JP2005237155A - Battery charger applicable to multiple-voltage specifications, battery charging system, and battery unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To charge an electronic apparatus by automatically discriminating the voltage of a battery on the apparatus to be charged and by automatically adjusting a charging voltage. <P>SOLUTION: The electronic apparatus 1 includes the battery 8, a first operation device 6, a first memory 7, and an RFID/IC tag 9. The battery charger 2 includes a second operation device 12, a second memory 13, an IC 14 of a Scanner, and power supply system controlling devices 17 to 20 that make the charging voltage variable. When the electronic apparatus 1 is set in the battery charger 2, the second operation device 12 receives a data corresponding to the charging specifications of the battery 8 via the RFID/IC tag 9 and the IC 14 of the Scanner. A voltage that corresponds to the charging specifications is generated by the power supply system controlling devices 17 to 20 so that the battery 8 is charged via a power transmission coil 22 and a receiving coil 10. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a battery charger mounted on an electronic device or the like, and in particular, battery charging in which a charging voltage is automatically adjusted even in a model having a different voltage specification of a power supply battery used in the electronic device or the like. The present invention relates to a battery charger, a battery charging system, and a battery unit.

  Conventionally, battery chargers mounted on electronic devices such as mobile phones, PDAs (Personal Digital Assistance), and Note PCs are charged using dedicated battery chargers that meet the battery voltage specifications of the electronic devices. It was.

  Japanese Unexamined Patent Application Publication No. 2003-37861 describes an example in which a battery of a conventional mobile phone is mounted. As shown in FIG. 1A of the above publication, this conventional battery for a mobile phone is mounted inside the mobile phone and covered with a battery cover from the back side. The voltage of the battery of this type of mobile phone often varies depending on the type of mobile phone.

The battery of the mobile phone is usually equipped with a rechargeable battery, and the charge amount is consumed by using the mobile phone. Therefore, when the charge amount is exhausted, the battery is charged to recover the charge amount. There is a need. For this purpose, it is charged with an adapter that receives a commercial power supply and outputs a DC voltage that meets the voltage specification of the battery. A mobile phone generally has a battery charging connector and a battery charging contact at the bottom. When charging, the direct current output of the adapter is connected directly to the mobile phone with the connector. Alternatively, the DC output of the adapter is received by a charging stand, and charging is performed by bringing the charging contact provided on the charging stand into contact with the battery charging contact of the mobile phone.
In this conventional battery charging system, when a mobile phone is purchased, an adapter suitable for the mobile phone is attached as a dedicated product.

  Japanese Patent Laid-Open No. 2001-307032 describes a battery charging system for portable terminals. This battery charging system is a charging system configured to charge a battery of a mobile terminal in a non-contact manner by electromagnetic coupling with an external charging power supply device. Also in the charging system described in this prior art, the charging voltage is a charging voltage that meets the battery voltage specification of the portable terminal.

In addition, there are both contact type and contact type charging methods for the handset of the fixed telephone, but when the handset is not in use, it is charged by setting it on the charging stand. ing. Also in this case, the charging specification such as the charging voltage is specialized for the model.
JP 2001-307032 A JP 2003-37861 A

  As described above, the battery voltage specifications of electronic devices such as mobile phones, PDAs, and Note PCs correspond to the electronic devices. However, the development of electronic devices in recent years is remarkable, and in particular, mobile phones, PDAs, New products are released one after another in Note PC and the like. The voltage of the power supply battery mounted on these developed products is often about 1V to 10V, but this voltage specification is not necessarily the same, and various types of voltage specifications are mixed and the number increases. This is the current situation. Therefore, even though there are some battery chargers that can be used in combination, there are quite a few types in the range of a charging voltage of about 1 V to 10 V and a charging current of about 1 A. In addition, since the charging voltage and current are different from each other, there is a problem that they cannot be used with each other. In addition, each time a product with different voltage and current specifications is developed, there is a problem that a charger with voltage and current specifications corresponding to the product must be made. Moreover, even if there is something that can be used in combination, it is difficult to confirm whether the specifications are met, or it is troublesome, so that it cannot be used in the end.

An object of the present invention is to solve these problems and to perform charging automatically corresponding to a plurality of voltage specifications.
It is another object of the present invention to automatically determine a battery voltage specification of an electronic device to be charged and automatically adjust the charging voltage to perform charging.
Moreover, this invention aims at setting it as the structure which can respond not only to a contact type but to non-contact type charge.

