KR20150046567A - Multi-function wireless charging device - Google Patents

Abstract

Disclosed is a multifunctional wireless charging device which transfers power to different wireless devices such as a smartphone, a smart watch, etc., to enable battery charging. The multifunctional wireless charging device according to the present invention comprises: a first wireless power transfer means which wirelessly transfers power to a first user terminal; a second wireless power transfer means which wirelessly transfers power to a second user terminal; and a wireless power signal generating and control means which determines whether it is required to charge the first and second user terminals mounted on the first and second wireless power transfer means to select the user terminal required to be charged, selectively generates a wireless power signal, and transfers the generated wireless power signal to the selected user terminal.

Description

Multi-function wireless charging device < RTI ID = 0.0 >

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multifunctional wireless charging device capable of charging a battery by transmitting power to different wireless devices such as a smart phone and a smart watch, The present invention relates to a multifunctional wireless charging device that combines a clock, a speaker, and an emotional lighting that are interlocked with the smart device while charging.

Smart Watch, a leader in the next generation of smart devices, wearable devices, is gaining popularity as an auxiliary device for smartphones because it has the strength of relieving the inconvenience of carrying it. For example, it is possible to use a smart watch to check calls, mail / messages without taking out a smart phone, perform a payment function with an electronic wallet function, and combine the functions of a health device, and the usage is expected to explode explosively.

However, in order to be widely available to the general public, it is necessary to upgrade the technology for solving battery mounting problems due to a narrow mounting space, time problems due to battery size limitation, small screens, and inconvenient input methods.

2. Description of the Related Art A secondary battery (battery) that can be recharged as a driving power source is used as a portable electronic device such as a smart phone and a smart watch in order to enhance user's convenience.

Particularly, the prior art (Publication No. 10-2012-0131779) discloses a flexible battery for convenience of use in various portable electronic devices. Even when physical deformation such as bending of the battery occurs, the distance between the electrodes that are reacted is maintained to be very constant, so that a stable electrochemical reaction takes place and the peeling phenomenon of the electrode layer is prevented.

Prior art (Publication No. 10-2012-0052644) discloses a flexible battery and a flexible electronic device including the same as a power source. The disclosed flexible battery includes a cell stack including a plurality of unit cells and an enclosure sealing the cell stack, wherein each unit cell includes a cathode, an anode, an electrolyte layer, and a cathode, an anode, and the electrolyte A flexible polymer electrolyte membrane that includes a plurality of unit cells slidingly contacted with each other to at least partially surround the polymer electrolyte membrane, the flexible polymer electrolyte membrane having excellent flexibility and capable of stable electrochemical reaction even when the cells are repeatedly bent .

BACKGROUND ART [0002] A battery is stored with energy by charging by an external power source. In general, a wire charging system in which a terminal of a charging device and a terminal of a battery are physically brought into contact with each other to be electrically connected is mainly used. However, since the electrical connection in the above-described manner is performed in such a manner that the terminals are physically coupled to each other, physical abrasion may occur and connection reliability may be deteriorated. In many cases, contact terminals are exposed to the outside, So that the contact state is easily deteriorated.

In addition, in an environment with high moisture and humidity, problems such as an electric short-circuit accident or a loss of charged energy may occur.

In order to solve the problem of the contact type wire charging method, a wireless charging technique in which the charging device and the terminals of the battery are physically and non-contact with each other is needed.

Many people are using smart phones and smart phones are used as an auxiliary device in the future. When the smart watch is activated, a wired charging device and a complicated cable for connecting them are smart It becomes necessary for each device and a cosmetic problem arises.

The present invention has been made in order to solve the problems of the prior art described above and it is an object of the present invention to provide a smart phone and a smart watch which can wirelessly and simultaneously charge wirelessly with one wireless charging device, , A clock function, and a speaker function.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a multi-function wireless charging device including first wireless power transmission means for wirelessly transmitting power to a first user terminal, first wireless power transmission means for wirelessly transmitting power to a second user terminal, A second wireless power transmission means for transmitting a wireless power signal to the first and second wireless power transmission means, a second wireless power transmission means for transmitting the wireless power signal to the first and second wireless power transmission means, And transmits the generated power control signal to the selected user terminal.

In a preferred embodiment, the first user terminal is a wrist bracelet-type smart watch, and the first wireless power transmission means is a wrist bracelet- Shape.

