JP2011155755A - Charging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a charging device which can efficiently charge a plurality of portable terminal devices while suppressing an introduction expense. <P>SOLUTION: A CPU 11 acquires the remaining voltages of secondary batteries 40 of the portable terminal devices 2 connected to a connection part 4 at each prescribed time T. The CPU 11 decides one portable terminal device 2 which satisfies a prescribed condition related to the remaining voltages on the basis of the acquired remaining voltages of the secondary batteries 40. Then, the CPU 11 electrically connects the secondary battery 40 of the decided one portable terminal device 2 with a power feed part 30, allows the one portable terminal device 2 to feed power via the power feed part 30 in preference to the other portable terminal device 2, and charges the secondary batteries 40. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a charging device that charges a plurality of portable terminal devices.

  Conventionally, when charging a plurality of portable terminal devices at once, it is known to use a charging device such as a charging station (see, for example, Patent Documents 1 and 2). Further, when the number of mobile terminal devices to be charged is large, a charging device corresponding to the number of mobile terminal devices and a table tap corresponding to the charging device are required.

  Patent Document 1 discloses a charging station that charges a plurality of portable terminal devices and calculates a charge related to charging and displays the charge on a display unit when charging is completed. Patent Document 2 discloses a device capable of charging a plurality of portable terminal devices.

JP 10-32639 A JP 2002-063645 A

  However, when the number of portable terminal devices is large, the table tap itself becomes large in size to charge the number of portable terminal devices, and the introduction cost increases accordingly. Moreover, the charging devices as shown in Patent Documents 1 and 2 are expensive, and when charging a large number (for example, 30) of portable terminal devices with the above-described charging device, table tap, or the like, charging is performed. The power consumed by the device and the table tap increases, and the efficiency during charging may be deteriorated.

  An object of the present invention is to provide a charging device that efficiently charges a plurality of portable terminal devices while suppressing introduction costs.

  In order to solve the above problems, a charging device according to the present invention is configured to connect a plurality of portable terminal devices each having a secondary battery, and to supply power to the secondary battery of the portable terminal device connected to the connection unit. A power supply unit that supplies and charges the battery, an acquisition unit that acquires a remaining voltage of the secondary battery of the mobile terminal device connected to the connection unit, and the secondary battery acquired by the acquisition unit One portable terminal device satisfying a predetermined condition relating to the remaining voltage is determined based on the remaining battery voltage, and the determined secondary battery of the one portable terminal device is electrically connected to the power supply unit. The secondary battery of the one mobile terminal device includes a control unit that supplies power by the power supply unit in preference to the other mobile terminal devices.

  In addition, the charging device includes a wireless communication unit that performs wireless communication with the plurality of mobile terminal devices in conformity with a predetermined wireless standard, and the acquisition unit is connected to each of the plurality of mobile terminal devices by the wireless communication unit. It is preferable to acquire the remaining voltage of the secondary battery every predetermined period.

  Further, the mobile terminal device satisfying the predetermined condition is a mobile terminal device having a secondary battery in which the lowest remaining voltage of the secondary batteries acquired by the acquiring unit is acquired. Is preferred.

  Moreover, it is preferable that the said control part makes the said one portable terminal device satisfy | fill the said predetermined condition supply electric power by the said electric power supply part to the voltage which the said one portable terminal device can perform a predetermined | prescribed function.

  Moreover, it is preferable that the said control part makes the said one portable terminal device which satisfy | fills the said predetermined | prescribed condition supply electric power by the said electric power supply part until the secondary battery of the said one portable terminal device becomes a full charge.

  In addition, the control unit includes a time from when each of the plurality of mobile terminal devices is connected to the connection unit until the connection is released, and a secondary of each of the plurality of mobile terminal devices acquired by the acquisition unit. It is preferable to change the predetermined period based on the remaining voltage of the battery.

  A first mode in which the power supply unit supplies power to the one mobile terminal device that satisfies the predetermined condition up to a voltage at which the one mobile terminal device can execute a predetermined function; A second mode in which the power supply unit supplies power to the one portable terminal device that satisfies the predetermined condition within a specified period that is specified in advance; and the one portable terminal device that satisfies the predetermined condition It is preferable that the third mode in which power is supplied by the power supply unit until the secondary battery of the one mobile terminal device is fully charged can be set.

  Moreover, it is preferable that the said control part transmits the control information for charging the said 1 portable terminal device which satisfy | fills the said predetermined condition with a charging device to the said 1 portable terminal device by the said wireless communication part.

