JP2013046444A - Charging mechanism, charging method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress temperature rise of object equipment and to charge a secondary battery at a high speed.SOLUTION: A charging mechanism comprises: a first power receiving coil 41 which is arranged inside a housing of a portable terminal, is electromagnetically coupled with a power transmitting coil incorporated in a charger, and receives power emitted from the power transmitting coil; a second power receiving coil 51 which is arranged inside an auxiliary charging unit, is electromagnetically coupled with the power transmitting coil, and receives the power emitted from the power transmitting coil; and a charging control unit 30 which detects a temperature inside the portable terminal and a temperature inside the auxiliary charging unit and selects the first power receiving coil 41 or the second power receiving coil 51 on the basis of the temperatures to charge the secondary battery 19 by the power received by the selected first power receiving coil 41 or second power receiving coil 51.

Description

  The present invention relates to a charging mechanism, a charging method, and a program.

  A contactless charger that transmits power to a target device wirelessly without using a connector or an electric wire and charges a secondary battery incorporated in the target device has been developed and put into practical use.

  The non-contact charger incorporates a power transmission coil in a case, and transmits power to the power reception coil incorporated in the target device using electromagnetic induction.

  However, in charging using electromagnetic induction, the power loss in power transmission is large, the power loss changes to heat, and the temperature of the target device rises due to this heat. When the temperature of the target device rises, there is a risk of threatening the safety of the target device or degrading the performance.

  Methods to limit the temperature rise of the target device include a method of limiting the transmission power, a method of detecting the temperature and temporarily stopping the power transmission when the temperature rises, and restarting the power transmission when the temperature drops, and patenting the target device A method of providing a heat dissipation mechanism as shown in Document 1 has been considered.

JP 2007-207870 A

  In order to suppress the temperature rise of the target device, the method of limiting the power transmitted from the non-contact charger or the method of temporarily stopping charging by detecting the temperature of the target device There was a problem that the charging time to the target device was longer than when not considered.

  In the method of installing a heat dissipation mechanism on the target device, the temperature rise of the target device can be suppressed if the heat dissipation capability of the heat dissipation mechanism is sufficiently high, but if the heat dissipation mechanism is not provided or if the heat dissipation capability is low, the above non-contact Similar to the method of limiting the power transmitted from the battery charger of the type, there is a problem that it takes time to charge.

  The present invention is an invention made in view of such a current situation, and when charging using a non-contact type charger, it is possible to suppress a temperature rise of a target device and perform high-speed charging. With the goal.

In order to achieve the above object, a charging mechanism according to the first aspect of the present invention includes:
A charging mechanism that receives power released by a power transmission coil incorporated in a charger and charges a secondary battery with the received power,
A first power receiving coil that is disposed in the first housing and electromagnetically couples to the power transmitting coil to receive power emitted from the power transmitting coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing, and electromagnetically coupled to the power transmitting coil to receive power emitted from the power transmitting coil;
The secondary battery disposed in the first casing or the second casing;
Temperature detecting means for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detecting means, the second casing is attached to the first casing. Charge control means for selecting one power receiving coil or the second power receiving coil, and charging the secondary battery with power received by the selected first power receiving coil or the second power receiving coil; ,
It is characterized by providing.

In order to achieve the above object, a charging method according to the second aspect of the present invention includes:
A charging method for receiving electric power emitted by a power transmission coil incorporated in a charger and charging a secondary battery with the received electric power,
A first power receiving process for receiving power emitted from the power transmission coil by a first power receiving coil that is disposed in the first housing and electromagnetically coupled to the power transmission coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing and electromagnetically coupled to the power transmitting coil receives power released from the power transmitting coil. 2 power reception processing,
A temperature detection process for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Charging control processing for controlling charging of the secondary battery disposed in the first casing or the second casing,
In the charge control process,
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection process, the second casing is attached to the first casing. Selecting the power received in the first power receiving process or the power received in the second power receiving process, and charging the secondary battery with the selected power;
It is characterized by that.

In order to achieve the above object, a program according to the third aspect of the present invention provides:
On the computer,
Electromagnetic coupling to a power transmission coil built in the charger and the temperature in the first housing in which the first power reception coil for receiving the power discharged from the power transmission coil is disposed, and electromagnetic coupling to the power transmission coil And a temperature detection function for detecting a temperature in a second casing in which the first power receiving coil for receiving the power emitted from the power transmission coil is disposed and detachably attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection function, the first power receiving coil or the second power receiving coil is selected and selected. A charge control function for charging the secondary battery with power received by the first power receiving coil or the second power receiving coil;
It is characterized by realizing.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to suppress the temperature rise of an object apparatus and to charge at high speed.

It is a figure which shows the principal part of the portable terminal as a charge object apparatus. It is a figure which shows a portable terminal and an auxiliary charging unit. It is a permeation | transmission perspective view which shows the state at the time of charge. It is a block diagram which shows the charging mechanism which concerns on embodiment of this invention. It is a figure which shows the structural example of a charger. It is a flowchart which shows operation | movement of the charging mechanism at the time of charging a secondary battery. It is a flowchart which shows a full charge process. It is a figure for demonstrating the structure of another charger.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram illustrating a main part of a mobile terminal 100 as a charging target device.

