elastic component generates elastic force. The button 130 is restored to a spaced state relative to the base portion 143 by the elastic force of the elastic member.

As shown in fig. 3, the portion of the key 130 exposed outside the second casing 112 is used for receiving external force, which is convenient for operation.

In other alternative embodiments, the second housing 112 has: avoiding holes;

the key 130 penetrates through the avoidance hole.

As shown in fig. 3, a portion of the key 130 is located between the first casing 111 and the second casing 112 to contact the base portion 143, and another portion of the key passes through the avoiding hole and is at least partially exposed outside the second casing 112, so that the exposed first component 140 is more convenient for a user to apply an external force to move the first component 140.

In other optional embodiments, the storage module further comprises:

two stoppers 190, each having a through hole 191, connected to the second housing 112;

the moving column 151 penetrates through the through hole 191;

the self-locking element 152 is located between two of the position-limiting elements 190, and the first elastic element 160 is located between the self-locking element 152 and one of the position-limiting elements 190.

As shown in fig. 1, 2 and 4, the through hole 191 has a guiding function for the movement of the second assembly 150, and the two stoppers 190 define the maximum distance that the second assembly can move up and down, respectively. For example: when the second magnet 120 is at the first position, the lower position limiting member 190 can limit the second assembly 150 from moving downwards by contacting the self-locking member 152; similarly, when the second magnet 120 is in the second position, the upper position-limiting member 190 contacts the self-locking member 152, and limits the second assembly 150 from moving upward.

In other optional embodiments, the storage module further comprises:

a cover 200 connected to the second housing 112;

a cover magnet 210 coupled to the cover body 200;

a third magnet 170 coupled to the first assembly 140;

the first pole of the third magnet 170 is aligned with the cover magnet 210 when the second magnet 120 is in the first position;

the second pole of the third magnet 170 is aligned with the cover magnet 210 when the second magnet 120 is in the second position.

As shown in fig. 1, the cover magnet 210 and the third magnet 170 are coupled in a similar manner to the first magnet 300 and the second magnet 120, and will not be described in detail.

The cover body can play a certain sealing role in the containing cabin, and further enhances the protection of the target object.

In some embodiments, the cover 200 and the second housing 112 rotate relative to each other. When the second magnet 120 is at the first position, if the second magnet 120 and the first magnet 300 attract each other, the cover 200 has a first posture; when the second magnet 120 is in the second position, the second magnet 120 and the first magnet repel each other, and the cover 200 has a second posture. At this time, the first posture means: the posture of the cover 200 when the cover is in a closed state with respect to the accommodation compartment 113. The second posture refers to a posture of the cover body 200 when the cover body 200 is in an open state with respect to the receiving compartment. When the second magnet 120 is in the first position, the separation of the cover body 200 from the second housing 112 is restricted by the mutual attraction force of the cover magnet 21 and the third magnet 170. When the target object needs to be taken, the first component 140 is moved to drive the second magnet 120 to move to the second position, so that not only the target object is bounced, but also the cover body 200 can be bounced off under the action of repulsive force between the magnets, and further the target object is convenient to take.

In other optional embodiments, the storage module further comprises:

a second elastic member 180 having both ends connected to the first assembly 140 and the second housing 112, respectively;

when the second magnet 120 is in the second position, the first component 140 drives the second elastic member 180 to be in a deformed state storing elastic force.

The second elastic element is, without limitation, a spring or a leaf spring.

As shown in fig. 1 and 2, the second elastic member 180 is a compression spring, and when the second magnet 120 is in the second position, the base portion 143 of the first assembly 140 compresses the second elastic member 180 to store the elastic force. After the second assembly 150 releases the limit on the second assembly 150, the second elastic member 180 recovers the elastic deformation, and the released elastic force is utilized to drive the first assembly 140 to move, so that the first assembly 140 drives the second magnet 120 to automatically recover to the first position.

In other optional embodiments, the storage module further comprises:

a limit rod 113 connected to the second housing 112 and having a passage with the first housing 111;

the channel accommodates the first component 140.