The subject matter of claim 1 of the present invention is a battery charger that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device, wherein the battery charger has different voltage specifications. The battery charger is characterized by comprising charging voltage varying means for automatically varying the charging voltage so as to generate charging voltages corresponding to a plurality of batteries.
The gist of the invention described in claim 2 of the present invention is that the charging voltage varying means is set in a plurality of power system control units for generating different voltages corresponding to battery charging voltage specifications, and the battery charger. And a power control unit that automatically determines the electronic device and selects and operates a power system controller that generates a voltage corresponding to the battery charging voltage specification from the plurality of power system controllers. A battery charger according to claim 1.
According to a third aspect of the present invention, the charging voltage varying means includes a power supply system control unit that generates a variable voltage corresponding to a battery charging voltage specification and the battery charger. 2. The apparatus according to claim 1, further comprising power control means for automatically discriminating an electronic device and outputting data for generating a voltage corresponding to the battery charging voltage specification to the power system control section. Resides in the battery charger described.
According to a fourth aspect of the present invention, there is provided an electronic device including a rechargeable battery, and charging the rechargeable battery mounted on the electronic device by receiving AC power from a commercial power source. In the battery charging system including a battery charger, the electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and an RFID / IC tag. The battery charger generates a charging voltage corresponding to a plurality of batteries having different voltage specifications and a second arithmetic unit using a microcomputer, a second memory as a storage device, a scanner IC, and the like. Charging voltage varying means for varying the charging voltage as described above, and data corresponding to the battery charging voltage specification is stored in the first memory. When the electronic device is stored in advance and the electronic device is set in the battery charger, the first arithmetic device reads data corresponding to the charging voltage specification stored in the first memory, and the data is The second arithmetic unit that transmits the data to the second arithmetic unit via the RFID / IC tag and the scanner IC in a non-contact manner and receives the data. The battery charging system is characterized by outputting a command signal so as to generate a voltage corresponding to a charging voltage specification.
According to a fifth aspect of the present invention, there is provided an electronic device having a rechargeable battery and an AC power received from a commercial power source to charge the rechargeable battery mounted on the electronic device. In the battery charging system including a battery charger, the electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and an RFID / IC tag. The battery charger generates a charging voltage corresponding to a plurality of batteries having different voltage specifications and a second arithmetic unit using a microcomputer, a second memory as a storage device, a scanner IC, and the like. Charging voltage varying means for varying the charging voltage as described above, and data corresponding to the type of the electronic device is stored in the first memory in advance. In the second memory, data corresponding to the type of the electronic device and the battery charging voltage specification are stored in advance, and the first device is set when the electronic device is set in the battery charger. The arithmetic device reads out the data corresponding to the model stored in the first memory, and transmits the data to the second arithmetic device through the RFID / IC tag and the scanner IC in a non-contact manner. The second arithmetic unit that has received the data reads a charging voltage specification corresponding to the model from the second memory based on the data, and the second arithmetic unit is configured to read the charging voltage that has been read. The battery charging system is characterized in that a command signal is output to the charging voltage variable means based on the specification so as to generate a voltage corresponding to the battery charging voltage specification.
According to a sixth aspect of the present invention, there is provided a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device. 1st arithmetic device using a memory, a first memory as a storage device and an electronic device equipped with an RFID / IC tag, a second arithmetic device using a microcomputer, a second memory as a storage device, a scanner And a battery charger equipped with a charging voltage varying means for varying the charging voltage, and the first memory has at least a charging voltage specification as data corresponding to the type of the electronic device or a charging specification of the battery. The first arithmetic unit stores data corresponding to a model of the electronic device, or the charging specifications, in advance. Read out from the memory, and transmitted to the second arithmetic device in a non-contact manner via the RFID / IC tag and the scanner IC and stored in the second memory, and the second arithmetic device is the electronic device. The battery charging system is characterized in that the charging voltage varying means is controlled based on the data corresponding to the model or the charging specification to generate the charging voltage corresponding to the charging voltage specification.
According to a seventh aspect of the present invention, the battery charger further includes a power transmission coil, the electronic device further includes a power reception coil electromagnetically coupled to the power transmission coil, and corresponds to the charging specification. The battery charging system according to claim 6, wherein charging energy is transmitted from the power transmission coil to the power receiving coil in a non-contact manner, and the electronic device charges the battery with the charging energy transmitted to the power receiving coil. Exist.
The gist of the invention described in claim 8 of the present invention is that the battery charger further comprises a contact for outputting a charging voltage corresponding to the charging specification, and the electronic device further receives the charging voltage. And a charging voltage is transmitted from the battery charger to the electronic device via the contact, and the electronic device charges the battery with the charging voltage transmitted via the contact. It exists in the battery charging system of Claim 6.
According to a ninth aspect of the present invention, the electronic device downloads data corresponding to the charging specification via a communication network and stores the data in the first memory. It exists in the battery charging system of Claim 6 thru | or 8.
According to a tenth aspect of the present invention, the gist of the present invention includes a measuring unit that measures a time from when the electronic device is set in the battery charger and starts charging, and is measured by the measuring unit. 7. An alarm signal is output when charging is not completed even after a standard charging time of the battery stored in the first or second memory as the charging specification has elapsed. A battery charging system according to claim 9.
The gist of the invention described in claim 11 of the present invention is that the charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker. Exist.
According to a twelfth aspect of the present invention, a charging voltage of the battery is detected, the detected charging voltage value is compared with a predetermined value, and the charging voltage becomes a predetermined value. The battery charging system according to claim 6, wherein feedback control is performed.
According to a thirteenth aspect of the present invention, the battery charger includes two power transmission coils juxtaposed so that their coil winding central axes substantially coincide with each other, and the electronic device includes the electronic device. When set in the battery charger, the power receiving coil is arranged so that the coil winding center axis of the power receiving coil substantially coincides with the coil winding center axis of the power transmission coil and is sandwiched between the two power transmission coils. The battery charging system according to claim 7, wherein the battery charging system is disposed in the electronic device.
According to a fourteenth aspect of the present invention, there is provided a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device. 1st arithmetic device using a memory, a first memory as a storage device and a battery unit equipped with an RFID / IC tag, a second arithmetic device using a microcomputer, a second memory as a storage device, a scanner And a battery charger equipped with a charging voltage varying means for varying the charging voltage, and the first arithmetic unit reads out the battery charging specifications stored in advance from the first memory, and the RFID / The second arithmetic unit is transmitted to the second arithmetic unit in a non-contact manner via an IC tag and the scanner IC. And controls the charging voltage changing means consists in a battery charging system, characterized in that to generate a charging voltage corresponding to the charging specifications.
Further, according to a fifteenth aspect of the present invention, the battery charger further includes a power transmission coil, the battery unit further includes a power reception coil electromagnetically coupled to the power transmission coil, and corresponds to the charging specification. 15. The battery charging system according to claim 14, wherein charging energy is transmitted from the power transmission coil to the power receiving coil in a non-contact manner, and the battery unit charges the battery with the charging energy transmitted to the power receiving coil. Exist.
According to a sixteenth aspect of the present invention, there is provided a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device. And a battery charger equipped with a computing device using a microcomputer, a memory as a storage device, a barcode reader, and a charging voltage varying means for varying a charging voltage. At least a charging voltage specification is recorded in advance as data corresponding to a model of the electronic device, or a charging specification of the battery, and the arithmetic device uses the barcode reader to store data corresponding to the type of the electronic device or the charging specification. Read from the barcode, and the arithmetic unit reads information from the barcode Wherein by controlling the charging voltage changing means consists in a battery charging system, characterized in that to generate a charging voltage corresponding to the charging voltage specification based.
According to a seventeenth aspect of the present invention, the battery charger further includes a power transmission coil, the electronic device further includes a power reception coil electromagnetically coupled to the power transmission coil, and corresponds to the charging specification. 17. The battery charging system according to claim 16, wherein charging energy is transmitted from the power transmission coil to the power receiving coil in a contactless manner, and the electronic device charges the battery with the charging energy transmitted to the power receiving coil. Exist.
The subject matter of claim 18 of the present invention is that the battery charger further comprises a contact for outputting a charging voltage corresponding to the charging specification, and the electronic device further receives the charging voltage. The battery charger transmits the charging voltage via the contact, and the electronic device charges the battery with the charging voltage transmitted via the contact. Item 17. The battery charging system according to Item 16.
According to a nineteenth aspect of the present invention, there is provided a measuring means for measuring a time from when the electronic device is set in the battery charger and charging is started, and is measured by the measuring means. An alarm signal is output when the charging is not completed even after the standard charging time of the battery that has been stored in advance corresponding to the type of the electronic device or as the charging specification has elapsed. The battery charging system according to any one of Items 16 to 18.
The gist of the invention described in claim 20 of the present invention is that the charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker. Exist.
According to a twenty-first aspect of the present invention, the battery charger includes two power transmission coils juxtaposed so that their coil winding central axes substantially coincide with each other, and the electronic device includes the electronic device. When set in the battery charger, the power receiving coil is arranged so that the coil winding center axis of the power receiving coil substantially coincides with the coil winding center axis of the power transmission coil and is sandwiched between the two power transmission coils. The battery charging system according to claim 17, wherein the battery charging system is disposed in the electronic device.
The gist of the invention described in claim 22 of the present invention is that it has positioning means capable of recognizing a position where the electronic device is set in the battery charger. The battery charging system according to claim 15, claim 17, or claim 21.
The gist of the invention described in claim 23 of the present invention is that the positioning means opposes the power transmission coil and the power reception coil so that the centers of the power transmission coil and the power reception coil are aligned when the electronic device is set in the battery charger. The battery charging system according to claim 22, wherein the battery charging system is a positioning means.
According to a twenty-fourth aspect of the present invention, the electronic device is set in the battery charger, and when charging of the battery is started, a charging voltage obtained from an output of the power receiving coil is the set. An alarm signal is output when the reference voltage corresponding to the charging voltage of the charging specification of the battery mounted on the electronic device is not satisfied. 24. The battery charging system according to any one of claim 17, claim 21, claim 22, and claim 23.
25. The battery charging system according to claim 24, wherein the gist of the invention described in claim 25 is that charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker.
The subject matter of claim 26 of the present invention is a first memory which is a rechargeable battery, a first arithmetic unit using a microcomputer, and a storage device storing a charging specification of the battery. And an RFID / IC tag communicable with a scanner IC provided in an external battery charger under the control of the first arithmetic unit.
According to a twenty-seventh aspect of the present invention, the battery unit further includes a power receiving coil electromagnetically coupled to a power transmitting coil provided in the battery charger, and the charging energy corresponding to the charging specification is 27. The battery unit according to claim 26, wherein the battery unit is configured to receive power from a power transmission coil to the power receiving coil in a non-contact manner and to charge the battery with the received charging energy.
According to a twenty-eighth aspect of the present invention, there is provided an electronic device including a rechargeable battery, and charging the rechargeable battery mounted on the electronic device by receiving AC power from a commercial power source. In the battery charging system including a battery charger, the electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first electrical device. The battery charger includes a second arithmetic unit using a microcomputer, a second memory as a storage device, a second electrical signal transmission / reception unit, Charge voltage varying means for varying the charge voltage so as to generate charge voltages corresponding to a plurality of batteries having different voltage specifications is provided, and the battery includes the battery. -Data corresponding to the charging voltage specification is stored in advance, and when the electronic device is set in the battery charger, the first arithmetic unit corresponds to the charging voltage specification stored in the first memory. The data is read out, and the data is transmitted in a non-contact manner to the second arithmetic unit via the first electrical signal transmission / reception means and the second electrical signal transmission / reception means, In the battery charging system, the second arithmetic unit that has received the data outputs a command signal so as to generate a voltage corresponding to the battery charging voltage specification to the charging voltage variable means based on the data. Exist.
According to a twenty-ninth aspect of the present invention, there is provided an electronic device having a rechargeable battery and an AC power received from a commercial power source to charge the rechargeable battery mounted on the electronic device. In the battery charging system including a battery charger, the electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first electromagnetic device. The battery charger includes a second arithmetic unit using a microcomputer, a second memory as a storage device, a second electromagnetic signal transmission / reception unit, Charging voltage changing means for changing the charging voltage so as to generate charging voltages corresponding to a plurality of batteries having different voltage specifications; -Data corresponding to the charging voltage specification is stored in advance, and when the electronic device is set in the battery charger, the first arithmetic unit corresponds to the charging voltage specification stored in the first memory. And the data is transmitted to the second arithmetic device in a non-contact manner via the first electromagnetic signal transmission / reception means and the second electromagnetic signal transmission / reception means, In the battery charging system, the second arithmetic unit that has received the data outputs a command signal so as to generate a voltage corresponding to the battery charging voltage specification to the charging voltage variable means based on the data. Exist.
According to a thirty-sixth aspect of the present invention, there is provided an electronic device including a rechargeable battery and an AC power received from a commercial power source, and charging the rechargeable battery mounted on the electronic device. In the battery charging system including a battery charger, the electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first optical device. The battery charger includes a second arithmetic unit using a microcomputer, a second memory as a storage device, a second optical signal transmission / reception unit, Charge voltage varying means for varying the charge voltage so as to generate charge voltages corresponding to a plurality of batteries having different voltage specifications is provided, and the battery includes the battery. -Data corresponding to the charging voltage specification is stored in advance, and when the electronic device is set in the battery charger, the first arithmetic unit corresponds to the charging voltage specification stored in the first memory. The data is read out, and the data is transmitted in a non-contact manner to the second arithmetic unit via the first optical signal transmission / reception unit and the second optical signal transmission / reception unit, In the battery charging system, the second arithmetic unit that has received the data outputs a command signal so as to generate a voltage corresponding to the battery charging voltage specification to the charging voltage variable means based on the data. Exist.