  The mobile terminal 100 includes, for example, a CPU (Central Processing Unit) 11, a communication unit 12, a ROM (Read Only Memory) 13, a RAM (Random Access Memory) 14, and a nonvolatile memory connected via a bus B. 15, a display unit 16, a sound processing unit 17, a vibrator 18, and a secondary battery 19.

  The CPU 11 operates based on a program stored in the ROM 13, controls the overall operation of the mobile terminal 100, and performs data processing.

The communication unit 12 transmits and receives voice and data to and from a communication partner.
The RAM 14 provides a storage area for the CPU 11.

The nonvolatile memory 15 stores various data.
The display unit 16 displays images and data.
The voice processing unit 17 includes a microphone, a speaker, and the like, and rings a ringtone and inputs / outputs voice.
The vibrator 18 is composed of a vibration motor, and vibrates to notify the user of an incoming call when the incoming call is received.

  The CPU 11, communication unit 12, ROM 13, RAM 14, nonvolatile memory 15, display unit 16, sound processing unit 17, and vibrator 18 are operated by power supplied from the secondary battery 19 through the power line PL, and are portable. Various functions are realized as the terminal 100. The secondary battery 19 is, for example, a lithium ion battery. The negative electrode of the secondary battery 19 is connected to the ground, and the power supply line PL is connected to the positive electrode of the secondary battery 19.

  When charging the secondary battery 19 of the mobile terminal 100, an auxiliary charging unit 200 that is detachably attached to the mobile terminal 100 is used as shown in FIG.

  When charging the secondary battery 19, the auxiliary charging unit 200 is attached to the portable terminal 100, and the portable terminal 100 and the auxiliary charging unit 200 are placed on the upper surface of the charger 300 as shown in FIG. 3.

  In the charger 300, a plurality of power transmission coils 310 are arranged and arranged. Each power transmission coil 310 is configured by winding a winding in a flat plate shape, and is arranged so that the flat plate surface faces upward. The charger 300 transmits electric power by causing an exciting current to flow through the power transmission coil 310 to generate a magnetic field. The portable terminal 100 and the auxiliary charging unit 200 receive the power transmitted from the charger 300 side and charges the secondary battery 19.

  A charging mechanism 20 for charging the secondary battery 19 of the mobile terminal 100 is incorporated in the mobile terminal 100 and the auxiliary charging unit 200.

FIG. 4 is a configuration diagram showing the charging mechanism 20 according to the embodiment of the present invention.
The charging mechanism 20 includes a charging control unit 30, a power pickup unit 40, and a power pickup unit 50.

  The charging control unit 30 and the power pickup unit 40 are incorporated in the casing of the portable terminal 100, and the power pickup unit 50 is incorporated in the casing of the auxiliary charging unit 200. The charging control unit 30 is supplied with power from the secondary battery 19 incorporated in the mobile terminal 100 via the power line PL. Note that the charging control unit 30 can also be configured by the CPU 11.

  The auxiliary charging unit 200 is connected to the charging control unit 30 via the connector 60 while being attached to the portable terminal 100.

  The power pickup unit 40 includes a power receiving coil 41, a capacitor 42, a diode 43 as a rectifying element, a smoothing capacitor 44, a current detecting resistor 45, a changeover switch 46, an overcharge preventing switch 47, And a temperature sensor 48.

  The power pickup unit 50 includes a power receiving coil 51, a capacitor 52, a diode 53 as a rectifying element, a smoothing capacitor 54, an overcharge prevention switch 55, and a temperature sensor 56.

  In a state where the auxiliary charging unit 200 is attached to the mobile terminal 100, the ground on the mobile terminal 100 side and the ground of the auxiliary charging unit 200 are connected as shown in FIG.

  In the power pickup unit 40, the temperature sensor 48 is disposed in the vicinity of the power receiving coil 41. The temperature sensor 48 is connected to the charge control unit 30, measures the ambient temperature, and supplies the measured temperature to the charge control unit 30.

  One end of the power receiving coil 41 is connected to the ground, and the other end of the power receiving coil 41 is connected to one end of the overcharge prevention switch 47. The other end of the power receiving coil 41 is connected to the charging control unit 30 so that a signal can flow from the charging control unit 30 to the power receiving coil 41.

  The overcharge prevention switch 47 is turned off when a high level control signal is supplied from the charge control unit 30 and turned on when a high level control signal is not supplied from the charge control unit 30. The charging control unit 30 monitors the charging current and charging voltage of the secondary battery 19 and determines whether or not the secondary battery 19 is fully charged. When it is determined that the secondary battery 19 is in a fully charged state, the charge control unit 30 gives a high level control signal to the overcharge prevention switch 47. When the charge control unit 30 determines that the secondary battery 19 is not fully charged, the charge control unit 30 does not give a high-level control signal to the overcharge prevention switch 47.

