JP5372537B2 - Electronic device charging system, charger, and electronic device - Google Patents

Description

  The present invention relates to an electronic device charging system, a charger, and an electronic device, in particular, a charger that transmits electric power in a non-contact manner, an electronic device that uses a secondary battery that is charged by electric power received in a non-contact manner as a power source, And an electronic device charging system including a charger and an electronic device.

  In recent years, a charger and an electronic device constitute an electronic device charging system, and power is transmitted from the charger to the electronic device without using a metal contact or a connector (hereinafter referred to as non-contact power transmission or simply power transmission). In addition, the secondary battery included in the electronic device is charged with the transmitted power (hereinafter referred to as non-contact charging). When the charger performs non-contact charging for the electronic device, after performing a predetermined authentication process, the non-contact power transmission is performed to start charging the secondary battery in the electronic device.

  As one of such devices for contactless power transmission, the primary side power transmission coil and the secondary side power reception coil are magnetically coupled, and the primary side power transmission coil is contactlessly contacted with the secondary side power reception coil. In the power transmission device for transmitting power at the power transmission device, the voltage is supplied to the primary side power transmission coil in series with the primary side power transmission coil. The resonance point of the series resonance circuit, which includes a capacitor constituting the resonance circuit and includes the mutual inductance of the secondary power receiving coil, is set to a higher frequency than the resonance point of the primary series resonance circuit consisting of the primary power transmission coil and the capacitor. An electric power transmission device characterized by the setting is known (for example, see Patent Document 1).

  As another example, contactless power transmission that electromagnetically couples a primary coil and a secondary coil to transmit power from a power transmitting device to a power receiving device and supplies power to the main load of the power receiving device. A power transmission control device provided in the power transmission device of a system, wherein the power transmission device includes an LC resonance circuit having a variable resonance characteristic including the primary coil as a component, and the LC resonance circuit is activated by an enable signal Including at least one of at least one sub-capacitor and at least one sub-coil in which a state / inactive state is selected, wherein the power transmission control device includes a power transmission side control circuit that controls the power transmission device, and the power transmission side control circuit Each of the at least one sub-capacitor or the at least one sub-coil by the enable signal. Selectively an active state, thereby, the power transmission control device is known, which comprises controlling the resonance characteristics of the LC resonant circuit (e.g., see Patent Document 2).

  Furthermore, as another example, in a non-contact power supply device that supplies power to a load in a non-contact manner, at least two or more induction coils, a power source connected to one end of the induction coil, and the induction coil A switching circuit connected to the other end; a damper diode connected in parallel to the switching circuit; and a resonance capacitor connected in parallel to the switching circuit; There is known a non-contact power supply device that supplies an exciting current to the induction coil and supplies power to the load by electromagnetic induction of the induction coil (see, for example, Patent Document 3).

JP 2006-230032 A JP 2008-206327 A Japanese Patent Laid-Open No. 10-2225020

  However, the authentication process performed by a conventional charger (a device that performs power transmission including a primary coil and an induction coil) assumes that one charger performs authentication for only one electronic device. For this reason, authentication processing is performed between one charger and a plurality of electronic devices, and contactless charging cannot be performed at the same time.

  The present invention has been made in view of the above circumstances, and an electronic device charging system, a charger, and an electronic device capable of simultaneously performing non-contact charging between a single charger and a plurality of electronic devices. The purpose is to provide.

An electronic device charging system according to the present invention is an electronic device charging system including a charger that transmits electric power in a non-contact manner and at least one electronic device that uses a secondary battery that is charged with electric power received in a non-contact manner as a power source. The charger transmits a load confirmation signal for confirming whether or not there is a load, and the at least one electronic device charges the secondary battery for a predetermined period after receiving the load confirmation signal. stop, the load response signal indicating that the load is transmitted using load modulation at a given time, the charger, at least according to the magnitude of the load current caused by the reception of the previous SL load response signal The number of one electronic device is detected.

  With this configuration, it is possible to perform non-contact charging simultaneously between one charger and a plurality of electronic devices. In other words, the load confirmation signal transmitted by the charger is used as a trigger to transmit the load response signal from the electronic device, so even when there are two or more electronic devices, the two or more electronic devices transmit the load response signal at the same timing. can do. Therefore, the charger can recognize that there are two or more electronic devices as an addition, and can simultaneously perform non-contact charging between one charger and a plurality of electronic devices. Further, since the load response signal uses a load modulation signal, when there are two or more electronic devices, the current value (load current value) of the load modulation signal increases according to the number of electronic devices. As a result, the charger can detect the number of electronic devices according to the current value of the load modulation signal of the load response signal.