  Further, the acquisition unit acquires user information in each of the plurality of portable terminal devices by the wireless communication unit, and the control unit changes the predetermined period based on the user information acquired by the acquisition unit. It is preferable to do.

  In addition, the acquisition unit sets the remaining voltage of the secondary battery in each of the plurality of mobile terminal devices by the wireless communication unit in a state where the connection between the connection unit and the plurality of mobile terminal devices is released. And the control unit, based on the remaining voltage of the secondary battery acquired by the acquiring unit, one or more of the remaining voltage of the secondary battery does not exceed a predetermined threshold It is preferable that the mobile terminal device is determined, and the wireless communication unit transmits information for the predetermined one or more mobile terminal devices to perform predetermined notification to the one or more mobile terminal devices.

  ADVANTAGE OF THE INVENTION According to this invention, the charging device which charges a some portable terminal device efficiently can be provided, suppressing introduction expense.

It is the schematic of the charging device which is 1st Embodiment of the charging device which concerns on this invention. It is a block diagram which shows the internal structure of the charging device of 1st Embodiment. It is a graph which shows the relationship between the electric quantity (battery remaining amount) of a secondary battery, and the residual voltage of a secondary battery. It is a figure which shows the internal structure of a charging device and a portable terminal device. It is a flowchart shown about the process of the standard mode by CPU of 1st Embodiment. It is a flowchart shown about the process of the time restriction designation | designated mode by CPU of 1st Embodiment. It is a flowchart shown about the process of the full charge designation | designated mode by CPU of 1st Embodiment. It is a block diagram which shows the internal structure of the charging device of 2nd Embodiment. It is a flowchart shown about the process of the standard mode by CPU of 2nd Embodiment. It is a flowchart shown about the process of the time restriction designation | designated mode by CPU of 2nd Embodiment. It is a flowchart shown about the process of the full charge designation | designated mode by CPU of 2nd Embodiment.

<First Embodiment>
Hereinafter, preferred embodiments of the present invention will be described. FIG. 1 is a schematic diagram of a charging device 1 that is a first embodiment of a charging device according to the present invention.
As shown in FIG. 1, the charging device 1 includes a connection unit 4 (4a, 4b, 4c,... 4j), an LED 5 (5a, 5b, 5c,... 5j), a changeover switch 6, and an LED 7a. , 7b, 7c and an AC adapter 8.

  Hereinafter, as for the connection unit 4 and the LED 5 shown in FIG. 1, the connection unit 4a and the LED 5a will be described as typical examples, but the same applies to the connection units 4b, 4c,... 4j and the LEDs 5b, 5c,. It is a configuration.

The connection part 4a connects with the portable terminal device 2a via the cable 3a. Specifically, one end side of the cable 3a is connected to the connection portion 4a, and the other end side of the cable 3a is connected to the mobile terminal device 2a.
The LED 5a lights up when charging of the mobile terminal device 2a is started, and notifies that the mobile terminal device 2a is being charged. Then, the LED 5a is turned off when the charging of the mobile terminal device 2a is completed or not charged.

  The changeover switch 6 is a switch for changing over a standard mode, a time limit designation mode, and a full charge designation mode, which will be described later. The changeover switch 6 is constituted by, for example, a slide switch, a push switch, or the like.

The LEDs 7a, 7b, and 7c light up corresponding to the standard mode, the time limit designation mode, and the full charge designation mode, respectively. Specifically, the LED 7 a is turned on when the standard mode is selected by the changeover switch 6, the LED 7 b is turned on when the time limit designation mode is selected by the changeover switch 6, and the LED 7 c is turned on by the changeover switch 6. Lights when full charge designation mode is selected. Thereby, it can be notified to the user which mode is designated among the standard mode, the time limit designation mode, and the full charge designation mode.
The AC adapter 8 is connected to an external power source and supplies power to the charging device 1 main body.

FIG. 2 is a block diagram illustrating an internal configuration of the charging device 1 according to the first embodiment.
As illustrated in FIG. 2, the charging device 1 includes a connection unit 4 (4a, 4b, 4c,... 4j), a changeover switch 6, LEDs 7a, 7b, and 7c, an AC adapter 8, and a power input terminal 9. And a control IC 10, a regulator 19, a switching unit 20, and a current detection resistor Rd. In addition, the AC adapter 8 and the power input terminal 9 constitute a power supply unit 30.

