KR20200083114A - Suppementary battery for wire and wireless power transmission - Google Patents

Abstract

Provided is a supplementary battery capable of wireless power transmission. According to an embodiment of the present invention, the supplementary battery comprises: a reception module receiving at least one power signal through one wireless charging method of an RF method, a magnetic induction method, or a magnetic resonance method from a power device; a power storage unit storing at least one power signal transmitted from the reception module; a sensor sensing whether at least one user reception device is in proximity or contact; and a transmission module, when the at least one user reception device is detected to be in proximity or contact, transmitting the at least one power signal stored in the power storage unit or the at least one power signal transmitted from the reception module to the at least one user reception device through the one wireless charging method of the RF method, the magnetic induction method, or the magnetic resonance method.

Description

Auxiliary battery that can transmit wired and wireless power{SUPPEMENTARY BATTERY FOR WIRE AND WIRELESS POWER TRANSMISSION}

The following embodiments relate to an auxiliary battery capable of transmitting wired/wireless power, and to an auxiliary battery transmitting power wirelessly or wired to a user receiver including a wireless charging receiver.

Mobile devices such as a smart phone, a tablet pc, and a wearable device are small in size, but various parts are mounted to secure many functions. Among them, a battery for operating various parts is a core part that is essentially provided in a mobile device.

Since such a battery has a limitation in use time according to capacity, a supplementary battery that can charge the battery at any time regardless of location is widely used.

On the other hand, recently, for the convenience of charging the mobile device, a mobile device capable of wireless charging has been released.

However, the technology development for the secondary battery capable of wireless charging and wireless power transmission has not been developed.

One embodiment proposes an auxiliary battery capable of wireless power transmission to provide wireless charging of the user receiver.

In more detail, one embodiment stores and maintains at least one power signal wirelessly received from a power device in a power storage unit, and then transmits it wirelessly to at least one user receiver when necessary, or a power device and at least one user. It proposes an auxiliary battery that wirelessly directly transmits at least one power signal wirelessly received from a power supply device to at least one user receiver without going through a power storage unit when in close proximity or contact with all of the receivers.

In addition, in one embodiment, when the wireless charging method supported by the power supply device is different from the wireless charging method supported by the at least one user receiver, the wireless charging method between the power supply device and the at least one user receiver serves to relay the wireless charging method. Suggest a secondary battery.

According to an embodiment, the auxiliary battery capable of transmitting wireless power includes: a receiving module configured to receive at least one power signal from a power device through one of a wireless charging method of an RF method, a magnetic induction method, or a magnetic resonance method; A power storage unit that stores at least one power signal transmitted from the receiving module; A sensor that detects whether at least one user receiver is in proximity or in contact; And when the at least one user receiver is detected to be in close proximity or contact, the RF method, the magnetic induction method, or the at least one power signal stored in the power storage unit or the at least one power signal transmitted from the receiving module. And a transmission module transmitting to the at least one user receiver through any one of the self-resonant wireless charging methods.

According to one side, the sensor detects whether the power device is in close proximity or contact, and the transmitting module, if both of the at least one user receiver and the power device are detected to be in close proximity or contact, the reception It may be characterized in that the at least one power signal transmitted from the module is transmitted directly to the at least one user receiver without going through the power storage unit.

According to another aspect, the auxiliary battery further includes a communication antenna for communicating with the at least one user receiver, and the transmission module is configured to recharge information related to the at least one user receiver received through the communication antenna. It may be characterized in that the at least one power signal is transmitted to the at least one user receiver.

According to another aspect, the sensor detects whether the power device is in proximity or in contact, and the receiving module detects whether the power device is in proximity or in contact with the at least one power from the power device. It may be characterized by receiving a signal.

According to another aspect, a wireless charging scheme in which the transmitting module transmits the at least one power signal to the at least one user receiver includes a wireless charging in which the receiving module receives the at least one power signal from the power device. It may be characterized by a wireless charging method different from the method.

According to another aspect, at least a portion of the case of the auxiliary battery may be characterized in that a gel pad or a nano suction foam is formed to be detachable from the at least one user receiver.