  A capacitor 42 is connected between the other end of the overcharge prevention switch 47 and the ground. The capacitor 42 forms a resonance circuit in combination with the power receiving coil 41.

  The other end of the overcharge prevention switch 47 is connected to the anode of the diode 43, and the cathode of the diode 43 is connected to one electrode of the smoothing capacitor 44. A contact 49 a is connected to one electrode of the smoothing capacitor 44. The other electrode of the smoothing capacitor 44 is connected to the negative electrode of the secondary battery 19.

  The negative electrode of the secondary battery 19 is connected to the ground. One end of a resistor 45 is connected to the positive electrode of the secondary battery 19. The resistor 45 converts a charging current for the secondary battery 19 into a voltage. The positive electrode of the secondary battery 19 and the other end of the resistor 45 are connected to the charge control unit 30.

A changeover switch 46 is connected to the other end of the resistor 45.
The changeover switch 46 connects the other end of the resistor 45 to the contact 49a or the contact 49b based on a control signal from the charge control unit 30. In a state where the changeover switch 46 connects the resistor 45 to the contact 49a, the positive electrode of the secondary battery 19 is connected to the positive electrode of the smoothing capacitor 44 of the power pickup unit 40, and the secondary battery 19 receives power at the power pickup unit 40. It is charged with electricity.

  In a state where the changeover switch 46 connects the resistor 45 to the contact 49 b, the positive electrode of the secondary battery 19 is connected to the power pickup unit 50, and power from the power pickup unit 50 is applied to the secondary battery 19. That is, the charging control unit 30 selects whether to charge the secondary battery 19 from the power pickup unit 40 side or from the power pickup unit 50.

  In the power pickup unit 50, the temperature sensor 56 is disposed in the vicinity of the power receiving coil 51. The temperature sensor 56 is connected to the charging control unit 30 via the connector 60 in a state where the auxiliary charging unit 200 is attached to the portable terminal 100, measures the ambient temperature, and gives the measured temperature to the charging control unit 30.

  One end of the power receiving coil 51 is connected to the ground, and one end of an overcharge prevention switch 55 is connected to the other end of the power receiving coil 51. The other end of the power receiving coil 51 is connected to the charging control unit 30 via the connector 60 with the auxiliary charging unit 200 attached to the portable terminal 100, and a signal is sent from the charging control unit 30 to the power receiving coil 51. Is possible.

  The overcharge prevention switch 55 is connected to the charge control unit 30 in a state where the auxiliary charging unit 200 is attached to the portable terminal 100, and a control signal is given from the charge control unit 30 via the connector 60. The overcharge prevention switch 55 is turned off when a high level control signal is supplied from the charge control unit 30, and is turned on when a high level control signal is not supplied from the charge control unit 30.

  When it is determined that the secondary battery 19 is fully charged, the charging control unit 30 provides a high-level control signal to the overcharge prevention switch 55. When the charge control unit 30 determines that the secondary battery 19 is not fully charged, the charge control unit 30 does not give a high-level control signal to the overcharge prevention switch 55.

  A capacitor 52 is connected between the other end of the overcharge prevention switch 55 and the ground. The capacitor 52 forms a resonance circuit together with the power receiving coil 51.

  The anode of the diode 53 is connected to the other end of the overcharge prevention switch 55, and the cathode of the diode 53 is connected to one electrode of the smoothing capacitor 54. One electrode of the smoothing capacitor 54 is connected to a contact 49 b in the power pickup unit 40 via the connector 60 in a state where the auxiliary charging unit 200 is attached to the portable terminal 100. The other electrode of the smoothing capacitor 54 is connected to the ground.

  On the other hand, as shown in FIG. 5, the charger 300 includes a plurality of power transmission coils 310, a power supply circuit 311, and a power transmission control unit 312.

  The power supply circuit 311 generates transmission power to be supplied to the power transmission coil 310 by performing voltage conversion and frequency conversion on power supplied from the commercial power supply via the plug 313.

  The power transmission control unit 312 selects the power transmission coil 310 that transmits the transmission power from the plurality of power transmission coils 310, controls the power supply circuit 311, and causes AC power transmission to flow from the power supply circuit 311 to the selected power transmission coil 310.

  Next, operations of the charger 300 and the charging mechanism 20 when receiving the secondary battery 19 of the mobile terminal 100 will be described.

  When charging the secondary battery 19, the auxiliary charging unit 200 is attached to the portable terminal 100, and the portable terminal 100 and the auxiliary charging unit 200 are placed on the upper surface of the charger 300.

  When the secondary battery 19 is not fully charged, the overcharge prevention switch 47 of the power pickup unit 40 and the overcharge prevention switch 55 of the power pickup unit 50 are turned on.