  In the following description, when describing the overall configuration, expressions such as the mobile terminal device 2, the connection unit 4, and the LED 5 are used. When describing individual configurations, the mobile terminal device 2a and the connection unit 4a are used. The expression such as LED 5a is used.

  The AC adapter 8 has a positive terminal 81 and a negative terminal 82, and the power input terminal 9 has a positive terminal 91 and a negative terminal 92. Then, the positive terminal 81 and the positive terminal 91 are connected, and the negative terminal 82 and the negative terminal 92 are connected, so that power from an external power source (not shown) is supplied to the main body of the charging device 1.

  The regulator 19 receives power (voltage) supplied from the power input terminal 9, converts the input voltage to a constant voltage VDD, and outputs the voltage to the control IC 10.

  The control IC 10 is a circuit that controls the entire charging device 1. The control IC 10 includes a CPU 11 (acquisition unit, control unit), a RAM 12, a ROM 13, an ADC (AD converter) 14, a current amplifier 15, a voltage amplifier 16, a selector 17, a switch SW12, and a switch SW13. With.

In the RAM 12, for example, the remaining voltage of each of the plurality of portable terminal devices 2 connected to the connection unit 4 is amplified by the voltage amplifier 16, and the value digitally converted by the ADC 14 is stored.
The ROM 13 stores, for example, information on the specified voltage in the standard mode and information such as the student's school leaving time.

  The current amplifier 15 amplifies the current flowing through the current detection resistor Rd in a state where any one of the switches SW1, SW2,. The ADC 14 digitally converts the current amplified by the current amplifier 15 and supplies it to the CPU 11. That is, the CPU 11 detects that the mobile terminal device 2 is connected to the connection unit 4 based on a change in the current amplified by the current amplifier 15.

  The voltage amplifier 16 amplifies the remaining voltage of each of the plurality of mobile terminal devices 2 and supplies the amplified residual voltage to the ADC 14. The ADC 14 digitally converts the amplified remaining voltage and supplies it to the CPU 11. Thereby, the CPU 11 can acquire the remaining voltage in the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4.

  When the switch 6 is operated and the terminal 18a and the terminal 18b are connected by the switch 6, the CPU 11 sets the standard mode. Similarly, when the switch 6 is operated and the terminal 18b and the terminal 18c are connected by the switch 6, the CPU 11 sets the time limit designation mode. In addition, when the switch 6 is operated and the terminal 18c and the terminal 18d are connected by the switch 6, the CPU 11 sets the full charge designation mode.

  Further, when the standard mode is set, the CPU 11 turns on the LED 7a. Similarly, the CPU 11 lights the LED 7b when the time limit designation mode is set, and lights the LED 7c when the full charge designation mode is set.

  The selector 17 turns on one of the switches SW1, SW2,... SW10 in the switching unit 20 according to the control of the CPU 11. For example, when the switch SW1 is turned on, the selector 17 turns off the switches other than the switch SW1 (SW2... SW10). Note that all of the switches W1, SW2,.

The connection unit 4 includes a positive terminal and a negative terminal that are connected to the mobile terminal device 2.
Specifically, the connecting part 4a has a positive terminal 41 connected to the positive terminal 31 of the mobile terminal device 2a, and has a negative terminal 42 connected to the negative terminal 32 of the mobile terminal device 2a. The connection portion 4b, the connection portion 4c,... Have the same configuration, the connection portion 4b has a positive electrode terminal 43 and a negative electrode terminal 44, and the connection portion 4c has a positive electrode terminal 45 and a negative electrode terminal 46. .

The switching unit 20 includes switches SW1, SW2, SW3... SW10, LEDs 5a, 5b, 5c... 5j, and resistors R1, R2, R3.
The switching unit 20 electrically connects one mobile terminal device 2 and the connection unit 4 among the plurality of mobile terminal devices 2 under the control of the control IC 10 (CPU 11), so that two of the one mobile terminal devices 2 are connected. Electric power is supplied to the secondary battery 40 through the power input terminal 9.

  For example, in the switching unit 20, when the switch 17 is turned on by the selector 17, the positive terminal 91 of the power input terminal 9, the positive terminal 41 of the connection unit 4a, and the positive terminal 31 of the mobile terminal device 2a are in a conductive state. And the negative electrode terminal 42 of the connection part 4a and the negative electrode terminal 32 of the portable terminal device 2a will be in a conduction | electrical_connection state. Thereby, electric power is supplied with respect to the secondary battery 40a of the portable terminal device 2a by the power input terminal 9, and the secondary battery 40a is charged.