According to an embodiment, the auxiliary battery device capable of wireless power transmission includes: a power supply device that receives power from a wired line from the outside; And an auxiliary battery implemented to be detachably attached to the power device, wherein the auxiliary battery receives at least one power signal from the power device through a wireless charging method of any one of an RF method, a magnetic induction method, or a magnetic resonance method. A receiving module for receiving; A power storage unit that stores at least one power signal transmitted from the receiving module; A sensor that detects whether at least one user receiver is in proximity or in contact; And when the at least one user receiver is detected to be in close proximity or contact, the RF method, the magnetic induction method, or the at least one power signal stored in the power storage unit or the at least one power signal transmitted from the receiving module. And a transmission module transmitting to the at least one user receiver through any one of the self-resonant wireless charging methods.

According to one side, the sensor detects whether the power device is in close proximity or contact, and the transmitting module, if both of the at least one user receiver and the power device are detected to be in close proximity or contact, the reception It may be characterized in that the at least one power signal transmitted from the module is transmitted directly to the at least one user receiver without going through the power storage unit.

According to another aspect, the auxiliary battery further includes a communication antenna for communicating with the at least one user receiver, and the transmission module is configured to recharge information related to the at least one user receiver received through the communication antenna. It may be characterized in that the at least one power signal is transmitted to the at least one user receiver.

According to another aspect, the power supply device further includes a communication antenna for communicating with the auxiliary battery, and based on the charging related information of the auxiliary battery received through the communication antenna, the at least one power signal is auxiliary It can be characterized in that the transmission by the battery.

According to another aspect, the auxiliary battery device, a separate wireless charging method supporting any one of the wireless charging method that is not supported by the transmission module of the auxiliary battery among the RF method, the magnetic induction method, or the magnetic resonance method It may further include a support module.

According to another aspect, the wireless charging method support module may be implemented to be coupled to the power supply device.

According to an embodiment, a wireless charging system providing wireless charging includes: at least one user receiver; And an auxiliary battery device that provides wireless charging for the at least one user receiver, the auxiliary battery device comprising: a power device that is supplied with power from a wired line from the outside; And an auxiliary battery implemented to be detachably attached to the power device, wherein the auxiliary battery receives at least one power signal from the power device through a wireless charging method of any one of an RF method, a magnetic induction method, or a magnetic resonance method. A receiving module for receiving; A power storage unit that stores at least one power signal transmitted from the receiving module; A sensor that detects whether the at least one user receiver is in proximity or in contact; And when the at least one user receiver is detected to be in close proximity or contact, the RF method, the magnetic induction method, or the at least one power signal stored in the power storage unit or the at least one power signal transmitted from the receiving module. And a transmission module transmitting to the at least one user receiver through any one of the self-resonant wireless charging methods.

According to one side, the sensor detects whether the power device is in close proximity or contact, and the transmitting module, if both of the at least one user receiver and the power device are detected to be in close proximity or contact, the reception It may be characterized in that the at least one power signal transmitted from the module is transmitted directly to the at least one user receiver without going through the power storage unit.

According to another aspect, the auxiliary battery further includes a communication antenna for communicating with the at least one user receiver, and the transmission module is configured to recharge information related to the at least one user receiver received through the communication antenna. It may be characterized in that the at least one power signal is transmitted to the at least one user receiver.

One embodiment may propose an auxiliary battery that is capable of wireless power transmission and provides wireless charging of the user receiver.

In more detail, one embodiment stores and maintains at least one power signal wirelessly received from a power device in a power storage unit, and then transmits it wirelessly to at least one user receiver when necessary, or a power device and at least one user. It is possible to propose an auxiliary battery that wirelessly directly transmits at least one power signal wirelessly received from a power supply device to at least one user receiver without passing through the power storage unit when it is in close proximity or contact with all of the receivers.

In addition, in one embodiment, when the wireless charging method supported by the power supply device is different from the wireless charging method supported by the at least one user receiver, the wireless charging method between the power supply device and the at least one user receiver serves to relay the wireless charging method. An auxiliary battery can be proposed.

