KR20200095093A - Multi charging system and method - Google Patents

Abstract

The present invention relates to a multi-charging device in which only one short-range communication module is operated in a scanning mode at each time point and a wireless power transmission module disposed in the same charging slot is operated to prevent an occurrence of a pairing error with an electronic device, and a method thereof. The multi-charging device comprises: a housing in which a plurality of charging slots are formed; a plurality of short-range communication modules individually disposed in the plurality of charging slots and communicating with an electronic device inserted in the charging slot; and a plurality of wireless power transmission modules individually disposed on the plurality of charging slots and wirelessly transmitting power to the electronic device inserted in the charging slot. The plurality of short-range communication modules operate in the scanning mode at different times.

Description

Multi charging device and method {MULTI CHARGING SYSTEM AND METHOD}

The present invention relates to a multi-charging apparatus and method, and more particularly, to a multi-charging apparatus and method capable of simultaneously charging a plurality of electronic devices.

Electronic devices such as smartphones and laptops have built-in batteries so that users can use them while moving. The user uses a separate charging device to charge the battery built into the electronic device. At this time, the charging device charges a battery built in the electronic device by converting commercial power into a charging current.

Since a general charging device is connected to an electronic device on a one-to-one basis, it is difficult to simultaneously charge a plurality of electronic devices. For example, in the case of a practice room using a plurality of notebooks, learners must simultaneously charge the plurality of notebooks using the notebook during the learning time and then using the break time. When using a general charging device, it takes a lot of time to charge a plurality of notebooks, so it is impossible to charge all notebooks through the break.

Accordingly, a multi-charging device capable of simultaneously charging a plurality of electronic devices has been developed. A general multi charging device includes a plurality of charging slots to simultaneously charge a plurality of electronic devices. In this case, a charging connector for supplying a charging current to an electronic device is disposed in the charging slot. As the electronic device is inserted into the charging slot, the charging connector is mechanically fastened to the charging terminal of the electronic device. A conventional multi-charging device charges a battery embedded in an electronic device by applying a charging current through a charging connector and a charging terminal.

However, since the conventional multi-charging device has a structure in which the charging connector and the charging terminal are connected by wire, when charging is repeatedly performed, the charging connector or charging terminal wears out and the fastening force decreases, so that the charging slot cannot be used or charging efficiency. There is a problem of this deterioration.

Korean Patent Registration No. 10-1850553 (Name: Multi-charging device for portable terminals)

The present invention has been proposed to solve the above-described conventional problem, and operates only one short-range communication module in a scanning mode at each time point, and operates a wireless power transmission module disposed in the same charging slot to It is an object of the present invention to provide a multi-charging device and method to prevent the occurrence of a pairing error.

In order to achieve the above object, a multi-charging device according to an embodiment of the present invention includes a housing having a plurality of charging slots, a plurality of short-range communication modules disposed in the plurality of charging slots, respectively, and communicating with electronic devices inserted into the charging slots. And a plurality of wireless power transmission modules respectively disposed in the plurality of charging slots and wirelessly transmitting power to an electronic device inserted in the charging slot, wherein the plurality of short-range communication modules operate in a scanning mode at different times.

The multi-charging device according to an embodiment of the present invention further includes a central processing unit that operates a plurality of short-range communication modules in a scanning mode at different times based on one of a scan period and pairing status of the short-range communication module. May be.

The central processing unit operates one short-range communication module in the scanning mode at one point in time, and the scan cycle of the short-range communication module operating in the scanning mode arrives, or the short-range communication module operating in the scanning mode is When paired, the next-order short-range communication module can be operated in a scanning mode.

The multi-charging apparatus according to an embodiment of the present invention further includes a plurality of serial communication modules respectively disposed in a plurality of charging slots, and the plurality of serial communication modules may communicate with serial communication modules disposed in other charging slots. At this time, the plurality of serial communication modules are activated at different times, and the short-range communication module disposed in the same charging slot as the activated serial communication module operates in the scanning mode, and the short-range communication module disposed in the same charging slot as the inactive serial communication module. The communication module may be in a stopped state.

