CN110980441A - Intelligent device and charging wire storage device - Google Patents

Abstract

The utility model provides an intelligent device and charging wire storage device. The intelligent device includes: fuselage, electric quantity storage module, charging wire, storage assembly and electricity generation subassembly. The body is formed with an accommodation cavity and an outlet hole. The electric quantity storage module is arranged in the accommodating cavity. The chamber is held to at least part of charging wire, and one end is connected with electric quantity storage module, and the fuselage is worn out by the wire hole to the other end, and is connected with connecting plug. Accomodate the subassembly and locate and hold the chamber for release and accomodate the charging wire. The power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and when the charging wire is released and accommodated by the accommodating assembly, the power generation assembly is driven to generate power. The charging wire can not only be accomodate to the smart machine, still can generate electricity, promotes product competitiveness and user experience.

Description

Intelligent device and charging wire storage device

Technical Field

The utility model relates to an intelligence house product field especially relates to an intelligent equipment and charging wire storage device.

Background

With the advent of the internet of things era, more and more intelligent devices such as intelligent household products are provided. But most of smart machines need insert the power through the charging wire and realize the power supply, and when there are a plurality of smart machines, can go out the line charging wire and be mixed and disorderly, cause to use with and the potential safety hazard easily. Based on this, it is necessary to store a charging wire of the smart device.

Disclosure of Invention

The utility model provides a modified smart machine and charging wire storage device.

One aspect of the present disclosure provides a smart device, including:

the body is provided with an accommodating cavity and a wire outlet hole;

the electric quantity storage module is arranged in the accommodating cavity;

the charging wire is at least partially arranged in the accommodating cavity, one end of the charging wire is connected with the electric quantity storage module, and the other end of the charging wire penetrates out of the machine body through the wire outlet and is connected with a connecting plug;

the accommodating assembly is arranged in the accommodating cavity and used for releasing and accommodating the charging wire; and

the power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and the storage assembly releases and stores the power generation assembly for power generation when the charging wire is used for driving the power generation assembly to generate power.

Optionally, the charging wire is wound around the storage assembly, at least part of the power generation assembly is arranged on the storage assembly, the charging wire is released and stored to drive the storage assembly to rotate, the storage assembly drives at least part of the power generation assembly to rotate, and the power generation assembly generates power based on electromagnetic induction.

Optionally, the power generation assembly comprises a magnetic induction coil and at least two magnetic poles, and a magnetic induction line region is formed between the at least two magnetic poles;

the magnetic induction coil is arranged on the containing assembly and is positioned in the magnetic induction line area, and two ends of the magnetic induction coil are connected with the electric quantity storage module;

the storage assembly releases and stores the charging wire and rotates to drive the magnetic induction coil to rotate in the magnetic induction line area so as to cut the magnetic induction line.

Optionally, an axis of the magnetic induction coil is perpendicular to an axis of a rotation direction of the receiving assembly, and the axis of the rotation direction of the receiving assembly is perpendicular to a magnetic induction line between at least two magnetic poles.

Optionally, at least two of the magnetic poles are longitudinally arranged in the accommodating cavity, and the accommodating assembly is transversely arranged and rotates around the transverse direction.

Optionally, the receiving assembly comprises a fixing shaft, a rotating body and a first elastic piece; the fixed shaft is arranged in the accommodating cavity; the rotating body is rotatably sleeved on the fixed shaft;

the charging wire is wound on the rotating body, and the magnetic induction coil is arranged on the rotating body;

the one end of first elastic component with the rotor is connected, the other end with the fixed axle is connected, the rotor release during the charging wire, first elastic component is followed the direction of rotation of rotor is compressed.

Optionally, the accommodating assembly further includes a first limiting member slidably disposed at the outlet of the outlet hole, and configured to limit the charging wire.

Optionally, the accommodating assembly includes a rotatable rotating shaft and a driving member for driving the rotating shaft to rotate, the charging wire is wound around the rotating shaft, and the magnetic induction coil is disposed on the rotating shaft;

the intelligent device further comprises a control module connected with the driving piece and the power generation assembly, wherein the control module is configured to control the driving piece to drive the rotating shaft to rotate for a first reference time in response to receiving an induced current signal generated by the power generation assembly when the charging wire is released, so as to release the charging wire.

