JP2014200137A - Electronic apparatus, power feeding method and power feeding system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid inconvenience resulting from residual magnetism by demagnetizing magnetization generated during power feeding.SOLUTION: The electronic apparatus (charging platforms 4-1, 4-2, electronic apparatuses 6-1, 6-2) has a non-contact power feeding function including coils (12, 22) and includes current supply sections (14, 24). The coil generates a magnetic field (M1) with an energization current or generates a current by receiving a magnetic field. The current supply section supplies, after non-contact power feeding, a current running in the opposite direction to a current running through the coil during non-contact power feeding to the coil and generates a magnetic field (M2) with reverse polarity to a magnetic field generated during non-contact power feeding. The electronic apparatus demagnetizes magnetization generated by non-contact power feeding.

Description

The present disclosure relates to an electronic device such as a portable terminal device including a contactless power feeding function, a power feeding method, and a power feeding system.

  A battery is mounted on an electronic device such as a portable terminal device. The battery is charged by using non-contact power supply that wirelessly receives power from an external power source. In the non-contact power feeding, the power feeding side device and the mobile terminal device are electrically connected without contact, and power for charging is supplied to the mobile terminal device.

With respect to this non-contact power feeding, it is known to generate an induced electromotive force between coils to transmit electric power (for example, Patent Documents 1 and 2). Moreover, it is known that a shielding member is provided to block a magnetic field (for example, Patent Document 1).

Special table 2009-501000 gazette JP 2011-172437 A

  By the way, in non-contact power supply, electric power is transmitted through a magnetic field, so a magnetic field is generated inside the electronic device during power supply. The magnetic material contained in this magnetic field is magnetized. Electronic components such as a magnetic sensor and a microphone including a magnetic material are magnetized. Even if the power supply is completed, if the magnetized state is maintained, that is, if the remanent magnetism is maintained, the operation of the electronic component becomes unstable, and an accurate sensor output cannot be obtained. There is a problem that cannot be expected.

In view of such problems, it is an object of the present disclosure to provide an electronic device, a power feeding method, and a power feeding system that demagnetize magnetization generated during power feeding and avoid inconvenience due to residual magnetism.

In order to achieve the above object, the electronic device of the present disclosure has a non-contact power feeding function including a coil and includes a current supply unit. The coil generates a magnetic field by an exciting current, or generates a current by receiving the magnetic field. The current supply unit supplies a current that flows in a direction opposite to the current flowing through the coil during the non-contact power supply to the coil after the non-contact power supply, and generates a magnetic field having a polarity opposite to the magnetic field generated during the non-contact power supply. The electronic device demagnetizes the magnetization generated by the non-contact power feeding.

  According to the electronic device, the power feeding method, and the power feeding system of the present disclosure, a magnetic field having a polarity opposite to the magnetic field generated during power feeding is generated. For example, the operation of the electronic component is stabilized.

Other objects, features, and advantages of the present invention will become clearer with reference to the accompanying drawings and each embodiment.

It is a figure which shows an example of the charging system which concerns on 1st Embodiment. It is a figure which shows an example of the charging system in charge. It is a figure which shows an example of the charging system in demagnetization. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a figure which shows an example of the charging system which concerns on 2nd Embodiment. It is a figure which shows an example of the charging system in charge. It is a figure which shows an example of the charging system in demagnetization. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a figure which shows an example of the charging system which concerns on 3rd Embodiment. It is a figure which shows an example of the function of a control part. It is a figure which shows an example of the circuit structure of a charging system. It is a figure which shows an example of the circuit structure of an electric power supply circuit. It is a figure which shows an example of the flow of the electric current at the time of charge. The figure which shows an example of the electric current value by the side of a charging stand, and the polarity of a magnetic field. The figure which shows an example of the electric current value by the side of a battery pack, and the polarity of a magnetic field. It is a figure which shows an example of the flow of the electric current at the time of demagnetization. The figure which shows an example of the electric current value by the side of a charging stand, and the polarity of a magnetic field. The figure which shows an example of the electric current value by the side of a battery pack, and the polarity of a magnetic field. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a flowchart which shows an example of the process sequence of a charging abnormality detection process. It is a chart which shows an example of the operation timing of non-contact charge. It is a figure which shows an example of the circuit structure of the charging system which concerns on 4th Embodiment. It is a figure which shows an example of the flow of the electric current at the time of demagnetization. The figure which shows an example of the electric current value by the side of a battery pack, and the polarity of a magnetic field. The figure which shows an example of the electric current value by the side of a charging stand, and the polarity of a magnetic field. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a chart which shows an example of the operation timing of non-contact charge. It is a figure which shows an example of the circuit structure of the charging system which concerns on 5th Embodiment. It is a figure which shows an example of the flow of the electric current at the time of demagnetization. The figure which shows an example of the electric current value by the side of a battery pack, and the polarity of a magnetic field. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a chart which shows an example of the operation timing of non-contact charge. It is a figure which shows an example of the circuit structure of the charging system which concerns on 6th Embodiment. It is a figure which shows an example of the charging system which concerns on other embodiment. It is a figure which shows an example of the charging system which concerns on other embodiment. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a chart which shows an example of the operation timing of non-contact charge. It is a flowchart which shows an example of the process sequence of the electric power feeding method. It is a chart which shows an example of the operation timing of non-contact charge. It is a flowchart which shows an example of the process sequence of the electric power feeding method.

  [First Embodiment]

  A first embodiment of the present invention will be described with reference to FIG. FIG. 1 shows an example of a charging system according to the first embodiment. Note that the arrows in FIG. 1 indicate the direction of the magnetic field or current.

  A charging system 2-1 illustrated in FIG. 1 is an example of a power feeding system and a power feeding method according to the present disclosure, and includes a charging base 4-1 and an electronic device 6-1. The charging stand 4-1 and the electronic device 6-1 have a non-contact charging function, generate the magnetic field M1, and charge the storage battery 8 of the electronic device 6-1 in a non-contact manner. Charging of the storage battery 8 is an example of power feeding of the electronic device 6-1. The magnetic field M1 is an example of a charging magnetic field or a feeding magnetic field, and the magnitude thereof varies with time. In addition, the charging system 2-1 generates a magnetic field M2 with the charging base 4-1, and demagnetizes the magnetization of the magnetic material 30 generated by charging. The magnetic field M2 is an example of a demagnetizing magnetic field that demagnetizes the magnetization, and is a magnetic field having a polarity opposite to that of the magnetic field M1. The magnetic field M2 may be a static magnetic field or an alternating magnetic field. Non-contact charging is an example of wireless charging, and is performed by electrically connecting the charging base 4-1 and the electronic device 6-1 without contact of contacts. The electrical connection includes a connection that generates an induced electromotive force between coils and transmits electric power. This contactless charging is an example of contactless power feeding. Non-contact charging is performed, for example, by electromagnetic induction with a magnetic field M1 interposed.

The charging stand 4-1 is an example of a primary-side power feeding device or charging device for non-contact power feeding, and is an electronic device that functions as a power feeding unit of the charging system 2-1. The charging stand 4-1 passes an exciting current I ₁ through the coil 12 and generates a magnetic field M1. The charging stand 4-1 generates a magnetic field M < _b > ₂ by passing an exciting current I < _b > ₂ through the coil 12. The charging stand 4-1 includes a coil 12, a current supply unit 14, a switching unit 16, and a control unit 18.

  The coil 12 is an example of a unit that generates the magnetic fields M1 and M2. The coil 12 receives a current from the current supply unit 14 and generates the magnetic field M1 or the magnetic field M2.

The current supply unit 14 is an example of means for supplying excitation currents I ₁ and I ₂ to the coil 12. For example, the current supply unit 14 generates an alternating current and supplies it to the coil 12. This alternating current is, for example, a current that flows in one direction, and its flow rate varies periodically.

The switching unit 16 includes, for example, a switch, and switches the connection of the coil 12 so that the connection between the coil 12 and the current supply unit 14 is reversed. The switching unit 16 connects the current supply unit 14 to the coil 12 so that the exciting current I ₁ flows through the coil 12 while charging the storage battery 8. After charging, the switching unit 16 switches the connection and connects the current supply unit 14 to the coil 12 so that the exciting current I ₂ flows through the coil 12. This exciting current I ₂ is a current in the direction opposite to the direction of the exciting current I ₁ . This exciting current I ₂ has a maximum current value equivalent to the maximum current value of the exciting current I ₁ , for example.

  The control unit 18 is an example of a control unit of the charging stand 4-1. The control unit 18 transmits a drive signal for driving or stopping the current supply unit 14 to the current supply unit 14. Thereby, supply and stop of the current from the current supply unit 14 are controlled. The control unit 18 transmits a switching signal indicating connection switching to the switching unit 16. Thereby, the connection of the switching unit 16 is switched, and the direction of the current flowing through the coil 12 is reversed. When the control unit 18 controls the current supply unit 14 and the switching unit 16, a magnetic field M2 is generated in the coil 12, and the magnetization of the magnetic material 30 generated by charging is demagnetized. The drive signal and the switching signal only need to include at least two types of distinguishable signals. For example, a high voltage such as 5 [V] voltage and a low voltage such as 0 [V] can be used. For the control unit 18, for example, a processor such as a central processing unit (CPU) or a micro processing unit (MPU) is used.

Electronic device 6-1, for example mobile phone, PDA (personal digital assistant), a smart phone, a portable electronic device such as a tablet terminal device, a magnetic field M1 receives by the coil 22 generates a charge current I _3. The charging current I ₃ is an example of a feeding current. The electronic device 6-1 charges the storage battery 8 with the charging current I ₃ . The electronic device 6-1 includes a power storage 8, a coil 22, a switching unit 26, a control unit 28, a magnetic material 30, and an electronic component 32.

  The storage battery 8 is an example of means for storing electricity and supplying electricity to the electronic component 32 of the electronic device 6-1. The storage battery 8 only needs to have a function of storing and supplying electricity. For example, a lithium ion battery, a nickel hydrogen battery, a nickel cadmium battery, or the like is used.

The coil 22 is an example of a means for generating a current, receives the magnetic field M1, and generates a charging current I ₃ by electromagnetic induction.

  The switching unit 26 includes, for example, a switch, and switches the connection of the coil 22. The switching unit 26 connects the coil 22 to the storage battery 8 or disconnects the coil 22 from the storage battery 8.

  The control unit 28 is an example of a unit that controls charging of the storage battery 8. The control unit 28 transmits a switching signal indicating switching of the connection of the coil 22 to the switching unit 26 and controls the switching of the switching unit 26. For the control unit 28, for example, a processor such as a CPU or MPU is used.

  The coil 22, the switching unit 26, the control unit 28, and the storage battery 8 form a charging device 34-1. The charging device 34-1 is an example of a secondary-side power feeding device or charging device for non-contact power feeding, and is an electronic device that functions as a power receiving unit of the charging system 2-1. Charging device 34-1 charges power storage location 8.

  The magnetic material 30 includes, for example, a shield metal plate that suppresses radiation noise, a magnetic sheet that easily induces an induced magnetic field, and the like, and is used for countermeasures against radiation noise of the electronic device 6-1 or induced magnetic fields.

  The electronic component 32 is an example of a component that forms the electronic device 6-1. The electronic component 32 includes a magnet mounting component including a magnet, a magnetic force detection integrated circuit such as a geomagnetic sensor and a magnetic sensor, and a magnetic component including a magnetic material. Magnet-mounted components, magnetic force detection integrated circuits, and magnetic body components are affected by magnetism, and the performance and function of these components change. That is, the magnet-mounted component, the magnetic force detection integrated circuit, and the magnetic material component react sensitively to magnetism.

  Next, FIG. 2 and FIG. 3 will be referred to for charging the storage battery 8 and demagnetizing the magnetization of the magnetic material 30. FIG. 2 shows a charging system during charging that charges the storage battery, and FIG. 3 shows a charging system during demagnetization in which the magnetization is demagnetized.

  (Charging system during charging)

The switching unit 16 connects the coil 12 and the current supply unit 14 so that the exciting current I ₁ flows based on the switching signal of the control unit 18. The current supply unit 14 supplies the exciting current I ₁ to the coil 12 based on the drive signal from the control unit 18. The switching unit 26 connects the coil 22 to the storage battery 8 based on a switching signal from the control unit 28. When the exciting current I ₁ flows through the coil 12, a magnetic field M1 is generated between the coil 12 and the coil 22 by electromagnetic induction. This magnetic field M1 is also generated inside the electronic device 6-1, and a charging current I ₃ flows through the coil 22. The charging current I ₃ is supplied to the storage battery 8 connected to the coil 22. As a result, the storage battery 8 is charged. The storage battery 8 is charged by the exciting current I ₁ flowing through the coil 12. That is, the excitation current I ₁ is an example of a charging current. Due to the generation of the magnetic field M1, the magnetic material 30 in the electronic device 6-1 is magnetized.