  When the secondary battery 19 is in a fully charged state, the charging control unit 30 gives a high-level control signal to the overcharge prevention switches 47 and 55 to turn off the overcharge prevention switches 47 and 55. When the overcharge prevention switches 47 and 55 are off, no current flows through the power receiving coils 41 and 51, and the secondary battery 19 is not charged.

  The power transmission control unit 312 of the charger 300 scans the transmission coil 310 that does not supply the transmission power, and sequentially supplies a pulse signal. The power transmission control unit 312 periodically performs a process of scanning the power transmission coil 310 that does not transmit transmission power and sequentially flowing pulse signals.

  When the secondary battery 19 is not in a fully charged state, if there is the power receiving coil 41 of the power pickup unit 40 facing the power transmitting coil 310 through which the pulse signal has flowed, a current flows through the power receiving coil 41 by electromagnetic coupling. When a current flows through the power receiving coil 41, an echo signal corresponding to the pulse signal is induced in the power transmitting coil 310 that has passed the pulse signal.

  The power transmission control unit 312 detects the echo signal induced in the power transmission coil 310, and detects the power transmission coil 310 disposed opposite to the position closest to the power reception coil 41 from the intensity of the echo signal. The power transmission control unit 312 controls the power supply circuit 311 and causes the transmission power to flow through the power transmission coil 310 disposed opposite to the position closest to the power reception coil 41. When the transmitted power flows through the power transmission coil 310, power is induced in the power receiving coil 41 opposite to the power transmission coil 310 by electromagnetic coupling, and power transmission is started.

  In addition, if there is a power receiving coil 51 of the power pickup unit 50 facing the power transmitting coil 310 through which the pulse signal flows, a current flows through the power receiving coil 51 by electromagnetic coupling. When a current flows through the power receiving coil 51, an echo signal corresponding to the pulse signal is induced in the power transmitting coil 310 that has passed the pulse signal.

  The power transmission control unit 312 detects the power transmission coil 310 disposed opposite to the position closest to the power reception coil 51 from the echo signal induced in the power transmission coil 310, controls the power supply circuit 311, and receives power Transmitted power is supplied to the power transmission coil 310 disposed opposite to the position closest to the coil 51. When the transmitted power flows through the power transmission coil 310, power is induced in the power reception coil 51 opposite to the power transmission coil 310 by electromagnetic coupling, and power transmission is started.

  On the other hand, the charging control unit 30 provided in the charging mechanism 20 stops power transmission to the power receiving coil 41 or the power receiving coil 51 in a state where power is supplied from the secondary battery 19 and a control signal can be generated. A stop request signal for causing the signal to flow is sent as a control signal.

  In a state in which the changeover switch 46 connects the other end of the resistor 45 to the contact 49 a, the charging control unit 30 sends a stop request signal to the power receiving coil 51. When the changeover switch 46 connects the other end of the resistor 45 to the contact 49 b, the charging control unit 30 sends a stop request signal to the power receiving coil 41.

  When the stop request signal is passed through the power receiving coil 41, a signal corresponding to the stop request signal is induced in the power transmitting coil 310 facing the power receiving coil 41, and the power transmission control unit 312 detects this. Upon detecting that a signal corresponding to the stop request signal is induced in the power transmission coil 310, the power transmission control unit 312 controls the power supply circuit 311 to flow through the power transmission coil 310 in which the signal corresponding to the stop request signal is induced. Stop transmission power.

When the stop request signal is passed through the power receiving coil 51, a signal corresponding to the stop request signal is induced in the power transmitting coil 310 facing the power receiving coil 51, and the power transmission control unit 312 detects this. Upon detecting that a signal corresponding to the stop request signal is induced in the power transmission coil 310, the power transmission control unit 312 controls the power supply circuit 311 to flow through the power transmission coil 310 in which the signal corresponding to the stop request signal is induced. Stop transmission power.
In this way, by sending a stop request signal to the power receiving coil 41 or the power receiving coil 51, unnecessary power transmission is suppressed.

The charge control unit 30 continuously selects and flows the power reception coil 41 or the power reception coil 51 during the period in which the control signal can be generated.
Note that the frequency of the stop request signal is preferably different from the transmitted power flowing in the power transmission coil 310.

Next, the charging operation of the charging mechanism 20 will be described with reference to FIG.
FIG. 6 is a flowchart showing the operation of the charging mechanism 20.
Here, the operation of the charging mechanism 20 will be described assuming that, for example, when the charger 300 starts power transmission, the changeover switch 46 connects the other end of the resistor 45 to the contact 49a.

  When the charger 300 starts power transmission, the received power corresponding to the transmitted power flows through the power receiving coil 41 facing the power transmitting coil 310 through which the transmitted power is passed, due to electromagnetic coupling. The diode 43 arranges the power flowing through the power receiving coil 41, and the smoothing capacitor 44 smoothes the received power supplied from the diode 43, and supplies it to the secondary battery 19 through the changeover switch 46 and the resistor 45 to provide secondary charging. The battery 19 is charged. That is, charging of the secondary battery 19 is started from the power pickup unit 40 side (step S10).