The serial communication module activated among the plurality of serial communication modules may activate the serial communication module of the next sequence when the scan period of the short-range communication module arrives or the short-range communication module operating in the scanning mode is paired with the electronic device.

One of the plurality of serial communication modules may be a master serial communication module set to a master mode, and the other serial communication module may be a slave serial communication module set to a slave mode. At this time, the master serial communication module activates the plurality of serial communication modules first, operates the short-range communication module arranged in the same charging slot in the scanning mode, and when the scan cycle of the short-range communication module operating in the scanning mode arrives, the next sequence is performed. The slave serial communication module of is activated, and the activated slave serial communication module can operate the short-range communication module disposed in the same charging slot in the scanning mode.

The plurality of short-range communication modules may be configured as BLE modules, and may be set to BLE Central mode when operating in a scanning mode.

Among the plurality of wireless power transmission modules, a wireless power transmission module disposed in the same charging slot as a short-range communication module operating in a scanning mode may transmit power to an electronic device disposed in the charging slot.

In order to achieve the above object, a multi-charging method according to an embodiment of the present invention includes operating one short-range communication module among a plurality of short-range communication modules in a scanning mode, and a scan period or pairing of a short-range communication module operating in the scanning mode. It includes the step of operating the other short-range communication module of the plurality of short-range communication modules based on whether the completion of the scanning mode, the plurality of short-range communication modules may operate in the scanning mode at different times.

Operating the short-range communication module in the scanning mode includes activating the serial communication module set as the master mode among the plurality of serial communication modules, and operating the short-range communication module disposed in the same charging slot as the activated serial communication module in the scanning mode. It may include steps. In this case, operating the short-range communication module in the scanning mode may further include activating the wireless power transmission module disposed in the same charging slot as the activated serial communication module.

Operating the short-range communication module in the scanning mode may further include deactivating the serial communication module set as the slave mode among the plurality of serial communication modules.

The step of operating the other short-range communication module in the scanning mode includes activating one of the plurality of serial communication modules set to the slave mode based on the scan period or pairing status of the short-range communication module operating in the scanning mode. It may include operating the short-range communication module disposed in the same charging slot as the communication module in a scanning mode.

Operating the other short-range communication module in the scanning mode may further include activating the wireless power transmission module disposed in the same charging slot as the activated serial communication module.

In the step of activating one of the plurality of serial communication modules, the remaining serial communication modules and the serial communication modules set to the master mode among the plurality of serial communication modules set to the slave mode may be deactivated.

According to the present invention, the multi-charging device and method operate only one short-range communication module in the scanning mode at each time point, so that even when a plurality of electronic devices are simultaneously inserted into the multi-charging device, the multi-charging device and the electronic device are There is an effect that can prevent a pairing error from occurring.

In addition, the multi-charging apparatus and method operates a wireless power transmission module disposed in the same charging slot as the short-range communication module operating in the scanning mode, supplying power only to the electronic device inserted in the corresponding charging slot, and is inserted into the adjacent charging slot. There is an effect of preventing the electronic device and the short-range communication module from being paired.

In addition, the multi-charging device and method operate only one short-range communication module in the scanning mode at each time point, and operate the wireless power transmission module disposed in the same charging slot to prevent the occurrence of a pairing error with the electronic device. There is an effect of preventing a decrease in charging efficiency.

1 and 2 are views for explaining a multi-charging device according to an embodiment of the present invention.
3 and 4 are views for explaining the configuration of a multi-charging device according to an embodiment of the present invention.
5 to 11 are views for explaining a multi-charging device according to an embodiment of the present invention.
12 is a flowchart illustrating a multi charging method according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the most preferred embodiments of the present invention will be described in detail so that those skilled in the art to which the present invention pertains can easily implement the technical spirit of the present invention. . First, when adding reference numerals to the components of each drawing, it should be noted that the same components have the same reference numerals as possible even though they are displayed on different drawings. In addition, in describing the present invention, when it is determined that detailed descriptions of related well-known structures or functions may obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

1 and 2, a multi-charging device 100 according to an embodiment of the present invention is installed in educational facilities, office facilities, etc. using a plurality of electronic devices 10 at the same time, and provides a plurality of electronic devices 10. Charge at the same time. The multi-charging device 100 has a stationary structure fixed to a specific position or a movable structure.