  (Charging system during demagnetization)

When charging is completed, the switching unit 16 connects the coil 12 and the current supply unit 14 based on the switching signal of the control unit 18 so that the exciting current I ₂ flows through the coil 12. The switching unit 26 disconnects the coil 22 from the storage battery 8 based on the switching signal from the control unit 28. When the exciting current I ₂ flows through the coil 12, a magnetic field M2 is generated between the coil 12 and the coil 22 by electromagnetic induction. The magnetization of the magnetic material 30 is demagnetized by the magnetic field M2. The exciting current I ₂ is an example of a demagnetizing current that generates the magnetic field M2.

  Next, FIG. 4 is referred with respect to the power feeding method of the storage battery 8 of the electronic device 6-1 or the charging device 34-1. FIG. 4 shows an example of the processing procedure of the power feeding method.

  When the charging process is started in the non-charging state, non-contact charging is detected (step S1). In the control part 18, non-contact charge is detected by the automatic detection of arrangement | positioning of the electronic device 6-1, or the detection of the manual operation of the charging stand 4-1. For automatic detection of the arrangement of the electronic device 6-1, for example, a change in the inductance of the coil 12 caused by the electronic device 6-1 being superimposed on the charging base 4-1 is used. For detection of manual operation of the charging stand 4-1, for example, operation of an operation switch formed on the charging stand 4-1.

When the control unit 18 drives the current supply unit 14 and switches the switching unit 16, the excitation current I ₁ flows through the coil 12 and a magnetic field M 1 is generated. The control unit 28 detects the magnetic field M1 and detects non-contact charging.

  When non-contact charging is detected (Yes in step S1), the magnetic field M1 is generated, and when the control unit 28 switches the switching unit 26, the coil 22 is connected to the storage battery 8 and non-contact charging is started (step S2). . When the electronic device 6-1 is separated from the charging base 4-1, and non-contact charging is not detected (No in Step S1), the control unit 18 repeats detection of non-contact charging.

  During charging, the control units 18 and 28 determine whether or not the charging is finished (step S3). If the charging is not finished (No in step S3), the control units 18 and 28 continue the charging. When the charging is finished (Yes in step S3), the control units 18 and 28 finish the non-contact charging (step S4). When the non-contact charging ends, the control unit 18 stops the generation of the magnetic field M1, and the control unit 28 disconnects the coil 22 from the storage battery 8 by the switching unit 26.

After the end of non-contact charging, the control unit 18 switches the switching unit 16. By this switching, the exciting current I ₂ is supplied to the coil 12 (step S5). Magnetic field M2 is generated by the supply of the exciting current I _2, the magnetization of the magnetic material 30 is demagnetized. When the demagnetization is finished, the control unit 18 finishes the process.

  According to 1st Embodiment, when the charging stand 4-1 produces | generates the magnetic field M2, the magnetization of the magnetic material 30 produced by non-contact charge can be demagnetized. That is, the magnetic field inside the electronic device 6-1 can be returned to the state before the non-contact charging. Deterioration of the performance or function of the above-described magnet-mounted component, magnetic force detection integrated circuit, and magnetic component existing inside the electronic device 6-1 is prevented. As a result, the operation of the electronic component 32 sensitive to magnetism can be stabilized. Further, it is possible to prevent the performance of the magnetic material 30 such as a magnetic sheet from being deteriorated by the magnetization.

  By providing the switching unit 16 between the coil 12 of the charging base 4-1 and the current supply unit 14, the charging base 4-1 enables demagnetization inside the electronic device 6-1.

  [Second Embodiment]

  A second embodiment will be described with reference to FIG. FIG. 5 shows an example of a charging system according to the second embodiment. Note that the configuration illustrated in FIG. 5 is an example, and the configuration of the present disclosure is not limited to such a configuration. The same parts as those in FIGS. 1 to 3 are denoted by the same reference numerals. The arrows in FIG. 5 indicate the direction of the magnetic field or current.

  A charging system 2-2 illustrated in FIG. 5 is an example of a power feeding system and a power feeding method according to the present disclosure, and includes a charging base 4-2 and an electronic device 6-2. The charging stand 4-2 and the electronic device 6-2 have the non-contact charging function described above, generate the magnetic field M1 described above, and charge the storage battery 8 of the electronic device 6-2. Charging of the storage battery 8 is an example of power feeding of the electronic device 6-2. In addition, the charging system 2-2 generates the magnetic field M2 described above with the electronic device 6-2, and demagnetizes the magnetization of the magnetic material 30 generated by the charging.

The charging stand 4-2 is an example of a primary-side power feeding device or charging device for non-contact power feeding, and is an electronic device that functions as a power feeding unit of the charging system 2-2. The charging stand 4-2 passes an exciting current I ₁ through the coil 12 and generates a magnetic field M1. The charging stand 4-2 includes a coil 12, a current supply unit 14, and a control unit 18.

The coil 12 is an example of a unit that generates the magnetic field M1, and receives the excitation current I ₁ from the current supply unit 14 to generate the magnetic field M1.

The current supply unit 14 is an example of a unit that supplies the exciting current I ₁ to the coil 12. For example, the current supply unit 14 generates an alternating current and supplies the generated alternating current to the coil 12. This alternating current is, for example, a current that flows in one direction, and its flow rate varies periodically. The current supply unit 14 is connected to the coil 12.

  The control unit 18 is an example of a unit that controls the charging stand 4-2. The control unit 18 transmits the drive signal described above to the current supply unit 14. Thereby, supply and stop of the current from the current supply unit 14 to the coil 12 are controlled. For the control unit 18, for example, a processor such as a CPU or MPU is used.

The electronic device 6-2 is the same as the electronic device 6-1 of the first embodiment, except that the charging device 34-2 is included instead of the above-described charging device 34-1. Electronic devices 6-2, a magnetic field M1 receives by the coil 22 generates a charge current I _3. In addition, the electronic device 6-2 generates the magnetic field M2 by causing the exciting current I ₄ to flow through the coil 22.

  The coil 22, the current supply unit 24, the switching unit 26, the control unit 28, and the storage battery 8 form a charging device 34-2. The charging device 34-2 is an example of a secondary-side power feeding device or charging device for non-contact power feeding, and is an electronic device that functions as a power receiving unit of the charging system 2-2. The charging device 34-2 charges the storage battery 8.

The coil 22 is an example of a means for generating a current or a means for generating a magnetic field. The coil 22 receives the magnetic field M1 and generates a charging current I ₃ by electromagnetic induction. The coil 22 receives the exciting current I ₄ from the current supply unit 24 and generates a magnetic field M2.

The current supply unit 24 is an example of a unit that supplies the exciting current I ₄ to the coil 22. The current supply unit 24 generates, for example, an alternating current and supplies it to the coil 22. This alternating current is, for example, a current that flows in one direction, and the flow rate of which varies periodically. This exciting current I ₄ is a current in the direction opposite to the direction of the charging current I ₃ . This exciting current I ₄ has a maximum current value equivalent to the maximum current value of the exciting current I ₁ , for example.

  The switching unit 26 includes, for example, a switch, and switches the connection of the coil 22. The switching unit 26 connects the battery 8 to the coil 22 while charging the storage battery 8. When charging is completed, the switching unit 26 switches the connection and connects the current supply unit 24 to the coil 22.

  The control unit 28 is an example of a control unit of the charging device 34-2. The control unit 28 transmits a drive signal for driving or stopping the current supply unit 24 to the current supply unit 24. Thereby, supply and stop of the current from the current supply unit 24 are controlled. The control unit 28 transmits a switching signal indicating connection switching to the switching unit 26. Based on this switching signal, the switching unit 26 switches the connection of the coil 22. When the control unit 28 controls the current supply unit 24 and the switching unit 26, a magnetic field M2 is generated in the coil 22, and the magnetization of the magnetic material 30 generated by charging is demagnetized. For the control unit 28, for example, a processor such as a CPU or MPU is used.

  Since other configurations are the same as those of the first embodiment, the description thereof is omitted.

  Next, FIG. 6 and FIG. 7 will be referred to for charging the storage battery 8 and demagnetizing the magnetization. FIG. 6 shows a charging system during charging that charges the storage battery, and FIG. 7 shows a charging system during demagnetization that demagnetizes the magnetization.

  (Charging system during charging)

The current supply unit 14 supplies the exciting current I ₁ to the coil 12 based on the drive signal from the control unit 18. The switching unit 26 connects the coil 22 to the storage battery 8 based on a switching signal from the control unit 28. When the exciting current I ₁ flows through the coil 12, a magnetic field M1 is generated, and the charging current I ₃ flows through the coil 22. The charging current I ₃ is supplied to the storage battery 8 connected to the coil 22. As a result, the storage battery 8 is charged.

  (Charging system during demagnetization)

When charging is completed, the current supply unit 14 stops based on the drive signal of the control unit 18 and stops supplying the excitation current I ₁ . The switching unit 26 connects the coil 22 to the current supply unit 24 based on a switching signal from the control unit 28. The current supply unit 24 supplies the exciting current I ₄ to the coil 22 based on the drive signal from the control unit 28. When the exciting current I ₄ flows through the coil 22, a magnetic field M2 is generated. The magnetization of the magnetic material 30 is demagnetized by the magnetic field M2. The exciting current I ₄ is an example of a demagnetizing current that generates the magnetic field M2.

  Next, FIG. 8 is referred with respect to the method of feeding the storage battery 8 of the electronic device 6-1 or the charging device 34-1. FIG. 8 shows an example of the processing procedure of the power feeding method.

When the charging process is started in the non-charged state, non-contact charge is detected (step S11). The control unit 18 detects non-contact charging by the above-described automatic detection or manual operation detection. When the control unit 18 drives the current supply unit 14, the exciting current I ₁ flows through the coil 12 and a magnetic field M 1 is generated. The control unit 28 detects the magnetic field M1 and detects non-contact charging.

  When non-contact charging is detected (Yes in step S11), the magnetic field M1 is generated, and when the control unit 28 switches the switching unit 26, the coil 22 is connected to the storage battery 8 and non-contact charging is started (step S12). . When the electronic device 6-2 is separated from the charging base 4-2 and non-contact charging is not detected (No in Step S11), the control unit 18 repeats the detection of the arrangement.

  During charging, the control units 18 and 28 determine whether the charging is finished (step S13). If the charging is not finished (No in step S13), the control units 18 and 28 continue the charging. When the charging is finished (Yes in step S13), the control units 18 and 28 finish the non-contact charging (step S14). When the non-contact charging is completed, the control unit 18 stops the generation of the magnetic field M1, and the control unit 28 disconnects the coil 22 from the storage battery 8 by the switching unit 26 and connects it to the current supply unit 24.

After the end of non-contact charging, the control unit 28 drives the current supply unit 24 and supplies the exciting current I ₄ to the coil 22 (step S15). The magnetic field M2 is generated by supplying the exciting current I ₄ , and the magnetization of the magnetic material 30 is demagnetized. When the demagnetization is finished, the process is terminated.

  According to the second embodiment, when the charging device 34-2 of the electronic device 6-2 generates the magnetic field M2, it is possible to demagnetize the magnetization of the magnetic material 30 generated by the non-contact charging. That is, the magnetic field inside the electronic device 6-2 can be returned to the state before the non-contact charging. Deterioration of the performance or function of the above-described magnet-mounted component, magnetic force detection integrated circuit, and magnetic component existing inside the electronic device 6-2 is prevented. As a result, the operation of the electronic component 32 sensitive to magnetism can be stabilized. Further, it is possible to prevent the performance of the magnetic material 30 such as a magnetic sheet from being deteriorated by the magnetization.

  The charging device 34-2 of the electronic device 6-2 can generate the magnetic field M2. That is, the electronic device 6-2 itself can degauss. For this reason, for example, when the electronic device 6-2 is separated from the charging base 4-2 in the middle of charging and the non-contact charging is terminated in the middle, for example, when the non-contact charging is interrupted, the electronic device 6-2 is charged. It is possible to demagnetize the magnetization of the magnetic material 30 after the end of the process.

  The magnetization of the magnetic material 30 generated in the electronic device 6-2 can be demagnetized by the electronic device 6-2 itself.