  In a state where the charging control unit 30 does not send a stop request signal to the power receiving coil 51, when the charger 300 sends transmission power to the power transmission coil 310 that faces the power receiving coil 51, the power transmission coil 310. However, since the switch 46 is not connected to the contact 49b at the other end of the resistor 45, the secondary battery 19 is connected from the power pickup unit 50 side. It will not be charged.

  When charging of the secondary battery 19 is started, the secondary battery 19 stores electric power to be given to each part of the mobile terminal 100. When the charging control unit 30 can receive power from the secondary battery 19 and generate a control signal, the charging control unit 30 sends a stop request signal as a control signal to the power receiving coil 51 to receive power. Power transmission to the coil 51 is stopped.

The charging control unit 30 monitors the temperature measurement results of the temperature sensors 48 and 56 and detects the temperature near the power receiving coil 41 and the temperature near the power receiving coil 51.
The charge control unit 30 measures the voltage at one end of the resistor 45 and monitors the voltage at the other end of the resistor 45. The charging control unit 30 detects the charging voltage of the secondary battery 19 from the voltage at one end of the resistor 45, and detects the charging current of the secondary battery 19 from the voltage at both ends of the resistor 45.

  The charge control unit 30 determines whether or not the secondary battery 19 is fully charged based on the voltage across the resistor 45 (step S20). For example, when the charging current of the secondary battery 19 decreases to a predetermined value after the charging voltage of the secondary battery 19 reaches a predetermined voltage, the charging control unit 30 determines that the secondary battery 19 is fully charged. To do.

  When the charge control unit 30 determines that the secondary battery 19 has been fully charged (step S20: YES), the charge control unit 30 performs a full charge process (step S30).

FIG. 7 is a flowchart showing the full charge process.
In the full charge process, a high-level control signal is sent to the overcharge prevention switches 47 and 55 of the power pickup unit 40 and the power backup unit 50 to turn off the overcharge prevention switches 47 and 55 (step S31). Further, the charging control unit 30 sends a stop request signal as a control signal to the power receiving coil 41 and the power receiving coil 51 (step S32), and ends the process.

  By sending a stop request signal to the power receiving coil 41 and the power receiving coil 51, a signal corresponding to the stop request signal is induced in each power transmitting coil 310 facing the power receiving coil 41 and the power receiving coil 51. The control unit 312 detects this. The power transmission control unit 312 controls the power supply circuit 311 so that the transmitted power does not flow through the power receiving coil 41 and the power transmitting coil 310 facing the power receiving coil 51.

The charge control unit 30 determines that the secondary battery 19 is no longer fully charged when the voltage at the other end of the resistor 45 becomes equal to or lower than a predetermined value after the full charge process is completed, and the overcharge prevention switch The high-level control signal given to 47 and 55 is stopped, and the overcharge prevention switches 47 and 55 are turned on.
Further, the charging control unit 30 stops the stop request signal from flowing through the power receiving coil 41 or the power receiving coil 51 of the power pickup units 40 and 50 on the side not selected by the changeover switch 46. For example, when the changeover switch 46 connects the other end of the resistor 45 to the contact 49a, the flow of the stop request signal to the power receiving coil 51 is stopped. When the changeover switch 46 connects the other end of the resistor 45 to the contact 49b, the flow of the stop request signal to the power receiving coil 41 is stopped. As a result, the secondary battery 19 can be recharged.

  When it is determined in step S20 that the secondary battery 19 is not fully charged (step S20: NO), the charging control unit 30 determines that the periphery of the power receiving coil 41 is predetermined based on the temperature measurement result of the temperature sensor 48. It is determined whether or not the temperature has been exceeded (step S40).

  When it is determined that the temperature around the power receiving coil 41 has reached a predetermined temperature or higher (step S40: YES), the charging control unit 30 sends a control signal to the changeover switch 46, changes the connection destination of the changeover switch 46, and the resistance 45 Is connected to the contact 49. Furthermore, the charging control unit 30 causes the stop request signal to flow through the power receiving coil 41 and stops the stop request signal from flowing through the power receiving coil 51. This process enables power reception on the power pickup unit 50 side and stops charging of the secondary battery 19 from the power pickup unit 40 side (step S50).

Furthermore, the charging control unit 30 stops the stop request signal from flowing through the power receiving coil 51. Thereby, it is possible to receive power on the power pickup unit 50 side.
The power transmission control unit 312 of the charger 300 gives a pulse signal while scanning a plurality of power transmission coils 310 that are not performing power transmission, and changes the power transmission coil 310 facing the power reception coil 51 from an echo signal that responds to the pulse signal. It detects and controls the power supply circuit 311 with respect to the coil 310 for power transmission, and sends transmission power. That is, the charger 300 starts power transmission.