Optionally, the smart device further includes a pay-off button disposed on the surface of the body, and the pay-off button is connected to the control module, and the control module is further configured to control the driving member to drive the rotating shaft to rotate the first reference time in response to receiving a pay-off instruction sent by the pay-off button, so as to release the charging wire.

Optionally, the smart machine is still including locating the receipts line button on fuselage surface, with control module connects, control module is still configured to be in response to receiving receive the line instruction that receives the line button and send, control the driving piece drive the pivot rotates the second reference time, in order to accomodate the charging wire.

Optionally, the storage assembly further includes a second elastic member, one end of the second elastic member is connected to the rotating shaft, the other end of the second elastic member is connected to the body, and when the rotating shaft releases the charging wire, the second elastic member is compressed along the rotating direction of the rotating shaft; and/or the presence of a gas in the gas,

the storage assembly further comprises a second limiting part which is arranged at the outlet of the wire outlet hole in a sliding mode and used for limiting the charging wire.

Optionally, the bottom of the body forms the accommodating cavity and the wire outlet hole.

Optionally, the smart device comprises a smart speaker.

Another aspect of the present disclosure provides a charging wire storage device, the charging wire storage device includes:

the shell is provided with an accommodating cavity and a wire outlet hole;

the electric quantity storage module is arranged in the accommodating cavity;

the charging wire is at least partially arranged in the accommodating cavity, one end of the charging wire is connected with the electric quantity storage module, and the other end of the charging wire penetrates out of the machine body through the wire outlet and is connected with a connecting plug;

the accommodating assembly is arranged in the accommodating cavity and used for releasing and accommodating the charging wire; and

the power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and the storage assembly releases and stores the power generation assembly for power generation when the charging wire is used for driving the power generation assembly to generate power.

The intelligent device and charging wire storage device that this disclosed embodiment provided release the charging wire through storage assembly to conveniently charge to the intelligent device. Accomodate the charging wire through storage assembly, avoid influencing the environment because of the charging wire is mixed and disorderly to and the charging wire mixes the problem that causes the potential safety hazard. And, when accomodating the subassembly release and accomodating the charging wire, the drive power generation subassembly electricity generation and save in electric quantity storage module to when guaranteeing not having the power, smart machine can also use, promotes product competitiveness and user experience.

Drawings

FIG. 1 illustrates a partial cutaway view of a smart device according to an exemplary embodiment of the present disclosure;

FIG. 2 is a schematic diagram illustrating the relative positions of charging wires and the receiving assembly and the power generating assembly according to an exemplary embodiment of the present disclosure;

FIG. 3 is a schematic diagram illustrating a charging cord and storage assembly and a power generation assembly according to an exemplary embodiment of the present disclosure;

FIG. 4 is a schematic view illustrating the connection between the first elastic member and the fixing shaft and the rotating body according to an exemplary embodiment of the present disclosure;

fig. 5 is a schematic structural diagram illustrating a charging wire and a receiving assembly and a power generation assembly according to an exemplary embodiment of the present disclosure.

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 apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

The terminology used in the present disclosure is for the purpose of describing particular embodiments only and is not intended to be limiting of the disclosure. Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in the description and claims does not indicate any order, quantity, or importance, but rather is used to distinguish one element from another. Also, the use of the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. Unless otherwise indicated, the word "comprise" or "comprises", and the like, means that the element or item listed before "comprises" or "comprising" covers the element or item listed after "comprises" or "comprising" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect.

As used in this disclosure and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

In some embodiments, the smart device is connected to the power source through a charging wire for charging. In other embodiments, the smart machine embeds the battery, but the battery can influence smart machine's volume and weight to battery power uses up the back, still needs external power source to charge, uses the charging wire again naturally. Along with the diversification of intelligent house product, a plurality of smart machine can appear in the environment at home, and every smart machine all has the charging wire, and this makes the environment at home mixed and disorderly, still can arouse to use in mixture, causes the potential safety hazard.

In some embodiments, the smart device includes a charging cord storage assembly, such as a vacuum cleaner. However, the subassembly is accomodate to the charging wire only can accomodate the charging wire, when not having the power, still can not normal use smart machine, can not promote product competitiveness and user experience.