  Since the LED 5a and the resistor R1 are connected in series between the signal line connecting the positive terminal 91 and the switch SW1 and the signal line connecting the switch SW1 and the selector 17, the switch SW1 is turned on by the selector 17. When the state is set, the LED 5a is turned on.

Here, since the charging device 1 can connect a plurality of mobile terminal devices 2, for example, the mobile terminal device 2 owned by many users such as a school can be connected.
For example, when the charging device 1 of the present embodiment is used at school, the remaining voltage in the secondary battery 40 (see FIG. 4) of the mobile terminal device 2 is preferably fully charged, but the minimum required remaining The amount voltage is sufficient if the amount necessary for the student who owns the mobile terminal device 2 to go home is secured.

Thus, as a result of examinations by the present inventors, it has been found that the remaining voltage required when the student returns home is an amount that can make a one-hour call and a 20-minute buzzer. The amount of electricity that the mobile terminal device 2 needs for a one-hour call is 200 mA × 1 hour (1 h) = 200 mAh. In addition, the amount of electricity required for ringing the buzzer for 20 minutes is 400 mA × 1/3 hour (1/3 h) ≈133 mAh.
Therefore, the amount of electricity required when the student returns home is 200 mAh + 133 mAh = 333 mAh.

FIG. 3 is a graph showing the relationship between the amount of electricity (remaining battery level) of the secondary battery 40 and the remaining voltage of the secondary battery 40 when the AC adapter 8 supplies a current of 600 mA.
As shown in FIG. 3, the remaining voltage of the secondary battery 40 is 3.8 V at the amount of electricity 333 mAh required when the student returns home. That is, the remaining voltage of the secondary battery 40 required when the student returns home is 3.8V. Note that the remaining voltage when the secondary battery 40 of the mobile terminal device 2a is fully charged is 4.2V.

FIG. 4 is a diagram illustrating an internal configuration of the charging device 1 and the mobile terminal device 2a in FIG. As shown in FIG. 4, the mobile terminal device 2a includes a positive terminal 21, a negative terminal 22, a diode D1, a resistor R21, a transistor switch TR, and a secondary battery 40a.
In addition, the diode D1, the resistor R21, and the transistor switch TR constitute a charging circuit 50.

  The voltage loss at the diode D1 in the charging circuit 50 of the mobile terminal device 2a is about 0.19V, the voltage loss at the resistor R21 is about 0.06V, and the voltage loss at the transistor switch TR is The loss is about 0.05V. Therefore, in consideration of the loss in the mobile terminal device 2, the voltage supplied from the charging device 1 to the mobile terminal device 2 is 3.8V + 0.19V + 0.06V + 0.05V = 4.1V. Therefore, in order for the remaining voltage of the secondary battery to be 3.8 V, the specified voltage supplied from the charging device 1 to the mobile terminal device 2 is set to 4.1 V in consideration of the loss in the mobile terminal device 2. There is a need.

  Next, the operation | movement at the time of charging the portable terminal device 2 with the charging device 1 of this embodiment is demonstrated.

  First, in a state where a plurality of mobile terminal devices 2 are connected to the connection unit 4, the CPU 11 sets the remaining voltage of the secondary battery 40 of each mobile terminal device 2 connected to the connection unit 4 at a predetermined time T. To get to. CPU11 determines the one portable terminal device 2 which satisfy | fills the predetermined condition regarding a residual voltage based on each acquired residual voltage of the secondary battery 40. FIG.

Then, the CPU 11 electrically connects the determined secondary battery 40 of the one portable terminal device 2 and the power supply unit 30 to connect the secondary battery 40 of the one portable terminal device 2 to another portable terminal device. Power is supplied by the power supply unit 30 in preference to 2, and the secondary battery 40 is charged.
Here, the portable terminal device 2 that satisfies the predetermined condition regarding the remaining voltage has the secondary battery 40 that has acquired the lowest remaining voltage among the remaining voltages of the secondary battery 40 acquired by the CPU 11. The terminal device 2 is preferable.

  Specifically, for example, in a state where a plurality of portable terminal devices 2a, 2b, and 2c are connected to the connection portions 4a, 4b, and 4c, the CPU 11 uses the selector 17 to select one of the switches SW1, SW2,. One is sequentially turned on, and the remaining voltage of each of the secondary batteries 40a, 40b, 40c of the mobile terminal devices 2a, 2b, 2c connected to the connection units 4a, 4b, 4c is set at a predetermined time T. Acquired and stored in the RAM 12.