  When the charger 300 starts power transmission, the received power corresponding to the transmitted power flows through the power receiving coil 51 facing the power transmitting coil 310 through which the transmitted power is passed, due to electromagnetic coupling. The diode 53 arranges the power flowing in the power receiving coil 51, and the smoothing capacitor 54 smoothes the power received from the diode 53, and supplies it to the secondary battery 19 through the contact 49 b, the changeover switch 46 and the resistor 45. The secondary rechargeable battery 19 is charged. That is, charging of the secondary battery 19 is started from the power pickup unit 50 side (step S60).

  The charge control unit 30 determines whether or not the secondary battery 19 is fully charged based on the voltage across the resistor 45 (step S70). For example, when the charging current of the secondary battery 19 decreases to a predetermined value after the charging voltage of the secondary battery 19 reaches a predetermined voltage, the charging control unit 30 determines that the secondary battery 19 is fully charged. To do.

  If the charge control unit 30 determines that the secondary battery 19 has been fully charged (step S70: YES), the charge control unit 30 moves the process to step S30 and performs the full charge process.

  If it is determined in step S70 that the secondary battery 19 is not fully charged (step S70: NO), the charging control unit 30 determines that the periphery of the power receiving coil 51 is predetermined based on the temperature measurement result of the temperature sensor 56. It is determined whether or not the temperature has been exceeded (step S80).

  When it is determined that the periphery of the power receiving coil 41 has reached a predetermined temperature or higher (step S80: YES), the charging control unit 30 sends a control signal to the changeover switch 46, changes the connection destination of the changeover switch 46, and the resistance 45 Is connected to the contact 49a. Furthermore, the charging control unit 30 causes the stop request signal to flow through the power receiving coil 51 and stops the stop request signal from flowing through the power receiving coil 41. This process enables power reception on the power pickup unit 40 side and stops charging of the secondary battery 19 from the power pickup unit 50 side (step S90).

  The power transmission control unit 312 of the charger 300 gives a pulse signal while scanning a plurality of power transmission coils 310 that are not performing power transmission, and changes the power transmission coil 310 facing the power reception coil 41 from an echo signal that responds to the pulse signal. It detects and controls the power supply circuit 311 with respect to the coil 310 for power transmission, and sends transmission power. That is, the charger 300 starts power transmission. Thereafter, the processing in the charging mechanism 20 proceeds to step S10.

  As described above, the charging mechanism 20 according to the present embodiment includes the charging control unit 30 and the power pickup unit 40 that are incorporated in the casing of the mobile terminal 100, and the power pickup unit 50 that is incorporated in the auxiliary charging unit 200. Has been. When the temperature of the power pickup unit 40 reaches a predetermined value when the temperatures of the power pickup unit 40 and the power pickup unit 50 are detected and the secondary battery 19 is charged with the power received by the power pickup unit 40 The secondary battery 19 is charged with the electric power received by the power pickup unit 50 by switching the selection. In addition, when the secondary battery 19 is being charged with the power received by the power pickup unit 50, if the temperature of the power pickup unit 50 reaches a predetermined value, the power is received by the power pickup unit 40 by switching the selection. Then, the secondary battery 19 is charged. Therefore, the temperature of the portable terminal 100 and the auxiliary charging unit 200 does not increase so much that the portable terminal 100 and the auxiliary charging unit 200 are damaged. In addition, since charging of the secondary battery 19 is not stopped, the secondary battery can be received at high speed.

  Further, when it is detected that the secondary battery 19 is fully charged, a stop request signal is sent to the power receiving coils 41 and 51 so that the secondary battery 19 is not charged. The overcharge of the battery 19 can be prevented.

  Further, since the stop request signal is sent to the power receiving coils 41 and 51 and the release of the power from the power transmitting coils facing the power receiving coils 41 and 51 is stopped, it is possible to prevent unnecessary power transmission.

The present invention is not limited to the above embodiment.
The power pickup unit 40 and the power pickup unit 50 are not limited to the configuration shown in FIG. For example, the overcharge prevention switches 47 and 55 may be provided between the power receiving coils 41 and 51 and the ground.

  Further, the charge control unit 30 may be disposed in the power pickup unit 50.

  Moreover, although the charging mechanism 20 charges the secondary battery 19 using the portable terminal 100 as a target device, the target device is not limited to the portable terminal 100. For example, a charging mechanism may be provided in a shaver or the like, and a secondary battery built in the shaver or the like may be charged.

In addition, the charger 300 is configured to detect the power transmission coil facing the power receiving coils 41 and 51 from the plurality of power transmission coils 310 arranged, and perform power transmission, but other configurations are also conceivable.
FIG. 8 is a diagram for explaining the configuration of another charger.
For example, the charger 400 shown in FIG. 8 includes two power transmission coils 410, a moving mechanism 420 that moves each power transmission coil 410 in the X direction and the Y direction, and the positions of the power receiving coils 41 and 51 in the X direction. And a plurality of coils 440 for detecting the position of the power receiving coils 41 and 51 in the Y direction.