In order to solve the above problem, the embodiment of the present disclosure provides a smart device and a charging wire storage device. In some embodiments, smart devices include, but are not limited to: the system comprises a mobile phone, a tablet computer, an iPad, a digital broadcast terminal, a messaging device, a game console, a medical device, a fitness device, a personal digital assistant, an intelligent wearable device, an intelligent television, an intelligent home product and the like. In other embodiments, the smart device comprises a smart speaker.

Fig. 1 is a partial cross-sectional view of a smart device 100 according to an exemplary embodiment of the present disclosure, in which a vertical arrow indicates a magnetic induction line direction and a dotted arrow indicates a rotation direction of a storage assembly 140 in fig. 1. Referring to fig. 1, the smart device 100 includes: the body 110, the power storage module 120, the charging wire 130, the receiving assembly 140 and the power generation assembly 150.

The body 110 is formed with a receiving cavity 111 and an outlet hole 112. In some embodiments, the bottom of the body 110 forms a receiving cavity 111 and an outlet hole 112, and the receiving cavity 111 communicates with the outlet hole 112. Therefore, the layout of other components in the machine body 110 is not influenced, the space at the bottom of the machine body 110 is fully utilized, and the attractiveness of the intelligent device 100 is facilitated.

The power storage module 120 is disposed in the accommodating cavity 111, and the power storage module 120 supplies power to the smart device 100. In some embodiments, the power storage module 120 includes rechargeable batteries. The battery may be a lithium ion battery.

At least a portion of the charging wire 130 is disposed in the accommodating cavity 111, one end of the charging wire is connected to the power storage module 120 (not shown), and the other end of the charging wire passes through the body 110 via the wire outlet 112 and is connected to the connection plug 131. It can be appreciated that the connector plug 131 is retained outside the outlet 112 to facilitate the user pulling the charging cord 130. In some embodiments, the connection plug 131 is connected to an external power source, so that the power source charges the charge storage module 120 through the charge line 130.

The receiving assembly 140 is disposed in the accommodating cavity 111 for releasing and receiving the charging cable 130. It can be appreciated that when the storage assembly 140 releases the charging cord 130, a portion of the charging cord 130 exits the storage assembly 140 and extends out of the receiving cavity 111 through the outlet aperture 112, and the length of the charging cord 130 outside the body 110 increases. When the charging cable 130 is received in the receiving assembly 140, a large number of charging cables 130 are received in the receiving assembly 140, and the length of the charging cable 130 outside the body 110 is reduced.

The power generation assembly 150 is disposed in the accommodating cavity 111 and connected to the power storage module 120, and when the charging wire 130 is released and accommodated in the accommodating assembly 140, the power generation assembly 150 is driven to generate power. The current generated by the power generation assembly 150 is stored in the power storage module 120 to power the smart device 100.

The smart device 100 provided by the embodiment of the present disclosure releases the charging wire 130 through the storage assembly 140, so as to conveniently charge the smart device 100. Accomodate charging wire 130 through accomodating subassembly 140, avoid influencing the environment because of charging wire 130 is mixed and disorderly to and charging wire 130 mixes the problem that causes the potential safety hazard. Moreover, when the charging line 130 is released and stored in the storage assembly 140, the power generation assembly 150 is driven to generate power and store the power in the power storage module 120, so that the intelligent device 100 can be used when no power supply exists, and the product competitiveness and the user experience are improved.

In some embodiments, the charging wire 130 is wound around the storage assembly 140, at least a portion of the power generation assembly 150 is disposed on the storage assembly 140, the charging wire 130 drives the storage assembly 140 to rotate when being released and stored, the storage assembly 140 drives at least a portion of the power generation assembly 150 to rotate, and the power generation assembly 150 generates power based on electromagnetic induction. In this way, the receiving assembly 140 drives the power generating assembly 150 to rotate so as to cut the magnetic induction lines, thereby generating power. In some embodiments, the receiving assembly 140 drives the magnetic induction coil 151 to rotate so as to cut the magnetic induction line to generate power. In other embodiments, the receiving assembly 140 drives the magnetic pole 152 to rotate, so that the magnetic induction lines are changed, and the magnetic induction coil 151 cuts the magnetic induction lines to generate electricity.