If it is determined that the user terminal is not stationed in the first or second wireless power transmission means or the user terminal is stationary but no charging is required, the wireless power transmission and reception means And controls to switch to the standby power mode.

In a preferred embodiment, the wireless power signal generation and control means comprises at least one processor, wherein the processor is configured to: (a) when the first user terminal is placed on the first wireless power transmission means, (B) receiving, from the first user terminal, information relating to the strength of a received signal, required power (information relating to battery remaining capacity) and an identifier; (c) And selectively generate a wireless power signal using the identifier.

Meanwhile, the multi-function wireless charging device according to the present invention may further include short-distance wireless communication means for short-range wireless communication connection with the first user terminal or the second user terminal.

The multifunction wireless charging apparatus according to the present invention may further comprise illumination means for providing illumination based on a control signal received from the first or second user terminal communicatively connected to the short-range wireless communication means.

 The multi-function wireless charging device may further include speaker means for outputting an audio signal or a voice signal based on the control signal received from the first or second user terminal communicatively connected to the short-range wireless communication means have.

In another embodiment, the multi-function wireless charging device according to the present invention further comprises short-range wireless communication means for supporting a short-range wireless communication connection with the first user terminal or the second user terminal, And automatically select and connect the communicating user terminals based on the information related to the required power.

As described above, according to the present invention, a plurality of smart devices such as a smart phone and a smart watch can be simultaneously wirelessly charged by a single wireless charging device. In addition, The power consumption can be reduced and the convenience of the user can be increased as compared with a case where a separate charging device is used to charge a plurality of smart devices.

1 is a view showing a first use state of a multifunctional wireless charging according to the present invention.
2 is a diagram showing a second use state diagram of the multifunctional wireless charging according to the present invention.
3 is a block diagram showing an internal configuration of a multifunctional wireless charging apparatus according to the present invention.
4 is a cross-sectional view of a smart watch radio power transmission unit in a multifunctional wireless charging apparatus according to the present invention.
5 is a diagram showing a smart watch section to be wirelessly charged, according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Wireless charging technology applicable to wireless charging products such as smart phones is wireless power transmission technology such as magnetic induction method and magnetic resonance method. First, after briefly reviewing these schemes, a multi-function wireless charging device according to the present invention for wirelessly transmitting power to a smart device using any of these schemes will be described.

Magnetic induction method ( Magnetic Induction )

The wireless charging technology of the magnetic induction method is a practical technology step of transferring power of several watts at a distance of less than a few centimeters and a transmission efficiency of 60 to 90%. The Wireless Power Consortium (WPC) In 2010, we established the Qi standard, which is an international standard of 5W class. When the intensity of the current flowing through the primary coil of the two adjacent coils is changed, the magnetic field is changed by the current, and the magnetic flux passing through the secondary coil is changed to 2 An induced electromotive force is generated on the car coil side. The frequency characteristics are not greatly affected, but the power efficiency is affected by the arrangement and distance between the power transmitting device including the coils and the power receiving device.

Magnetic resonance method ( Magnetic Resonant )

Magnetic resonance wireless charging technology is a wireless charging method that is standardized in A4WP (Alliance for Wireless Power) which Qualcomm, Samsung Electronics, SK Telecom, and LG Electronics are participating in. It uses Near Field Resonant And it is possible to simultaneously charge a plurality of terminals of various sizes. It is less affected by the arrangement and distance between the power transmitting apparatus and the power receiving apparatus and has a merit that the plurality of terminals can be wirelessly charged at the same time.

Capacity coupling method ( Capacitive Coupling )

At the 2011 CES, Murata Japan demonstrated a capacitive coupling wireless charging technology. The capacitive coupling method uses a capacitive coupling method using capacitors instead of magnetic inductive coupling using an inductor or a coil as the radio coupling method, assuming that the distance between the power transmitting device and the power receiving device is within 0.1 cm to 1 cm . The capacitive coupling scheme has a structure in which a power transmission electrode of a power transmission device and a power reception electrode of a power reception device constitute a large capacitor, which is advantageous in that it is simple to manufacture compared to a coil and does not generate heat during charging.

The multi-function wireless charging device according to the present invention is located on a bedroom table or an office desk, and functions necessary in a bedroom or an office are integrated into one wireless charging device. In recent years, the use of smartphones has led to the need for more than two smartphone charging devices in the bedroom, and Smart Watch, a leading wearable device, is expected to increase in popularity in the future. In addition, recently, instead of wired charging by connecting the output terminal of the wired charger to the socket of the smart device, the wireless charging device which is charged by charging the smart device to the wireless charging pad has been activated and started to be used .