  [Third Embodiment]

  A third embodiment of the present invention will be described with reference to FIGS. 9, 10, 11 and 12. FIG. FIG. 9 shows an example of a charging system according to the third embodiment. FIG. 10 is a diagram illustrating an example of functions of the control unit. FIG. 11 is a diagram illustrating an example of a circuit configuration of the charging system. FIG. 12 is a diagram illustrating an example of a circuit configuration of the power supply circuit. Note that the configurations illustrated in FIGS. 9, 10, 11, and 12 are examples, and the configurations of the present disclosure are not limited to such configurations. The same parts as those in FIGS. 1 to 3 and FIGS. 5 to 7 are denoted by the same reference numerals. The arrows in FIG. 9 indicate the direction of the magnetic field. The arrows in FIG. 11 indicate the direction of current. In FIG. 11, a part of the configuration of the mobile terminal device 104-1 is omitted.

  A charging system 102-1 illustrated in FIG. 9 is an example of a power feeding system and a power feeding method according to the present disclosure, and includes a mobile terminal device 104-1 and a charging base 106-1.

  The portable terminal device 104-1 is an example of the electronic device 6-1. The portable terminal device 104-1 includes a speaker 112, a receiver 114, a magnetic actuator 116, a geomagnetic sensor 118, a vibrator 120, a magnetic sensor 122, a key switch 124, and a display device 126. The portable terminal device 104-1 includes a control unit 128, a memory unit 130, and a battery pack 132-1. The portable terminal device 104-1 includes a shield metal plate 134, and the shield metal plate 134 suppresses radiation noise. The portable terminal device 104-1 includes a sheet-like magnetic sheet 136, and makes it easy to induce an induced magnetic field by the magnetic sheet 136. The shield metal plate 134 and the magnetic sheet 136 are examples of the magnetic material 30.

  The speaker 112 is an example of an audio output device, receives an audio signal from the control unit 128, and outputs the audio to the outside.

  The receiver 114 is an example of an audio input device, converts external audio into an audio signal, and outputs the audio signal to the control unit 128.

  The magnetic actuator 116 is an example of an energy conversion device, and converts externally input energy into physical motion. This magnetic actuator 116 is used for an autofocus function of a camera module, for example.

  The geomagnetic sensor 118 is an example of a magnetic field detection device, and functions as a magnetic detection unit of the mobile terminal device 104-1. The geomagnetic sensor 118 is used to detect a magnetic field. This geomagnetic sensor 118 is used for an electronic compass, for example.

  Vibrator 120 is an example of a vibration device, and generates vibration by rotating a motor, for example. That is, the vibrator 120 uses the power of electromagnetic induction. This vibrator 120 is used, for example, for calling the owner of portable terminal device 104-1.

  The magnetic sensor 122 is an example of a magnetic force detection device that detects magnetic force. The magnetic sensor 122 is an AMR sensor including a magnetoresistive effect element such as AMR (Anisotropic Magneto Resistance). This magnetic sensor 122 is used as, for example, a non-contact switch using magnetism.

  The key switch 124 is an example of an input device. The key switch 124 forms a keyboard, for example. The key switch 124 generates an operation signal according to the operation, and outputs this operation signal to the control unit 128. The key switch 124 includes a conductive metal such as a dome-shaped sheet metal as a magnetic material.

  The display device 126 is an example of a means for displaying information, and includes, for example, a display device or a light emitting element such as an LED (light emitting diode).

  The speaker 112, the receiver 114, the magnetic actuator 116, the geomagnetic sensor 118, the vibrator 120, the magnetic sensor 122, the key switch 124, and the display device 126 are examples of the electronic component 32 including the magnetic material 30. The speaker 112, the receiver 114, the magnetic actuator 116, the geomagnetic sensor 118, the vibrator 120, and the magnetic sensor 122 are examples of the electronic component 32 that is sensitive to magnetism.

  The memory unit 130 is an example of a storage device, and includes, for example, a ROM (Read Only Memory) and a RAM (Random Access Memory). The ROM is a non-volatile memory, such as a flash memory or an EEPROM (Electrically Erasable and Programmable Read Only Memory). The ROM stores programs such as an OS (Operating System) and applications (application software), and is used for storing various data and setting values. The RAM is a memory that can be accessed at high speed, and is used for temporary storage of data and setting values, for example.

  The control unit 128 is an example of a unit that controls the mobile terminal device 104-1. The control unit 128 includes a CPU, for example, and executes an OS and an application stored in the memory unit 130. The control unit 128 functions the electronic component 32 mounted on the portable terminal device 104-1, so that the audio signal processing unit 142, the wireless communication unit 144, the display unit 146, the clock unit 148, the power supply unit 150, , An application processing unit 152, a storage unit 154, and a charging unit 156.

  The audio signal processing unit 142 processes the audio signal output from the speaker 112, receives the audio signal input to the receiver 114 from the receiver 114, and processes the received audio signal.

  The wireless communication unit 144 controls wireless communication performed by the mobile terminal device 104-1. This wireless communication is cellular communication, WLAN (Wireless Local Area Network) communication, Wi-Fi communication, Bluetooth (registered trademark) communication, or the like.

  The display unit 146 controls display such as character display, video display, lighting of light, or flashing of light, and causes the display device 126 to display these displays.

  The clock unit 148 measures time. For example, the operation clock of the control unit 128 is used for this time measurement.

  The power supply unit 150 controls power reception from the battery pack 132-1. The power supply unit 150 monitors the power state of the battery pack 132-1. This power state includes, for example, information on the remaining power of battery pack 132-1. The power supply unit 150 controls the power consumption of the mobile terminal device 104-1 according to the power state.

  The application processing unit 152 executes application software stored in the memory unit 130.

  The storage unit 154 controls writing of information into the memory unit 130 and reading of information from the memory unit 130.

  The charging unit 156 communicates with the MPU 188 (FIG. 11) of the battery pack 132-1 when charging the battery pack 132-1, and provides the MPU 188 with information used for charging. This information includes, for example, magnetization information of the geomagnetic sensor 118. This magnetization information is generated based on magnetism measurement data measured by the geomagnetic sensor 118 and represents the magnetization state of the magnetic material. The charging unit 156 receives information related to the charging abnormality of the battery pack 132-1 from the MPU 188, and is used for displaying the abnormality and reporting an alarm.

  When the battery pack 132-1 of the portable terminal device 104-1 is charged by the above-described non-contact charging, the electronic component 32 including the magnetic material 30 and the magnetic material 30 are magnetized by the above-described magnetic field M1. The magnetic component 32 sensitive to magnetism is affected by this magnetization. Therefore, the charging stand 106-1 generates the magnetic field M2 described above, and demagnetizes the magnetization of the magnetic material 30. This demagnetization of the magnetization stabilizes the operation of the electronic component.

  The charging stand 106-1 shown in FIG. 11 is an example of the charging stand 4-1. The charging stand 106-1 generates the magnetic fields M1 and M2 described above. The charging stand 106-1 includes a coil 12, a power supply circuit 174, a changeover switch 176, a charging control unit 178, and a capacitor 180. The coil 12, the power supply circuit 174, the changeover switch 176, and the capacitor 180 form a primary circuit for non-contact charging. Charging base 106-1 includes an operation unit 182, a display unit 184, and a storage unit 185.

  The coil 12 is an example of a unit that generates the magnetic fields M1 and M2, and receives a current from the power supply circuit 174 to generate the magnetic field M1 or the magnetic field M2.

  The power supply circuit 174 is an example of the current supply unit 14, generates an alternating current, and supplies the alternating current to the coil 12. For example, as shown in FIG. 12, the power supply circuit 174 includes a power source 242, a rectifier circuit 244, and an inverter circuit 246. For the power source 242, for example, a three-phase AC power source is used. The power source 242 is connected to the rectifier circuit 244.

  The rectifier circuit 244 includes six diodes 248-1, 248-2,... 248-6. The two diodes 248-1, 248-2, the two diodes 248-3, 248-4 and the two diodes 248-5, 248-6 are connected in series to form a set of diode strings. . Three sets of diode rows are connected in parallel to form a parallel circuit. Each phase of the power source 242 is connected between the diodes in each diode row. With such a configuration, the rectifier circuit 244 converts an alternating current into a direct current. Both ends of the parallel circuit are connected to the inverter circuit 246.

  The inverter circuit 246 includes four switches 250-1, 250-2, 250-3, and 250-4. Each switch 250-1, 250-2, 250-3, 250-4 includes, for example, a circuit configuration in which a feedback diode and a transistor are connected in parallel. The two switches 250-1, 250-2 and the two switches 250-3, 250-4 are respectively connected in series to form a set of switch rows. Two sets of switch trains are connected in parallel to form a parallel circuit. Both ends of the parallel circuit are connected to both ends of the rectifier circuit 244.

  An electrode line connecting the rectifier circuit 244 and the inverter circuit 246 is connected via a capacitor 252. By installing the capacitor 252, the current output from the inverter circuit 246 to the inverter circuit 246 can be rapidly changed. Power lines 254-1 and 254-2 are drawn from between the switches of each switch row. With such a configuration, an alternating current that generates electromagnetic induction in the coil 12 is generated.

  The changeover switch 176 is an example of the switching unit 16, receives a switching signal from the charging control unit 178, switches the connection of the coil 12, and reverses the direction of the current flowing through the coil 12. The coil 12 is connected to one of the changeover switches 176, and connection ends 1a, 1b, 2a, and 2b are formed on the other. The power line 254-1 of the power supply circuit 174 is connected to the connection ends 1a and 2b, and the power line 254-2 is connected to the connection ends 1b and 2a. The changeover switch 176 connects the connection ends 1a and 2a to the coil 12 as the first connection, or connects the connection ends 1b and 2b to the coil 12 as the second connection.

  Capacitor 180 is connected in series to coil 12. The capacitor 180 functions as a series resonant capacitor in charging with electromagnetic induction. The capacitor 180 forms a resonance circuit together with the capacitor 198 connected in parallel to the coil 22.

  The operation unit 182 is connected to the charge control unit 178 and is used to operate the charging stand 106-1. The operation unit 182 includes, for example, an operation switch. When the operation unit 182 is operated, the operation unit 182 outputs an operation signal corresponding to the operation to the charge control unit 178.

  The display unit 184 is an example of a unit that displays information, and includes, for example, a display device or a light emitting element such as an LED. Display unit 184 receives display information related to the display from charge control unit 178 and displays the information.

  The storage unit 185 includes the ROM and RAM described above, and is used for storing various data and setting values. Further, the storage unit 185 may store a control program for the charging control unit 178, and the charging control unit 178 may execute the control program to control the charging stand 106-1.

  The charging control unit 178 is an example of the control unit 18. The charge control unit 178 transmits the drive signal described above to the power supply circuit 174. The power supply circuit 174 is driven or stopped by this drive signal. The charging control unit 178 transmits the aforementioned switching signal to the changeover switch 176. The charging control unit 178 controls the display unit 18 and the storage unit 185 in addition to the control of the power supply circuit 174 and the changeover switch 176. The charge control unit 178 may include other functions, for example, a clock function, and may measure time.

  Battery pack 132-1 is an example of charging device 34-1, and forms, for example, a charging receiver module. The battery pack 132-1 includes a coil 22, a switch 186, an MPU 188, a battery cell 190, a protection circuit 192, a current detection unit 194, a temperature detection unit 196, and a capacitor 198.

The coil 22 is an example of a means for generating a current, receives the magnetic field M1, and generates a charging current I ₃ by electromagnetic induction.

  Capacitor 198 functions as a parallel resonant capacitor in charging via electromagnetic induction.

  The switch 186 is an example of the switching unit 26 and includes a transistor such as an FET (field effect transistor). The switch 186 is installed on the positive electrode side of the battery cell 190, for example.

  The MPU 188 is an example of the control unit 28, forms a control unit of the battery pack 132-1, and controls the charging of the battery cell 190. The MPU 188 transmits the above-described switching signal to the switch 186, and controls switching of the switch 186. The MPU 188 uses the detection information of the temperature detection unit 196 and the current detection unit 194 and the above-described magnetization information received from the control unit 128 for controlling the charging of the battery cell 190.

  The battery cell 190 is an example of the storage battery 8, and forms the power source of the portable terminal device 104-1.