As shown in fig. 1 and 2, the first member 140 moves within the channel when driven by an external force. The channel has a guiding effect on the movement of the first component 140.

In other optional embodiments, the storage module further comprises:

and a charging device located between the first housing 111 and the second housing for charging the object.

In the embodiment of the present disclosure, when the target has a battery, the charging device can charge the target accommodated in the accommodating compartment 113, so as to charge the target while accommodating the target, thereby enriching the functions of the accommodating module.

In some embodiments, the charging device is a wireless charging device comprising a charging coil capable of coupling with a receiving coil in a target object to enable wireless charging.

In some embodiments, the charging device is a wired charging device, the wired charging device comprising: and a charging terminal contacting the power receiving terminal of the object to realize wired charging.

In some embodiments, the housing further has: and the external interface can be at least used for being connected with an external power supply to realize the charging of the charging device.

In a specific example, as shown in fig. 1 to 9, the target is a TWS (True Wireless Stereo) headset, and the storage module includes: the magnetic coupling device comprises a magnet part, a linkage component part, a self-locking part and a slide fixing part. The magnet part is as follows: the second magnet 120 includes a headphone eject magnet and a headphone adsorption magnet. The second magnet 120 may be a bipolar or multipolar magnet, the attracting magnet of the second magnet 120 corresponds to the earphone built-in magnet (i.e., the first magnet 300) in an N-S manner toward the opposite surface, and the control manner is based on the fact that the magnetic pole can effectively attract the earphone built-in magnet; the opposite surface of the ejection magnetic pole of the control magnet and the built-in magnet of the earphone is N-N or S-S corresponding, and the control mode is based on the fact that the magnetic pole can effectively eject the built-in magnet of the earphone. The second magnet 120 is a bipolar magnet, or a multi-pole magnet, or two magnets N, S are arranged in a close-fitting manner, that is, N, S magnetic poles are arranged on the same surface at the same time, one magnet can be used for bipolar magnetization or multi-pole magnetization, two magnets can be used for bipolar or multi-pole magnetization and then bonded together (the magnet shape includes square, round, triangular or special-shaped), or the magnet can be obtained by radial magnetization of a cylindrical magnet. The pole face of the second magnet 120 needs to effectively act on the pole face of the built-in magnet of the earphone, and by moving the pole face of the second magnet 120, the adsorption magnetic pole of the earphone corresponding to the position of the built-in magnet of the earphone is gradually moved to be the ejection magnetic pole of the earphone. The height of the ejected earphone can be controlled by adjusting the position of the magnetic pole of the second magnet 120 corresponding to the magnet in the earphone. The earpiece ejection height may be controlled by the second magnet 120 push distance.

The linkage assembly portions are as follows: two second magnets 120 corresponding to the left earphone and the right earphone are respectively installed at corresponding positions of the linkage push rod (namely, the base part 143), the distance between the left-end earphone adsorption magnet 121 and the left-end earphone ejection magnet 122 on the left earphone second magnet 120 is arranged at equal intervals with the right-end earphone adsorption magnet 121 and the right-end earphone ejection magnet 122 on the right earphone second magnet 120, the opposite ends of the second magnets 120 and the built-in earphone magnets are tightly attached to the upper end of the linkage push rod, and the second magnets are firmly adhered by an adhesive after being fixed in position. The third magnet 170 is installed to a corresponding position of the linkage push rod, the third magnet 170 has an adsorption magnetic pole 171 (which may be referred to as a first magnetic pole) and an ejection magnetic pole 172 (which may be referred to as a second magnetic pole), the adsorption magnetic pole 171 is opposite to the built-in magnet of the earphone hatch, and the fixed position is adhered by an adhesive. The spring (i.e., the second elastic member 180) connected with the linkage push rod is sleeved on the connecting rod spring pin 142, and the connecting end of the spring and the linkage push rod is firmly bonded by an adhesive. The pop-up push button (i.e. the push button 130) is installed at a position corresponding to the linkage push rod. The initial position of the linkage push rod is an earphone adsorption position, the ejection push button is pushed to be ejected, the ejection push button drives the linkage push rod to move towards the spring end of the linkage push rod, the left and right earphone second magnets 120 and the third magnet 170 fixed on the linkage push rod move towards the spring end of the linkage push rod at equal intervals, the magnets on the earphone built-in magnet, the cover magnet 210 and the push rod gradually change from an attraction state to a mutual repulsion state, and the earphone cabin cover are automatically ejected.