1 is a view showing a wireless charging system according to an embodiment.
FIG. 2 is a view for explaining the power supply device shown in FIG. 1.
3 is a block diagram showing the auxiliary battery shown in FIG. 1.
4 is a view for explaining a receiving module and a transmitting module included in the auxiliary battery shown in FIG. 3.
5 is a view for explaining a wireless charging method support module coupled to the power supply device shown in FIG. 1.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. In addition, the same reference numerals shown in each drawing denote the same members.

In addition, terms used in the present specification (terminology) are terms used to properly express a preferred embodiment of the present invention, which may vary according to a user, an operator's intention, or customs in the field to which the present invention pertains. Therefore, definitions of these terms should be made based on the contents throughout the present specification.

1 is a view showing a wireless charging system according to an embodiment, FIG. 2 is a view for explaining the power supply device shown in FIG. 1, and FIG. 3 is a block diagram showing the auxiliary battery shown in FIG. 1, FIG. 4 is a diagram for explaining a receiving module and a transmitting module included in the auxiliary battery shown in FIG. 3, and FIG. 5 is a diagram for explaining a wireless charging method supporting module coupled to the power supply device shown in FIG. 1.

1 to 5, the wireless charging system 100 according to an embodiment includes at least one user receiver 110 and an auxiliary battery device providing wireless charging for the at least one user receiver 110 ( 120). Hereinafter, the at least one user receiver 110 is the same as a mobile device used by a user, and is equipped with a wireless charging receiver to support a wireless charging method.

The auxiliary battery device 120 transmits at least one power signal to the at least one user receiver 110 as the at least one user receiver 110 approaches or contacts the at least one user receiver 110. For wireless charging. Hereinafter, the power signal may be implemented in the form of a pulse or CW (Continuous Wave).

In addition, hereinafter, the auxiliary battery device 120 is described as providing wireless charging by wirelessly transmitting at least one power signal to the at least one user receiver 110, but is not limited thereto, but is not limited thereto. Instead of transmitting a signal, the at least one user receiver 110 is wiredly connected (for example, the auxiliary battery 122 included in the auxiliary battery device 120 is connected to the at least one user receiver 110) Wired charging may also be provided by transmitting at least one power signal over the wire.

The auxiliary battery device 120 is composed of a power supply unit 121 that is supplied with power from the outside through a wire and an auxiliary battery 122 that is implemented to be detachably attached to the power supply unit 121.

Hereinafter, as the power device 121 is formed in a square box shape and the auxiliary battery 122 is formed in a circular column shape, the auxiliary battery device 120 is described and illustrated as having a camera shape, but is not limited or limited thereto. The auxiliary battery 122 may be formed in a shape that functions as an accessory that is portable to a user who uses the at least one user receiver 110. For example, the auxiliary battery 122 is formed in the form of a doll and the power device 121 is formed in the shape of a Christmas tree, so that the auxiliary battery 122 in the form of a doll is detachably attached to the power device 121 in the shape of a Christmas tree. It can have structure.

The power device 121 is a device that receives power by wire from the outside and transmits at least one power signal to the detachable auxiliary battery 122, or charges the power storage unit included in the auxiliary battery 122, or the auxiliary battery At least one user receiver 110 may be directly charged through 122. In more detail, the power supply unit 121 converts and supplies external AC power to DC as shown in FIG. 2, and supplies AC-DC power supplies 210 and at least one frequency band based on the supplied DC power. Oscillator 220 for generating a power signal, a matching unit 230 for matching and outputting at least one power signal for each frequency, and a transmitting antenna 240 for transmitting at least one power signal to the auxiliary battery 122 It may be implemented in a structure comprising a. In some cases, the power device 121 may be implemented to further include a power amplifier 250 that amplifies at least one power signal output from the oscillator 220 as shown in the figure.

At this time, an RF method, a magnetic induction method, or a magnetic resonance method may be used as a wireless charging method in which the power device 121 transmits at least one power signal. Therefore, the components constituting the power supply 121 are not limited to or limited to the above-described examples, and may be variously implemented in a structure capable of using an RF method, a magnetic induction method, or a magnetic resonance method.