The present invention can perform charging corresponding to a plurality of voltage and current specifications.
Moreover, the battery specification of the electronic device to be charged can be automatically determined, and charging can be performed by automatically adjusting the charging voltage.
Moreover, this invention can be set as the structure which can respond not only to a contact type but non-contact type charging.
In addition, the present invention can automatically determine completion of charging and notify the completion of charging, and can issue an alarm when charging becomes abnormal.
Further, the charging efficiency can be increased by the charger having the sandwich structure of the present invention.

(First embodiment)
FIG. 1 shows a first embodiment of the present invention.
In FIG. 1, reference numeral 1 denotes an electronic device that needs to be charged, and for example, an electronic device such as a mobile phone, a PDA, or a Note PC. Reference numeral 2 denotes a battery charger. 3 is a communication network such as the Internet, and 4 is a radio base station.

  Reference numeral 5 denotes an antenna for wireless communication provided in the electronic device 1, which is an antenna that performs wireless communication with the wireless base station 4. Reference numeral 6 denotes an arithmetic device using a microcomputer, and reference numeral 7 denotes a memory used as a storage device for the arithmetic operation of the microcomputer, which includes a RAM, a ROM, an EEPROM as a rewritable ROM, a flash memory, or the like. A rechargeable battery 8 is used as a power source for the electronic device 1. Reference numeral 9 denotes an RFID / IC tag, which is used in combination with a scanner IC 14 described later. Here, RFID refers to an “ID system that uses a radio frequency identification system to recognize a person or an object using radio waves as a medium”. Reference numeral 10 denotes a power receiving coil for transmitting energy for charging the battery 8 by electromagnetic coupling, and is used in combination with a power transmitting coil 22 described later. Reference numeral 11 denotes an AC / DC converter that converts alternating current from the receiving coil 10 into direct current. Reference numeral 33 denotes an analog / digital converter (A / D converter) that inputs the voltage of the battery 8 or the charging voltage obtained from the AC / DC converter 11 and outputs the digital data to the arithmetic unit 6.

  Reference numeral 12 denotes an arithmetic unit using a microcomputer provided in the battery charger 2, and reference numeral 13 denotes a memory used as a storage device for the microcomputer's arithmetic operation, which is composed of RAM, ROM, rewritable EEPROM such as EEPROM or flash memory. Is done. Reference numeral 14 denotes a scanner IC, which is used in combination with the RFID / IC tag 9 described above. Here, “Scanner” refers to “an apparatus for reading / writing an RFID / IC tag”. Reference numeral 15 denotes a commercial power receiving wire. Reference numeral 16 denotes a power supply control circuit. Reference numerals 17 to 20 denote a plurality of power supply system control units prepared in accordance with the battery specifications of the electronic device 1, which are shown as four circuits here, but are not limited thereto. Reference numeral 21 denotes a DC / AC converter that converts direct current into alternating current. A power transmission coil 22 receives AC power from the DC / AC converter 21 and transmits charging energy to the power receiving coil 10 by electromagnetic coupling. 23 is an LED for displaying the state of the battery charger 2, and 24 is a speaker for notifying the state of the battery charger 2 by voice. Reference numerals 25 and 26 denote electric wires that connect the power system control units 17 to 20 and the DC / AC converter 21. Reference numeral 26 denotes a common line. Reference numerals 27 and 28 denote electric wires for connecting the AC / DC converter 11 and the battery 8. 29 is an electric wire connecting the DC / AC converter 21 and the power transmission coil 22, and 30 is an electric wire connecting the power receiving coil 10 and the AC / DC converter 11.