The electronic device charging system of the present invention, the charger comprises a primary coil, the at least one electronic device, each provided with a secondary coil, an electromagnetic induction using the said primary coil secondary coil Transmit and receive power.

  With this configuration, an electronic device charging system that performs non-contact charging using electromagnetic induction can be configured.

  Further, in the electronic device charging system according to the present invention, the primary coil and the secondary coil are arranged to face the facing surface, and an area of a cross section parallel to the facing surface of the secondary coil is equal to that of the primary coil. It is larger than the area of the cross section parallel to the facing surface.

  With this configuration, two or more secondary coils can be arranged corresponding to one primary coil. That is, two or more electronic devices can be arranged for one charger.

  In the electronic device charging system of the present invention, the flatness of the cross section of the primary coil parallel to the facing surface is greater than the flatness of the cross section of the secondary coil parallel to the facing surface.

  With this configuration, when two or more electronic devices are arranged side by side, that is, when two or more secondary coils are arranged side by side, when the primary coil is flattened along the direction in which the secondary coils are arranged, A primary coil can be arranged corresponding to the arranged secondary coils.

In the electronic device charging system according to the present invention, the charger changes the electric power transmitted based on the detected number of the at least one electronic device.

  With this configuration, since the power to be transmitted is changed according to the number of electronic devices, the power to be transmitted can be increased as the number of electronic devices increases. Thereby, the electric power transmitted per electronic device does not become small, and the charge time in an electronic device does not become long.

In the electronic device charging system of the present invention, when the charger detects that all of the at least one electronic device has been removed, the electric power to be transmitted is set to a predetermined value or less.

  With this configuration, when there is no electronic device to be charged, the transmitted power is set to a predetermined value or less, so that it is possible to prevent wasteful power consumption.

In the electronic device charging system of the present invention, the at least one electronic device transmits the load response signal at a first timing after receiving the load confirmation signal.

  With this configuration, the electronic device transmits the load response signal at the first timing after receiving the load confirmation signal transmitted from the same charger. Therefore, even if there are two or more electronic devices, each electronic device Can be transmitted at the same timing with reference to the load confirmation signal.

In the electronic device charging system according to the present invention, the charger detects a load current value generated by receiving the load response signal at substantially the same timing as the first timing after transmitting the load confirmation signal. .

  With this configuration, the load response signal can be reliably captured by setting the timing at which the load response signal is reliably transmitted as the second timing.

In the electronic device charging system of the present invention, the charger notifies the number of detected at least one electronic device.

  With this configuration, the number of electronic devices charged by the charger can be notified to the user.

The charger according to the present invention is a charger that transmits power in a non-contact manner, transmits a load confirmation signal for confirming the presence or absence of a load, and then receives a load response signal from at least one electronic device. The number of the at least one electronic device is detected according to the magnitude of the load current value generated by the reception of .

  With this configuration, the electronic device charging system can be configured, and non-contact charging can be performed simultaneously between one charger and a plurality of electronic devices. In other words, when an electronic device transmits a load response signal triggered by a load confirmation signal transmitted by the charger, even if there are two or more electronic devices, two or more electronic devices send load response signals at the same timing. Can be sent. Therefore, the charger can recognize that there are two or more electronic devices as a load, and can perform non-contact charging simultaneously between one charger and a plurality of electronic devices. Further, since the load response signal uses a load modulation signal, when there are two or more electronic devices, the current value of the load modulation signal increases according to the number of electronic devices. As a result, the charger can detect the number of electronic devices according to the current value of the load modulation signal of the load response signal.

  According to the present invention, it is possible to perform non-contact charging simultaneously between one charger and a plurality of electronic devices. In addition, the number of electronic devices that are simultaneously charged by the charger can be detected.

  Hereinafter, an electronic device charging system, a charger, and an electronic device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 is an overview of an electronic device charging system according to an embodiment of the present invention. FIG. 1A shows an electronic device charging system 1 including a charger 2 and an electronic device 3. FIG. 1B shows the electronic device 3. FIG. 1C shows the charger 2.

  The electronic device charging system 1 includes a mobile phone, a PHS (Personal Handy-phone System), a PDA (Personal Digital Assistant), an electronic device 3 such as a portable terminal, and a charging stand for charging the electronic device 3 in a contactless manner. The charger 2 is provided. The electronic device 3 can charge a rechargeable battery (secondary battery) by receiving power from the charger 2 in a non-contact state with the charger 2. Here, non-contact means that the electronic device 3 and the charger 2 can exchange power (radio waves), signals, and the like between the two in a state where the electronic device 3 and the charger 2 are not directly electrically connected via the metal terminal. .