In the charger 400, pulse signals are sent to the plurality of coils 430, the positions of the power receiving coils 41 and 51 in the X direction are detected from the echo signals corresponding to the pulse signals, the pulse signals are sent to the plurality of coils 440, and the pulses The position of the power receiving coils 41 and 51 in the Y direction is detected from the echo signal corresponding to the signal. Based on these detection results, the moving mechanism 420 moves the power transmission coil 410 in the X direction and the Y direction, respectively, and opposes the power transmission coil 410 to the power reception coils 41 and 51.
The charging mechanism of the present invention can also be applied when such a charger is used.

  The present invention includes a program for causing a computer to realize the functions of the apparatus described above. These programs may be read from a recording medium and loaded into a computer, or may be transmitted via a communication network and loaded into a computer.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
A charging mechanism that receives power released by a power transmission coil incorporated in a charger and charges a secondary battery with the received power,
A first power receiving coil that is disposed in the first housing and electromagnetically couples to the power transmitting coil to receive power emitted from the power transmitting coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing, and electromagnetically coupled to the power transmitting coil to receive power emitted from the power transmitting coil;
The secondary battery disposed in the first casing or the second casing;
Temperature detecting means for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detecting means, the second casing is attached to the first casing. Charge control means for selecting one power receiving coil or the second power receiving coil, and charging the secondary battery with power received by the selected first power receiving coil or the second power receiving coil; ,
A charging mechanism comprising:

(Appendix 2)
When the temperature in the first casing exceeds a predetermined value when the secondary battery is being charged with power received by the first power receiving coil, When a power receiving coil is selected, the secondary battery is charged with power received by the selected second power receiving coil, and the secondary battery is charged with power received by the second power receiving coil When the temperature in the second casing exceeds a predetermined value, the first power receiving coil is selected, and the secondary battery is charged with power received by the selected first power receiving coil. The charging mechanism according to appendix 1, characterized by:

(Appendix 3)
The charging control means stops the release of power to the first power receiving coil of the power transmission coil or the power to the second power receiving coil, thereby stopping the unselected side. The charging mechanism according to appendix 1 or 2, wherein power reception by the first power receiving coil or the second power receiving coil is stopped.

(Appendix 4)
The charge control means includes
Detecting whether the secondary battery is fully charged,
When it is detected that the secondary battery is in a fully charged state, by stopping the release of power to the first power receiving coil and the second power receiving coil of the power transmitting coil Any one of Supplementary notes 1 to 3, wherein charging of the secondary battery with power received by the first power receiving coil and power received by the second power receiving coil is stopped. The charging mechanism described.

(Appendix 5)
A charging method for receiving electric power emitted by a power transmission coil incorporated in a charger and charging a secondary battery with the received electric power,
A first power receiving process for receiving power emitted from the power transmission coil by a first power receiving coil that is disposed in the first housing and electromagnetically coupled to the power transmission coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing and electromagnetically coupled to the power transmitting coil receives power released from the power transmitting coil. 2 power reception processing,
A temperature detection process for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Charging control processing for controlling charging of the secondary battery disposed in the first casing or the second casing,
In the charge control process,
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection process, the second casing is attached to the first casing. Selecting the power received in the first power receiving process or the power received in the second power receiving process, and charging the secondary battery with the selected power;
A charging method characterized by that.

(Appendix 6)
In the charging control process, when the temperature in the first casing exceeds a predetermined value when the secondary battery is being charged with the power received in the first power receiving process, the second control When the power received in the power receiving process is selected, the secondary battery is charged with the power received in the second power receiving process, and the secondary battery is charged with the power received in the second power receiving process When the temperature in the second casing exceeds a predetermined value, the power received in the first power receiving process is selected, and the secondary battery is charged with the power received in the first power receiving process. To
The charging method according to appendix 5, wherein:

(Appendix 7)
In the charging control process, when the power to be received in the first power receiving process is selected, the first power receiving coil stops the discharge of the power to the second power receiving coil, thereby When the power reception by the second power receiving coil is stopped and the power received by the second power receiving process is selected, the power is discharged to the first power receiving coil of the power transmitting coil. By stopping the power reception by the first power receiving coil,
The charging method according to appendix 5 or 6, characterized in that:

(Appendix 8)
In the charge control process,
Detecting whether the secondary battery is fully charged,
When it is detected that the secondary battery is in a fully charged state, by stopping the release of power to the first power receiving coil and the second power receiving coil of the power transmitting coil The charging of the secondary battery with the power received in the first power receiving process and the power received in the second power receiving process is stopped, according to any one of appendices 5 to 7, Charging method.

(Appendix 9)
On the computer,
Electromagnetic coupling to a power transmission coil built in the charger and the temperature in the first housing in which the first power reception coil for receiving the power discharged from the power transmission coil is disposed, and electromagnetic coupling to the power transmission coil And a temperature detection function for detecting a temperature in a second casing in which the first power receiving coil for receiving the power emitted from the power transmission coil is disposed and detachably attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection function, the first power receiving coil or the second power receiving coil is selected and selected. A charge control function for charging the secondary battery with power received by the first power receiving coil or the second power receiving coil;
A program characterized by realizing.