As the wireless charging technique used in the embodiment of the present invention, any one of the magnetic induction method of the WPC, the magnetic resonance method of A4WP, and the capacity coupling method of Murata may be used. However, The present invention will be described by applying the currently activated wireless charging technique of the magnetic induction method.

1 is a view showing a first use state of a multifunctional wireless charging according to the present invention.

1, a multifunctional wireless charging apparatus according to the present invention includes a smart wired wireless power transmission unit 200 in the form of a wrist, a smart wired charging status display unit 290, The first smartphone charging status display unit 490-1, the second smartphone wireless power transmission unit 400-2, the second smartphone charging status display unit 490-2, the operation switch unit 700, an emotion lighting LED 810, a clock 820, and a speaker 830.

The multi-function wireless charging apparatus according to the present invention may further include a wireless power signal generating and controlling unit 500 and a short range wireless communication unit 600 although they are not shown in FIG. A detailed description thereof will be given later with reference to FIG.

Meanwhile, in the embodiment of the present invention, a multi-function wireless charging device including one smart watch wireless power transmission unit 200 and two smartphone wireless power transmission units 400-1 and 400-2 has been described, The scope of the invention is not limited to this, and it goes without saying that the design can be changed so that various numbers of smart devices can be charged at the same time.

The smart watch wireless power transmission unit 200 has a cylindrical shape that simulates a wrist shape capable of wirelessly charging the wrist bracelet type smart watch 100. Charging is started by simply removing the wrist bracelet type smart watch 100 from which the user has been kicked and putting it in the smart watch wireless power transmission unit 200.

A primary coil is mounted on the bottom of the surface of the smart watch radio power transmission unit 200. The smart watch wireless power transmission unit 200 is designed to form a small space in the vertical direction between the primary coil and the secondary coils of the smart watch 100, thereby enabling wireless charging with high wireless power transmission efficiency Do.

As shown in FIG. 1, the smart watch wireless power transmission unit 200 is designed so that the wrist bracelet-type smart watch 100 can be inserted in the longitudinal direction so that the user can perform a separate operation Without the user's view angle, the basic functions of the SmartWatch clock function, message / text notification function can be easily seen, and has a beauty and well-organized form.

The smart watch charging status display unit 290 is used to display the battery level and charging status of the wrist bracelet type smart watch 100 fastened to the smart watch wireless power transmission unit 200.

The first smartphone wireless power transmission unit 400-1 is used to wirelessly charge the first smartphone 300-1. In order to stably store the viewing angle of the user and the smartphone being wirelessly charged, a multi- At an angle of about 30 degrees.

A primary coil is mounted below the surface of the first smartphone wireless power transmission unit 400-1. The surface of the first smartphone wireless power transfer unit 400-1 may be configured to include an interface surface on which the first smartphone 300-1 is to be placed. The first smartphone 300-1 is placed on the upper surface of the interface and the vertical space between the primary coil and the secondary coil located on the rear surface of the first smartphone 300-1 is small, Wireless charging is possible with wireless power transmission efficiency.

The first smartphone charging status display unit 490-1 is used to display the battery level and charging status of the first smartphone 300-1 placed in the first smartphone wireless power transmission unit 400-1.

The second smartphone wireless power transmission unit 400-2 is accommodated in the internal space of the multifunctional wireless charging apparatus, if necessary, expanded to the outside when necessary, and used for wirelessly charging the second smart phone 300-2 .

For example, when there is one smartphone to be charged, the second smartphone wireless power transmission unit 400-2 and the second smartphone charging status display unit 490-2 are located in the internal space of the multi function wireless charging apparatus, It is invisible and does not work. When there are two smartphones to be charged, the second smartphone wireless power transmission unit 400-2 and the second smartphone charging status display unit 490-2 are extended out from the inside of the multi function wireless charging apparatus, Is used to wirelessly charge the battery 300-2.

According to the present invention, when a user has one smartphone to be charged, an extra second smartphone wireless power transmission unit 400-2 is accommodated in the device, thereby minimizing the area occupied by the wireless charging device, In addition, the power consumption of the second smartphone wireless power transmission unit 400-2 is cut off, thereby reducing unnecessary power consumption.