In some embodiments, referring to fig. 1, the power generation assembly 150 includes a magnetic induction coil 151 and at least two poles 152. At least two magnetic poles 152 form a magnetic induction line area, and at least part of the receiving assembly 140 is rotatably arranged in the magnetic induction line area. The magnetic induction coil 151 is disposed in the receiving assembly 140 and located in the magnetic induction line region, and the magnetic induction coil 151 is connected to the power storage module 120. In specific implementation, two ends of the wire wound around the magnetic induction coil 151 may be led out and connected to the power storage module 120. In addition, the outgoing lines at the two ends of the outgoing line need to have a suitable length, so that when 140 rotates and drives the magnetic induction coil 151 to rotate, the outgoing line at the two ends of the outgoing line is not damaged in the winding process, for example: breaking or breaking away from the charge storage module 120, etc. The storage assembly 140 rotates when releasing and storing the charging wire 130, and since the magnetic induction coil 151 is disposed on the storage assembly 140, the storage assembly 140 drives the magnetic induction coil 151 to rotate in the magnetic induction area to cut the magnetic induction wire, thereby generating power. In some embodiments, when the storage assembly 140 releases the charging wire 130 by pulling or other methods, the charging wire 130 drives the storage assembly 140 to rotate in the first direction 191, and the storage assembly 140 drives the magnetic induction coil 151 to rotate in the first direction 191 and cut the magnetic induction wire, thereby generating power. In other embodiments, when the charging wire 130 is received by the receiving assembly 140, the charging wire 130 drives the receiving assembly 140 to rotate in the second direction 192, and the receiving assembly 140 drives the magnetic induction coil 151 to rotate in the second direction 192 and cut the magnetic induction line, so as to generate electricity. In fig. 1, the first direction 191 and the second direction 192 are rotation directions of the receiving assembly 140, and the second direction 192 is opposite to the first direction 191. The power generation assembly 150 and the storage assembly 140 are matched, power can be generated when the charging wire 130 is released and stored, energy is fully utilized, the position relation between the power generation assembly and the storage assembly is favorable for reducing occupied space, and high integration and size miniaturization of the intelligent device 100 are facilitated. In some embodiments, the holding assembly 140 is provided with a fixing bracket 149, and the magnetic coil 151 is disposed on the fixing bracket 149, so that when the holding assembly 140 rotates, the magnetic coil 151 disposed on the fixing bracket 149 is driven to rotate. Wherein the fixing bracket 149 includes a disk around which the magnetic induction coil 151 may be wound. Alternatively, the magnetic induction coil 151 is connected to an end of the fixed bracket 149. The present disclosure does not specifically limit how the magnetic induction coil 151 is provided to the housing assembly 140.

In some embodiments, the magnetic induction coil 151 has a regular or irregular structure such as a circle, a square, an ellipse, etc., which is not particularly limited in the present disclosure. In some embodiments, at least two poles 152 are oppositely disposed, and one of the two opposite poles 152 is a pole N and the other is a pole S.

In order to provide the power generating assembly 150 with a strong power generating capability so as to enable current to flow to the power storage module 120, in some embodiments, referring to a schematic diagram of relative positions of the charging wire 130, the accommodating assembly 140 and the power generating assembly 150 shown in fig. 2 according to an exemplary embodiment of the present disclosure, an axis L1 of the magnetic induction coil 151 is perpendicular to an axis L2 of a rotation direction of the accommodating assembly 140, and an axis L2 of the rotation direction of the accommodating assembly 140 is perpendicular to a magnetic induction line between at least two magnetic poles 152. In some embodiments, the magnetic flux of the magnetic induction coil 151 changes most when the magnetic induction coil rotates, so that a larger current can be generated.

In some embodiments, referring to fig. 1, at least two magnetic poles 152 are disposed in the accommodating cavity 111 along the longitudinal direction, a magnetic induction line region is formed between the at least two magnetic poles 152, and the receiving assembly 140 is disposed along the transverse direction and rotates around the transverse direction. In this way, the storage module 140 and the power generation module 150 are facilitated to be matched with the space of the body 110 of the smart device 100, the high integration and the volume miniaturization of the smart device 100 are facilitated, and the storage module 140 and the power generation module 150 are conveniently arranged.