DESCRIPTION OF SYMBOLS 19 Secondary battery 20 Charging mechanism 30 Charging control part 40,50 Electric power pick-up part 41,51 Power receiving coil 42,52 Capacitor 43,53 Diode 44,54 Smoothing capacitor 45 Resistance 46 Changeover switch 47,55 Overcharge prevention switch 48 , 56 Temperature sensor 100 Mobile terminal 200 Auxiliary charging unit 300, 400 Charger 310 Coil for power transmission

Claims (9)

A charging mechanism that receives power released by a power transmission coil incorporated in a charger and charges a secondary battery with the received power,
A first power receiving coil that is disposed in the first housing and electromagnetically couples to the power transmitting coil to receive power emitted from the power transmitting coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing, and electromagnetically coupled to the power transmitting coil to receive power emitted from the power transmitting coil;
The secondary battery disposed in the first casing or the second casing;
Temperature detecting means for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detecting means, the second casing is attached to the first casing. Charge control means for selecting one power receiving coil or the second power receiving coil, and charging the secondary battery with power received by the selected first power receiving coil or the second power receiving coil; ,
A charging mechanism comprising:   When the temperature in the first casing exceeds a predetermined value when the secondary battery is being charged with power received by the first power receiving coil, When a power receiving coil is selected, the secondary battery is charged with power received by the selected second power receiving coil, and the secondary battery is charged with power received by the second power receiving coil When the temperature in the second casing exceeds a predetermined value, the first power receiving coil is selected, and the secondary battery is charged with power received by the selected first power receiving coil. The charging mechanism according to claim 1.   The charging control means stops the release of power to the first power receiving coil of the power transmission coil or the power to the second power receiving coil, thereby stopping the unselected side. 3. The charging mechanism according to claim 1, wherein power reception by the first power receiving coil or the second power receiving coil is stopped. 4. The charge control means includes
Detecting whether the secondary battery is fully charged,
When it is detected that the secondary battery is in a fully charged state, by stopping the release of power to the first power receiving coil and the second power receiving coil of the power transmitting coil 4. The charging of the secondary battery with the power received by the first power receiving coil and the power received by the second power receiving coil is stopped. 5. The charging mechanism described in 1. A charging method for receiving electric power emitted by a power transmission coil incorporated in a charger and charging a secondary battery with the received electric power,
A first power receiving process for receiving power emitted from the power transmission coil by a first power receiving coil that is disposed in the first housing and electromagnetically coupled to the power transmission coil;
A second power receiving coil disposed in a second housing detachably attached to the first housing and electromagnetically coupled to the power transmitting coil receives power released from the power transmitting coil. 2 power reception processing,
A temperature detection process for detecting a temperature in the first casing and a temperature in the second casing in a state where the second casing is attached to the first casing;
Charging control processing for controlling charging of the secondary battery disposed in the first casing or the second casing,
In the charge control process,
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection process, the second casing is attached to the first casing. Selecting the power received in the first power receiving process or the power received in the second power receiving process, and charging the secondary battery with the selected power;
A charging method characterized by that. In the charging control process, when the temperature in the first casing exceeds a predetermined value when the secondary battery is being charged with the power received in the first power receiving process, the second control When the power received in the power receiving process is selected, the secondary battery is charged with the power received in the second power receiving process, and the secondary battery is charged with the power received in the second power receiving process When the temperature in the second casing exceeds a predetermined value, the power received in the first power receiving process is selected, and the secondary battery is charged with the power received in the first power receiving process. To
The charging method according to claim 5. In the charging control process, when the power to be received in the first power receiving process is selected, the first power receiving coil stops the discharge of the power to the second power receiving coil, thereby When the power reception by the second power receiving coil is stopped and the power received by the second power receiving process is selected, the power is discharged to the first power receiving coil of the power transmitting coil. By stopping the power reception by the first power receiving coil,
The charging method according to claim 5 or 6 characterized by things. In the charge control process,
Detecting whether the secondary battery is fully charged,
When it is detected that the secondary battery is in a fully charged state, by stopping the release of power to the first power receiving coil and the second power receiving coil of the power transmitting coil 8. The charging of the secondary battery with the power received by the first power receiving process and the power received by the second power receiving process is stopped. 8. Charging method. On the computer,
Electromagnetic coupling to a power transmission coil built in the charger and the temperature in the first housing in which the first power reception coil for receiving the power discharged from the power transmission coil is disposed, and electromagnetic coupling to the power transmission coil And a temperature detection function for detecting a temperature in a second casing in which the first power receiving coil for receiving the power emitted from the power transmission coil is disposed and detachably attached to the first casing;
Based on the temperature in the first casing and the temperature in the second casing detected by the temperature detection function, the first power receiving coil or the second power receiving coil is selected and selected. A charge control function for charging the secondary battery with power received by the first power receiving coil or the second power receiving coil;
A program characterized by realizing.

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