In addition, according to the present invention, when there are two smart phones to be charged, an extra second smartphone wireless power transmission unit 400-2 can be externally connected to the outside of the wireless charging device without needing to add an additional wireless charging device By expanding it, the user can easily charge two smart phones wirelessly.

Like the first smartphone wireless power transmission unit 400-1, the second smartphone wireless power transmission unit 400-2 is also connected to the front of the multi-function wireless charging device 400-1 in order to stably store the viewing angle of the user and the smart- It is located at a slightly inclined angle to the position slightly protruding from the surface.

Since the position where the primary coil is mounted, the manner of charging the smartphone, and the technical ideas related to the battery level and the charging status display are the same as those described in the first smartphone charging status unit 490-1, Is replaced with a description of the first smartphone charging status unit 490-1.

The operation switch unit 700 is located at the front of the multifunctional wireless charging device and includes a mode setting control of the emotional illumination LED 810, a smart device selection to be interlocked with the short range wireless communication unit 600, , A clock unit 820, and the like.

The emotional illumination LED unit 810 is located on the upper surface of the multifunctional wireless charging device and can be used not only in a simple lighting function of a general lighting device required in a bedroom but also in a smart Various emotional services such as changing the color depending on the songs played on the device are possible.

The clock unit 820 is located at the center of the front of the multifunctional wireless charging apparatus and performs a clock function to easily identify the time at night in the bedroom. Such a clock function may constitute a separate clock electronic device in the clock unit 820 or may display a time input from a smart device interfaced with short-range wireless communication.

 The speaker unit 830 is located at the center of the front face of the multifunctional wireless charging device and outputs music and alarm sounds input from a smart device interfaced with short-distance wireless communication.

2 is a diagram showing a second use state diagram of the multifunctional wireless charging according to the present invention.

1, the second smartphone wireless power transmission unit 400-2 and the second smartphone charging status display unit 490-2, which are extended to the left for two charging operations, Is moved to the inside of the multifunctional wireless charging device and becomes invisible from the outside, and the area occupied by the charging device and the consumed power are also reduced.

3 is a block diagram showing an internal configuration of a multifunctional wireless charging apparatus according to the present invention.

3, the multifunctional wireless charging apparatus according to the present invention includes a smart watch wireless power transmission unit 200, a smart watch charging status display unit 290, a first smartphone wireless power transmission unit 400-1, The second smartphone wireless power transmission unit 400-2, the second smartphone charging status display unit 490-2, the operation switch unit 700, the emotional illumination LED unit (not shown) 810, a clock unit 820, a speaker unit 830, a wireless power signal generation and control unit 500, and a short range wireless communication unit 600.

In the description of FIG. 3, a description will be given of portions which are not described except for the overlapping portions in the description of FIG.

The wireless power signal generation and control unit 500 determines whether the smart phone and the smart watch need to be charged, collectively generates and controls the wireless power signal when wireless charging is required, and transmits the generated wireless power transmission signal do.

The wireless power signal generation and control unit 500 may be configured such that if the smart watch 100 to be charged does not exist in the smart watch wireless power transmission unit 200 or if the smart watch 100 is present but charging is not required, The power transfer unit 200 enters the standby power mode so as to minimize power consumption.

If the smart watch 100 to which charging is desired is mounted on the smart watch radio power transmission unit 200, the radio power signal generation and control unit 500 transmits the wireless power signal through the smart watch radio power transmission unit 200 And transmits it to the smart watch 100. The specific procedure will be described below.

First, the wireless power signal generation and control unit 500 starts signal transmission to the wireless power receiving unit in the smart watch 100 waiting for signal reception, and the wireless power receiving unit in the smart watch transmits a response providing the received signal strength to the wireless And transmits it to the power signal generation and control unit 500. Here, the signal transmission / reception between the wireless power signal generation and control unit 500 and the wireless power reception unit in the smart watch is performed through the smart watch wireless power transmission unit 200.

The wireless power receiving unit in the smart watch 100 transmits necessary power (information related to the remaining capacity of the battery) and its own identifier, and the wireless power signal generating and controlling unit 500 transmits the wireless power signal to the smart watch 100 through the smart watch wireless power transmitting unit 200 Generates a wireless power signal with a configuration for power transmission using the required power and an identifier, and transmits power to a wireless power receiving unit in the smart watch 100 through the smart watch wireless power transmitting unit 200. [

Also, the wireless power signal generation and control unit 500 senses the battery level and the charging state of the smart watch 100 and displays the battery level and the charging state on the smart watch charging state display unit 290.