The present disclosure gives the following embodiments with respect to the structure of the receiving assembly 140:

in some embodiments, referring to a schematic structural view of the charging wire 130 and the receiving assembly 140 and the power generating assembly 150 shown in fig. 3 according to an exemplary embodiment of the present disclosure, the receiving assembly 140 includes a fixed shaft 141, a rotating body 142, and a first elastic member 143. The fixing shaft 141 is fixed to the receiving cavity 111. The rotating body 142 is rotatably fitted on the fixed shaft 141. The charging wire 130 is wound around the rotating body 142, and the magnetic induction coil 151 is provided on the rotating body 142. Fig. 4 is a schematic view illustrating the connection between the first elastic member 143 and the fixed shaft 141 and the rotating body 142 according to an exemplary embodiment of the present disclosure. Referring to fig. 4, one end of the first elastic member 143 is coupled to the rotating body 142 and the other end is coupled to the fixed shaft 141, and when the rotating body 142 releases the charging wire 130, the first elastic member 143 is compressed in a rotating direction of the rotating body 142. In some embodiments, when the charging wire 130 is pulled, the charging wire 130 drives the rotating body 142 to rotate, the rotating body 142 drives the magnetic induction coil 151 to rotate, and the magnetic induction coil 151 cuts the magnetic induction wire to generate power. In other embodiments, after the charging is completed, the rotating body 142 is rotated again under the elastic action of the first elastic member 143 to store the charging wire 130, and the magnetic induction coil 151 is driven to rotate to generate power.

In some embodiments, with continued reference to fig. 4, the first elastic element 143 may be a flat spiral spring, which can compress and restore in the rotation direction. In some embodiments, the rotating body 142 has a disc shape, a cylinder shape or other structures, and a limiting groove may be disposed thereon to prevent the charging wire 130 from being separated from the rotating body 142 during the storage process.

In order to stabilize the length of the charging wire 130 outside the body 110, in some embodiments, the receiving assembly 140 further includes a first limiting member 144 slidably disposed at the wire outlet 112 for limiting the charging wire 130.

In other embodiments, referring to fig. 5, which is a schematic structural view illustrating a charging wire 130, a receiving assembly 140 and a power generating assembly 150 according to an exemplary embodiment of the present disclosure, the receiving assembly 140 includes a rotatable rotating shaft 145 and a driving member 146 for driving the rotating shaft 145 to rotate, the charging wire 130 is wound around the rotating shaft 145, and the magnetic induction coil 151 is disposed on the rotating shaft 145. The smart device 100 further includes a control module 160 connected to the driving member 146 and the power generating assembly 150, wherein the control module 160 is configured to control the driving member 146 to drive the rotating shaft 145 to rotate for a first reference time in response to receiving an induced current signal generated by the power generating assembly 150 when the charging wire 130 is released, so as to release the charging wire 130. In some embodiments, the charging wire 130 is pulled outwards, the charging wire 130 drives the rotating shaft 145 to rotate, since the magnetic induction coil 151 is disposed on the rotating shaft 145, the rotating shaft 145 drives the magnetic induction coil 151 to rotate, the magnetic induction coil 151 cuts the magnetic induction wire to generate an induced current signal, and the control module 160 controls the driving member 146 to drive the rotating shaft 145 to rotate after receiving the induced current signal, so as to automatically release the charging wire 130. At the same time, the current generated by the magnetic induction coil 151 cutting the magnetic induction lines is also stored in the power storage module. In some embodiments, the magnetic coil 151 may be mounted to the shaft 145 by a mounting bracket 149.

The first reference time is set based on the release length of the charging wire 130, and may be, for example, 1 to 10 seconds. In some embodiments, the control module 160 receives the induced current signal at a third reference time interval, which is set based on the release time of the charging line 130. In some embodiments, the drive 146 may be a micro-motor. In some embodiments, control module 160 is a Central Processing Unit (CPU) of smart device 100.

In other embodiments, the smart device 100 further includes a pay-off button 170 disposed on the surface of the body 110, and the control module 160 is connected to the control module 160, and the control module 160 is further configured to control the driving member 146 to drive the rotating shaft 145 to rotate for a first reference time in response to receiving a pay-off command from the pay-off button 170, so as to release the charging cable 130. In some embodiments, when the pay-off button 170 is pressed, the pay-off button 170 sends a pay-off command to the control module 160, and the control module 160 controls the driving member 146 to rotate the rotating shaft 145 based on the pay-off command, so as to release the charging cable 130. This way can avoid magnetic induction coil 151 can not produce induced current signal and can not drive the pivoted condition of pivot 145 rotation, guarantees to conveniently control smart machine 100 and releases charging wire 130.