The operation of the battery charging system configured as described above will be described below.
The battery charging system uses the RFID / IC tag 9 and the IC 14 of the scanner, and the power transmission coil 22 and the power reception coil 10 to completely signal and charge the electronic device 1 and the battery charger 2 in an electrically non-contact state. It is designed to transmit energy. In the battery charging system, the charging voltage is variable, and this voltage is automatically set according to the battery specifications of the electronic device 1 to start charging.

  First, when charging, the electronic device 1 is set in the battery charger 2. When the electronic device 1 is set in the battery charger 2, the RFID / IC tag 9 and the IC 14 of the scanner approach each other, so that the arithmetic devices 6 and 12 detect that the electronic device 1 is set in the battery charger 2. . The memory 7 stores in advance a charging voltage specification, a charging current specification, and a standard charging time specification, which are the charging specifications of the battery 8, and the electronic device 1 is set in the battery charger 2. When detected, the arithmetic unit 6 reads the specification of the charging voltage, the specification of the charging current, and the specification of the standard charging time of the battery 8 built in the electronic device 1 stored in the memory 7. The read charging specifications are transmitted to the scanner IC 14 via the RFID / IC tag 9 in a non-contact manner. The arithmetic unit 12 sends a command to the power supply control circuit 16 according to the transmitted charging specification.

  In response to a command from the arithmetic device 12, the power supply control circuit 16 selects a voltage that meets the charging voltage specification so as to be output from any one of the power supply system control units 17 to 20. For example, when the power system controller 17 operates to output the charging voltage, the power system controllers 18 to 20 are turned off and become inoperative. As a result, the voltage from the power system controller 17 is input to the DC / AC converter 21. Moreover, when outputting the voltage of another specification, it selects so that any one of the power supply system control parts 18-20 may operate | move.

  In this way, a voltage that meets the battery charging voltage specification of the electronic device 1 is output to the electric wires 25 and 26. This voltage is converted into alternating current by the DC / AC converter 21 and applied to the power transmission coil 22. The power transmission coil 22 and the power reception coil 10 face each other in a non-contact manner, and are transmitted to the power reception coil 10 as electromagnetic energy. At this time, a voltage corresponding to the battery charging voltage specification is applied to the power transmission coil 22 and the power reception coil 10. The AC voltage from the power receiving coil 10 is converted into a DC voltage by the AC / DC converter 11, and the battery 8 connected to the output side of the AC / DC converter 11 has an appropriate voltage suitable for the charging specifications of the battery, It is charged with current.

  Here, the power transmission coil 22 and the power reception coil 10 are electromagnetically coupled, and the RFID / IC tag 9 and the scanner IC 14 are electromagnetically coupled or electromagnetically coupled. However, the electromagnetic coupling between the power transmission coil 22 and the power reception coil 10 generates a leakage magnetic flux. There is a possibility of interfering with communication between the RFID / IC tag 9 and the IC 14 of the scanner. Therefore, the frequency of the voltage applied to the power transmission coil 22 is set to a frequency band that does not interfere with the IC 14 communication frequency of the RFID / IC tag 9 and the scanner.

  The arithmetic device 6 receives data from the A / D converter 33 and monitors the voltage of the battery 8 and the charging voltage of the AC / DC converter 11. The voltage of the battery 8 is converted into a digital quantity by the A / D converter 33 and read into the arithmetic unit 6, and the charging voltage value from the AC / DC converter 11 is converted into a digital quantity by the A / D converter 33. Then, it is read into the arithmetic unit 6 as charging voltage data. Thereby, the arithmetic unit 6 detects the voltage of the battery 8 and the charging voltage.

  Here, if the electronic device 1 is correctly set in the battery charger 2, the power transmission coil 22 and the power reception coil 10 face each other at a distance capable of transmitting charging energy, and the power transmission coil 22 and the power reception coil 10 have a desired charging voltage. Although the voltage is transmitted as a voltage, the charging energy is not efficiently transmitted when the electronic device 1 is set to be shifted. Therefore, the arithmetic device 6 reads the charging voltage information from the AC / DC converter 11, compares the predetermined reference value with the charging voltage information from the AC / DC converter 11, and has the electronic device 1 been set correctly? To monitor. When the charging voltage information from the AC / DC converter 11 falls below the predetermined reference value, it is determined that the set of the electronic device 1 is shifted and an alarm signal is output. In response to this alarm signal, the LED 23 is turned on, and a notification that the set of the electronic device 1 is shifted from the speaker 24 is given by voice.

  When charging, the battery charger 2 and the electronic device 1 are marked with a mark of the coil pattern so that the relative position of the power transmission coil 22 and the power reception coil 10 can be set to face each other within a predetermined range. If it is drawn on the surface of the device 1, the positions of the power transmission coil 22 and the power reception coil 10 are known, which is convenient for setting. Further, for the positioning of the set, if an uneven fitting portion is provided in the vicinity of the center of the power transmission coil 22 and the power receiving coil 10, the positioning is facilitated. This is shown in FIG. 84 is a positioning convex part, 85 is a positioning concave part. Thus, if positioning is performed by providing an uneven fitting portion in the vicinity of the center, there is an advantage that the electronic device 1 of various sizes can be handled.

  In addition, as a charging specification, a standard charging time specification of the battery 8 is stored in the memory 7, and the arithmetic unit 12 measures the time after the charging of the battery 8 is started. The computing device 6 monitors the state of charge of the battery 8, and the monitoring result is transmitted to the computing device 12 via the RFID / IC tag 9 and the IC 14 of the scanner. Therefore, the arithmetic unit 12 can know the state of charge of the battery 8 from the start of charging. The arithmetic unit 12 outputs an error signal when the measurement time of the charging time of the battery 8 does not reach the charging completion state even if the standard value of the charging time of the battery 8 elapses. This error output turns on the LED 23 and notifies the speaker 24 of an error by voice. It should be noted that the state of completion of charging can be determined by this because the potential of the battery 8 slightly decreases after charging.

  This embodiment can be made completely non-contact electrically and does not expose contact points and the like, so that reliability can be improved by covering with resin molding. Moreover, since there is no contact by a contact point, there is an advantage that contact failure does not occur due to rust or dust.

Although not shown in FIG. 1, it is also possible to detect the charging current and detect the charging completion state.
In addition, the maximum rating of the charging current of the battery charger 2 is stored in the memory 13 and is compared with the specification value of the charging current that is the charging specification of the battery 8. When the charging current of the battery 8 exceeds, an alarm signal is output, and if the charging operation is stopped by this alarm signal, overheating and burning of the electronic device 1 and the battery charger 2 can be prevented. If the speaker 24 informs that the charging current is over, the user can recognize this.

(Second Embodiment)
In the first embodiment, the example in which the memory 7 of the electronic device 1 directly stores the charging specification of the battery mounted on the electronic device 1 has been described. May be selected from a plurality of charging specifications stored in the memory 13 on the battery charger 2 side, obtained from the electronic device 1 side. FIG. 2 shows an example of the second embodiment using a table stored in the memory 13 in this case.

  The circuit configuration of the second embodiment is the same as that of the first embodiment, but data corresponding to the model number of the electronic device 1 is stored in the memory 7 in advance, and the memory 13 stores the above data. A model number and a charging voltage specification, a charging current specification, and a charging time specification are stored as shown in the table of FIG.