Meanwhile, the concrete processor for wirelessly charging the smartphone performed by the wireless power signal generation and control unit 500 is the same as the specific process for charging the smartwatch described above, so a description thereof will be omitted.

Although the wireless power signal generation and control unit 500 has been described as performing wireless power transmission through a maximum of three wireless power transmission units in the present embodiment, It is possible to minimize the amount of hardware used and power consumption, and to perform wireless power transmission to a further smart device.

The short-distance wireless communication unit 600 performs a short-range wireless communication with the one smart device selected by the operation switch unit 700 among the smart phone and the smart watch requiring charging.

Alternatively, the short-distance wireless communication unit 600 can automatically select a connection target smart device even if there is no user's selection input by the operation switch unit 700. [

For example, the short-range wireless communication unit 600 may transmit the most power (information related to the remaining battery capacity) received from the smart device, which is placed in each of the wireless power transmission units 200, 400-1, The smart device with remaining battery capacity can be automatically selected and communication can be established.

Meanwhile, the short-distance wireless communication unit 600 outputs a control signal to the emotional illumination LED unit 810 under the control of the interlocked smart device. The emotional illumination LED 810 receiving the control signal changes various brightness and color to provide various emotional services.

When the clock unit 820 is provided for displaying the time input from the smart device linked to the short-range wireless communication, the short-range wireless communication unit 600 provides the time input from the smart device linked to the clock unit 820, Time to be displayed. The short range wireless communication unit 600 outputs music and a notification sound to the speaker unit 830 under the control of the interlocked smart device.

 4 is a cross-sectional view of a smart watch radio power transmission unit in a multifunctional wireless charging apparatus according to the present invention.

4, in the present invention, the smart watch wireless power transmission unit 200 has a function of wirelessly charging the wrist bracelet type smart watch 100 according to the power signal and control of the wireless power signal generation and control unit 500 The user starts to charge the wrist bracelet-shaped smart watch 100 by pulling it off and putting it in the smart watch wireless power transfer unit 200.

The smart watch radio power transmission unit 200 may have a circular inner shape and is formed with a layer including a coil used for wireless power transmission and a multilayer structure for protecting the layer.

For example, the outermost layer and the innermost layer of the smart watch wireless power transmission unit 200 may include an outer layer 210, which may be formed of plastic or the like, which protects against shocks and scratches from the outside, .

In addition, the outer layer 210 has a rectangular or oval-shaped protrusion at the rear lower end opposite to the user's viewing angle to prevent the bracelet-shaped smart watch from turning on the circular smart watch radio power transmission unit.

A wireless power transmission layer 220 constituting a primary coil is located inside the outer layer 210 except for the inside of the protrusion portion and a magnetic shielding and an eddy current A shielding film layer 230 composed of a ferrite sheet or the like is formed in order to increase the magnetic flux generated by reducing the eddy current.

The pattern of the primary coil is designed so that the direction of the magnetic flux generated by the current flowing in the primary coil is generated on the outer side (outer side) of the circular SmartWatch radio power transmission unit.

The smart watch wireless power transmission unit 200 according to the present invention is characterized in that it has a cylindrical shape in which a first wrist shape is simulated and a rectangular or arbitrary shape protrusion is provided in a rear lower end portion opposite to a viewing angle of the user, By preventing the smart watch from returning, the display portion of the smart watch installed in the smart watch wireless power transmission unit 200 always maintains a good angle for the user to view, and the wireless power transmission efficiency is the best It is to be precisely located.

5 is a diagram showing a smart watch section to be wirelessly charged, according to an embodiment of the present invention.

The smart watch used in the embodiment of the present invention is a flexible wrist bracelet-type smart watch which is separated from the conventional watch body and the general wristwatch type which is divided into a metal or leather wristwatch . It has the advantages of a large display with flexibility, a battery with flexibility, a short-range wireless communication function such as Bluetooth and NFC, and a built-in wireless charging function.