In addition, the power supply unit 121 further includes a communication antenna 260 for communicating with the auxiliary battery 122, so that at least one is based on charging-related information of the auxiliary battery 122 received through the communication antenna 260. The power signal may be transmitted to the auxiliary battery 122. Here, the charging-related information received from the auxiliary battery 122 includes information indicating that the auxiliary battery 122 is in proximity or contact, information indicating the current charge amount of the power storage unit included in the auxiliary battery 122, or the auxiliary battery 122. It may include information on the wireless charging method supported (information on the wireless charging method supported by the auxiliary battery 122 among the RF method, the magnetic induction method, or the magnetic resonance method). Accordingly, when the charge amount of the power storage unit of the auxiliary battery 122 is less than or equal to a predetermined value in the state where the auxiliary battery 122 is proximate or in contact, the power supply device 121 transmits at least one power signal to the auxiliary battery. By transmitting to the auxiliary battery 122 in a wireless charging method supported by the 122, the auxiliary battery 122 can be wirelessly charged.

The components of the power supply device 121 have been described as the main components of the respective operations, but are not limited or limited thereto, and may be a control unit (not shown). In this case, the power device 121 may be implemented with a structure including a control unit.

The auxiliary battery 122 has a case of a shape that can be coupled to a portion of the power supply unit 121, and at least a portion of the case is formed with a gel pad or nano suction foam that is detachably attached to at least one receiver 110. Can be.

The auxiliary battery 122 includes a receiving module 310, a power storage unit 320, a sensor 330, and a transmitting module 340 as shown in FIG. 3 inside the case, and at least one user receiver 110 Or it may further include a communication antenna 350 for communicating with the power supply 121. Detailed descriptions of these are described below with reference to FIG. 4.

The receiving module 310 receives at least one power signal from the power device 121 through a wireless charging method of any one of an RF method, a magnetic induction method, or a magnetic resonance method. Here, the receiving module 310 communicates with the communication antenna 260 included in the power supply device 121 through the communication antenna 350 or the sensor 330, which will be described later, and supplies charging-related information of the auxiliary battery 122 to the power supply device. By transmitting to (121), when the power supply device 121 is in proximity or contact, the power supply device 121 may transmit at least one power signal in a wireless charging method supported by the reception module 310.

More specifically, the receiving module 310 includes a receiving antenna 410 for receiving at least one power signal from the power supply 121, a rectifier 420 for converting at least one power signal into a DC signal, and a rectifier 420. It may be implemented in a structure including a DC-DC converter / voltage regulator 430 to convert the DC signal transmitted from the DC signal suitable for storage in the power storage unit 320.

The power storage unit 320 stores at least one power signal transmitted from the reception module 310.

The sensor 330 detects whether at least one user receiver 110 is in proximity or in contact. Various sensors capable of recognizing and detecting the approach of at least one user receiver 110, such as a proximity sensor, a pressure sensor, and an infrared sensor, may be used as the sensor 330, and the at least one user receiver 110 may be used. In addition to whether it is in close proximity or contact, it can also detect whether the power supply 121 is in proximity or contact. The detection result is transmitted to the transmitting module 340 or the receiving module 310, so that each of the transmitting module 340 or the receiving module 310 can selectively operate. For example, the receiving module 310 is activated only when the power device 121 is sensed to be in close proximity or to be contacted to receive at least one power signal from the power device 121, and at least one user receiver ( The transmission module 340 is activated only when it is sensed that 110 is approached or in contact, so that at least one power signal can be transmitted to the at least one user receiver 110.

The transmitting module 340 wirelessly charges at least one power signal stored in the power storage unit 320 or at least one power signal transmitted from the receiving module 310 by any one of an RF method, a magnetic induction method, or a magnetic resonance method. As a component that transmits to at least one user receiver 110 through a method, more specifically, a DC signal (at least one power signal) stored in the power storage unit 320 or a DC-DC converter of the receiving module 310 / DC power supply 440 for supplying a DC signal (at least one power signal) transmitted from the voltage regulator 430, based on the supplied DC signal to generate at least one power signal having at least one frequency band A structure including an oscillator 450, a matching unit 460 for matching and outputting at least one power signal for each frequency, and a transmitting antenna 470 for transmitting at least one power signal to at least one user receiver 110. Can be implemented as In some cases, the transmission module 340 may be implemented to further include a power amplifier 480 that amplifies at least one power signal output from the oscillator 450 as illustrated.