As shown in fig. 1 and 4, the self-locking portion is as follows: when the linkage push rod moves to the position of the earphone popping magnet, the self-locking piece 152 on the linkage push rod moves to the outer side of the bayonet of the self-locking piece (namely the limiting part 144 of the first component 140), an upward channel (namely the interval between the limiting part 144 and the key 130) of the self-locking piece 152 is released, the self-locking piece 152 is pushed by the elastic force of the self-locking rod spring (namely the first elastic piece 160) to lock the linkage push rod to move, so that the second magnet 120 keeps the earphone popping magnet opposite to the earphone built-in magnet, and the earphone is suspended on the earphone cabin, thereby being convenient for a user to take. The moving post 151 is upward with the self-locking member 152 and the top is higher than the upper surface of the earphone chamber.

When the cover of the earphone box is closed, the plane of the cover presses the movable column 151 downwards, and the movable column 151 is linked with the self-locking piece 152 to move downwards. When the self-locking member 152 is completely separated from the stopper 144, the link push rod automatically returns to the initial position due to the spring force of the link push rod.

As shown in fig. 1, 2, and 3, the row bit fixing part is as follows: the lower part of the linkage push rod is close to the limiting rod 113, and the upper part of the linkage push rod is tightly pressed by the bottom plane of the wall 112 of the earphone cabin, so as to control the horizontal position of the upper and lower stages of the linkage push rod. The limiting rod 113 is bonded to the corresponding position of the earphone case body by using an adhesive. One end of the first elastic member 160 is connected to the push rod, and the other end is connected to a linked push rod spring stop pin fixed on the housing 110, wherein the first elastic member 160 is sleeved outside the stop pin, and the stop pin and the earphone box body are adhered to the corresponding position of the housing 110 by an adhesive.

The disclosed embodiment also provides an earphone assembly, including:

the storage module of any of the above embodiments;

an earphone, located in the receiving compartment 113, has a first magnet 300.

The headset includes, but is not limited to, a wireless headset. For example: TWS headphones.

In practical application, the wireless earphone is placed in the accommodating cabin. When the earphone is used, the first assembly is pushed, the box cover is automatically opened, the two earphones automatically pop up to the height of 5-7 mm, and the popping state is kept for limiting the second assembly through the third assembly. The person of facilitating the use takes out the use, and when the earphone lid was covered, the lid pressed down the self-moving post that stretches out, and earphone and second magnet adsorption state are returned to in push rod automatic re-setting, and earphone cabin closely laminate, make to charge and contact firmly, stably. Therefore, the earphone has the advantages that the double functions of adsorbing and pushing out the earphone are achieved by utilizing a double magnetic circuit (two magnet units) or a multi-magnetic circuit design (more than two magnet units), the small space is effectively utilized, the earphone can be automatically switched between two states of close attachment between the earphone and the shell and automatic ejection of the earphone from the accommodating cabin, the earphone cabin has a self-locking function, and the earphone cabin and the earphone are kept in the adsorption and ejection states. Meanwhile, the earphone can be automatically recovered to the adsorption state from the ejection state by closing the box cover. And rational in infrastructure, can be applicable to various adverse circumstances, energy-concerving and environment-protective, easy operation, degree of automation is high to the earphone pops out the position and accomplishes controllably through the magnetic circuit design mode, and it is controllable to pop out the distance, and the earphone adsorbs, pops out the state auto-lock, and functions such as adsorption state automatic re-setting facilitate the user and take the earphone, has greatly increased the characteristics of the comfort level when the user uses.