In order to solve the problem of the conventional multi-charging apparatus 100, which is a connector connection method, the multi-charging apparatus 100 according to an embodiment of the present invention wirelessly charges a plurality of electronic devices 10 through wireless power transmission. In this case, the multi-charging device 100 may simultaneously charge the plurality of electronic devices 10 through wireless power transmission.

3 and 4, a multi-charging device 100 according to an embodiment of the present invention includes a housing 120, a plurality of short-range communication modules 140, and a plurality of wireless power transmission modules 160. do.

The housing 120 includes a plurality of charging slots 122 into which an electronic device 10 requiring charging is inserted. At this time, one electronic device 10 is inserted into one charging slot 122. The short-range communication module 140 and the wireless power transmission module 160 are disposed in the charging slot 122. The number of charging slots 122 may be configured differently according to the number of electronic devices 10 used in a place where the multi charging device 100 is installed. The charging slot 122 may be configured differently in shape and size depending on the electronic device 10 used.

The plurality of short-range communication modules 140 are respectively disposed in the plurality of charging slots 122 of the housing 120. That is, one short-range communication module 140 is disposed in one charging slot 122. In this case, the short-range communication module 140 is mounted inside the housing 120 and may be disposed adjacent to the bottom surface of the charging slot 122.

The short-range communication module 140 recognizes the electronic device 10 inserted into the charging slot 122 through short-range communication. When the short-range communication module 140 is configured as an NFC module, it is configured as a BLE module because communication with the electronic device 10 is impossible when the wireless power transmission module 160 transmits power.

The short-range communication module 140 operates in the BLE CENTRAL mode to recognize the electronic device 10 inserted into the charging slot 122. The short-range communication module 140 operates in a BLE CENTRAL mode and scans the electronic device 10 into which the charging slot 122 is inserted. The short-range communication module 140 receives the BLE signal broadcast from the electronic device 10 and recognizes the electronic device 10 inserted into the charging slot 122. At this time, the electronic device 10 operates in the BLE Peripheral mode to broadcast a BLE signal (ie, transmits an advertising signal).

The short-range communication module 140 recognizes the location of the electronic device 10 based on the received signal strength indication (RSSI) of the BLE signal (ie, advertising signal), and based on the recognized location, the charging slot ( As an example, recognizing the electronic device 10 inserted in 122).

The short-range communication module 140 transmits and receives charging-related information with the electronic device 10. The short-range communication module 140 performs pairing with the electronic device 10 inserted into the charging slot 122 to transmit and receive charging-related information. The short-range communication module 140 transmits and receives charging-related information with the paired electronic device 10. In this case, the charging-related information may include information generated in the process of charging the battery of the electronic device 10 such as a charge amount, a charging current, a voltage, a temperature, and a state of the battery.

The short-range communication module 140 may control the wireless power transmission module 160 based on charging related information. That is, the short-range communication module 140 performs charging PID control based on charging-related information such as battery temperature and battery voltage. The short-range communication module 140 controls a current and a voltage of power transmitted from the wireless power transmission module 160 by performing PID control based on charging-related information.

The plurality of wireless power transmission modules 160 are respectively disposed in the plurality of charging slots 122 of the housing 120. That is, one wireless power transmission module 160 is disposed in one charging slot 122. In this case, the wireless power transmission module 160 is mounted inside the housing 120 and may be disposed adjacent to the bottom surface of the charging slot 122. The wireless power transmission module 160 is disposed to be spaced apart from the short-range communication module 140 by a predetermined distance.