In particular, when the transmission module 340 detects that the at least one user receiver 110 is in close proximity or is in contact, the transmission module 340 is transmitted from the at least one power signal or the reception module 310 stored in the power storage unit 320 It is characterized in that at least one power signal is transmitted to at least one user receiver 110 through a wireless charging method of any one of an RF method, a magnetic induction method, or a magnetic resonance method.

For example, as a result of sensing by the sensor 330 or the communication antenna 350 to be described later, when at least one user receiver 110 is detected to be in close proximity or contact (the power supply 121 is not in proximity or contact) If it is detected), the transmission module 340 outputs at least one power signal stored in the power storage unit 320, and at least one user receiver from the charging-related information of the at least one user receiver 110 ( By checking the wireless charging method used by 110), at least one power signal may be transmitted to the at least one user receiver 110 through the wireless charging method.

For another example, when the sensor 330 or the communication antenna 350 described below detects that both the at least one user receiver 110 and the power supply 121 are in proximity or contact, the receiving module ( 310) will be already activated and receiving at least one power signal from the power supply unit 121. Accordingly, the transmission module 340 may directly transmit at least one power signal transmitted from the reception module 310 to the at least one user receiver 110 without going through the power storage unit 320.

As described above, when the transmission module 340 selectively receives at least one power signal to be transmitted to the at least one user receiver 110 from the power storage unit 320 or the reception module 310, the auxiliary battery 122 It may be possible by further including a switching element (490). For example, as shown in the drawing, the switching element 490 is disposed between the output terminal of the DC-DC converter/voltage regulator 430 of the receiving module 310 and the power storage unit 320, thereby transmitting at least one power signal. The power storage unit 320 may be supplied or at least one power signal may be supplied to the DC power supply 440. Accordingly, the transmission module 340 receives at least one power signal stored in the power storage unit 320 through the switching element 490 or at least one power received from the power supply 121 at the reception module 310. The signal can be supplied directly through the switching element 490.

That is, the auxiliary battery 122 including the transmission module 340 operating in this way acts as a "battery" that supports wireless charging and a role as a "relay" that relays wireless charging of the power supply 121. It can be selectively performed depending on whether it is close or in contact.

In this case, when the details of the role as a "repeater" for relaying the wireless charging of the auxiliary battery 122 are described in detail, the role as a "repeater" includes a wireless charging method supported by the power supply 121 and at least one user receiver In an environment in which the wireless charging methods supported by 110) are different, it may mean a role of relaying wireless charging between the power device 121 and at least one user receiver 110. For example, when the power device 121 supports the self-resonance method and at least one user receiver 110 supports the RF method, the receiving module 310 transmits at least one power signal through the self-resonance method. By receiving and transmitting to the transmission module 340, the transmission module 340 transmits at least one power signal transmitted to the at least one user receiver 110 in an RF manner, so that the auxiliary battery 122 is a "repeater" Can play a role as. In other words, the auxiliary battery 122 has a wireless charging method in which the transmitting module 340 transmits at least one power signal to the at least one user receiver 110. Based on the wireless charging method different from the wireless charging method for receiving at least one power signal, it may serve as a "relay".

The communication antenna 350 is configured to cause the transmission module 340 to transmit at least one power signal to the at least one user receiver 110 based on the charging related information of the at least one user receiver 110 received. Can. Here, the charging-related information received from the at least one user receiver 110 is information indicating that the at least one user receiver 110 is in close proximity or contact, and the power storage unit included in the at least one user receiver 110. Information indicating the current charging amount or information on a wireless charging method supported by at least one user receiver 110 (wireless charging supported by at least one user receiver 110 of an RF method, a magnetic induction method, or a magnetic resonance method) Method). Accordingly, the charging-related information of the at least one user receiver 110 received through the communication antenna 350 is at least one user receiver 110 in a state where the at least one user receiver 110 is in close proximity or contact. ), when the charge amount of the power storage unit has a predetermined value or less and indicates that charging is required, the transmission module 340 may transmit at least one power signal in a wireless charging method supported by at least one user receiver 110. By transmitting to one user receiver 110, at least one user receiver 110 can be wirelessly charged.