  The charger 2 includes a primary coil 21 for sending electric power to the electronic device 3 by electromagnetic induction, and the electronic device 3 includes a secondary coil 31 for receiving electric power from the charger 2 by electromagnetic induction. . The primary coil 21 and the secondary coil 31 are provided on a surface between the surface on which the electronic device is placed in the charger and the outer surface of the casing facing the charger in the electronic device (hereinafter referred to as a facing surface). It arrange | positions so that it may oppose. In FIG. 1, the primary coil 21 is illustrated as an oval and the secondary coil 31 is illustrated as a rectangular shape, but the present invention is not limited thereto. By disposing the electronic device 3 and the charger 2 opposite to each other at a predetermined position, the primary coil 21 and the secondary coil 31 face each other, and contactless power transmission is performed by electromagnetic induction using the secondary coil 31. It is possible to perform non-contact charging.

  Moreover, the area of the cross section of the primary coil 21 parallel to the opposing surface is larger than the area of the cross section of the secondary coil 31 parallel to the opposing surface. The cross-sectional area of the primary coil 21 is such that the charger 2 can charge a plurality of electronic devices 3. For example, it is configured to have a size capable of supplying sufficient power for charging secondary batteries of a plurality of electronic devices 3. For this reason, as shown to Fig.1 (a), the several electronic device 3 can be mounted in the charger 2, and can be arrange | positioned in the state which can be contactlessly charged.

  In addition, the electronic device 3 includes a circuit board at a position that does not overlap with the secondary coil 31 on the facing surface, and further includes a magnetic shielding sheet 38 closer to the secondary coil 31 of the charger 2 than the circuit board. That is, when performing non-contact charging, the secondary coil 31, the magnetic shield sheet 38, and the circuit board are arranged in this order. In this manner, by arranging the magnetic shielding sheet 38, it is possible to avoid a loss due to eddy current (heat generation) when the electronic device 3 receives power from the charger 2 in the metal portion on the circuit board.

  Although not shown, the electronic device 3 includes a secondary battery immediately below the secondary coil 31 in FIG. 1A, and a magnetic shield sheet 38 is provided between the secondary coil 31 and the secondary battery. I have.

  In addition, as described above, since the area of the cross section of the primary coil 21 is larger than the area of the cross section of the secondary coil 31, even when only one electronic device 3 is mounted on the charger 2. In addition to the case where one electronic device 3 is placed on the charger 2 in the center (see FIG. 2A), the case where one electronic device 3 is placed on the end of the charger 2 (see FIG. 2 ( b)), even when one electronic device 3 is placed obliquely on the charger 2 (see FIG. 2C), non-contact charging can be performed. Furthermore, even when the accessory device 4 of the electronic device 3 is mounted on the charger 2 together with the electronic device 3 (see FIG. 2D), the devices 3 and 4 can be charged in a non-contact manner. It is. As shown in FIG. 2, the position where the electronic device 3 is disposed is widened because the allowable range of positional deviation that allows non-contact charging is widened even if the position of the electronic device 3 slightly deviates from the predetermined position with respect to the charger 2. The degree of freedom increases.

  Further, the flatness of the cross section of the primary coil 21 (that is, the flatness of the circumference serving as the outer edge of the cross section, hereinafter the same) may be greater than the flatness of the cross section of the secondary coil 31. Good. For example, by flattening the primary coil 21 along the direction in which the secondary coils 31 are arranged, the charger 2 can perform non-contact charging on the plurality of electronic devices 3. At this time, the size of the magnetic shielding sheet 38 for covering the circuit board may be small.

  Further, in FIG. 1A, the battery charger 2 is disposed on the end side of the surface facing the electronic device 3, but the electronic device 3 includes the magnetic shielding sheet 38, so that an eddy current is generated in the circuit board. In order to prevent this, the secondary coil 31 may be configured over the entire facing surface.

Next, a specific configuration of the electronic device charging system 1 will be described.
FIG. 3 is a diagram illustrating an example of a specific configuration of the electronic device charging system 1.

  The charger 2 includes a primary coil 21, a phase difference detection unit 22, an authentication control unit 23, a power supply connection unit 24, an AC unit 25, a modulation unit 26, a switching unit 27, and a capacitor 28.

  The primary coil 21 transmits and receives power transmission and various signals for power transmission.

  The phase difference detection unit 22 detects the phase difference between the voltage and current of the primary coil 21. Thereby, for example, when a load modulation signal indicating that the electronic device 3 exists is received from the electronic device 3, the phase difference of the primary coil 21 is detected, and the electronic device 3 is detected by this detection. can do.