The wireless power transmission module 160 wirelessly transmits power to the electronic device 10 inserted into the charging slot 122. The wireless power transmission module 160 wirelessly transmits power to the wireless power receiving module 14 built in the electronic device 10. At this time, the wireless power transmission module 160 transmits power wirelessly when the short-range communication module 140 starts scanning. The wireless power transmission module 160 may wirelessly transmit power after recognizing that the electronic device 10 is inserted and accommodated in the charging slot 122.

As an example, the wireless power transmission module 160 is configured with a solenoid type antenna having a relatively narrow area due to the characteristics of the multi-charging device 100 for charging a plurality of electronic devices 10. Since the wireless power receiving module 14 is mainly disposed on the side of the electronic device 10, it may be configured as a solenoid type antenna.

Meanwhile, the wireless power transmission module 160 may communicate with the wireless power reception module 14 through In-Band communication to replace the short-range communication module 140. However, since the wireless power transmission module 160 is composed of a solenoid type antenna due to space constraints, in-band communication is difficult. Accordingly, the short-range communication module 140 is composed of a wireless power transmission module 160 and a separate BLE module.

5, the first electronic device 10a is inserted into the first charging slot 122a, the second electronic device 10b is inserted into the second charging slot 122b, and the electronic device 10 When the short-range communication module 140 is normally paired, the first short-range communication module 140a disposed in the first charging slot 122a is paired with the first electronic device 10a and is placed in the second charging slot 122b. The arranged second short-range communication module 140b is paired with the second electronic device 10b.

However, referring to FIG. 6, when the first electronic device 10a is inserted into the first charging slot 122a and the second electronic device 10b is inserted into the second charging slot 122b, the first short-range Since the communication module 140a and the second short-range communication module 140b simultaneously perform scanning, the first short-range communication module 140a disposed in the first charging slot 122a is not the first electronic device 10a. Pairing with the second electronic device 10b may cause a pairing error.

In this way, in the multi-charging device 100, when the electronic device 10 is simultaneously inserted into two adjacent charging slots 122, a pairing error occurs, and a charging error due to a pairing error occurs, thereby reducing reliability and charging efficiency. I can.

Accordingly, in the multi-charging apparatus 100 according to an embodiment of the present invention, the plurality of short-range communication modules 140 sequentially operate in order to prevent a decrease in reliability and charging efficiency.

Referring to FIG. 7, the multi charging device 100 may further include a central processing unit 170.

The central processing unit 170 is mounted inside the housing 120 and controls the operation of the plurality of short-range communication modules 140a to 140d. That is, the central processing unit 170 controls the plurality of short-range communication modules 140a to 140d to sequentially operate in the scanning mode.

At a first point in time, the central processing unit 170 controls the first short-range communication module 140a to operate in the scanning mode. At this time, the central processing unit 170 controls the second short-range communication module 140b, the third short-range communication module 140c, and the fourth short-range communication module 140d to maintain a stopped state in which scanning is not performed.

When a second point in time that has passed the scan period from the first point in time arrives, the central processing unit 170 controls the second short-range communication module 140b to operate in the scanning mode. In this case, the central processing unit 170 controls the first short-range communication module 140a, the third short-range communication module 140c, and the fourth short-range communication module 140d to maintain a stopped state in which scanning is not performed.

When a third point in time that has passed the scan period from the second point in time arrives, the central processing unit 170 controls the third short-range communication module 140c to operate in the scanning mode. At this time, the central processing unit 170 controls the first short-range communication module 140a, the second short-range communication module 140b, and the fourth short-range communication module 140d to maintain a stopped state in which scanning is not performed.

When the fourth time point after the scan period has passed from the third time point comes, the central processing unit 170 controls the fourth short-range communication module 140d to operate in the scanning mode. At this time, the central processing unit 170 controls the first short-range communication module 140a, the second short-range communication module 140b, and the third short-range communication module 140c to maintain a stopped state in which scanning is not performed.

In this way, the central processing unit 170 may prevent the occurrence of a pairing error by controlling the next-order short-range communication module 140 to operate in the scanning mode in units of a scan period.