  The protection circuit 192 is an example of means for preventing overcurrent, and is installed between the battery cell 190 and the current detection unit 194. The protection circuit 192 is installed on the negative electrode side of the battery cell 190, for example. The protection circuit 192 has a function of suppressing the flow rate of current when an overcurrent occurs, and includes, for example, a PTC (Positive Temperature Coefficient) thermistor. The PTC thermistor has a characteristic that when the temperature rises due to overcurrent, the resistance value increases rapidly. The increase in the resistance value suppresses the current flow rate. Further, since the change in resistance value is reversible, when the overcurrent is eliminated, the temperature of the PTC thermistor is lowered and the current flow rate suppression is released.

  The current detection unit 194 is an example of a means for detecting current, and is installed between the protection circuit 192 and the coil 22. Current detection unit 194 includes a current detection resistor, for example.

  The temperature detection unit 196 is an example of a means for detecting temperature, and is installed in the vicinity of the battery cell 190 and detects the temperature of the battery cell 190. The temperature detection unit 196 includes, for example, a thermistor.

The coil 22, the switch 186, the battery cell 190, the protection circuit 192, and the current detection unit 194 are connected in a ring shape by connection lines 202, 204, 206, 208, 210, 212, and 214 to form a charging current flow path. Yes. The capacitor 198 is connected to the coil 22 in parallel. The switch 186, the protection circuit 192, the current detection unit 194, and the capacitor 198 are disposed between the coil 22 and the battery cell 190, and form a non-contact charging power reception circuit 216 together with the MPU 188. The power receiving circuit 216 receives the charge current I _3, and supplies a charge current I ₃ to the battery cell 190.

  An MCU (micro controller unit) control line C4 of the MPU 188 is connected to a connection line 202 between the coil 22 and the switch 186. The MCU control line C4 detects a voltage change of the coil 22 due to the magnetic field M1.

  The MCU control line C3 of the MPU 188 is connected to the switch 186. This MCU control line C3 is used to control the switch 186.

  The first detection line (Sense 1) of the MPU 188 is connected to one end of the current detection unit 194 and the negative electrode 224, and the second detection line (Sense 2) is connected to the other end of the current detection unit 194. Connected to. Therefore, a voltage Cv between the terminals of the current detection unit 194 is generated between the first detection line (Sense 1) and the second detection line (Sense 2). The voltage Cv can be converted into a current value Bc flowing through the current detection unit 194. That is, the voltage Cv includes information on the current value Bc flowing through the current detection unit 194 in addition to the voltage information applied to the current detection unit 194. The MPU 188 receives the voltage Cv including such information from the current detection unit 194 via the first detection line (Sense 1) and the second detection line (Sense 2). The MPU 188 acquires a current value Bc based on the voltage Cv. Since the battery cell 190 and the current detection unit 194 are connected in series, the MPU 188 can obtain the current value Bc flowing through the battery cell 190 from the voltage Cv between the terminals. That is, the voltage Cv is charging state information and represents the charging state of the battery cell 190. The current value Bc is used for charging control of the battery cell 190 and charging abnormality processing.

  The control of charging the battery cell 190 includes, for example, constant current charge control and constant voltage charge control. In the constant current charge control, the battery cell 190 is charged with a constant current value. In the constant voltage charge control, the battery cell 190 is charged by applying a constant voltage. Charging of the battery cell 190 is started by constant current charge control, and then switched to constant voltage charge control. The charging time can be shortened by switching the charging control. The switching of the charging control is performed by the MPU 188 based on the voltage Cv between the terminals of the current detection unit 194.

  The temperature detection line (Temp) and the first detection line (Sense 1) of the MPU 188 are connected to different ends of the temperature detection unit 196. The voltage Vt of the temperature detection unit 196 is input between the temperature detection line (Temp) and the first detection line (Sense 1). This voltage Vt includes temperature information indicating the temperature Bt of the battery cell 190. The voltage Vt of the temperature detection unit 196 is used for determining the temperature abnormality of the battery cell 190.

  The battery pack 132-1 includes a plus electrode 222, a minus electrode 224, a temperature terminal 226, and an MPU control line 228. The plus electrode 222 and the minus electrode 224 form a power terminal for supplying power to the mobile terminal device 104-1. The temperature terminal 226 and the MPU control line 228 connect the control unit 128 and the MPU 188 to form a communication terminal for communication between the control unit 128 and the MPU 188.

  The positive electrode 222 is connected to the positive electrode of the battery cell 190, and the negative electrode 224 is connected to the negative electrode of the battery cell 190 via the protection circuit 192. That is, the protection circuit 192 is also used to supply power to the mobile terminal device 104-1. The negative electrode 224 is grounded, for example.

  The temperature terminal 226 is connected to the temperature detection unit 196 and the temperature detection line (Temp), and supplies temperature information of the battery cell 190 to the control unit 128. This temperature information is used by the control unit 128 to determine the temperature abnormality of the battery pack 132-1.

  The MPU control line 228 is connected to the MCU control line C1 of the MPU 188 and is used for communication between the control unit 128 and the MPU 188. This communication includes notification of the charging state from the MPU 188 to the control unit 128, notification of time information from the control unit 128 to the MPU 188, and notification of magnetization information of the geomagnetic sensor 118 from the control unit 128 to the MPU 188, and the like.

In the charging system 102-1 shown in FIG. 11, the charging stand 106-1 supplies AC exciting currents I ₁ and I ₂ to the coil 12. For this reason, the magnetic fields M1 and M2 generated between the coils 12 and 22 are both magnetic fields including an alternating magnetic field. That is, an alternating magnetic field is used for charging and demagnetization.

  (Relation between current and magnetic field during charging)

Next, FIG. 13, FIG. 14 and FIG. 15 are referred to regarding the relationship between the current during charging and the magnetic field. FIG. 13 shows an example of current flow during charging. FIG. 14 shows an example of the current flowing through the coil 12 during charging and an example of the magnetic field on the coil 12 side during charging. FIG. 15 shows an example of a current flowing through the coil 22 during charging and an example of a magnetic field on the coil 22 side during charging. In FIG. 13, only the electromagnetic coupling portion between charging base 106-1 and battery pack 132-1 is shown. 14A and 15A, the horizontal axis indicates time t, and the vertical axis indicates current value. The current shown in A of FIG. 14 represents the direction in which the excitation current I ₁ flows as a positive value. The current shown in A of FIG. 15 represents the direction in which the charging current I ₃ flows as a positive value. 14B and FIG. 15B, the horizontal axis represents time t, and the vertical axis represents the magnetic field polarity. The arrows in FIG. 13 indicate the direction of current.

In the charging stand 106-1 shown in FIG. 13, an excitation current I ₁ flows in the direction indicated by the arrow on the charging stand 106-1 side during charging. In this case, the charging current I ₃ flows through the battery pack 132-1 in the direction indicated by the arrow on the battery pack 132-1 side. As shown in FIG. 14A, the excitation current I ₁ varies in current value with respect to time. While the current flows, the current value shows a positive value. That is, the exciting current I ₁ flows in one direction while changing the current value. Due to the fluctuation of the excitation current I ₁ , a negative polarity magnetic field is generated on the coil 12 side as shown in FIG.

As shown in FIG. 15A, the charging current I ₃ varies in current value with respect to time. While the current flows, the current value shows a positive value. That is, the charging current I ₃ flows in one direction while changing the current value. For this reason, when the battery cell 190 is charged, a loss due to reversal of the direction of current does not occur. As the magnetic field action on the coil 12 side and the charging current I ₃ flow through the coil 22, a positive polarity magnetic field is generated on the coil 22 side as shown in FIG. The magnetic field M1 described above is formed by the magnetic field on the coil 12 side and the magnetic field on the coil 22 side.

  (Relationship between current and magnetic field during demagnetization)

Next, FIG. 16, FIG. 17 and FIG. 18 are referred to regarding the relationship between the current and magnetic field during demagnetization. FIG. 16 shows an example of current flow during demagnetization. FIG. 17 shows an example of a current flowing through the coil 12 during demagnetization and an example of a magnetic field on the coil 12 side during demagnetization. FIG. 18 shows an example of the current flowing through the coil 22 during demagnetization and an example of the magnetic field on the coil 22 side during demagnetization. In FIG. 16, only the electromagnetic coupling portion between charging base 106-1 and battery pack 132-1 is shown. 17A and 18A, the horizontal axis represents time t, and the vertical axis represents current values. The current shown in A of FIG. 17 represents the direction in which the exciting current I ₂ flows as a positive value. The current shown in A of FIG. 18 represents the flowing direction of the current I ₅ as a positive value. In the magnetic fields shown in B of FIG. 17 and B of FIG. 18, the horizontal axis represents time t, and the vertical axis represents the magnetic field polarity. The arrows in FIG. 16 indicate the direction of current.

In the charging stand 106-1 shown in FIG. 16, during demagnetization, as shown in FIG. 16, an excitation current I ₂ that is opposite to the excitation current I ₁ (FIG. 13) flows. The battery pack 132-1 has a current I ₅ that is opposite to the charging current I ₃ (FIG. 13). As shown in FIG. 17A, the excitation current I ₂ has a positive current value and flows in one direction while changing the current value. The coil 12 side by the variation of the exciting current I ₂ as shown in B of FIG. 17, the magnetic field of the positive polarity is generated.

As shown in FIG. 18A, the current I ₅ has a positive current value and flows in one direction while changing the current value. As a result of the magnetic field action on the coil 12 side and the current I ₅ flowing through the coil 22, a negative polarity magnetic field is generated on the coil 22 side as shown in FIG. The magnetic field M2 described above is formed by the magnetic field on the coil 12 side and the magnetic field on the coil 22 side.

  By reversing the direction of the current, the charging stand 106-1 can reverse the polarity of the magnetic field during charging and demagnetization.

  Next, FIG. 19 is referred with respect to the power feeding method. FIG. 19 shows an example of the processing procedure of the power feeding method.

  This power feeding method includes a charging step 262 for charging the battery cell 190 and a demagnetizing step 264-1 for demagnetizing the magnetization of the magnetic material 30 generated by the charging.

  (Charging step 262)

The charging process 262 includes processing from detection processing of the charging stand 106-1 (step S101) to switching processing of the switch 186 to the off state (step S109). In the non-charging state, the charging control unit 178 detects non-contact charging by automatic detection of the arrangement of the mobile terminal device 104-1 or by detection of manual operation of the charging stand 106-1. For example, the method described in the first embodiment is used for automatic detection and manual operation detection. The charge control unit 178 drives the power supply circuit 174, switching the changeover switch 176, the exciting current I ₁ flows through the coil 12, the magnetic field M1 is generated. The MPU 188 detects the voltage change of the coil 22 by the MCU control line C4, and the magnetic field M1 is detected. The MPU 188 determines whether the charging stand 106-1 is detected (step S101).

  When charging stand 106-1 is not detected (No in step S101), detection of charging stand 106-1 is repeated. When the charging stand 106-1 is detected (Yes in step S101), the charging state is notified to the control unit 128 of the mobile terminal device 104-1 (step S102). The MPU 188 notifies the control unit 128 of the state of charge through the MCU control line C1. By the notification of this state, the start of charging is notified to the control unit 128. The control unit 128 receives the notification of the charging state and performs a charging state display process. This charging state display processing includes, for example, lighting processing of the display device 126 such as an LED.

The MPU 188 switches on the switch 186 by the MCU control line C3, connects the coil 22 and the battery cell 190 (step S103), and starts non-contact charging (step S104). At the time of charging, the MPU 188 determines whether the charging abnormality detection process (step S105) and the charging end condition are satisfied (step S106). Whether or not the charging end condition is satisfied may be determined, for example, based on whether or not the flow rate of the charging current I ₃ flowing through the switch 186 is a current value for ending charging, that is, a termination current value. Whether or not the flow rate of the charging current I ₃ is a current value for terminating the charging may be determined by, for example, a change in the voltage of the MCU control line C3 used for controlling the switch 186. Whether or not the charging end condition is satisfied may be determined based on whether or not the charging time Tc has passed a preset charging stop time. The charging time Tc is time information from the start of charging, and is measured using time information transmitted from the control unit 128 via the MPU control line 228, for example. The charging time Tc may be measured by the MPU 188 counting time. If the charge termination condition is not satisfied (No in Step S106), the non-contact charge (Step S104) continues, and the charging abnormality detection process (Step S105) is repeated at the set interval to determine whether or not it is in an abnormal state. Monitor.

  When the charging end condition is satisfied (Yes in step S106), the MPU 188 notifies the control unit 128 of the mobile terminal device 104-1 of the charging state via the MCU control line C1 (step S107). The notification of this state notifies the control unit 128 of the end of charging. The control unit 128 stops the charging state display process, and the display device 126 is turned off. The MPU 188 ends the non-contact charging (step S108), turns off the switch 186 by the MCU control line C3, and disconnects the coil 22 and the battery cell 190 (step S109).