  When the electronic device 1 is set in the battery charger 2 when charging, the computing devices 6 and 12 indicate that the electronic device 1 is set because the RFID / IC tag 9 and the IC 14 of the scanner approach each other. Perceive. Since the model number data corresponding to the model number of the electronic device 1 is stored in the memory 7 in advance, when it is detected that the electronic device 1 is set in the battery charger 2, the arithmetic unit 6 stores the electronic device stored in the memory 7. The model number data corresponding to the model number of the device 1 is read out. The read model number data is transmitted to the scanner IC 14 via the RFID / IC tag 9 in a non-contact manner. Based on the transmitted model number data, the arithmetic device 12 refers to the table in the memory 13 (FIG. 2) and reads the charging specification corresponding to the model number. A command is sent to the power supply control circuit 16 according to this charging specification. In response to a command from the arithmetic device 12, the power supply control circuit 16 selectively switches and connects any of the power supply system control units 17 to 20 that meet the charging specifications. Since the following operations are the same as those in the first embodiment, description thereof will be omitted.

(Third embodiment)
The circuit configuration of the third embodiment of the present invention is the same as that of the first and second embodiments, but the method for storing the battery charge specifications is different. In the second embodiment, the charging specification table shown in FIG. 2 is referred to in correspondence with the model number of the electronic device 1, but the electronic device 1 has a model number corresponding to when a new product is released. If the information on the new product is not stored in the memory 13 of the battery charger 2, the charging specification becomes unknown. Therefore, in the present embodiment, the battery charging specifications stored in the memory 13 through the communication network 3 are updated so as to always keep the latest state.

  As shown in FIG. 1, the electronic device 1 communicates with a site providing product information of the electronic device 1 via the communication network 3 and the wireless base station 4, and downloads a battery charging specification related to the electronic device 1. And stored in the memory 7. Further, the downloaded battery charging specifications regarding the electronic device 1 are stored in the memory 13 via the RFID / IC tag 9 and the IC 14 of the scanner.

  In this case, the battery charging specification may be downloaded every time the battery is charged. However, when the model number of the electronic device 1 that has already been set or the corresponding battery charging specification is stored in the memory 7 or 13, the communication line is renewed. Since there is no need to download data through the network 3, when the electronic apparatus 1 is set, it is checked whether the model number is already stored. If the model number is not stored, the speaker 24 informs the user that the model number is not stored in the memory 7 or 13, and downloads the corresponding battery charging specification via the communication network 3. Prompt.

If the model number is not stored in the memory 7 or 13, a common data format is determined so that the data downloaded through the communication network 3 is automatically stored in the memory 7 or 13. Then, the data downloaded from the communication line network 3 can be automatically stored as the table data shown in FIG. 2 of the charging specification, and further automation can be performed.
(Fourth embodiment)

  Next, a fourth embodiment of the present invention shown in FIG. 3 will be described. The fourth embodiment is different from the first to third embodiments in that the battery charging voltage is performed by contact. The same reference numerals as those in FIG. 1 denote the same elements. A different part from FIG. 1 is demonstrated mainly.

  In FIG. 3, reference numerals 43 to 46 denote electrical contacts (contacts). When the electronic device 31 is set to the battery charger 42 for charging, the contacts 43 and 45 and the contacts 44 and 46 come into contact with each other. It has become. Thereby, the electric wires 25 and 27 and the electric wires 26 and 28 are connected, and the battery 8 is charged. The charging voltage is set in the same manner as in the first to third embodiments.

In the fourth embodiment, automatic determination of battery charging specifications, error display, and the like can be performed as in the first to third embodiments except that the charging voltage is a contact type.
(Fifth embodiment)

  Next, a fifth embodiment shown in FIG. 4 will be described. As shown in FIG. 4, the circuit configuration of this embodiment is obtained by replacing the power supply system control units 17 to 20 with an analog control power supply system control unit 50 with respect to the circuit configuration of FIG. 1. The analog control power supply system controller 50 outputs a voltage that changes in an analog manner as a charging voltage, receives charging voltage information from the power supply control circuit 36, and outputs a voltage that meets the charging specifications of the battery 8. In this case, digital data is received from the power supply control circuit 36 and a voltage corresponding to the digital data is output. For example, if the digital data from the power supply control circuit 36 is 8 bits, a DC voltage that changes in 256 steps can be obtained. The number of bits of this digital data may be set so as to match the desired voltage accuracy.

  In the first to fourth embodiments, since the charging voltage changes stepwise by switching the power supply system control units 17 to 20, it is not suitable for fine adjustment of the charging voltage. The fifth embodiment Since the voltage can be changed almost continuously, it is convenient to perform voltage feedback control. That is, the arithmetic unit 6 compares the predetermined reference value with the charging voltage information from the AC / DC converter 11, and the charging voltage information from the AC / DC converter 11 is the predetermined voltage described in the description of the first embodiment. If there is an excess or deficiency with respect to the desired charging voltage, the voltage difference information is transmitted to the arithmetic unit 12 via the RFID / IC tag 9 and the scanner IC 14. The arithmetic unit 12 sends a command to the power supply control circuit 36 so as to obtain a desired charging voltage. As a result, feedback control works so that the excess and deficiency becomes 0, and the charging voltage is automatically adjusted to a desired voltage.

  Further, the fifth embodiment can keep the electronic device 1 and the battery charger 52 in a completely non-contact state. Further, in the first to fourth embodiments, a plurality of power system control units 17 to 20 are provided, and the voltage is limited to the type corresponding to the number, but according to the present embodiment, the fine voltage It can be set and can easily handle various battery specifications.

(Sixth embodiment)
Next, the sixth embodiment shown in FIG. 5 will be described. Similar to the fifth embodiment, this embodiment is configured by replacing the power supply system control units 17 to 20 with an analog control power supply system control unit 50 in the circuit configuration of FIG. The same reference numerals as those in FIG. 3 denote the same elements. A different part from FIG. 3 is demonstrated mainly.

In FIG. 5, reference numerals 43 to 46 indicate electrical contacts. When the electronic device 31 is set in the battery charger 52 for charging, the contacts 43 and 45 and the contacts 44 and 46 come into contact with each other. Thereby, the electric wires 25 and 27 and the electric wires 26 and 28 are connected, and the battery 8 is charged. The charging voltage is set in the same manner as in the first to third embodiments.
In the sixth embodiment, except for the point that the charging voltage is a contact type, as in the first to fifth embodiments, automatic determination of battery charging specifications, error display, and the like can be performed.

(Seventh embodiment)
Next, the seventh embodiment shown in FIG. 6 will be described. In the circuit configuration shown in FIG. 6, power transmission coils 64 and 65 that transmit battery charging energy are arranged opposite to the circuit configuration shown in FIG. 1 so as to sandwich the power receiving coil 10 (sandwich structure charger). ). The power transmission coils 64 and 65 are connected to the output of the DC / AC converter 21 in series. However, this connection is not limited to this and may be a parallel connection.

  The circuit operation of the seventh embodiment is basically the same as that of the first to third and fifth embodiments. However, the arrangement of the power transmission coil and the power reception coil of the seventh embodiment is different. FIG. 7 shows the arrangement of the power transmitting coil and the power receiving coil according to the first to third and fifth embodiments. On the other hand, FIG. 8 shows the arrangement of the power transmitting coil and the power receiving coil according to the seventh embodiment.