In this case, when the short-range communication module 140d completes pairing with the electronic device 10, the next short-range communication module 140 may be controlled to operate in a scanning mode to prevent a pairing error.

Meanwhile, referring to FIG. 8, the multi-charging device 100 may further include a plurality of serial communication modules 180.

The plurality of serial communication modules 180 are respectively disposed in the plurality of charging slots 122 of the housing 120. That is, one serial communication module 180 is disposed in one charging slot 122. In this case, the serial communication module 180 may be mounted inside the housing 120.

The plurality of serial communication modules 180 configure a network by connecting the plurality of short-range communication modules 140 in a synchronous communication method. In this case, as an example, the plurality of serial communication modules 180 are connected through an inter-integrated circuit (I2C), which is a synchronization communication method, to form a network.

Each serial communication module 180 transmits an activation right to the adjacent serial communication module 180 according to a scan period or pairing of the short-range communication module 140 disposed in the same charging slot 122. The serial communication module 180 activates the short-range communication module 140 disposed in the same charging slot 122 as the activation right is received. Accordingly, the plurality of short-range communication modules 140 operate in the scanning mode at different times.

For example, referring to FIG. 9, one of the plurality of serial communication modules 180 may operate in a master mode, and the other serial communication modules 180 may operate in a slave mode.

At this time, the first serial communication module 180a is set to the master mode and operates as the master serial communication module 180a. The second serial communication module 180b, the third serial communication module 180c, and the fourth serial communication module 180d are set to the slave mode, respectively, and the first slave serial communication module 180b and the second slave serial communication module ( 180c), operates as a third slave serial communication module 180d.

The master serial communication module 180a controls only one short-range communication module 140 to operate in a scanning mode at a time in order to prevent a pairing error. The master serial communication module 180 transmits an activation right according to the scan period and pairing time of the short-range communication module 140. At this time, the master serial communication module 180 sequentially transmits the activation right to the first slave serial communication module 180b to the third slave serial communication module 180d. Accordingly, the plurality of short-range communication modules 140 are activated at a scan period interval or a pairing time interval, and operate in a scanning mode at different times. In this case, the scan period may be approximately 100 ms, and the pairing time may be approximately 20 ms.

The master serial communication module 180a operates the first short-range communication module 140a connected to itself at a first time point in a scanning mode. The master serial communication module 180a activates the first short-range communication module 140a disposed in the same charging slot 122.

Accordingly, the first short-range communication module 140a operates in the BLE Central mode to scan the electronic device 10 inserted in the charging slot 122. At this time, the second short-range communication module 140b to the fourth short-range communication module 140d includes a first slave serial communication module 180b, a second slave serial communication module 180c, and a third slave serial communication module 180d. Since the activation authority has not been received, it maintains a stopped state that does not perform scanning.

When a second point in time that has passed the scan period from the first point in time arrives, the master serial communication module 180a transmits an activation right to the first slave serial communication module 180b. The first slave serial communication module 180b activates the second short-range communication module 140b disposed in the same charging slot 122 as the activation right is received.

Accordingly, the second short-range communication module 140b operates in the BLE Central mode to scan the electronic device 10 inserted in the charging slot 122. At this time, the first short-range communication module 140a, the third short-range communication module 140c, and the fourth short-range communication module 140d are the master serial communication module 180a, the second slave serial communication module 180c, and the third slave. Since the serial communication module 180d has not received an activation right, it maintains a stopped state that does not perform scanning.

When a third point in time, which has passed the scan period from the second point in time, arrives, the master serial communication module 180a transmits an activation right to the second slave serial communication module 180c. Upon receiving the activation right, the second slave serial communication module 180c activates the third short-range communication module 140c disposed in the same charging slot 122.

Accordingly, the third short-range communication module 140c operates in the BLE Central mode to scan the electronic device 10 inserted in the charging slot 122. At this time, the first short-range communication module 140a, the second short-range communication module 140b, and the fourth short-range communication module 140d are the master serial communication module 180a, the first slave serial communication module 180b, and the third slave. Since the serial communication module 180d has not received an activation right, it maintains a stopped state that does not perform scanning.