In addition, the communication antenna 350 is the information indicating that the power supply device 121 is approaching or contacting (information that detects whether the power supply device 121 is approaching or contacting), wireless charging method information supported by the reception module 310 Alternatively, the charging related information of the auxiliary battery 122 including the information related to the charge amount of the power storage unit 320 may be transmitted to the power supply device 121.

At this time, the information indicating that the at least one user receiver 110 is in proximity or contact and the information indicating that the power supply 121 is in proximity or contact may be obtained by the sensor 330 described above. In this case, the transmission module 340 may perform an operation of transmitting at least one power signal when the sensor 330 detects that at least one user receiver 110 is in proximity or contact, and the reception module ( 310) may perform an operation of receiving at least one power signal when it detects that the power supply device 121 is in proximity or contact.

That is, information indicating that the at least one user receiver 110 is approaching or contacting and information indicating that the power supply unit 121 is approaching or contacting is obtained from any one of the communication antenna 350 or the sensor 330. As it can be, the auxiliary battery 122 may be implemented to selectively include only one of the sensor 330 or the communication antenna 350.

The components of the auxiliary battery 122 are described above as the main components of the respective operations, but are not limited or limited thereto, and may be a control unit (not shown). In this case, the auxiliary battery 122 may be implemented with a structure including a control unit, and the control unit is implemented to be included in each of the components constituting the auxiliary battery 122 or integrates the components constituting the auxiliary battery 122 It can be implemented as a single control.

In addition, when the auxiliary battery 122 does not support all of the RF method, the magnetic induction method or the magnetic resonance method, the auxiliary battery device 120 transmits the auxiliary battery 122 among the RF method, the magnetic induction method, or the magnetic resonance method The module 340 may further include a separate wireless charging method support module 510 that supports any one wireless charging method that is not supported. The wireless charging method support module 510 may be implemented to be coupled to the power supply device 121. For example, when the transmission module 340 of the auxiliary battery 122 does not support the magnetic induction method, the wireless charging method support module 510 is connected to the power supply device 121 to support the magnetic induction method wireless charging method. By being implemented in the form of a coupleable dongle, it is possible to transmit at least one power signal transmitted from the power supply device 121 to at least one user receiver 110 using a magnetic induction method in a magnetic induction method. Here, the wireless charging method support module 510 may be implemented in a structure including components except for the receiving module 310 and the power storage unit 320 in the structure of the auxiliary battery 122 described above.

As described above, although the embodiments have been described by a limited embodiment and drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques are performed in a different order than the described method, and/or the components of the described system, structure, device, circuit, etc. are combined or combined in a different form from the described method, or other components Alternatively, even if replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (15)