  (Demagnetization process 264-1)

  The degaussing process 264-1 is performed following the charging process 262 after the non-contact charging is completed. The demagnetization process 264-1 includes processes from the switching process of the changeover switch 176 (step S110) to the switching process of the changeover switch 176 (step S116).

The charging control unit 178 switches the setting of the changeover switch 176 from the first connection by the connection ends 1a and 2a to the second connection by the connection ends 1b and 2b (step S110), and drives the power supply circuit 174. The power supply circuit 174 starts to supply demagnetization power (step S111). In the coil 12, the exciting current I ₂ flows through the coil 12, the magnetic field M2 is generated, degaussing operation is initiated. Demagnetization of the magnetization of the magnetic material 30 caused by charging is started. After the start of demagnetization, the charge control unit 178 measures the demagnetization time Td. This demagnetization time Td represents the elapsed time from the start of demagnetization. The demagnetization time Td is measured using time information transmitted from the control unit 128, for example. The demagnetizing time Td is measured by, for example, the charging control unit 178 counting time. Further, the charging control unit 178 may receive time information from the control unit 128 or the MPU 188 via the electromagnetic coupling by the MPU control line 228 and the coils 12 and 22.

  The charging control unit 178 determines whether the degaussing time Td has timed out the set time Tout (step S112). This determination is made based on, for example, whether the degaussing time Td is the set time Tout. When the degaussing time Td is less than the set time Tout (No in step S112), the degaussing operation continues. When the degaussing time Td becomes equal to or longer than the set time Tout (Yes in step S112), the charging control unit 178 stops supplying the demagnetizing power (step S113) and ends the degaussing operation. The set time Tout may be a time set in advance in the storage unit 185. The set time Tout may be a time set by the charge control unit 178 based on the charge time from the start to the end of charging. When the set time Tout is set based on the charging time, the degaussing time can be set according to the charging time. That is, the demagnetization time can be set according to the amount of magnetization that varies in accordance with the charging time.

  After the degaussing operation ends, the charging control unit 178 measures the magnetic field in the mobile terminal device 104-1 (step S114). For example, the magnetic field change of the portable terminal device 104-1 is measured by the geomagnetic sensor 118. Based on the measurement data of the geomagnetic sensor 118, for example, difference information between the sensor value before charging and the sensor value after charging is obtained as the magnetization information described above. This magnetization information is transmitted from the geomagnetic sensor 118 to the control unit 128 and transmitted to the MPU 188 via the MPU control line 228. Further, this magnetization information is transmitted from the MPU 188 to the charge control unit 178 via, for example, electromagnetic coupling by the coils 12 and 22.

  The charge control unit 178 determines whether the measurement value of the geomagnetic sensor 118 is within the measurement range (step S115). This determination is made based on, for example, whether or not the value of the difference information included in the magnetization information is small enough to be within a range where the geomagnetic sensor 118 can measure. When the measured value of the geomagnetic sensor 118 is not within the measurement range (No in step S115), the charging control unit 178 returns to the start of supplying the demagnetizing power (step S111), and the degaussing operation is repeated. By repeating the demagnetization operation, it is possible to demagnetize more magnetization generated by charging. When the measurement value of the geomagnetic sensor 118 is within the measurement range (Yes in step S115), the charging control unit 178 switches the setting of the changeover switch 176 to the first connection by the connection ends 1a and 2a (step S116), The contact charging process is terminated.

  Next, FIG. 20 is referred with respect to a charging abnormality detection process (step S105). FIG. 20 is a flowchart illustrating an example of a processing procedure of charging abnormality detection processing. The processing procedure of the charging abnormality detection process is a subroutine of the charging abnormality detection process.

In the charging abnormality detection processing shown in FIG. 20, a high temperature abnormality and cold abnormality of the battery cell 190, overcurrent and overvoltage of the charging current I _3, and the charging time Tc abnormality is determined. The MPU 188 determines whether the temperature Bt of the battery cell 190 is abnormally high (step S121). The temperature Bt of the battery cell 190 that is input to the MPU 188 as temperature information is used to determine the high temperature abnormality. When the temperature Bt is higher than the high temperature set value Bh of the battery cell 190 and the MPU 188 determines that the temperature is abnormal (Yes in step S121), the MPU 188 proceeds to an abnormality notification process (step S126). If the temperature Bt is lower than the high temperature set value Bh and the MPU 188 determines that the temperature is not abnormally high (No in step S121), the MPU 188 determines whether the temperature Bt of the battery cell 190 is abnormal in low temperature (step S122). .

When it is determined that the temperature Bt of the battery cell 190 is lower than the low temperature set value Bl of the battery cell 190 and the MPU 188 is abnormal in low temperature (Yes in step S122), the MPU 188 proceeds to an abnormality notification process (step S126). When it is determined that the temperature Bt is higher than the low temperature set value Bl and the MPU 188 is not abnormal in low temperature (No in step S122), the MPU 188 determines whether the charging current I ₃ is an overcurrent (step S123).

  For the determination of the overcurrent, the current value Bc of the battery cell 190 is used. If the current value Bc is higher than the overcurrent set value Co of the battery cell 190 and the MPU 188 determines that the current is overcurrent (Yes in step S123), the MPU 188 proceeds to an abnormality notification process (step S126). When the current value Bc is lower than the overcurrent set value Co and the MPU 188 determines that it is not an overcurrent (No in step S123), the MPU 188 determines whether the charging voltage is an overvoltage (step S124).

  For the determination of the overvoltage, the voltage value Bv of the battery cell 190 is used. When the voltage value Bv is higher than the overvoltage set value Vo of the battery cell 190 and the MPU 188 determines that the voltage is overvoltage (Yes in step S124), the MPU 188 proceeds to an abnormality notification process (step S126). When it is determined that the voltage value Bv is lower than the overvoltage set value Vo and the MPU 188 is not an overvoltage (No in step S124), the MPU 188 determines whether it is in the charging time range (step S125). The voltage value Bv is obtained when the portable terminal device 104-1 detects a potential difference between the plus electrode 222 and the minus electrode 224. The MPU 188 receives this voltage value Bv from the mobile terminal device 104-1 side via the MPU control line 228. Alternatively, the MPU 188 may be connected to the plus electrode 222, and the voltage value Bv may be obtained from the potential difference with the first detection line (Sense 1).

  For example, the above-described charging time Tc is used to determine whether or not the charging time is in the range. When the charging time Tc is equal to or longer than the set charging time To, the MPU 188 determines that the charging time Tc is out of the charging time range and the charging time is abnormal (Yes in step S125). When the charging time Tc is out of the charging time range, the MPU 188 proceeds to an abnormality notification process (step S126). When the charging time Tc is less than the set charging time To and the MPU 188 determines that the charging time is not abnormal (No in step S125), the process returns to the charging end condition determination process (step S106). The determination of the charging time may be set when the determination of the charging end condition (step S106) is determined by, for example, the charging current value. When determining the charge termination condition (step S106) by the charge stop time, the non-contact charge is completed before the charge time becomes abnormal by setting a charge stop time smaller than the set charge time To. To do. When the determination is made based on the charging stop time, the abnormality determination of the charging time can be omitted.

  In the abnormality notification process (step S126), the MPU 188 notifies the control unit 128 of the charging abnormality, instructs the control unit 128 to perform the abnormality display process (step S127), and terminates the non-contact charging due to the abnormality. Further, in the mobile terminal device 104-1, the control unit 128 causes the display device 126 to display characters indicating charging abnormality and to light or blink the light, and the charging abnormality is displayed.

  This charging abnormality detection process is repeated at predetermined time intervals. This time interval may be set in advance in the MPU 188, for example, as an abnormality detection interval. This charging abnormality detection process is repeated for each of the high temperature set value Bh, the low temperature set value Bl, the overcurrent set value Co, the overvoltage set value Vo, and the set charge time To. The high temperature set value Bh, the low temperature set value B1, the overcurrent set value Co, the overvoltage set value Vo, and the set charge time To may be set in advance in the MPU 188, for example. In addition, a setting value for determining this abnormality may be stored in the memory unit 130 of the mobile terminal device 104-1, and read during the charging abnormality detection process.

  Next, FIG. 21 will be referred to regarding the operation timing of non-contact charging. FIG. 21 shows an example of the operation timing of contactless charging. In the operation timing shown in FIG. 21, time t1 represents the detection time of charging base 106-1, and time t2 represents the start time of non-contact charging. Time t3 represents the charging mode switching time, and time t4 represents the non-contact charging stop time. Times t5 and t9 represent the start time of the degaussing operation, and times t6 and t10 represent the stop time of the degaussing operation. Time t7 represents the measurement start time of the residual magnetic field, and t8 represents the measurement stop time of the residual magnetic field.

  FIG. 21A shows a change in the voltage of the plus electrode 222 with respect to a reference voltage such as 0 [V]. The battery cell 190 is charged by constant current charging control from time t2 when non-contact charging is started to time t3 when the charging mode is switched. In this constant current charge control, the voltage of the positive electrode 222 rises rapidly. From time t3 to time t4 when non-contact charging stops, the battery cell 190 is charged by the constant voltage charging control. In this constant voltage charge control, the voltage of the plus electrode 222 is maintained at a constant voltage. After time t4, the voltage of the positive electrode 222 becomes the specified voltage when the battery cell 190 is fully charged. Note that charging by constant voltage charging control is performed at a voltage slightly higher than the specified voltage.

  FIG. 21B shows a change in the voltage of the MCU control line C4. The voltage of the MCU control line C4 rises from the low voltage (L) to the high voltage (H) at time t1. The charging stand 106-1 is detected by this voltage change. The voltage of the MCU control line C4 decreases from a high voltage to a low voltage when non-contact charging stops at time t4.

  C in FIG. 21 shows a change in the voltage of the MCU control line C1. The voltage of the MCU control line C1 becomes a high voltage from the time t2 to the time t4, indicating that non-contact charging is being performed.

  FIG. 21D shows a change in the voltage of the MCU control line C3. The voltage of the MCU control line C3 rises from a low voltage to a high voltage at time t2. Due to this voltage change, the switch 186 is fully turned on, that is, fully opened, and the battery cell 190 is charged with a constant current. The voltage of the MCU control line C3 gradually decreases from a high voltage to a low voltage from time t3 to time t4. Due to this change in voltage, the amount of current flowing through the switch 186 is gradually reduced, and the voltage of the battery cell 190 is maintained at a constant voltage.

  E in FIG. 21 indicates a change in the voltage Cv between the terminals of the current detection unit 194. The voltage Cv between the terminals decreases at time t2 when the non-contact charging is started and becomes a low voltage. At time t3, the voltage Cv between the terminals starts to rise. The charging mode is switched to the constant voltage charging control triggered by the increase in the voltage Cv between the terminals. After switching to the constant voltage charging mode, the voltage Cv between the terminals continues to rise and becomes a constant high voltage after time t4 when the non-contact charging ends.

F in FIG. 21 indicates the flow rate of the charging current I ₃ flowing through the switch 186. The flow rate of the charging current I ₃ is expressed as a current value, for example. The flow rate of the charging current I ₃ corresponds to the change in the voltage of the MCU control line C3. Under the control of the MCU control line C3, the switch 186 is turned off until time t2. At this time, the flow rate of the charging current I ₃ is zero. When the voltage of the MCU control line C3 becomes a high voltage, the switch 186 is fully turned on (Full ON), that is, fully opened, and the flow rate of the charging current is maximized. When the voltage of the MCU control line C3 is gradually lowered, the switch 186 is half-on (Half ON), that is, half-opened, and the flow rate of the charging current I ₃ is gradually lowered. At time t4 when the flow rate of the charging current I ₃ reaches the above-described termination current value, the non-contact charging is stopped and the switch 186 is turned off.

  G in FIG. 21 indicates driving of the power supply circuit 174. The power supply circuit 174 is driven from time t2 to time t4 for charging. In order to switch the changeover switch 176, the power supply circuit 174 is stopped from time t4 to time t5 and then driven from time t5 to time t6 for demagnetization. In order to measure the magnetic field, the power supply circuit 174 stops from time t6 to time t9. When the demagnetization operation is repeated as a result of the magnetic field measurement, the power supply circuit 174 waits for a predetermined waiting time (time t9-time t8) after the measurement of the residual magnetic field is completed at time t8, and then from time t9. Drive for time t10. In FIG. 21G, the drive is represented as ON and the stop is represented as OFF.