The configuration of the smart watch section suggested in the present invention is as follows. A large display 110 having flexibility at the center of the smart watch is located at the center of the smart watch, a smart watch is protected at the remaining portion, The protective layer 130 is located. A smart watch main unit 120 including an operation unit for driving a smart watch, a control unit, a memory unit, and a communication unit is located below the display 110. A battery portion 140 having a large volume of flexibility is divided into two portions on both sides of the smart watch main portion 120 under the outer protective layer 130. The divided battery portions 140 are electrically connected to each other And operates with one battery. A shielding film made of a ferrite sheet or the like is formed on the lower part of the battery unit 140 divided into the smart watch main unit 120 and the battery unit 140 in order to increase the magnetic flux generated by shielding the magnetic field and reducing the eddy current, Layer.

A wireless power receiver 150, which is a secondary coil, is located below the shielding layer. It is preferable that the pattern of the secondary coil corresponds to a pattern of the primary coil in the smart watch radio power transmission unit 200 to increase the coupling efficiency to thereby increase the radio power transmission efficiency.

If the intensity of the current flowing in the wireless power transfer layer 220 constituting the primary coil in the SmartWatch wireless power transfer unit 200 is changed, the magnetic field changes due to the current. As a result, The magnetic flux passing through the wireless power receiving unit 150 constituting the coil is changed and an induced electromotive force is generated on the side of the wireless power receiving unit 150 to complete the wireless charging. At this time, the position registration and the distance between the wireless power transmission layer 220 in the wireless power transmission unit 200 and the wireless power reception unit 150 in the smart watch are important because they affect the wireless charging efficiency. The inner protective layer 160 is positioned below the wireless power receiving unit 150 to contact the wrist.

 It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

100: Smart Watch 200: Smart Watch Wireless Power Transmission Unit
290: SmartWatch charging status display unit 400-1, 2: smartphone wireless power transmission unit
490-1, 2: smartphone charging status display unit 500: wireless power signal generation and control unit
700: operation switch unit 810: emotional illumination LED unit
820: clock section 830: speaker section

Claims (9)

First wireless power transmission means for wirelessly transmitting power to a first user terminal,
Second wireless power transmission means for wirelessly transmitting power to a second user terminal,
The first and second wireless power transmission means may determine whether charging is required for the first and second user terminals to select a user terminal that needs to be charged and selectively generate a wireless power signal and transmit the generated wireless power signal to the selected user terminal ≪ / RTI >
Lt; / RTI > The method according to claim 1,
Wherein the first user terminal is a smart watch of a wrist bracelet type and the first wireless power transmitting means is a cylindrical shape implemented to transmit power wirelessly while the smart watch is spaced apart at a predetermined interval
Lt; / RTI > wireless charging device. 2. The wireless communication system according to claim 1,
A first smartphone wireless power transmission unit 400-1 used for wirelessly charging the first smartphone 300-1 and a second smartphone wireless power transmission unit 400-1 used for wirelessly charging the second smart phone 300-2 2 smartphone wireless power transmission unit 400-2,
The second smartphone wireless power transmission unit 400-2 is housed in the internal space of the multifunctional wireless charging device and is in a dormant state,
Lt; / RTI > wireless charging device. 2. The wireless communication system according to claim 1,
If it is determined that the user terminal is not stationary to the first or second wireless power transmission means or that the user terminal is stationary but no charging is required, the wireless power transmission means is controlled to switch to the standby power mode
Lt; / RTI > wireless charging device. 2. The system of claim 1, wherein the wireless power signal generation and control means comprises at least one processor,
(a) when the first user terminal is placed on the first wireless power transmission means, starting signal transmission to the first user terminal,
(b) receiving, from the first user terminal, information and an identifier related to the strength of the received signal, required power (information relating to battery remaining capacity)
(c) implemented to selectively generate a wireless power signal using information associated with the required power and the identifier
Lt; / RTI > wireless charging device. The method according to claim 1,
A short-range wireless communication means for supporting a short-range wireless communication connection with the first user terminal or the second user terminal,
Further comprising: The method according to claim 6,
An illumination means for providing illumination based on a control signal received from the first or second user terminal communicatively coupled to the short-
Further comprising: The method according to claim 6,
A speaker means for outputting an audio signal or a voice signal based on a control signal received from the first or second user terminal communicatively connected to the short-
Further comprising: 6. The method of claim 5,
And short-range wireless communication means for supporting a short-range wireless communication connection with the first user terminal or the second user terminal,
The short-range wireless communication means may be configured to automatically select and connect a communication-connected user terminal based on information related to the received required power
Lt; / RTI > wireless charging device.

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