Further, in order to conveniently receive the charging cable 130, in some embodiments, the smart device 100 further includes a wire rewinding button 180 disposed on a surface of the body 110, and is connected to the control module 160, and the control module 160 is further configured to control the driving member 146 to drive the rotating shaft 145 to rotate for a second reference time in response to receiving a wire rewinding command sent by the wire rewinding button 180, so as to receive the charging cable 130. In some embodiments, when the wire retrieving button 180 is pressed, the wire retrieving button 180 sends a wire retrieving instruction to the control module 160, and the control module 160 controls the driving member 146 to drive the rotating shaft 145 to rotate based on the wire retrieving instruction, so as to receive the charging wire 130. This mode is simple, does benefit to smart machine 100 and accomodates charging wire 130 automatically to still can produce electric current and store in the electric quantity memory cell.

Further, in order to prevent the driving member 146 from being unable to work normally and thus the receiving assembly 140 from releasing and receiving the charging cable 130, in some embodiments, the receiving assembly 140 further includes a second elastic member 147, one end of which is connected to the rotating shaft 145, and the other end of which is connected to the body 110, and when the rotating shaft 145 releases the charging cable 130, the second elastic member 147 is compressed along the rotating direction of the rotating shaft 145. And/or, the receiving assembly 140 further includes a second limiting member 148 slidably disposed at the wire outlet 112 for limiting the position of the charging wire 130. In some embodiments, the charging cord 130 is pulled outward and engages the second stop 148 to stabilize the length of the charging cord 130 extending out of the body 110. When the charging wire 130 is stored, the sliding of the second limiting member 148 releases the limiting effect on the charging wire 130, and the second elastic member 147 restores to its original shape and drives the rotating shaft 145 to rotate to store the charging wire 130. In some embodiments, the second elastic member 147 includes a flat spiral spring.

Some embodiments of the present disclosure also provide a charging wire storage device, including: casing, electric quantity storage module, charging wire, storage assembly and electricity generation subassembly. The housing is formed with a receiving cavity and an outlet hole. The electric quantity storage module is arranged in the accommodating cavity. The chamber is held to at least part of charging wire, and one end is connected with electric quantity storage module, and the fuselage is worn out by the wire hole to the other end, and is connected with connecting plug. The storage assembly is arranged in the accommodating cavity and is wound by the charging wire for releasing and storing the charging wire. The power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and when the charging wire is released and accommodated by the accommodating assembly, the power generation assembly is driven to generate power.

The charging wire storage device that this disclosed embodiment provided releases the charging wire through storage assembly to conveniently charge to smart machine. Accomodate the charging wire through storage assembly, avoid influencing the environment because of the charging wire is mixed and disorderly to and the charging wire mixes the problem that causes the potential safety hazard. And, when accomodating the subassembly release and accomodating the charging wire, the drive power generation subassembly electricity generation and save in electric quantity storage module to when guaranteeing not having the power, smart machine can also use, promotes product competitiveness and user experience.

For the embodiment of the charging line storage apparatus, since it basically corresponds to the embodiment of the smart device, reference may be made to part of the description of the embodiment of the smart device for relevant points, and details are not described here again. The charging line storage device embodiment and the smart machine embodiment are complementary to each other.

The above embodiments of the present disclosure may be complementary to each other without conflict.

The above description is only exemplary of the present disclosure and should not be taken as limiting the disclosure, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure should be included in the scope of the present disclosure.

Claims (14)

1. A smart device, the smart device comprising:

the body is provided with an accommodating cavity and a wire outlet hole;

the electric quantity storage module is arranged in the accommodating cavity;

the charging wire is at least partially arranged in the accommodating cavity, one end of the charging wire is connected with the electric quantity storage module, and the other end of the charging wire penetrates out of the machine body through the wire outlet and is connected with a connecting plug;

the accommodating assembly is arranged in the accommodating cavity and used for releasing and accommodating the charging wire; and

the power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and the storage assembly releases and stores the power generation assembly for power generation when the charging wire is used for driving the power generation assembly to generate power.