  The authentication control unit 23 determines whether or not the electronic device 3 is mounted on the charger 2 based on the phase difference detected by the phase difference detection unit 22. When the electronic device 3 is detected, detection information indicating that the electronic device 3 has been detected is sent to the modulation unit 26. Further, by utilizing the fact that the magnitude of the current can be estimated from the phase difference, the number (number) of electronic devices 3 mounted on the charger 2 is counted. Further, based on the count, a power control command including information on power necessary for contactless charging of the electronic device 3 is sent to the AC unit 25.

  The power supply connection unit 24 receives power supply from a commercial power supply and sends the power to the AC unit 25.

  The AC unit 25 converts AC power from the power supply connection unit 24 into DC power. Further, based on the power control command from the authentication control unit 23, the magnitude of the DC power sent to the switching unit 27 is controlled.

  The modulation unit 26 sends a frequency command for transmitting power for power transmission or power for load confirmation signal to the electronic device 3 to the switching unit 27. The frequency of the power for power transmission is, for example, 120 KHz to 130 KHz, and the load confirmation signal is transmitted using, for example, 120 KHz as 0 information and 130 KHz as 1 information.

  The switching unit 27 also converts the power from the AC unit 25 into power for power transmission or power for a load confirmation signal based on the frequency modulation command from the modulation unit 26. The converted power is transmitted to the electronic device 3 via the capacitor 28 and the primary coil 21.

  The electronic device 3 includes a secondary coil 31, a rectifying unit 32, a load resistor 33, a load modulation switch 34, a charging switch 35, an authentication control unit 36, and a secondary battery unit 37. In the electronic device 3, the parts other than the secondary coil 31 are formed on the circuit board (not shown).

  The secondary coil 31 receives power for receiving power supply, receives power for receiving various signals, and transmits various signals.

  The rectification unit 32 rectifies the power received by the secondary coil 31, and is configured by a diode bridge, for example.

  The load resistor 33 is used when the electronic device 3 transmits a load modulation signal. For example, the resistance value is 20Ω.

  The load modulation switch 34 is ON / OFF controlled by the authentication control unit 36. When the load modulation switch 34 is in the on (closed) state, when viewed from the charger 2 side, it appears that the load on the electronic device 3 has increased.

  The charging switch 35 is on / off controlled by the authentication control unit 36. When the charging switch is in the on (closed) state, the secondary battery is charged with the power received by the secondary coil 31.

The authentication control unit 36 performs on / off control of the load modulation switch 34 and the charging switch 35 based on the load confirmation signal from the charger 2 and the charging completion signal from the secondary battery unit 37.
For example, when a load confirmation signal is received, the load modulation switch 34 is switched between an on state (for example, 1) and an off state (for example, 0) to switch the load via the secondary coil 31. A modulated signal (ACK signal) is transmitted. In a period other than the signal transmission after the load modulation signal is input to the authentication control unit 36, the authentication control unit 36 performs control so that the load modulation switch 34 is turned off.
When the load confirmation signal is received, the charging switch 35 is turned off for a predetermined period (a period longer than the short period in which the load modulation switch 34 is turned on). Note that when the charging switch 35 is in the OFF state, a load modulation signal is transmitted to the charger 2 (that is, power for load modulation is transmitted). The authentication control unit 36 turns on the charging switch 35 in a period other than the predetermined period after the load confirmation signal is input to the authentication control unit 36 and before the charging completion signal is input to the authentication control unit 36. Control to be in a state.

  The secondary battery unit 37 includes a secondary battery such as a lithium ion battery, a voltage sensor for detecting the voltage of the secondary battery, a current sensor for detecting a charging current, and the like. When the voltage of the secondary battery becomes equal to or higher than the predetermined voltage by the voltage sensor, a charging completion signal indicating that charging is completed is sent to the authentication control unit 36.

Next, a charging mode for performing non-contact charging of the electronic device charging system 1 will be described.
The electronic device charging system 1 has a standby mode, an authentication mode, and a power transmission mode as charging modes.

  The standby mode is a mode in which the charger 2 periodically transmits a load confirmation signal for confirming the load placed on the charger. When the charger 2 receives a load response signal (ACK signal) that is a response to the load confirmation signal, the charger 2 detects a load by detecting the phase difference by the phase difference detector 22 and shifts to the authentication mode. The load response signal is, for example, a load modulation signal by load modulation. Further, the load confirmation signal is periodically transmitted even after shifting to the later authentication mode and power transmission mode.

  The authentication mode is a mode in which an authentication process is performed between the charger 2 and the electronic device 3 to authenticate whether the charger 2 is charged and is a normal load. In the authentication process, the charger 2 transmits an authentication request signal to the load, and the load (electronic device) mounted on the charger transmits an authentication ID signal to the charger 2. If the authentication ID is valid, it is determined that the load is a normal load, and the mode is shifted to the power transmission mode.