  H in FIG. 21 indicates measurement by the geomagnetic sensor 118. After the demagnetization operation stops at time t6, the geomagnetic sensor 118 waits for a predetermined waiting time (time t7-time t6), then starts measuring the residual magnetic field at time t7 and ends the measurement at time 8. To do. In FIG. 21H, the measurement is represented as ON and the stop is represented as OFF.

  I in FIG. 21 indicates switching of the selector switch 176. The first connection is made from time t1 to time t5, including during charging, and switched to the second connection at time t5 when the degaussing operation is started. This second connection is maintained until time t10 when the degaussing operation is stopped, and is switched to the first connection at time t10.

  According to the third embodiment, in addition to the effects described in the first embodiment, the following effects can be obtained.

  Since demagnetization is determined again based on the measurement result of the geomagnetic sensor 118 after demagnetization, demagnetization can be performed reliably.

  [Fourth Embodiment]

  A fourth embodiment will be described with reference to FIG. FIG. 22 shows an example of a charging system according to the fourth embodiment. Note that the configuration illustrated in FIG. 22 is an example, and the configuration of the present disclosure is not limited to such a configuration. The same parts as those in FIGS. 1 to 3, 5 to 7, and 11 are denoted by the same reference numerals. The arrows in FIG. 22 indicate the direction of current.

  In the third embodiment, the charging stand 106-1 generates a magnetic field M2 that is opposite to the magnetic field M1, but in the fourth embodiment, the battery pack 132-2 is opposite to the magnetic field M1. A magnetic field M2 having a direction is generated, and the magnetization of the magnetic material 30 is demagnetized. Therefore, the charging system 102-2 according to the fourth embodiment includes a charging stand 106-2 instead of the charging stand 106-1 (FIGS. 9 and 11) according to the third embodiment. The mobile terminal device 104-2 of the charging system 102-2 includes a battery pack 132-2 instead of the battery pack 132-1 (FIGS. 9 and 11).

  The charging stand 106-2 shown in FIG. 22 is an example of the charging stand 4-2, and includes a coil 12, a power supply circuit 174, a changeover switch 176, a charge control unit 178, and capacitors 180 and 302. Yes. The coil 12, the power supply circuit 174, the changeover switch 176, and the capacitors 180 and 302 form a primary side circuit for non-contact charging. Charging base 106-2 includes an operation unit 182, a display unit 184, and a storage unit 185.

  The changeover switch 176 is an example of the switching unit 16, receives a switching signal from the charging control unit 178, and switches the connection of the coil 12. The coil 12 is connected to the power supply circuit 174 or the capacitor 302. The coil 12 is connected to one of the changeover switches 176. In addition, connection ends 1a, 1b, 2a, and 2b are formed on the other side of the changeover switch 176. A power line 254-1 of the power supply circuit 174 is connected to the connection end 1a, and a power line 254-2 of the power supply circuit 174 is connected to the connection end 2a. Different ends of the capacitor 302 are connected to the connection ends 1b and 2b. This capacitor 302 is connected in parallel to the coil 12 and functions as a parallel resonant capacitor during demagnetization.

  The charging control unit 178 transmits the aforementioned switching signal to the changeover switch 176. This switching signal represents connection to the power supply circuit 174 or connection to the capacitor 302.

  Other configurations are the same as those of the third embodiment.

A battery pack 132-2 shown in FIG. 22 is an example of a charging device 34-2, and forms, for example, a charging receiver module. The battery pack 132-2 includes a power supply circuit 304, a changeover switch 306, and a capacitor 308 in addition to the configuration described in the third embodiment.

  The power supply circuit 304 is an example of the current supply unit 24 and supplies current to the coil 22. The power supply circuit 304 has a circuit configuration similar to that of the charge control unit 178, for example, and generates an alternating current. The power supply circuit 304 is connected to the coil 22 by power lines 312-1 and 312-2.

  The changeover switch 306 is an example of the changeover unit 26 and switches the connection of the coil 22. The coil 22 is connected to one side of the changeover switch 306, and connection ends 1a, 1b, 2a, and 2b are formed on the other side. A connection line 202 is connected to the connection end 1a, and a connection line 214 is connected to the connection end 2a. In addition, the power line 312-1 is connected to the connection end 1b via the capacitor 308, and the connection end 2b is connected to the power line 312-2. The capacitor 308 is connected in series with the coil 22 and functions as a series resonant capacitor. The changeover switch 306 connects the connection ends 1a and 2a to the coil 22 as the first connection, or connects the connection ends 1b and 2b to the coil 22 as the second connection.

  The MCU control line C 2 of the MPU 188 is connected to the power supply circuit 304 and the changeover switch 306. The MPU 188 transmits a drive signal to the power supply circuit 304 through the MCU control line C2. The power supply circuit 304 is driven or stopped by this drive signal. The MPU 188 transmits a change signal to the changeover switch 306 through the MCU control line C2. Thereby, the connection of the selector switch 306 is switched.

  Since other configurations are the same as those of the third embodiment, the description thereof is omitted.

In the charging system 102-2 shown in FIG. 22, the charging stand 106-2, the exciting current I ₁ of the alternating current supplied to the coil 12, and supplies the battery pack 132-2 exciting current I ₄ of the AC to the coil 22. For this reason, the magnetic fields M1 and M2 generated between the coils 12 and 22 are both AC magnetic fields including AC magnetic fields. That is, an alternating magnetic field is used for charging and demagnetization.

  (Relation between current and magnetic field during charging)

  When charging the battery cell 190, the changeover switch 176 is connected to the connection ends 1a and 2a, and the power supply circuit 174 is connected to the coil 12. The changeover switch 306 is connected to the connection ends 1a and 2a, and the coil 22 is connected to the battery cell 190. The relationship between the current during charging and the magnetic field is the same as that in the third embodiment, as shown in FIGS.

  (Relationship between current and magnetic field during demagnetization)

  When demagnetizing the magnetization, the changeover switch 176 is connected to the connection ends 1 b and 2 b, and the capacitor 302 is connected to the coil 12. The changeover switch 306 is connected to the connection ends 1b and 2b, and the coil 22 is connected to the power supply circuit 304.

Reference is made to FIG. 23, FIG. 24 and FIG. 25 for the relationship between the current and magnetic field during demagnetization. FIG. 23 shows an example of current flow during demagnetization. FIG. 24 shows an example of a current flowing through the coil 22 during demagnetization and an example of a magnetic field on the coil 22 side during demagnetization. FIG. 25 shows an example of a current flowing through the coil 12 during demagnetization and an example of a magnetic field on the coil 12 side during demagnetization. In FIG. 23, only the electromagnetic coupling portion between charging base 106-2 and battery pack 132-2 is shown. 24A and 25A, the horizontal axis indicates time t, and the vertical axis indicates the current value. The current shown in A of FIG. 24 represents the direction in which the excitation current I ₄ flows as a positive value. The current shown in A of FIG. 25 represents the flowing direction of the current I ₆ as a positive value. In the magnetic fields shown in B of FIG. 24 and B of FIG. 25, the horizontal axis represents time t, and the vertical axis represents the magnetic field polarity. The arrows in FIG. 23 indicate the direction of current.

In the battery pack 132-2 shown in FIG. 23, at the time of degaussing, as shown in FIG. 23, an excitation current I _{4 in the} direction opposite to the charging current I ₃ (FIG. 13) flows. In this case, a current I ₆ having a direction opposite to the excitation current I ₁ (FIG. 13) flows through the charging stand 106-2.

As shown in FIG. 24A, the excitation current I ₄ has a positive current value. Also in the coil 22 side by the variation of the exciting current I ₄ as shown in B of FIG. 24, the magnetic field of negative polarity is generated.

As a magnetic field acts on the coil 12 side, a current I ₆ shown in FIG. 25A flows. Further, as shown in FIG. 25B, a positive polarity magnetic field is generated on the coil 12 side. The magnetic field M2 described above is formed by the magnetic field on the coil 12 side and the magnetic field on the coil 22 side.

  By reversing the direction of the current, the polarity of the magnetic field can be reversed during charging and degaussing.

  Next, a power feeding method will be described with reference to FIG. FIG. 26 shows an example of the processing procedure of the power feeding method.

  This power feeding method includes the above-described charging step 262 and a degaussing step 264-2 for demagnetizing the magnetization of the magnetic material 30 generated by the charging. Since the charging step 262 is the same as that of the third embodiment, the description thereof is omitted. The switching process (step S209) from the detection process (step S201) of the charging base 106-2 to the OFF state of the switch 186 is performed from the detection process (step S101) of the charging base 106-1 according to the third embodiment. This is the same as the process of switching to the off state (step S109).

    (Demagnetizing step 264-2)

  The degaussing step 264-2 is performed following the charging step 262 after the non-contact charging is completed. The degaussing step 264-2 includes processes from the switching process of the changeover switches 176 and 306 (step S210) to the determination of the measured value of the magnetic field (step S216).

After the non-contact charging is completed, the charging control unit 178 switches the connection setting of the changeover switch 176 from the first connection by the connection ends 1a and 2a to the second connection by the connection ends 1b and 2b. Further, the MPU 188 switches the connection setting of the changeover switch 306 from the first connection by the connection ends 1a and 2a to the second connection by the connection ends 1b and 2b (step S210). The MPU 188 drives the power supply circuit 304, and starts supplying demagnetizing power by the power supply circuit 304 (step S211). By such processing, in the coil 22, the exciting current I ₄ flows through the coil 22, the magnetic field M2 is generated, and the degaussing operation is started. Demagnetization of the magnetization of the magnetic material 30 caused by charging is started. In addition, the MPU 188 measures the above-described demagnetization time Td after the supply of demagnetization power is started. The demagnetization time Td is measured using time information transmitted from the control unit 128 via the MPU control line 228, for example. The demagnetization time Td may be measured by the MPU 188 counting time.

  The MPU 188 determines whether the degaussing time Td has timed out the set time Tout (step S212). This determination is made based on, for example, whether the degaussing time Td is the set time Tout. When the degaussing time Td is less than the set time Tout (No in step S212), the degaussing operation is maintained. When the demagnetizing time Td becomes equal to or longer than the set time Tout (Yes in step S212), the MPU 188 stops supplying demagnetizing power (step S213), and the connection setting of the changeover switch 306 is changed to the first connection by the connection terminals 1a and 2a. (Step S214). The charge control unit 178 switches the connection setting of the changeover switch 176 to the first connection by the connection ends 1a and 2a (step S214). The demagnetization operation is completed by stopping the power and switching the changeover switches 176 and 306. The set time Tout may be a time set in advance in the MPU 188. The set time Tout may be a time set by the MPU 188 based on the charge time from the start to the end of charging. When the set time Tout is set based on the charging time, the degaussing time can be set according to the charging time. That is, the demagnetization time can be set according to the amount of magnetization that varies in accordance with the charging time.

  After the degaussing operation is completed, the MPU 188 measures the magnetic field in the mobile terminal device 104-2 (step S215). That is, the magnetic field change of the portable terminal device 104-2 is measured by the above-described geomagnetic sensor 118, and magnetization information is obtained.

  The MPU 188 determines whether or not the measurement value of the geomagnetic sensor 118 is within the measurement range (step S216). This determination is made based on, for example, whether or not the value of the difference information included in the magnetization information is small enough to be within a range where the geomagnetic sensor 118 can measure. When the measurement value of the geomagnetic sensor 118 is not within the measurement range (No in step S216), the MPU 188 and the charging control unit 178 return to the switching of the changeover switches 176 and 306 (step S210), and the demagnetizing operation is repeated. By repeating the demagnetization operation, the magnetization generated by the charging can be increased and the demagnetization can be reliably performed. When the measurement value of the geomagnetic sensor 118 is within the measurement range (Yes in step S216), the charging control unit 178 and the MPU 188 end the non-contact charging process.

  Next, FIG. 27 is referred with respect to the operation timing of non-contact charging. FIG. 27 shows an example of the operation timing of contactless charging. Note that the timing illustrated in FIG. 27 is an example, and the configuration of the present disclosure is not limited to such timing. Times t1 to t10 shown in FIG. 27 are the same as the above-described times t1 to t10.

  Changes in the voltage of the positive electrode 222 shown in FIG. 27A, changes in the voltage of the MCU control line C4 shown in FIG. 27B, and changes in the voltage of the MCU control line C1 shown in FIG. It is the same as the form. A change in the voltage of the MCU control line C3 shown in FIG. 27E, a change in the voltage Cv between the terminals of the current detection unit 194 shown in FIG. 27F, and a change in the current value of the switch 186 shown in FIG. This is the same as in the third embodiment. The measurement of the geomagnetic sensor 118 shown in J of FIG. 27 is the same as that of the third embodiment.