  7 and 8, reference numeral 10 denotes a power receiving coil, 22, 64 and 65 denote power transmitting coils, and 80 and 81 denote ferrite cores. Reference numerals 82 and 83 denote power transmission coil support members. The structure of FIG. 8 with respect to the structure of FIG. 7 has an effect of reducing the leakage magnetic flux between the power transmission coil and the power reception coil and increasing the power transmission efficiency. In FIG. 8, the electronic device 1 is sandwiched between battery chargers 62.

  The distance between the power transmission coils 64 and 65 of the battery charger 62 is fixed as shown in FIG. 8, but may be variable according to the size of the electronic device 1 to be sandwiched. For example, the electronic device 1 is sandwiched with elasticity by an elastic member. In this way, when the electronic device 1 is inserted between the power transmission coils 64 and 65 of the battery charger 62, the distance between the power transmission coils 64 and 65 of the battery charger 62 is expanded elastically by the elastic member. Then, after the electronic device 1 is set, the surface of the battery charger 62 can be in close contact with the surface of the electronic device 1.

(Eighth embodiment)
Next, an eighth embodiment shown in FIG. 9 will be described.
In FIG. 9, the battery charger 72 has the same circuit configuration as that of FIG. 1, but in the eighth embodiment, what is set in the battery charger 72 is not the electronic device 1 but the battery 8 of the electronic device 1. It is removed from the electronic device 1 and charged. In this case, the battery unit 71 is configured as shown in FIG. 9 instead of the battery 8 alone.

  In FIG. 9, 76 is an arithmetic unit and 77 is a memory. In the circuit of FIG. 1, the arithmetic device 6 and the memory 7 perform an operation for realizing the function of the electronic device 1, but the arithmetic device 76 and the memory 77 of the present embodiment are specialized in the function of charging the battery 8. . Therefore, the antenna 5 is not provided and the communication function with the communication network 3 is not provided.

  The memory 77 stores the battery charging specifications as in the first embodiment, or the type of the battery 8 or the electronic device on which the battery 8 is mounted as in the second embodiment. One model number is stored. Therefore, when the battery unit 71 is set in the battery charger 72, a charging voltage that automatically meets the charging specifications of the battery 8 is automatically set, as in the embodiment in which the electronic device 1 is set in the battery charger. And start charging. In this case, the battery unit 71 can be separated from the electronic device 1, and when the battery 8 of the battery unit 71 is being charged, the electronic device 1 is operated by using another battery or a DC adapter. be able to.

  The first to eighth embodiments have been described above. In the first to third, fifth, seventh, and eighth embodiments, the RFID / IC tag 9 and the scanner IC 14 are used for transmission and reception. If the frequency used is set so that the frequencies used in the power transmission coil 22 and the power reception coil 10 for charging energy transmission are different, mutual interference can be prevented.

  For example, typical frequencies used for transmission / reception between the RFID / IC tag 9 and the scanner IC 14 are 125 kHz, 13.56 MHz, and 2.45 GHz. When 13.56 MHz or 2.45 GHz is used, the frequency used by the power transmission coil 22 and the power reception coil 10 for charging energy transmission can be set to about 100 kHz.

  Further, when 125 kHz is used for transmission / reception between the RFID / IC tag 9 and the scanner IC 14, the frequency used in the power transmission coil 22 and the power reception coil 10 for charging energy transmission can be set to about 10 to 50 kHz. . At 20 kHz or less, noise generated from the power transmission coil 22 and the power receiving coil 10 approaches the audible range. Setting is preferred. In short, by separating the frequency used for transmission / reception of the RFID / IC tag 9 and the IC 14 of the scanner into frequency bands that do not interfere with the frequencies used by the power transmission coil 22 and the power reception coil 10 for charging energy transmission, Can prevent interference.

  However, considering the signal transmission speed between the RFID / IC tag 9 and the IC 14 of the scanner, 13.56 MHz or 2.45 GHz is advantageous, and the antenna of the RFID / IC tag 9 and the scanner IC 14 and the power transmission coil 22 In order to reduce the size of the power receiving coil 10, it is advantageous to select a high frequency band. If the frequency band of 13.56 MHz or 2.45 GHz is used for the operating frequency of the RFID / IC tag 9 and the scanner IC 14, the number of turns of the antenna can be reduced, and a dipole antenna or the like can be used. In this case, there are advantages such as reduction in size and design using antenna directivity. If the frequency band of 13.56 MHz or 2.45 GHz is used for the operating frequency of the RFID / IC tag 9 and the scanner IC 14, 125 kHz or 400 kHz can be used for the operating frequency of the power transmission coil 22 and the power receiving coil 10. The power transmission coil 22 and the power reception coil 10 can be downsized.

  In the above description, the electronic devices 1 and 31 that can communicate with the communication network 3 are shown, but the present invention is not limited to this. For example, even if the electronic device cannot communicate with the communication line network 3 and downloads new data as in the third embodiment, the data can be downloaded by another electronic device capable of communication. It is also possible to input the acquired data using the RFID / IC tag of the other electronic device capable of communication and the IC 14 of the scanner of the battery charger 2.

  In the above embodiment, the charging specification of the battery 8 stored in the memory 7 is transmitted to the arithmetic device 12 by transmission / reception of the RFID / IC tag 9 and the IC 14 of the scanner. However, the present invention is not limited to this. For example, in FIG. 1, instead of the RFID / IC tag 9, a barcode that records the charging specifications of the battery 8 (see FIG. 2) or the type of the electronic device 1 on the electronic device 1 side, and a barcode that replaces the IC 14 of the scanner. A bar code reader can be used. In this case, a barcode that records the charging specifications of the battery 8 or the type of the electronic device 1 is affixed to the electronic device 1, and when the electronic device 1 is set in the battery charger 2, the barcode is opposed to the barcode. The barcode can be read by the arranged barcode reader. As the barcode reader, an optical barcode reader using a laser beam or the like can be used. When the electronic device 1 is set in the battery charger 2, the barcode reader reads the barcode, and the charging specification of the battery 8 recorded in the barcode is taken into the arithmetic device 12.

  As described above, the arithmetic unit 12 can acquire the charging specification of the battery 8 by using a barcode and a barcode reader instead of the RFID / IC tag 9 and the scanner IC 14. An embodiment in which the barcode and the reading means using the barcode reader are replaced with the RFID / IC tag 9 and the IC 14 of the scanner in the first to eighth embodiments can be considered. An effect can be obtained.

  Further, the barcode / barcode reader embodiment has been described as an alternative to the RFID / IC tag 9 and the scanner IC 14, but other optical means may be used as an alternative to the RFID / IC tag 9 and the scanner IC 14. It is conceivable to use electromagnetic means and electric means, and standards for them can also be used. For example, optical signal transmission / reception means such as optical wireless and IrDA (Infrared Data Association) can also be used as means for optically transmitting information, and IEEE802.11b as means for electromagnetically transmitting information. Electromagnetic signal transmission / reception means such as .ga, Bluetooth, IEEE802.15.4 / ZigBee, UWB (Ultra Wide Band) can be used, and IEEE 802.3af, Ethernet ( Electrical signal transmission / reception means using registered trademark or the like can also be used in the same manner. Needless to say, the present invention is not limited to the examples given here, and information transmission means that can be used in the present invention are included in the embodiments of the present invention.