  The power transmission mode is a mode in which the charger 2 transmits power to the authorized regular load. The electronic device 3 receives the transmitted power and charges the secondary battery.

Next, the flow of signals in the electronic device charging system 1 in a state where the electronic device 3 is placed on the charger 2 will be described.
FIG. 4 is a time chart illustrating an example of a signal flow in the electronic device charging system 1 in a state where one electronic device 3 is mounted on the charger 2.

In FIG. 4, when the charger 2 in the standby mode state detects a load, power transmission is started via the primary coil at time t1, and a secondary load confirmation signal is transmitted at t2.
The electronic device 3 receives the secondary load signal and returns a load ACK signal at t3. The charger 2 that has been authenticated based on the load ACK signal enters the power transmission mode on the assumption that a normal load is placed, and continuously transmits power. Also in the power transmission mode, the charger 2 periodically transmits a load confirmation signal, and transmits the load confirmation signal at time t2. When the charger 2 transmits the load confirmation signal, the switching unit 27 frequency-modulates the load confirmation signal according to an instruction from the modulation unit 26 and transmits the load confirmation signal via the primary coil 21. And the electronic device 3 receives a load confirmation signal via the secondary coil 31 at the time t3. When the authentication control unit 36 detects this load confirmation signal, the electronic device 3 controls the load modulation switch 34 to switch between the on state and the off state, and sends the load ACK signal to the charger 2 via the secondary coil 31. To send. The load ACK signal is transmitted by load modulation, and an arbitrary command is transmitted by load modulation.

  When the load ACK signal is transmitted from the electronic device 3 via the secondary coil 31, the charger 2 receives the load ACK signal via the primary coil 21 at approximately the same time. In FIG. 4, a load current is generated in the charger 2 by this reception. When the load current is generated, a phase difference between the voltage and the current is generated in the primary coil 21, and this phase difference is detected by the phase difference detection unit 22. That is, the load current can be detected by detecting the phase difference, and the load ACK signal can be detected by the change in the phase difference. In the charger 2, the authentication control unit 23 detects the electronic device 3 that is a normal load from the load ACK signal, and instructs the AC unit 25 to continue power transmission. Although it has been described that the transmission of the load ACK signal and the detection of the load current are at the same time, different timings may be used.

  In addition, after sending the load ACK signal, the electronic device 3 controls the authentication control unit 36 to turn on the charging switch 35 at time t4, and starts charging the secondary battery. In FIG. 4, the charging current starts to flow at time t4. Further, during charging of the secondary battery, the load current in the charger 2 continues to flow.

  Subsequently, when the charger 2 transmits a load confirmation signal at time t5, the electronic device 3 receives the load confirmation signal via the secondary coil 31, and the authentication control unit 36 turns off the charging switch 35. In this way, charging to the secondary battery is stopped at time t6.

  Further, when receiving the load confirmation signal, the electronic device 3 transmits a load ACK signal at time t7 while the charging is stopped. When the load ACK signal is transmitted from the electronic device 3 via the secondary coil 31, the charger 2 receives the load ACK signal at approximately the same time (t7). The charger 2 detects the electronic device 3 that is a regular load from the load current, and further continues power transmission.

  Subsequently, after sending the load ACK signal at time t7, the electronic device 3 controls the authentication control unit 36 to turn on the charging switch 35 at time t8, and resumes charging of the secondary battery. In addition, since the power transmission by the charger 2 is continued as long as the regular load is recognized, the power transmission is continued without being interrupted even when the charging is stopped at the times t6 to t8.

  Although charging to the secondary battery is stopped at time t6 to t8, when only the electronic device 3 that is a regular load is mounted on the charger 2, the charging switch 35 is in an off state. In addition, the load current in the charger 2 should drop to a predetermined value or less. However, when a foreign object is placed on the charger 2 in addition to the regular load, a small amount of load current due to the foreign object flows. In this case, since the load current does not decrease to a predetermined value or less, it can be detected that there is a foreign object. The foreign matter is determined by the phase difference detection unit 22 and the authentication control unit 23 based on the change in the phase difference due to the load current. When it is determined that there is a foreign matter, the authentication control unit 23 transmits power to the AC unit 25. Control to stop.

  Next, FIG. 5 is a time chart showing an example of a signal flow in the electronic device charging system 1 in a state where two electronic devices 3 are mounted on the charger 2. In FIG. 5, before the second electronic device 3 b is mounted on the charger 2, power transmission is performed in a state where the first electronic device 3 a illustrated in FIG. 4 is mounted. Assumes that.