  Changes in the voltage of the MCU control line C2 shown in D of FIG. 27, driving of the power supply circuit 304 shown in I of FIG. 27, and switching of the changeover switch 306 shown in K of FIG. 27 fluctuate at the same timing. In addition, the changeover of the changeover switch 176 indicated by L in FIG. 27 fluctuates at the same timing as the changeover of the changeover switch 306. At time t5 and time t9 when the demagnetization operation is started, the voltage of the MCU control line C2 changes to a high voltage, the power supply circuit 304 is driven, and the changeover switch 306 is switched to the second connection. At time t6 and time t10 when the demagnetization operation is stopped, the voltage of the MCU control line C2 changes to a low voltage, the power supply circuit 304 is stopped, and the changeover switch 306 is switched to the first connection.

  H in FIG. 27 indicates driving of the power supply circuit 174. The power supply circuit 174 is driven for charging from time t2 when non-contact charging is started to time t4 when non-contact charging is stopped.

  According to the fourth embodiment, in addition to the effects described in the second embodiment, the following effects can be obtained.

  Since demagnetization is determined again based on the measurement result of the geomagnetic sensor 118 after demagnetization, demagnetization can be performed reliably.

  [Fifth Embodiment]

  A fifth embodiment will be described with reference to FIG. FIG. 28 shows an example of a circuit configuration of the charging system according to the fifth embodiment. The configuration illustrated in FIG. 28 is an example, and the configuration of the present disclosure is not limited to such a configuration. 1 to 3, 5 to 7, 11, and 22 are denoted by the same reference numerals. The arrows in FIG. 28 indicate the direction of current.

In the fourth embodiment, magnetic fields M1 and M2 are generated by alternating excitation currents I ₁ and I ₄ . The magnetic fields M1 and M2 include a varying magnetic field that varies with time. In the fifth embodiment, the exciting current I ₁ of the AC to generate a magnetic field M1 which varies as a function of time, causing a magnetic field M2 is a static magnetic field by the excitation current I ₇ of a DC magnetic caused by charge Demagnetize the magnetization of the material 30. Therefore, a charging system 102-3 according to the fifth embodiment includes a charging stand 106-3 instead of the charging stand 106-2 (FIG. 22) according to the fourth embodiment. The mobile terminal device 104-3 of the charging system 102-3 includes a battery pack 132-3 instead of the battery pack 132-2 (FIG. 22).

  A charging stand 106-3 shown in FIG. 28 is an example of a charging stand 4-2. In the charging stand 106-3, the power line 254-1 of the power supply circuit 174 is connected to the coil 12 via the capacitor 180. A power line 254-2 of the power supply circuit 174 is connected to the coil 12. The coil 12, the power supply circuit 174, and the capacitor 180 form a primary circuit for non-contact charging.

  The charging control unit 178 is connected to the power supply circuit 174 and transmits the drive signal described above to the power supply circuit 174 to drive or stop the power supply circuit 174. In addition, the charging control unit 178 controls the display unit 184 and the storage unit 185. The charge control unit 178 may include other functions, for example, a clock function, and may measure time.

  A battery pack 132-3 illustrated in FIG. 28 is an example of a charging device 34-2. The battery pack 132-3 includes two coils 22 and 324, and the coils 22 and 324 are used to charge the battery cell 190 and demagnetize the magnetization of the magnetic material 30.

  In battery pack 132-3, the end of coil 22 is connected to connection lines 202 and 214, respectively. By including the coil 22, the capacitor 198, the switch 186, the battery cell 190, the protection circuit 192, and the current detection unit 194, a non-contact charging secondary circuit is formed in the battery pack 132-3.

  In the battery pack 132-3, instead of the power supply circuit 304 (FIG. 22), a power supply circuit 322 using the battery cell 190 as a DC power source is formed.

  The power supply circuit 322 is an example of the current supply unit 24 and supplies a direct current to the coil 324 installed in the battery pack 132-3. The power supply circuit 322 includes a protection circuit 192, a current adjustment unit 326, and a switch 328. The protection circuit 192 is shared by the power receiving circuit and the power supply circuit 322. In the battery pack 132-3, the protection circuit 192 is used efficiently. On the positive electrode side of the battery cell 190, a current adjustment unit 326 and a switch 328 are connected in series in the order of the current adjustment unit 326 and the switch 328. Switch 328 and protection circuit 192 are each connected to coil 324.

  The current adjustment unit 326 includes, for example, a current adjustment resistor, and adjusts the flow rate of the current flowing through the power supply circuit 322. Switch 328 includes, for example, an on / off switch, and connects or disconnects between battery cell 190 and coil 324. The switch 328 is connected to the MCU control line C2 of the MPU 188. The switch 328 connects or disconnects the battery cell 190 and the coil 324 according to a switching signal from the MPU 188.

  The coil 324 is provided with a core 325 made of a magnetic material such as an iron core. Upon receiving a direct current, the core 325 is magnetized to generate a static magnetic field. The static magnetic field generated by the coil 324 is an example of the magnetic field M2.

  Since other configurations are the same as those of the fourth embodiment, the description thereof is omitted.

In the charging system 102-3 shown in FIG. 28, the charging stand 106-3, the exciting current I ₁ of the alternating current supplied to the coil 12, the battery pack 132-3 supplies the exciting current I ₇ DC. For this reason, the magnetic field M1 generated between the coils 12 and 22 is a magnetic field including an alternating magnetic field. The magnetic field M2 generated in the coil 324 is a static magnetic field including a DC magnetic field. That is, an AC magnetic field is used for charging, and a DC magnetic field is used for demagnetization.

  (Relation between current and magnetic field during charging)

  The battery cell 190 is charged when the charge control unit 178 drives the power supply circuit 174 and the MPU 188 connects the switch 186. The relationship between the current during charging and the magnetic field is the same as that in the third and fourth embodiments, as shown in FIGS.

  (Relationship between current and magnetic field during demagnetization)

  When demagnetizing the magnetization of the magnetic material 30 generated by charging, the switch 328 is operated by the MPU 188, and the positive pole side of the battery cell 190 and the coil 324 are connected.

  Reference is made to FIG. 29 and FIG. 30 for the relationship between the current and magnetic field during demagnetization. FIG. 29 shows an example of a current flow during demagnetization. FIG. 30 shows an example of a current flowing through the coil 324 during demagnetization and an example of a magnetic field on the coil 324 side during demagnetization. 29 shows the coil 324 and the core 325 of the battery pack 132-3. In the current shown in FIG. 30A, the horizontal axis represents time t and the vertical axis represents current value. The current value represents the direction in which the current flows as a positive direction. In the magnetic field shown in FIG. 30B, the horizontal axis represents time t, and the vertical axis represents the magnetic field polarity. The arrows in FIG. 29 indicate the direction of current.

The battery pack 132-3, upon demagnetization, is the excitation current I ₇ as shown in FIG. 29 is flowing. This excitation current I ₇ is a current opposite to the charging current I ₃ (FIG. 13). That is, when the charging current I ₃ flows through the coil 22 clockwise, the exciting current I ₇ flows through the coil 324 counterclockwise. When the charging current I ₃ flows through the coil 22 counterclockwise, the exciting current I ₇ flows through the coil 324 clockwise.

The excitation current I ₇ is a direct current as shown in FIG. By installing the core 325 in the coil 324, the core 325 is magnetized, and as shown in FIG. 30B, the magnetic field has a negative polarity and the magnetic field M2 is generated.

  By reversing the direction of the current, the polarity of the magnetic field can be reversed during charging and degaussing.

  Next, FIG. 31 is referred to regarding a power feeding method. FIG. 31 shows an example of the processing procedure of the power feeding method.

  This power feeding method is an example of contactless charging, and includes a charging step 262 and a demagnetizing step 264-3. Since the charging step 262 is the same as the charging step 262 (FIG. 19) of the third embodiment and the fourth embodiment, the description thereof is omitted. That is, the switching process (step S229) from the detection process (step S221) of the charging stand 106-3 to the OFF state of the switch 186 is the same as the detection process (step S101) of the charging stand 106-1 of the third embodiment. This is the same as the switching process of the switch 186 to the off state (step S109).

    (Demagnetization process 264-3)

  The degaussing process 264-3 is performed following the charging process 262 after the non-contact charging is completed. The demagnetization process 264-3 includes processes from a process of turning on the switch 328 (step S230) to a process of determining whether the measurement value is within the measurement range (step S234).

  After the charging process 262 is completed, the MPU 188 sets the switch 328 to ON, and connects the positive electrode side of the battery cell 190 and the coil 324 to the switch 328 (step S230). By such connection, the current of the battery cell 190 flows to the coil 324, the magnetic field M2 is generated, and the degaussing operation is started. Demagnetization of the magnetization of the magnetic material 30 caused by charging is started. In addition, the MPU 188 measures the above-described demagnetization time Td after the supply of demagnetization power is started.

  The MPU 188 determines whether the degaussing time Td has timed out the set time Tout (step S231). This determination is made based on, for example, whether the degaussing time Td is the set time Tout. When the demagnetization time Td is less than the set time Tout (No in step S231), the demagnetization operation is maintained. When the demagnetizing time Td becomes equal to or longer than the set time Tout (Yes in step S231), the MPU 188 sets the switch 328 to OFF, disconnects the positive pole side of the battery cell 190 and the coil 324 (step S232), and degaussing operation Exit.

  The measurement start of the geomagnetic sensor 118 (step S233) and the determination of whether the measurement value of the geomagnetic sensor 118 is within the measurement range (step S234) are the same as in the third and fourth embodiments. Therefore, the description is omitted. By repeating the demagnetization operation by the measurement of the geomagnetic sensor 118, it is possible to demagnetize more the magnetization of the magnetic material 30 generated by charging. When the measurement value of the geomagnetic sensor 118 is within the measurement range (Yes in step S234), the MPU 188 ends the non-contact charging process.

  Next, FIG. 32 is referred about the operation timing of non-contact charge. FIG. 32 shows an example of the operation timing of non-contact charging. Note that the timing illustrated in FIG. 32 is an example, and the configuration and the power feeding method of the present disclosure are not limited to such timing. The times t1 to t10 shown in FIG. 32 are the same as the times t1 to t10 described above.

  Changes in the voltage of the positive electrode 222 shown in FIG. 32A, changes in the voltage of the MCU control line C4 shown in B of FIG. 32, and changes in the voltage of the MCU control line C1 shown in FIG. It is the same as the form. Changes in the voltage of the MCU control line C3 shown in E of FIG. 32, changes in the voltage Cv between the terminals of the current detection unit 194 shown in F of FIG. 32, and changes in the current value of the switch 186 shown in G of FIG. This is similar to the fourth embodiment. The driving of the power supply circuit 174 shown in H of FIG. 32 and the measurement of the geomagnetic sensor 118 shown in J of FIG. 32 are the same as in the fourth embodiment.

  The change in the voltage of the MCU control line C2 shown in FIG. 32D is the same as that in the fourth embodiment. The on / off state of the switch 328 shown in I of FIG. 32 fluctuates at the same timing as the voltage of the MCU control line C2.

  According to the fifth embodiment, in addition to the effects described in the fourth embodiment, the following effects can be obtained.

  Since the electric power of the battery cell 190 is used and the magnetic field M2 is generated by a direct current, it is not necessary to install an alternating current power supply like the power supply circuit 304 (FIG. 22) in the battery pack 132-3.

  [Sixth Embodiment]

  In the third to fifth embodiments, the magnetic field M2 is generated by any one of the charging bases 106-1, 106-2, 106-3 or the battery packs 132-1, 132-2, 132-3. did. In the sixth embodiment, as shown in FIG. 33, the charging system 102-4 includes, for example, a portable terminal device 104-2 and a charging stand 106-1, and the battery pack 132-2 and the charging stand 106-. 1 includes the function of generating the magnetic field M2. For which of the battery pack 132-2 and the charging base 106-1, the magnetic field M2 is generated, for example, priorities are set in advance, and either the battery pack 132-2 or the charging base 106-1 is prioritized. It can be used for. Further, it may be adjusted between the MPU 188 and the charging control unit 178 which generates the magnetic field M2 by communication before starting charging or during charging.

  When the magnetic field M2 is generated by the charging base 106-1, for example, the charging process is performed by the power feeding method and the operation timing described in the third embodiment.