When the fourth point in time, after which the scan period has passed from the third point in time, arrives, the master serial communication module 180a transmits the activation right to the third slave serial communication module 180d. The third slave serial communication module 180d activates the fourth short-range communication module 140d disposed in the same charging slot 122 as the activation right is received.

Accordingly, the fourth short-range communication module 140d operates in the BLE Central mode to scan the electronic device 10 inserted in the charging slot 122. At this time, the first short-range communication module 140a, the second short-range communication module 140b, and the third short-range communication module 140c are the master serial communication module 180a, the first slave serial communication module 180b, and the second slave. Since the serial communication module 180c has not received an activation right, it maintains a stopped state that does not perform scanning.

Through this, the master serial communication module 180a controls only one short-range communication module 140 to operate in the scanning mode at a time. At this time, when the pairing between the short-range communication module 140 and the electronic device 10 is completed within the scan period, the master serial communication module 180a immediately transmits the activation right to the serial communication module 180 of the order regardless of the scan period. Accordingly, the short-range communication module 140 disposed in the corresponding charging slot 122 may be operated in a scanning mode.

Referring to FIG. 10, the multi-charging device 100 according to an embodiment of the present invention scans a plurality of short-range communication modules 140 at different times through the central processing unit 170 or the serial communication module 180 in a scanning mode. To operate.

That is, the first short-range communication module 140a is operated in the scanning mode at the first time point, the second short-range communication module 140b is operated in the scanning mode at the second time point, and the third short-range communication module ( 140c) is operated in the scanning mode, and at the fourth time point, the fourth short-range communication module 140d is operated in the scanning mode.

Through this, the multi-charging device 100 may prevent the occurrence of a pairing error by blocking the short-range communication module 140 and the electronic device 10 disposed in different charging slots 122 from being paired.

Referring to FIG. 11, the plurality of wireless power transmission modules 160 may selectively wirelessly transmit power based on whether the short-range communication module 140 performs a scanning operation. That is, among the plurality of wireless power transmission modules 160, only one wireless power transmission module 160 disposed in the same charging slot 122 as the short-range communication module 140 operating in the scanning mode can wirelessly transmit power. At this time, the rest of the wireless power transmission module 160 maintains a stopped state in which wireless power transmission is not performed.

Accordingly, power is applied only to the electronic device 10 inserted into the charging slot 122 in which the short-range communication module 140 performing scanning is disposed. As power is applied, the electronic device 10 performs pairing with the short-range communication module 140 operating in the BLE Central mode by operating in the BLE Peripheral mode.

As such, the multi-charging device 100 transmits power only to the wireless power transmission module 160 disposed in the same charging slot 122 as the short-range communication module 140 operating in the scanning mode, thereby transmitting power to the corresponding charging slot 122. Only the inserted electronic device 10 can perform pairing with the short-range communication module 140.

Through this, the multi-charging device 100 can perform accurate pairing even if the electronic devices 10 are simultaneously mounted in the plurality of charging slots 122, and the reliability and charging efficiency can be prevented from deteriorating by minimizing charging errors. I can.

Referring to FIG. 12, in the multi-charging method according to an embodiment of the present invention, only one short-range communication module 140 operates in a scanning mode at each time point, and wireless power transmission disposed in the same charging slot 122 By operating the module 160 to supply power only to the electronic device 10 inserted into the corresponding charging slot 122, the short-range communication module even when a plurality of electronic devices 10 are simultaneously inserted into the multi charging device 100 The occurrence of a pairing error between the 140 and the electronic device 10 is prevented.

Hereinafter, the master serial communication module refers to the serial communication module 180 set as the master mode among the plurality of serial communication modules 180, and the n-th slave communication module is a serial communication module set as the slave mode among the plurality of serial communication modules 180. It means the communication module 180.