In the auxiliary battery capable of wireless power transmission,
A receiving module receiving at least one power signal from a power supply device through one of a wireless charging method of an RF method, a magnetic induction method, or a magnetic resonance method;
A power storage unit that stores at least one power signal transmitted from the receiving module;
A sensor that detects whether at least one user receiver is in proximity or in contact; And
When it is sensed that the at least one user receiver is in proximity or contact, the RF method, the magnetic induction method or the at least one power signal stored in the power storage unit or at least one power signal transmitted from the receiving module is detected. Transmission module for transmitting to the at least one user receiver through any one of the self-resonant wireless charging method
Secondary battery comprising a. According to claim 1,
The sensor,
It detects whether the power device is in close proximity or contact,
The transmission module,
When it is detected that both the at least one user receiver device and the power supply device are in close proximity or contact, the at least one power signal transmitted from the receiving module is directly transmitted to the at least one user receiver without passing through the power storage unit. A secondary battery, characterized in that. According to claim 1,
The auxiliary battery,
Communication antenna for communicating with the at least one user receiver
Further comprising,
The transmission module,
And the at least one power signal is transmitted to the at least one user receiver based on charging related information of the at least one user receiver received through the communication antenna. According to claim 1,
The sensor,
It detects whether the power device is in close proximity or contact,
The receiving module,
The auxiliary battery, characterized in that receiving the at least one power signal from the power device when it is detected that the power device is in close proximity or contact. According to claim 1,
A wireless charging method in which the transmission module transmits the at least one power signal to the at least one user receiver,
The auxiliary battery, characterized in that the receiving module is a wireless charging method different from the wireless charging method for receiving the at least one power signal from the power supply. According to claim 1,
On at least some of the cases of the auxiliary battery,
A secondary battery characterized in that a gel pad or a nano suction foam is formed to be detachable from the at least one user receiver. In the auxiliary battery device capable of wireless power transmission,
A power supply device that is supplied with power by wire from the outside; And
Auxiliary battery implemented to be detachable from the power supply
Including,
The auxiliary battery,
A receiving module for receiving at least one power signal from any of the RF devices, a magnetic induction method, or a magnetic resonance method through a wireless charging method;
A power storage unit that stores at least one power signal transmitted from the receiving module;
A sensor that detects whether at least one user receiver is in proximity or in contact; And
When it is sensed that the at least one user receiver is in proximity or contact, the RF method, the magnetic induction method or the at least one power signal stored in the power storage unit or at least one power signal transmitted from the receiving module is detected. Transmission module for transmitting to the at least one user receiver through any one of the self-resonant wireless charging method
Secondary battery device comprising a. The method of claim 7,
The sensor,
It detects whether the power device is in close proximity or contact,
The transmission module,
When it is detected that both the at least one user receiver device and the power supply device are in close proximity or contact, the at least one power signal transmitted from the receiving module is directly transmitted to the at least one user receiver without passing through the power storage unit. Secondary battery device, characterized in that. The method of claim 7,
The auxiliary battery,
Communication antenna for communicating with the at least one user receiver
Further comprising,
The transmission module,
And transmitting the at least one power signal to the at least one user receiver based on charging-related information of the at least one user receiver received through the communication antenna. The method of claim 7,
The power supply,
Communication antenna for communicating with the auxiliary battery
Further comprising,
An auxiliary battery device, characterized in that the at least one power signal is transmitted to the auxiliary battery based on charging related information of the auxiliary battery received through the communication antenna. The method of claim 7,
The auxiliary battery device,
A separate wireless charging method supporting module supporting any one of the RF method, the magnetic induction method, or the magnetic resonance method, which is not supported by the transmission module of the auxiliary battery.
Secondary battery device further comprising. The method of claim 11,
The wireless charging method support module,
Secondary battery device, characterized in that implemented to be coupled to the power supply. A wireless charging system that provides wireless charging,
At least one user receiver; And
An auxiliary battery device that provides wireless charging to the at least one user receiver
Including,
The auxiliary battery device,
A power supply device that is supplied with power by wire from the outside; And
Auxiliary battery implemented to be detachable from the power supply
It includes,
The auxiliary battery,
A receiving module receiving at least one power signal from the power device through a wireless charging method of any one of an RF method, a magnetic induction method, or a magnetic resonance method;
A power storage unit that stores at least one power signal transmitted from the receiving module;
A sensor that detects whether the at least one user receiver is in proximity or in contact; And
When it is sensed that the at least one user receiver is in proximity or contact, the RF method, the magnetic induction method or the at least one power signal stored in the power storage unit or at least one power signal transmitted from the receiving module is detected. Transmission module for transmitting to the at least one user receiver through any one of the self-resonant wireless charging method
Wireless charging system comprising a. The method of claim 13,
The sensor,
It detects whether the power device is in close proximity or contact,
The transmission module,
When it is detected that both the at least one user receiver device and the power supply device are in close proximity or contact, the at least one power signal transmitted from the receiving module is directly transmitted to the at least one user receiver without passing through the power storage unit. Wireless charging system, characterized in that. The method of claim 13,
The auxiliary battery,
Communication antenna for communicating with the at least one user receiver
Further comprising,
The transmission module,
And transmitting the at least one power signal to the at least one user receiver based on charging related information of the at least one user receiver received through the communication antenna.

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