  When the magnetic field M2 is generated by the battery pack 132-2, the charging process is performed, for example, by the power supply method and the operation timing described in the fourth embodiment.

  According to the sixth embodiment, in addition to the effects described in the third embodiment and the fourth embodiment, any one of the charging stand 106-1 and the mobile terminal device 104-2 is selected. The magnetization of the magnetic material 30 generated by charging can be demagnetized by the magnetic field M2.

  In the sixth embodiment, the charging system 102-4 is formed including the charging base 106-1 and the portable terminal device 104-2. Such a combination is an example, and the magnetic field M2 is generated by at least one of the devices. Any combination may be used as long as the configuration is generated.

  [Other Embodiments]

Reference is made to FIG. 34 and FIG. 35 for another embodiment. 34 and 35, arrows in the magnetic fields M1 and M2 indicate the direction of the magnetic field. The arrows of the excitation current I ₁ , the excitation current I ₂ , the charging current I ₃ and the excitation current I ₄ indicate the direction of the current. Note that the configurations illustrated in FIGS. 34 and 35 are examples, and the configurations of the present disclosure are not limited to such configurations. 1, 2, 9, 11, and 22 are denoted by the same reference numerals. 34 and 35, a part of the configuration of the battery packs 132-1 and 132-2 is omitted.

  A charging system 102-5 shown in FIG. 34 includes a portable terminal device 104-5 and the charging stand 106-1 described above.

  The mobile terminal device 104-5 includes a substrate 402. On one surface side of the substrate 402, magnetic field detection type integrated circuits 404-1, 404-2 and integrated circuits 406-1, 406-2, 406-3 are provided.

  The integrated circuits 404-1 and 404-2 are examples of the electronic component 32 (FIG. 1) described above, have a magnetic field detection function, and include, for example, the geomagnetic sensor 118 or the magnetic sensor 122.

  The integrated circuits 406-1, 406-2, and 406-3 are examples of the electronic component 32 described above, and form the control unit 128 or the memory unit 130, for example.

  A shield metal plate 134-1 is installed on one surface side of the substrate 402, and surrounds the integrated circuits 406-1 and 406-2. A shield metal plate 134-2 is installed on the other surface side of the substrate 402.

  On the other surface side of the substrate 402, the above-described battery pack 132-1 is arranged. That is, around the battery pack 132-1, as shown in FIG. 34, the magnetic material 30 such as the shield metal plates 134-1 and 134-2, and the integrated circuits 404-1, 404-2, 406-1, and 406 are provided. -2 and 406-3 are arranged.

During charging, the exciting current I ₁ flows through the coil 12 of the charging stand 106-1, and a magnetic field M1 is generated. After the charging is completed, a reverse excitation current I ₂ at the time of charging flows through the coil 12, a magnetic field M2 having a polarity opposite to the magnetic field M1 is generated between the coil 12 and the coil 22, and the magnetization of the magnetic material 30 generated at the time of charging is generated. Demagnetize.

  A charging system 102-6 illustrated in FIG. 35 includes a mobile terminal device 104-6 and a charging stand 106-2. In the mobile terminal device 104-6, the battery pack 132-1 of the mobile terminal device 104-5 described above is replaced with the battery pack 132-2.

  The above-described battery pack 132-2 is arranged on the other surface side of the substrate 402. That is, around the battery pack 132-2, as shown in FIG. 35, magnetic materials such as shield metal plates 134-1 and 134-2, and integrated circuits 404-1, 404-2, 406-1, and 406- Electronic components 32 such as 2, 406-3 are arranged. In this embodiment, the magnetic field M2 can be generated on both the mobile terminal device 104-6 side and the charging stand 106-2 side.

During charging, the exciting current I ₁ flows through the coil 12 of the charging stand 106-2, and a magnetic field M1 is generated. Upon receiving the magnetic field M1, a charging current I ₃ flows through the coil 22.

  (When magnetic field M2 is generated on charging base 106-2 side)

After charging is completed, a reverse excitation current I ₂ flows in the coil 12 in the opposite direction to that during charging, and a magnetic field M2 having a polarity opposite to that of the magnetic field M1 is generated between the coil 12 and the coil 22 to generate magnetic material generated during charging. Demagnetize the magnetization.

  (When magnetic field M2 is generated on the mobile terminal device 104-6 side)

After charging is completed, by supplying the exciting current I ₄ to the coil 22 from the power supply circuit 304 in the battery pack 132-2, the field M1 between the coil 12 and the coil 22 a magnetic field M2 of opposite polarity is generated Demagnetize the magnetization of the magnetic material generated during charging.

  According to these embodiments, in addition to the above-described effects, the magnetization of the magnetic material such as the shield metal plates 134-1 and 134-2 disposed around the battery pack 132-1 can be demagnetized, and the integrated circuit 404- The operation of electronic components such as 1, 404-2 can be stabilized.

  With respect to the embodiment described above, the features and modifications thereof are listed below.

  (1) In the above embodiment, contactless charging has been described as an example of contactless power supply. However, it is sufficient that power is transmitted without contact of a contact, and contactless power supply to an electronic device such as a mobile terminal device is possible. It may be. For example, the power received by the non-contact power feeding may be directly supplied to the electronic components constituting the electronic device. By generating the magnetic field M2 while the non-contact power supply to the electronic device is suspended, the magnetization of the magnetic material generated by the non-contact power supply can be demagnetized.

  (2) In the first embodiment and the second embodiment, the degaussing operation and the charging are terminated by the set time. In the first embodiment and the second embodiment, for example, as in the third embodiment and the fourth embodiment, the measurement value of the geomagnetic sensor 118 is acquired and the measurement value of the geomagnetic sensor is used. It is good also as a structure which repeats a degaussing operation | movement.

  In the third to sixth embodiments and other embodiments, demagnetization may be terminated by a single degaussing operation without performing measurement by the geomagnetic sensor 118. When degaussing is terminated by a single degaussing operation, contactless charging is terminated without performing magnetic field measurement processing (steps S114, S215, S233) and measurement value determination processing (steps S115, S216, S234). It ’s fine.

  (3) In the above embodiment, the MPU 188 detects the charging stand by the MCU control line C4. However, any detection may be performed as long as the MPU 188 detects the charging stand. For example, the charging unit may be detected on the control unit 128 side, and the detection information on the charging table may be received from the control unit 128 by the MPU control line 228 as a notification of the charging state. According to such a configuration, since the detection information is received by the MPU control line 228, it is not necessary to provide the MCU control line C4.

  (4) In the above embodiment, it is determined whether or not the measurement value of the geomagnetic sensor 118 is within the measurement range, but other difference information indicating the difference between the sensor before charging and the sensor after charging is within a certain range. You may judge by whether it exists in. For example, when the geomagnetic sensor 118 is a sensor that can be adjusted according to the state of the magnetic field, a difference between set values for adjusting the geomagnetic sensor 118 is used as the difference information. As an example, difference information between a set value before charging and a set value after charging may be used. If the geomagnetic sensor 118 transmits the difference information between the setting value before charging and the setting value after charging to the control unit 128 as magnetization information, the MPU 188 or the charging control unit 178 can receive this difference information. The MPU 188 or the charging control unit 178 may determine whether or not the received difference information is within the setting range.

  (5) In the above embodiment, the magnetic field measurement by the geomagnetic sensor 118 is performed after performing the demagnetization operation. However, the demagnetization operation may be performed based on the determination result by measuring the geomagnetic sensor after the end of charging. For example, instead of the demagnetizing step 264-2 of the fourth embodiment, as shown in FIG. 36, the magnetic field may be measured (step S215) following the charging step 262. In this case, the operation steps shown in FIG. 37 are performed. That is, the change in the voltage of the MCU control line C2, the driving of the power supply circuit 304, and the switching of the changeover switches 176 and 306 performed between the times t5 and t6 are skipped. Further, as shown in FIG. 38 by changing the demagnetization step 264-3 of the fifth embodiment, the magnetic field measurement (step S233) may be performed following the charging step 262. In this case, the operation steps shown in FIG. 39 are performed. That is, the voltage change of the MCU control line C2 and the on / off switching of the switch 328 performed between the times t5 and t6 are skipped.

  Further, instead of the degaussing step 264-2 of the fourth embodiment, a degaussing step 264-4 shown in FIG. 40 may be performed. In the demagnetization step 264-4, the changeover switches 176 and 306 are switched to the connection ends 1a and 2a (step S307) when the measured value of the magnetic field is within the measurement range (Yes in step S306). According to such a processing procedure, even when the degaussing operation is repeated by measuring the magnetic field, the switching operation of the changeover switches 176 and 306 can be suppressed to two times. The processing procedure (steps S301 to 304) of the demagnetization process 264-4 is the same as the processing procedure (steps S210 to 213) of the demagnetization process 264-2. The processing procedure (steps S305 to 306) of the demagnetization step 264-4 is the same as the processing procedure (steps S215 to 216) of the demagnetization step 264-2. These descriptions are omitted.

  (6) In the charging step 262 of the above embodiment, after the switch 186 is turned on, the state may be notified to the control unit 128. The order of executing the status notification to the control unit 128, the end of non-contact charging, and the process of turning off the switch may be mutually changed.

  (7) In the above embodiment, the magnetic field M1 is generated at the time of charging and the magnetic field M2 is generated at the time of demagnetization. However, the magnetic field M1 and the magnetic field M2 may have opposite polarities, and are not limited to such directions. . For example, the storage battery 8 or the battery cell 190 may be connected in the opposite direction so that the magnetic field is generated in the direction of the magnetic field M2 during charging and the magnetic field is generated in the direction of the magnetic field M1 during demagnetization. Even with such a configuration, the magnetization of the magnetic material 30 generated during charging can be demagnetized.

As described above, the most preferred embodiment of the present invention has been described. However, the configuration of the present disclosure is not limited to the above description, but is described in the claims or disclosed in the specification. It goes without saying that various modifications and changes can be made by those skilled in the art based on the gist of the present invention, and such modifications and changes are included in the scope of the present invention.

2-1, 2-2, 102-1, 102-2, 102-3, 102-4, 102-5, 102-6 Charging system 4-1, 4-2, 106-1, 106-2, 106 -3 Charging stand 6-1, 6-2 Electronic device 8 Storage battery 12, 22, 324 Coil 14 Current supply unit 16, 26 Switching unit 18, 28, 128 Control unit 34-1, 34-2 Charging device 104-1, 104-2, 104-3, 104-5, 104-6 Mobile terminal device 118 Geomagnetic sensor 126 Display device 132-1, 132-2 Battery pack 174, 304, 322 Power supply circuit 176, 306 Changeover switch 178 Charging control unit 188 MPU
190 battery cells

Claims (6)

An electronic device having a non-contact power supply function including a coil that generates a magnetic field by an excitation current or generates a current by receiving a magnetic field,
A current supply unit configured to supply a current flowing in a direction opposite to the current flowing in the coil during the non-contact power supply to the coil after the non-contact power supply and generate a magnetic field having a polarity opposite to the magnetic field generated during the non-contact power supply; Prepared,
An electronic apparatus characterized by demagnetizing the magnetization generated by the non-contact power feeding. A controller that acquires magnetization information representing the magnetization and controls supply of a current flowing in the reverse direction based on the magnetization information;
The electronic apparatus according to claim 1, further comprising: A magnetic detector for detecting magnetism;
With
3. The electronic apparatus according to claim 1, wherein the magnetism detected by the magnetism detection unit is used for controlling supply of a current flowing in the reverse direction.   4. The electronic apparatus according to claim 1, wherein the current flowing in the reverse direction is an alternating current or a direct current. A power supply method for an electronic device having a non-contact power supply function including a coil that generates a magnetic field by an excitation current or generates a current by receiving a magnetic field,
During the non-contact power supply, current is supplied to the coil to supply power,
A current that flows in the opposite direction to the current that flows during non-contact power feeding is supplied to the coil after the non-contact power feeding, and a magnetic field having a polarity opposite to that generated during the non-contact power feeding is generated,
Demagnetizing the magnetization generated by the non-contact power feeding method. A power supply system having a non-contact power supply function including a coil that generates a magnetic field by an exciting current or generates a current by receiving the magnetic field,
A current supply unit configured to supply a current flowing in a direction opposite to the current flowing in the coil during the non-contact power supply to the coil after the non-contact power supply and generate a magnetic field having a polarity opposite to the magnetic field generated during the non-contact power supply; Prepared,
A power feeding system that demagnetizes the magnetization generated by the non-contact power feeding.

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