  Moreover, it goes without saying that the present invention is not limited to the above-described embodiments, and that the present invention includes modifications that do not depart from the spirit of the invention. 1 and 3 to 9, the electronic device and the battery charger are depicted so as not to contact each other. However, when the electronic device is set on the battery charger, a part of the outer surface of the electronic device contacts each other. Is.

  The present invention is not limited to a mobile phone, a handset of a fixed phone, a PDA, and a Note PC charger, but can be applied to a charger for an electronic device that uses a battery as a power source in other electronic devices.

The figure which shows the circuit structure of the 1st thru | or 3rd Embodiment of this invention. The figure which shows the data table of the battery charge specification in the 2nd Embodiment of this invention. The figure which shows the circuit structure of the 4th Embodiment of this invention. The figure which shows the circuit structure of the 5th Embodiment of this invention. The figure which shows the circuit structure of the 6th Embodiment of this invention. The figure which shows the circuit structure of the 7th Embodiment of this invention. The layout of the power transmission coil and power receiving coil in the 1st thru | or 3rd, 5th, 8th embodiment of this invention. The layout diagram of the power transmission coil and power receiving coil in the 7th Embodiment of this invention. The figure which shows the circuit structure of the 8th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 31 ... Electronic device 2, 42, 52, 62, 72 ... Battery charger 3 ... Communication network 4 ... Wireless base station 5 ... Antenna 6, 12, 76 ... Arithmetic devices 7, 13, 77 ... Memory 8 ... Battery 9 ... RFID / IC tag 10 ... Receiving coil 11 ... AC / DC converter 14 ... Scanner IC
15 ... Receiving wire (for commercial power supply)
16, 36 ... Power control circuits 17-20 ... Power system controller 21 ... DC / AC converters 22, 64, 65 ... Power transmission coil 23 ... LED
24 ... Speakers 25-30, 67 ... Electric wire 33 ... A / D converters 43-46 ... Electrical contacts 50 ... Analog control power system controller 71 ... Battery unit 80 81 ... Ferrite cores 82, 83 ... Power transmission coil support member 84 ... Positioning convex part 85 ... Positioning concave part

Claims (30)