The multi-charging device 100 activates the master serial communication module (S100). Here, the multi-charging device 100 activates the master serial communication module among the plurality of serial communication modules 180.

The master serial communication module operates the short-range communication module disposed in the same charging slot in the scanning mode (S200). The short-range communication module 140 disposed in the same slot as the master serial communication module operates in the BLE Central mode to scan the electronic device 10 inserted into the charging slot 122.

At this time, the slave serial communication modules disposed in the charging slot 122 different from the master serial communication module maintain an inactive state.

Accordingly, the short-range communication modules 140 disposed in the charging slot 122 different from the master serial communication module maintain a stopped state in which scanning is not performed.

When the pairing of the electronic device 10 inserted in the charging slot 122 and the short-range communication module 140 is completed (S300; Yes), the multi charging device 100 is in the same charging slot 122 as the master serial communication module. The arranged wireless power transmission module 160 is operated (S400).

The multi-charging device 100 operates the wireless power transmission module 160 disposed in the same charging slot 122 as the master serial communication module among the plurality of wireless power transmission modules 160. The wireless power transmission module 160 wirelessly transmits power to the charging slot 122. At this time, the electronic device 10 inserted into the charging slot 122 receives wirelessly transmitted power and operates in the BLE Peripheral mode.

The multi-charging device 100 activates the n-th slave serial communication module (S500). That is, when the short-range communication module 140 is paired with the electronic device 10, the master serial communication module transmits an activation right to one of a plurality of slave serial communication modules. The slave serial communication module receiving the activation right is activated, and the master serial communication module is deactivated.

The n-th slave serial communication module operates the short-range communication module 140 disposed in the same charging slot in the scanning mode (S600). The short-range communication module 140 disposed in the same slot as the n-th slave serial communication module operates in the BLE Central mode and scans the electronic device 10 inserted into the charging slot 122.

At this time, the slave serial communication modules disposed in the charging slot 122 different from the n-th slave serial communication module maintain an inactive state.

Accordingly, the short-range communication modules 140 disposed in the charging slot 122 different from the n-th slave serial communication module maintain a stopped state in which scanning is not performed.

When the pairing of the electronic device 10 inserted in the charging slot 122 and the short-range communication module 140 is completed (S700; YES), the multi charging device 100 is charged with the same charging slot 122 as the n-th slave serial communication module. ) To operate the wireless power transmission module 160 (S800). The multi-charging device 100 operates the wireless power transfer module 160 disposed in the same charging slot 122 as the n-th slave serial communication module among the plurality of wireless power transfer modules 160. The wireless power transmission module 160 wirelessly transmits power to the charging slot 122. At this time, the electronic device 10 inserted into the charging slot 122 receives wirelessly transmitted power and operates in the BLE Peripheral mode.

When scanning of the short-range communication modules 140 arranged in the same slot as the slave serial communication module is completed (S900; YES), the multi-charging device 100 repeats steps S100 to S900 described above.

On the other hand, if the scanning of the short-range communication modules 140 disposed in the same slot as the slave serial communication module is not completed (S900; No), the multi-charging device 100 repeats steps S500 to S900 described above, and the next sequence ( By activating the nth slave serial communication module of n=n+1), the short-range communication module 140 and the wireless power transmission module 160 disposed in the corresponding charging slot 122 are activated.

The preferred embodiment according to the present invention has been described above, but it can be modified in various forms, and those skilled in the art can make various modifications and modifications without departing from the claims of the present invention. It is understood that it can be practiced.