  Since the first electronic device 3a is charged from the beginning in FIG. 5, a charging current flows. When detecting the load confirmation signal transmitted by the charger 2 at time t9, the electronic device 3a stops charging the secondary battery included in the electronic device 3a at time t10. After time t10, operations similar to those of the electronic apparatus 3 shown in FIG. 4 are performed, such as transmission of a response ACK signal, resumption of charging of the secondary battery, and stop of charging of the secondary battery again.

  On the other hand, when the second electronic device 3b is mounted on the charger 2 and transmits the load confirmation signal transmitted by the charger 2 at time t9, the electronic device 3b is the same as the electronic device 3a at time t11. In addition, a load ACK signal is transmitted by load modulation. In the load ACK signal, the signal transmitted by the electronic device 3a and the signal transmitted by the electronic device 3b are synchronized. Therefore, as a load current in the charger 2, a load current twice as large is detected when the electronic devices 3a and 3b transmit as compared with a case where only the electronic device 3a transmits. Although FIG. 5 shows a case where there are two electronic devices 3a, the present invention is not limited to this, and the load current flows three times in the case of three devices and four times in the case of four devices. Such a magnitude of the load current is detected based on the phase difference detected by the phase difference detection unit 22, and the authentication control unit 23 can detect the number of electronic devices 3. In order to detect the number, the charger 2 recognizes in advance the magnitude of the load current generated corresponding to one electronic device.

  After transmitting the load ACK signal, the electronic device 3b starts charging the secondary battery included in the electronic device 3b at time t12. In addition, while the secondary battery is being charged, the load current on the charger side continues to flow, but in order to deal with the electronic devices 3a and 3b, the load is twice that of the electronic device 3a. A current is detected.

  Subsequently, when the charger 2 transmits a load confirmation signal at time t13, the electronic device 3b stops charging the secondary battery at time t14, similarly to the electronic device 3a.

  Further, when receiving the load confirmation signal, the electronic device 3b transmits a load ACK signal at the time t15 in the same manner as the electronic device 3a while the charging is stopped. When the load ACK signal is transmitted from the electronic device 3 via the secondary coil 31, the charger 2 receives the load ACK signal at approximately the same time (t15). The charger 2 detects the electronic device 3 (electronic devices 3a and 3b) which is a normal load from the received ACK signal, and further continues power transmission. The load ACK signal is also synchronized with the signals of the electronic devices 3a and 3b, and the load current is twice as large as that of the single electronic device, similarly to the load current at time t11.

  Subsequently, after sending the load ACK signal at time t15, the electronic device 3b resumes charging the secondary battery at time t16. In addition, since the power transmission by the charger 2 is continued as long as the regular load is recognized, the power transmission is continued without being interrupted even when the charging is stopped at the times t14 to t16.

  As in FIG. 4, charging to the secondary battery is stopped at times t14 to t16. However, when only the electronic devices 3a and 3b that are regular loads are mounted on the charger 2, Since the switch 35 for use is in an off state, the load current in the charger 2 should be reduced to a predetermined value or less. However, when a foreign object is placed on the charger 2 in addition to the regular load, a small amount of load current due to the foreign object flows. In this case, since the load current does not decrease to a predetermined value or less, it can be detected that there is a foreign object.

  According to the operation of the electronic device charging system 1 shown in FIGS. 4 and 5, non-contact charging is simultaneously performed between one charger 2 and a plurality of electronic devices 3 (for example, electronic devices 3 a and 3 b). Can be done. It is also possible to know the number of electronic devices 3 mounted on the charger 2 based on the magnitude of the load current in the charger 2.

  Although not shown in FIGS. 4 and 5, even when the secondary battery is being charged, when the secondary battery unit 37 detects that the secondary battery has been charged to a predetermined voltage or higher, that effect is obtained. Is included in the charge completion signal and sent to the authentication control unit 36. The authentication control unit 36 controls the charging switch 35 to be turned off based on the charging completion signal.

  For example, when only the secondary battery of the electronic device 3a is fully charged, the magnitude of the load current in the charger 2 is equivalent to one, so that only the electronic device 3b is detected on the charger 2 side. Thus, it is possible to recognize the completion of charging for one device (electronic device 3a). In this case, the power for power transmission may be changed by the authentication control unit 23 controlling the AC unit 25. That is, the magnitude of transmitted power may be changed according to the number of electronic devices 3 to be charged. Thereby, it is possible to prevent excessive power transmission, and it is possible to prevent excessive power transmission when foreign matter is mixed, thereby further improving safety.

  Further, when the secondary battery of the electronic device 3b is also charged after the electronic device 3a, the electronic device 3b to be charged is not detected (that is, the number of detected electronic devices is 0). . In this case, the charger may change the magnitude of the transmitted power to a predetermined value or less (for example, about 0.02 to 0.03 W). Thereby, it is possible to prevent excessive power transmission and to save power.