The CPU 11 compares the remaining voltage of each of the secondary batteries 40a, 40b, 40c stored in the RAM 12, and determines the portable terminal device 2 having the secondary battery 40 from which the lowest remaining voltage is acquired as the remaining voltage. Is determined to be one portable terminal device 2 that satisfies a predetermined condition.
For example, when the remaining voltage of the secondary battery 40a is the lowest, the CPU 11 determines that the portable terminal device 2a having the secondary battery 40a is one portable terminal device 2 that satisfies a predetermined condition regarding the remaining voltage. decide.

  Then, the CPU 11 electrically connects the determined secondary battery 40a of the mobile terminal device 2a and the power supply unit 30, and gives priority to the secondary battery 40a of the mobile terminal device 2a over the other mobile terminal devices 2. Then, the power supply unit 30 supplies power to charge the secondary battery 40a.

  Once the CPU 11 starts charging the secondary battery 40a, it may continuously charge the secondary battery 40a until the secondary battery 40a is fully charged (4.2V) or the standard voltage (4.1V). Or you may charge after performing the following processes.

  That is, after the charging of the secondary battery 40a is started, the CPU 11 acquires the remaining voltage of the secondary batteries 40a, 40b, and 40c every predetermined time T and stores it in the RAM 12 when the predetermined period T elapses. Let

Next, the CPU 11 compares the remaining voltages of the secondary batteries 40a, 40b, and 40c stored in the RAM 12, and when the remaining voltage of the secondary battery 40b is the lowest, the CPU 11 is charged. In addition, the mobile terminal device 2b having the secondary battery 40b, not the mobile terminal device 2a having the secondary battery 40a, is determined to be one mobile terminal device 2 that satisfies a predetermined condition regarding the remaining voltage.
Then, the CPU 11 electrically connects the determined secondary battery 40b of the one portable terminal device 2b and the power supply unit 30, and connects the secondary battery 40b of the one portable terminal device 2b to another portable terminal device. Power is supplied by the power supply unit 30 in preference to 2, and the secondary battery 40b is charged.

  As described above, according to the charging device 1 of the first embodiment, the CPU 11 satisfies a predetermined condition related to the remaining voltage based on the remaining voltage of each of the secondary batteries 40 acquired every predetermined time T. Mobile terminal device 2 is determined. Then, the CPU 11 electrically connects the determined secondary battery 40 of the one portable terminal device 2 and the power supply unit 30 to connect the secondary battery 40 of the one portable terminal device 2 to another portable terminal device. Power is supplied by the power supply unit 30 in preference to 2, and the secondary battery 40 is charged. Thereby, the charging device 1 can determine the portable terminal device 2 which should be charged according to the residual voltage of each secondary battery 40 acquired for every predetermined period T.

  Therefore, the charging device 1 can charge the secondary batteries 40 of the plurality of mobile terminal devices 2 to an equal remaining voltage. Furthermore, since the single charging device 1 can charge a large number of portable terminal devices 2, the portable terminal device 2 can be efficiently charged while suppressing the introduction cost.

  In addition, the charging device 1 replaces the portable terminal device 2 that satisfies the predetermined condition regarding the remaining voltage with the secondary battery having the lowest remaining voltage among the remaining voltages of the secondary battery 40 acquired by the CPU 11. The mobile terminal device 2 having 40 is assumed. For this reason, the charging device 1 can more preferably charge the secondary batteries 40 of the plurality of mobile terminal devices 2 to an equal remaining voltage.

  Moreover, it is preferable that the predetermined period T is a period shorter than the time when the remaining voltage of the secondary battery 40 is fully charged from 0V. Thereby, the charging device 1 can more preferably charge the secondary batteries 40 of the plurality of portable terminal devices 2 to an equal remaining voltage.

  In addition, the CPU 11 causes the power supply unit 30 to supply power to one mobile terminal device 2 that satisfies a predetermined condition regarding the remaining voltage, to a voltage at which the one mobile terminal device 2 can execute a predetermined function. Here, the voltage capable of executing the predetermined function is, for example, a voltage (3.8 V) required when the student returns home as described above.

  That is, the CPU 11 supplies the power to the one portable terminal device 2 that satisfies the predetermined condition regarding the remaining voltage by the power supply unit 30 up to the above-described specified voltage 4.1 V, so that the remaining voltage of the secondary battery 40 is increased. Can be set to a voltage (3.8 V) required when the student returns home.