Features disclosed in several of the product embodiments provided in this disclosure may be combined in any combination to yield new product embodiments without conflict.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This disclosure is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (12)

1. A storage module, comprising:

a first housing having a receiving compartment; the accommodating cabin is used for accommodating a target object with a first magnet;

a second housing located outside the first housing;

the linkage module is positioned between the first shell and the second shell; the linkage module includes:

a second magnet having, relative to the containment compartment: a first position in which a first magnetic pole of the second magnet faces the housing compartment, and a second position in which a second magnetic pole of the second magnet faces the housing compartment;

a first assembly coupled to the second magnet;

the first component drives the second magnet to switch between the first position and the second position along a first direction along with an external force; wherein the first direction is parallel to a distribution direction of the first magnetic pole and the second magnetic pole.

2. The containing module of claim 1, wherein the linkage module further comprises:

the second assembly is vertically distributed with the first assembly;

when the second magnet is in the first position, the first component is in contact with a first surface of the second component, and the second component is limited to move along a second direction along with the first component, wherein the second direction is perpendicular to the first direction;

when the second magnet is in the second position, a second surface of the second component is in contact with the first component, and the first component is limited from moving along the first direction; wherein the second surface is an adjacent surface to the second surface.

3. The containing module of claim 2, wherein the second magnet is in the first position, the second magnet being attracted to the first magnet;

the second magnet is in the second position, the second magnet is mutually repulsive with the first magnet; and the top end of the second component is higher than the top surface of the first shell and/or the second shell.

4. The containing module of claim 2, wherein the second assembly comprises:

moving the column;

a self-locking member connected to the moving post and having the first surface and the second surface;

the storage module further comprises: the two ends of the first elastic piece are respectively connected with the self-locking piece and the second shell;

the first assembly includes:

a base portion connected to the second magnet and located between the self-locking member and the first housing;

a stopper portion connected to the base portion, protruding toward the second component;

the second magnet is in the first position, the limiting part is parallel to the self-locking piece in the second direction, the limiting part is in contact with the first surface, and the first elastic piece is in an elastic deformation state for storing elastic force;

the second magnet is in the second position, the limiting part is parallel to the self-locking piece in the first direction, the limiting part is aligned with the second surface of the self-locking piece and contacts with the second surface, and the first elastic piece restores elastic deformation.

5. The containing module of claim 4, wherein the first assembly further comprises:

the key is connected with the base part and has a gap with the limiting part, at least part of the key is positioned outside the second shell, and the key is used for receiving the external force;

the second magnet is in the second position and the self-locking member is located in the space between the key and the retainer portion.

6. The containing module of claim 5, wherein the second housing has: avoiding holes;

the key penetrates through the avoiding hole.

7. The containing module of claim 4, further comprising:

the two limiting pieces are provided with through holes and connected with the second shell;

the moving column penetrates through the through hole;

the self-locking piece is located between two locating parts, and the first elastic piece is located between the self-locking piece and one locating part.

8. The containing module of any one of claims 1 to 7, further comprising:

the cover body is connected with the second shell;

a cover magnet connected to the cover body;

a third magnet coupled to the first assembly;

a first pole of the third magnet is aligned with the cover magnet when the second magnet is in the first position;

the second pole of the third magnet is aligned with the cover magnet when the second magnet is in the second position.

9. The containing module of claim 1, further comprising:

the two ends of the second elastic piece are respectively connected with the first assembly and the second shell;

when the second magnet is located at the second position, the first assembly drives the second elastic piece to be in a deformation state of storing elastic force.

10. The containing module of claim 1, further comprising:

the limiting rod is connected with the second shell, and a channel is formed between the limiting rod and the first shell;

the channel receives the first component.

11. The containing module of claim 1, further comprising:

and the charging device is positioned between the first shell and the second shell and is used for charging the target object.

12. An earphone assembly, comprising:

the containing module of any one of claims 1 to 11;

an earphone is positioned in the accommodating cabin and provided with a first magnet.

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