Next, an operation sequence when performing non-contact charging of the electronic device charging system 1 will be described.
FIG. 6 is a diagram illustrating an example of an operation sequence when the electronic device charging system 1 performs non-contact charging. Here, the first electronic device is 3a, and the second electronic device is 3b.

  First, the charger 2 periodically transmits a load confirmation signal. When the electronic device 3a is placed on the charger 2, a load ACK signal is returned from the electronic device 3a in response to the load confirmation signal transmitted by the charger 2. Accordingly, the load (electronic device 3a) is detected by receiving the load ACK signal. When the charger 2 detects a load (electronic device 3a) mounted on the charger 2, the charger 2 starts power transmission, that is, starts supplying power to the load side (electronic device 3a).

  Even after power supply to the electronic device 3a is started, the charger 2 periodically transmits a load confirmation signal, and the electronic device 3a returns a load ACK signal. Thereby, the charger 2 is monitoring the load and confirms whether there is a regular load. At this time, as described as processing at times t6 to t8 in FIG. 4, the electronic device 3a temporarily stops charging the secondary battery, returns a load ACK signal, and then resumes charging the secondary battery. To do. Thereby, the number (here, one) of regular loads (here, only the electronic device 3a) can be confirmed. In addition, foreign matter detection is performed by confirming that the load current value is equal to or lower than a predetermined current during a period in which charging of the secondary battery is interrupted and not during the transmission period of the load ACK signal.

  Subsequently, when the electronic device 3b is placed on the charger 2, a load ACK signal is returned from the electronic device 3b together with the electronic device 3a in response to the load confirmation signal transmitted by the charger 2. Accordingly, the load (electronic devices 3a and 3b) is detected by receiving the load ACK signal. When the charger 2 detects a load (electronic devices 3a and 3b) placed on the charger 2, the charger 2 starts power transmission, that is, continues to supply power to the load side (electronic devices 3a and 3b). In addition, since the charger 2 can recognize that the load has increased, the supply capability of the electric power transmitted according to the number of the electronic devices 3 may be changed.

  Even after power supply to the electronic devices 3a and 3b is started, the charger 2 periodically transmits a load confirmation signal, and the electronic devices 3a and 3b return a load ACK signal. Thereby, the charger 2 is monitoring the load and confirms whether there is a regular load. At this time, as described as the processing at times t14 to t16 in FIG. 4, the electronic devices 3a and 3b once suspend charging the secondary battery, return the load ACK signal, and then charge the secondary battery. To resume. Thereby, the number of regular loads (here, two electronic devices 3a and 3b) can be confirmed. In addition, foreign matter detection is performed by confirming that the load current value is equal to or lower than a predetermined current during a period in which charging of the secondary battery is interrupted and not during the transmission period of the load ACK signal.

  The charger 2 may stop power transmission when a foreign object is detected in the load monitoring or when no regular load (electronic device 3) exists. Thereby, unnecessary power transmission can be avoided. Further, the charger 2 may display information indicating the number of regular loads using an LED or the like (not shown). Thereby, it is possible to confirm how many regular loads the charger 2 is charging.

  According to the operation of the electronic device charging system 1 shown in FIG. 6 as described above, non-contact charging is simultaneously performed between one charger 2 and a plurality of electronic devices 3 (for example, electronic devices 3a and 3b). Is possible. It is also possible to know the number of electronic devices 3 mounted on the charger 2 based on the magnitude of the load current in the charger 2.

Next, state transition when performing non-contact charging of the electronic device charging system 1 will be described.
FIG. 7 is a diagram illustrating an example of state transition when the electronic device charging system 1 performs non-contact charging.

  The initial mode of the electronic device charging system 1 is a standby mode and is in a standby state (step S11). That is, the charger 2 periodically transmits a load confirmation signal.

  Subsequently, the electronic device charging system 1 performs an authentication process between the charger 2 and the electronic device 3 (step S12). In the authentication process, an authentication request signal, an authentication ID signal, and the like are transmitted and received. When the authentication is successful (for example, when the authentication ID is valid), the process proceeds to step S14. When the authentication is unsuccessful (for example, when the authentication ID is not valid), information indicating that the authentication has failed is displayed. (Step S13).

  Subsequently, when the authentication is successful, the electronic device 3 stops charging the secondary battery when receiving the load confirmation signal from the charger 2 (step S14). Subsequently, the charger 2 determines whether or not there is a foreign object while charging of the secondary battery is stopped (step S15). If there is a foreign object, the charger 2 displays information indicating that there is a foreign object (step S16). If no foreign object exists, the charger 2 proceeds to step S17.