10: electronic device 12: short-range communication module
14: wireless power receiving module 100: multi charging device
120: housing 122: charging slot
140: short-range communication module 160: wireless power transmission module
170: central processing unit 180: serial communication module

Claims (20)

A housing formed with a plurality of charging slots;
A plurality of short-range communication modules disposed in the plurality of charging slots and communicating with electronic devices inserted into the charging slots; And
Each of the plurality of charging slots, including a plurality of wireless power transmission modules for wirelessly transmitting power to the electronic device inserted into the charging slot,
The plurality of short-range communication modules operate in a scanning mode at different times. The method of claim 1,
A multi-charging device further comprising a central processing unit configured to operate the plurality of short-range communication modules in a scanning mode at different times based on one of a scan period of the short-range communication module and whether to pair or not. According to claim 2,
The central processing unit is a multi-charging device that operates one short-range communication module in a scanning mode at one point in time. According to claim 2,
The central processing unit,
A multi-charging device for operating the next short-range communication module in the scanning mode when the scan cycle of the short-range communication module operating in the scanning mode arrives or when the short-range communication module operating in the scanning mode is paired with an electronic device. The method of claim 1,
Further comprising a plurality of serial communication modules respectively disposed in the plurality of charging slots,
The plurality of serial communication modules are multi-charging device for communicating with serial communication modules disposed in different charging slots. The method of claim 5,
The plurality of serial communication modules are activated at different times,
The short-range communication module disposed in the same charging slot as the activated serial communication module is a multi-charging device that operates in scanning mode. The method of claim 6,
A multi-charging device in which the short-range communication module placed in the same charging slot as the disabled serial communication module is in a stopped state. The method of claim 5,
An activated serial communication module among the plurality of serial communication modules,
A multi-charging device that activates the next serial communication module when the scan cycle of the short-range communication module arrives or the short-range communication module operating in the scanning mode is paired with an electronic device. The method of claim 5,
One of the plurality of serial communication modules is a master serial communication module set to a master mode, and the other serial communication modules are slave serial communication modules set to a slave mode. The method of claim 9,
The master serial communication module activates the plurality of serial communication modules first, and operates a short-range communication module disposed in the same charging slot in a scanning mode. The method of claim 10,
The master serial communication module
When the scan cycle of the short-range communication module operating in the scanning mode arrives, the next slave serial communication module is activated.
The activated slave serial communication module is a multi-charging device that operates the short-range communication module disposed in the same charging slot in the scanning mode. The method of claim 1,
The plurality of short-range communication modules are composed of BLE modules, and when operating in a scanning mode, a multi-charging device that is set to a BLE Central mode The method of claim 1,
Among the plurality of wireless power transmission modules, a wireless power transmission module disposed in the same charging slot as a short-range communication module operating in a scanning mode transmits power to an electronic device disposed in the charging slot. In the multi charging method using a multi charging device,
Operating one short-range communication module among a plurality of short-range communication modules in a scanning mode; And
Operating another short-range communication module from among the plurality of short-range communication modules in a scanning mode based on a scan period of a short-range communication module operating in a scanning mode or whether pairing is completed,
The multi-charging method in which the plurality of short-range communication modules operate in a scanning mode at different times. The method of claim 14,
Operating the short-range communication module in a scanning mode,
Activating a serial communication module set as a master mode among a plurality of serial communication modules; And
A multi-charging method comprising the step of operating a short-range communication module disposed in the same charging slot as the activated serial communication module in a scanning mode. The method of claim 15,
Operating the short-range communication module in a scanning mode,
Multi charging method further comprising the step of activating the wireless power transmission module disposed in the same charging slot as the activated serial communication module. The method of claim 15,
Operating the short-range communication module in a scanning mode,
Deactivating a serial communication module set to a slave mode among the plurality of serial communication modules. The method of claim 14,
Operating the other short-range communication module in a scanning mode,
Activating one of a plurality of serial communication modules set as a slave mode based on a scan period of a short-range communication module operating in a scanning mode or whether to pair; And
And operating a short-range communication module disposed in the same charging slot as the activated serial communication module in a scanning mode. The method of claim 18,
Operating the other short-range communication module in a scanning mode,
Multi charging method further comprising the step of activating the wireless power transmission module disposed in the same charging slot as the activated serial communication module. The method of claim 18,
In the step of activating one of the plurality of serial communication modules
A multi charging method that disables the remaining serial communication modules and the serial communication modules set as master mode among the plurality of serial communication modules set as slave mode.

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