2. The intelligent device according to claim 1, wherein the charging wire is wound around the storage assembly, at least part of the power generation assembly is arranged on the storage assembly, the charging wire drives the storage assembly to rotate when being released and stored, the storage assembly drives at least part of the power generation assembly to rotate, and the power generation assembly generates power based on electromagnetic induction.

3. The smart device of claim 2, wherein the power generation assembly comprises a magnetic induction coil and at least two magnetic poles, a magnetic induction line region being formed between at least two of the magnetic poles;

the magnetic induction coil is arranged on the containing assembly and is positioned in the magnetic induction line area, and the magnetic induction coil is connected with the electric quantity storage module;

the storage assembly releases and stores the charging wire and rotates to drive the magnetic induction coil to rotate in the magnetic induction line area so as to cut the magnetic induction line.

4. The smart device of claim 3, wherein an axis of the magnetic induction coil is perpendicular to an axis of a rotational direction of the housing assembly, and the axis of the rotational direction of the housing assembly is perpendicular to a magnetic induction line between at least two of the magnetic poles.

5. The smart device of claim 3, wherein at least two of the magnetic poles are disposed in the receiving cavity in a longitudinal direction, and the receiving assembly is disposed in a transverse direction and rotates around a transverse axis.

6. The smart device of claim 3, wherein the housing assembly comprises a fixed shaft, a rotating body, and a first elastic member; the fixed shaft is arranged in the accommodating cavity; the rotating body is rotatably sleeved on the fixed shaft;

the charging wire is wound on the rotating body, and the magnetic induction coil is arranged on the rotating body;

the one end of first elastic component with the rotor is connected, the other end with the fixed axle is connected, the rotor release during the charging wire, first elastic component is followed the direction of rotation of rotor is compressed.

7. The smart device of claim 6, wherein the housing assembly further comprises a first limiting member slidably disposed at the outlet, for limiting the charging wire.

8. The intelligent device according to claim 3, wherein the housing assembly comprises a rotatable rotating shaft and a driving member for driving the rotating shaft to rotate, the charging wire is wound around the rotating shaft, and the magnetic induction coil is arranged on the rotating shaft;

the intelligent device further comprises a control module connected with the driving piece and the power generation assembly, wherein the control module is configured to control the driving piece to drive the rotating shaft to rotate for a first reference time in response to receiving an induced current signal generated by the power generation assembly when the charging wire is released, so as to release the charging wire.

9. The smart device as claimed in claim 8, wherein the smart device further comprises a pay-off button disposed on the surface of the body and connected to the control module, and the control module is further configured to control the driving member to drive the rotating shaft to rotate for the first reference time in response to receiving a pay-off command from the pay-off button, so as to release the charging wire.

10. The intelligent device of claim 8, further comprising a take-up button disposed on the surface of the body and connected to the control module, wherein the control module is further configured to control the driving member to drive the rotating shaft to rotate for a second reference time in response to receiving a take-up command from the take-up button to receive the charging wire.

11. The intelligent device according to claim 8, wherein the storage assembly further comprises a second elastic member, one end of the second elastic member is connected with the rotating shaft, the other end of the second elastic member is connected with the machine body, and when the rotating shaft releases the charging wire, the second elastic member is compressed along the rotating direction of the rotating shaft; and/or the presence of a gas in the gas,

the storage assembly further comprises a second limiting part which is slidably arranged at the wire outlet and used for limiting the charging wire.

12. The smart device of claim 1, wherein a bottom of the body forms the receiving cavity and the outlet hole.

13. The smart device of any one of claims 1-12, wherein the smart device comprises a smart sound box.

14. The utility model provides a charging wire storage device, its characterized in that, charging wire storage device includes:

the shell is provided with an accommodating cavity and a wire outlet hole;

the electric quantity storage module is arranged in the accommodating cavity;

the charging wire is at least partially arranged in the accommodating cavity, one end of the charging wire is connected with the electric quantity storage module, and the other end of the charging wire penetrates out of the machine body through the wire outlet and is connected with a connecting plug;

the accommodating assembly is arranged in the accommodating cavity and used for releasing and accommodating the charging wire; and

the power generation assembly is arranged in the accommodating cavity and connected with the electric quantity storage module, and the storage assembly releases and stores the power generation assembly for power generation when the charging wire is used for driving the power generation assembly to generate power.

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