  Subsequently, the charger 2 confirms the number of regular loads (step S17). If there is no regular load, the process returns to step S11 to return to the standby state. When the regular load is one, the charger 2 displays information indicating that the regular load is one (step S18). If there are two regular loads, the charger 2 displays information indicating that the regular loads are two (step S19). Thereby, the user can confirm at a glance how many electronic devices are being charged.

  Subsequently, the electronic device 3 charges the power supplied from the charger 2 to the secondary battery (step S20). The charging here is continued until a load confirmation signal is received from the charger 2, charging is completed, or the electronic device 3 is separated from the charger 2.

  According to the operation of the electronic device charging system 1 shown in FIG. 7, it is possible to perform non-contact charging simultaneously between one charger 2 and a plurality of electronic devices 3. It is also possible to know the number of electronic devices 3 mounted on the charger 2 based on the magnitude of the load current in the charger 2.

  INDUSTRIAL APPLICABILITY The present invention is useful for an electronic device charging system, a charger, an electronic device, and the like that can simultaneously perform non-contact charging between a single charger and a plurality of electronic devices.

Overview of an example of an electronic device charging system according to an embodiment of the present invention Overview of an example of an electronic device charging system according to an embodiment of the present invention The figure which shows the specific structure of the electronic device charging system in embodiment of this invention. 4 is a time chart illustrating an example of a signal flow in the electronic device charging system in a state where one electronic device is mounted on the charger according to the embodiment of the present invention. 4 is a time chart showing an example of a signal flow in the electronic device charging system in a state where a plurality of electronic devices are mounted on the charger according to the embodiment of the present invention. The figure which shows an example of the operation | movement sequence at the time of performing non-contact charge of the electronic device charging system in embodiment of this invention The figure which shows an example of the state transition at the time of performing non-contact charge of the electronic device charging system in embodiment of this invention

DESCRIPTION OF SYMBOLS 1 Electronic device charging system 2 Charger 21 Primary coil 22 Phase difference detection part 23 Authentication control part 24 Power supply connection part 25 AC part 26 Modulation part 27 Switching part 28 Capacitor 3 Electronic device 31 Secondary coil 32 Rectification part 33 Load resistance 34 Load Modulation switch 35 Charging switch 36 Authentication control unit 37 Secondary battery unit 38 Magnetic shielding sheet

Claims (10)

An electronic device charging system comprising a charger that transmits electric power in a non-contact manner and at least one electronic device that uses a secondary battery that is charged with electric power received in a non-contact manner as a power source,
The charger sends a load confirmation signal to confirm the presence or absence of a load,
The at least one electronic device stops charging the secondary battery for a predetermined period after receiving the load confirmation signal, and uses a load response signal at a predetermined time to indicate that there is a load. Send
The charger electronic device charging system for detecting the number of said at least one electronic device in accordance with the magnitude of the load current value caused by the reception of the previous SL load response signal. The electronic device charging system according to claim 1,
The charger comprises a primary coil;
Each of the at least one electronic device includes a secondary coil,
An electronic device charging system that transmits and receives electric power by electromagnetic induction using the primary coil and the secondary coil. The electronic device charging system according to claim 2,
The primary coil and the secondary coil are arranged to face opposite surfaces,
The electronic device charging system, wherein an area of a cross section parallel to the facing surface of the secondary coil is larger than an area of a cross section parallel to the facing surface of the primary coil. The electronic device charging system according to claim 3,
The electronic device charging system in which a flatness of a section parallel to the facing surface of the primary coil is larger than a flatness of a section parallel to the facing surface of the secondary coil. The electronic device charging system according to any one of claims 1 to 4,
The charger is an electronic device charging system that changes power to be transmitted based on the detected number of the at least one electronic device. The electronic device charging system according to claim 5,
When the charger detects that all of the at least one electronic device has been removed, the electronic device charging system reduces the electric power to be transmitted to a predetermined value or less. The electronic device charging system according to any one of claims 1 to 6,
The electronic device charging system, wherein the at least one electronic device transmits the load response signal at a first timing after receiving the load confirmation signal. The electronic device charging system according to claim 7,
The charger is an electronic device charging system that detects a load current value generated by receiving the load response signal at substantially the same timing as the first timing after transmitting the load confirmation signal. The electronic device charging system according to any one of claims 1 to 8,
The charger is an electronic device charging system that notifies the detected number of the at least one electronic device. A charger for transmitting power in a non-contact manner,
A load confirmation signal for confirming the presence / absence of a load is transmitted, and then the number of the at least one electronic device is detected according to the magnitude of a load current value generated by receiving a load response signal from at least one electronic device received thereafter. Charger.

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