In a battery charger that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device,
The battery charger includes a charging voltage varying unit that automatically varies a charging voltage so as to generate a charging voltage corresponding to a plurality of batteries having different voltage specifications. The charging voltage varying means is
A plurality of power system control units that generate different voltages corresponding to the battery charge voltage specifications;
Power control means for automatically determining the electronic device set in the battery charger and selecting and operating a power system controller that generates a voltage corresponding to the battery charge voltage specification from the plurality of power system controllers The battery charger according to claim 1, wherein the battery charger is provided. The charging voltage varying means is
A power supply system controller that generates a variable voltage corresponding to the battery charge voltage specification;
The power supply control means for automatically discriminating the electronic device set in the battery charger and outputting data for generating a voltage corresponding to the battery charge voltage specification to the power supply system control unit. The battery charger according to claim 1. An electronic device with a rechargeable battery,
In a battery charging system comprising a battery charger that receives AC power from a commercial power source and charges the rechargeable battery mounted on the electronic device,
The electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and an RFID / IC tag,
The battery charger generates a charging voltage corresponding to a plurality of batteries having different voltage specifications and a second arithmetic device using a microcomputer, a second memory as a storage device, a scanner IC, and the like. A charging voltage varying means for varying the charging voltage is provided,
In the first memory, data corresponding to the battery charging voltage specification is stored in advance,
When the electronic device is set in the battery charger,
The first arithmetic unit reads data corresponding to the charging voltage specification stored in the first memory, and the data is transferred to the second arithmetic unit via the RFID / IC tag and the scanner IC. Send without contact,
The second arithmetic unit that has received the data outputs a command signal to the charging voltage variable means so as to generate a voltage corresponding to the battery charging voltage specification based on the data. . An electronic device with a rechargeable battery,
In a battery charging system comprising a battery charger that receives AC power from a commercial power source and charges the rechargeable battery mounted on the electronic device,
The electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and an RFID / IC tag,
The battery charger generates a charging voltage corresponding to a plurality of batteries having different voltage specifications and a second arithmetic device using a microcomputer, a second memory as a storage device, a scanner IC, and the like. A charging voltage varying means for varying the charging voltage is provided,
In the first memory, data corresponding to the type of the electronic device is stored in advance,
In the second memory, data corresponding to the type of the electronic device and the battery charging voltage specification are stored in advance,
When the electronic device is set in the battery charger,
The first arithmetic unit reads out data corresponding to the type stored in the first memory, and the data is not contacted with the second arithmetic unit via the RFID / IC tag and the scanner IC. Send in
The second arithmetic unit that has received the data reads a charging voltage specification corresponding to the model from the second memory based on the data,
The second arithmetic unit outputs a command signal to the charging voltage variable means to generate a voltage corresponding to the battery charging voltage specification based on the read charging voltage specification. system. In a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device,
An electronic device equipped with the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and an RFID / IC tag;
A battery charger equipped with a second computing device using a microcomputer, a second memory as a storage device, a scanner IC, and a charging voltage varying means for varying the charging voltage;
In the first memory, data corresponding to the type of the electronic device, or at least a charging voltage specification as a charging specification of the battery is stored in advance.
The first arithmetic unit reads out data corresponding to a model of the electronic device or the charging specification from the first memory, and contacts the second without contact via the RFID / IC tag and the IC of the Scanner. And the second arithmetic device controls the charging voltage varying means based on the data corresponding to the type of the electronic device, or the charging specification, A battery charging system for generating a charging voltage corresponding to the charging voltage specification. The battery charger further includes a power transmission coil,
The electronic device further includes a power receiving coil electromagnetically coupled to the power transmitting coil,
The charging energy corresponding to the charging specification is transmitted from the power transmission coil to the power receiving coil in a contactless manner, and the electronic device charges the battery with the charging energy transmitted to the power receiving coil. The battery charging system described in. The battery charger further includes a contact for outputting a charging voltage corresponding to the charging specification,
The electronic device further includes a contact for receiving the charging voltage,
The charging voltage is transmitted from the battery charger to the electronic device through the contact, and the electronic device charges the battery with the charging voltage transmitted through the contact. 6. The battery charging system according to 6. The battery charging system according to claim 6, wherein the electronic device downloads data corresponding to the charging specification via a communication network and stores the data in the first memory. The electronic device has a measuring unit that measures the time from when the battery charger is set and charging is started, and the time measured by the measuring unit is stored in the first or second memory as the charging specification. 10. The battery charging system according to claim 6, wherein an alarm signal is output when charging is not completed even after the stored standard charging time of the battery elapses. 11. The battery charging system according to claim 10, wherein charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker. The charging voltage of the battery is detected, the detected charging voltage value is compared with a predetermined value, and feedback control is performed so that the charging voltage becomes a predetermined value. Battery charging system. The battery charger includes two power transmission coils juxtaposed so that their coil winding center axes are substantially aligned, and when the electronic device is set in the battery charger, the coil winding center of the power receiving coil The power receiving coil is disposed in the electronic device so that an axis substantially coincides with a coil winding center axis of the power transmission coil and is sandwiched between the two power transmission coils. Battery charging system. In a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device,
A battery unit including the rechargeable battery, a first arithmetic unit using a microcomputer, a first memory as a storage device, and an RFID / IC tag;
A battery charger equipped with a second computing device using a microcomputer, a second memory as a storage device, a scanner IC, and a charging voltage varying means for varying the charging voltage;
The first arithmetic device reads out the battery charging specifications stored in advance from the first memory, and transmits them to the second arithmetic device in a non-contact manner via the RFID / IC tag and the scanner IC. The second arithmetic unit controls the charging voltage varying means to generate a charging voltage corresponding to the charging specification. The battery charger further includes a power transmission coil,
The battery unit further includes a power receiving coil electromagnetically coupled to the power transmitting coil,
15. The charging energy corresponding to the charging specification is transmitted from the power transmission coil to the power receiving coil in a contactless manner, and the battery unit charges the battery with the charging energy transmitted to the power receiving coil. The battery charging system described in. In a battery charging system that receives AC power from a commercial power source and charges a rechargeable battery mounted on an electronic device,
An electronic device comprising the rechargeable battery and a barcode;
A computing device using a microcomputer, a memory as a storage device, a barcode reader, and a battery charger equipped with a charging voltage varying means for varying the charging voltage,
In the barcode, data corresponding to the type of the electronic device, or at least a charging voltage specification is recorded in advance as a charging specification of the battery,
The arithmetic device reads the data corresponding to the type of the electronic device or the charging specification from the barcode by the barcode reader, and the arithmetic device uses the charging voltage variable means based on the information read from the barcode. A battery charging system that controls to generate a charging voltage corresponding to the charging voltage specification. The battery charger further includes a power transmission coil,
The electronic device further includes a power receiving coil electromagnetically coupled to the power transmitting coil,
The charging energy corresponding to the charging specification is transmitted from the power transmission coil to the power receiving coil in a contactless manner, and the electronic device charges the battery with the charging energy transmitted to the power receiving coil. The battery charging system described in. The battery charger further includes a contact for outputting a charging voltage corresponding to the charging specification,
The electronic device further includes a contact for receiving the charging voltage,
The battery charger according to claim 16, wherein the battery charger transmits the charging voltage via the contact, and the electronic device charges the battery using the charging voltage transmitted via the contact. Battery charging system. The electronic device has a measuring unit that measures a time from when the battery charger is set and charging is started, and the time measured by the measuring unit corresponds to the type of the electronic device or the charging 19. The battery charging system according to claim 16, wherein an alarm signal is output when charging is not completed even after a standard charging time of the battery stored in advance as a specification has elapsed. The battery charging system according to claim 19, wherein charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker. The battery charger includes two power transmission coils juxtaposed so that their coil winding center axes are substantially aligned, and when the electronic device is set in the battery charger, the coil winding center of the power receiving coil 18. The power receiving coil is disposed in the electronic device so that an axis substantially coincides with a coil winding center axis of the power transmission coil and is sandwiched between the two power transmission coils. Battery charging system. The battery according to any one of claims 7, 13, 15, 17, and 21, further comprising positioning means capable of recognizing a position where the electronic device is set in the battery charger. Charging system. 23. The battery charging according to claim 22, wherein the positioning means is positioning means for making the power transmitting coil and the power receiving coil face each other when the electronic device is set in the battery charger. system. When the electronic device is set in the battery charger and charging of the battery is started, the charging voltage obtained from the output of the power receiving coil is the charging voltage of the charging specification of the battery mounted on the set electronic device. An alarm signal is output when the reference voltage corresponding to the above is not satisfied. Any one of claims 7, 13, 15, 17, 17, 21, 22, and 23. The battery charging system according to the above 25. The battery charging system according to claim 24, wherein charging is stopped by the alarm signal, and an alarm is displayed by an LED or a voice is notified by a speaker. A rechargeable battery, a first arithmetic device using a microcomputer, a first memory that is a storage device storing the charging specifications of the battery, and an external battery charger under the control of the first arithmetic device A battery unit comprising an RFID / IC tag capable of communicating with a scanner IC provided in the device. The battery unit further includes a power reception coil electromagnetically coupled to a power transmission coil provided in the battery charger,
27. The battery according to claim 26, wherein charging energy corresponding to the charging specification is received from the power transmission coil to the power receiving coil in a non-contact manner, and the battery is charged with the received charging energy. unit. An electronic device with a rechargeable battery,
In a battery charging system comprising a battery charger that receives AC power from a commercial power source and charges the rechargeable battery mounted on the electronic device,
The electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first electrical signal transmission / reception means,
The battery charger supports a second arithmetic unit using a microcomputer, a second memory as a storage device, a second electrical signal transmission / reception means, and a plurality of batteries having different voltage specifications. Charging voltage varying means for varying the charging voltage so as to generate a charged voltage,
In the first memory, data corresponding to the battery charging voltage specification is stored in advance,
When the electronic device is set in the battery charger,
The first arithmetic unit reads data corresponding to a charging voltage specification stored in the first memory, and reads the data from the first electrical signal transmission / reception unit and the second electrical signal. Non-contact transmission to the second arithmetic unit via the signal transmission / reception means,
The second arithmetic unit that has received the data outputs a command signal to the charging voltage variable means so as to generate a voltage corresponding to the battery charging voltage specification based on the data. . An electronic device with a rechargeable battery,
In a battery charging system comprising a battery charger that receives AC power from a commercial power source and charges the rechargeable battery mounted on the electronic device,
The electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first electromagnetic signal transmission / reception means,
The battery charger supports a second arithmetic unit using a microcomputer, a second memory as a storage device, a second electromagnetic signal transmission / reception means, and a plurality of batteries having different voltage specifications. Charging voltage varying means for varying the charging voltage so as to generate a charged voltage,
In the first memory, data corresponding to the battery charging voltage specification is stored in advance,
When the electronic device is set in the battery charger,
The first arithmetic unit reads data corresponding to a charging voltage specification stored in the first memory, and reads the data from the first electromagnetic signal transmission / reception means and the second electromagnetic signal. Non-contact transmission to the second arithmetic unit via the signal transmission / reception means,
The second arithmetic unit that has received the data outputs a command signal to the charging voltage variable means so as to generate a voltage corresponding to the battery charging voltage specification based on the data. . An electronic device with a rechargeable battery,
In a battery charging system comprising a battery charger that receives AC power from a commercial power source and charges the rechargeable battery mounted on the electronic device,
The electronic device includes the rechargeable battery, a first arithmetic device using a microcomputer, a first memory as a storage device, and a first optical signal transmission / reception means,
The battery charger supports a second arithmetic unit using a microcomputer, a second memory as a storage device, a second optical signal transmission / reception means, and a plurality of batteries having different voltage specifications. Charging voltage varying means for varying the charging voltage so as to generate a charged voltage,
In the first memory, data corresponding to the battery charging voltage specification is stored in advance,
When the electronic device is set in the battery charger,
The first arithmetic unit reads data corresponding to a charging voltage specification stored in the first memory, and reads the data from the first optical signal transmission / reception unit and the second optical signal. Non-contact transmission to the second arithmetic unit via the signal transmission / reception means,
The second arithmetic unit that has received the data outputs a command signal to the charging voltage variable means so as to generate a voltage corresponding to the battery charging voltage specification based on the data. .

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