  In addition, the CPU 11 causes one power supply unit 30 to supply power to one mobile terminal device 2 that satisfies a predetermined condition regarding the remaining voltage until the secondary battery 40 of the one mobile terminal device 2 is fully charged. Also good. Thereby, the charging device 1 can charge the one portable terminal device 2 which satisfy | fills the predetermined condition regarding residual voltage to a full charge.

  Further, the CPU 11 determines the time from when each of the plurality of mobile terminal devices 2 is connected to the connection unit 4 until the connection is released, and the remaining secondary battery 40 of each of the plurality of mobile terminal devices 2 acquired by the CPU 11. The predetermined period T may be changed based on the quantity voltage.

  Specifically, the ROM 13 stores the time when the student leaves the school in advance, and the CPU 11 uses a timer (not shown) built in the CPU 11 to connect each of the plurality of mobile terminal devices 2 to the connection unit. The time connected to 4 is acquired. Next, the CPU 11 calculates a time during which the mobile terminal device 2 can be charged from the acquired time and the time stored in the ROM 13 when the student leaves the school.

  Then, when the chargeable time is shorter than the preset charge time, and the remaining voltage of the secondary battery 40 does not reach the specified voltage (4.1 V) within the chargeable time, the CPU 11 Changes the predetermined period T to a shorter period.

  For example, the predetermined period T is set to 5 minutes, the student leaves the school at 15:00, the preset charging time is 6 hours, and the mobile terminal device 2a is connected to the connection unit 4 at 11:00. Let us consider a case where the remaining voltage of the portable terminal device 2a is 2.0V. In this case, the CPU 11 acquires the time 11:00 when the portable terminal device 2a is connected to the connection unit 4. Next, the CPU 11 calculates that the portable terminal device 2a can be charged for 4 hours from the acquired time 11:00 and the time 15:00 stored in the ROM 13 when the student leaves the school.

Then, the CPU 11 has a chargeable time (4 hours) shorter than a preset charging time (6 hours), and the remaining voltage (2.0V) of the mobile terminal device 2a becomes the specified voltage (4.1V). If not, the predetermined period T is changed from 5 minutes to 3 minutes.
As described above, the charging device 1 changes the predetermined period T to a shorter period, thereby increasing the frequency of acquiring the remaining voltage of each of the plurality of mobile terminal devices 2, and thus more preferably the plurality of mobile terminal devices 2. The secondary battery 40 can be charged to a uniform remaining voltage.

  In addition, the CPU 11 causes the power supply unit 30 to supply power to one mobile terminal device 2 that satisfies a predetermined condition regarding the remaining voltage to a voltage at which the one mobile terminal device 2 can execute a predetermined function. (First mode) and a time limit designation mode (first mode) in which the power supply unit 30 supplies power to one portable terminal device 2 that satisfies a predetermined condition within a designated period (for example, 5 hours) designated in advance. 2) and a full charge designation mode in which the power supply unit 30 supplies power to one mobile terminal device 2 that satisfies a predetermined condition until the secondary battery 40 of the one mobile terminal device 2 is fully charged. (Third mode) may be settable.

Specifically, the CPU 11 can set any one of the standard mode, the time limit designation mode, and the full charge mode by operating the switch 6.
Thereby, since the charging device 1 can set any one mode among three modes, it can charge the portable terminal device 2 more appropriately by setting the mode according to a charging condition.

  Next, specific processing in the standard mode, the time limit designation mode, and the full charge mode in the first embodiment will be described with reference to FIGS.

FIG. 5 is a flowchart illustrating the standard mode processing performed by the CPU 11 according to the first embodiment.
In step S1, when the AC adapter 8 is connected to an external power supply, the CPU 11 turns on all the switches SW1, SW2,. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 2, the CPU 11 determines whether or not a current change is detected by the current amplifier 15, that is, the CPU 11 determines whether or not the mobile terminal device 2 is connected to the connection unit 4. When the mobile terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S3. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), the process of step S2 is repeated.

  In step S <b> 3, the CPU 11 acquires the remaining voltage in the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4. Specifically, in a state where the mobile terminal device 2 is connected to the connection unit 4, the CPU 11 sequentially turns on one of the switches SW 1, SW 2,. The remaining voltage of the secondary battery 40 of each of the mobile terminal devices 2 connected to is acquired every predetermined time T and stored in the RAM 12. And CPU11 determines the order of the portable terminal device 2 which supplies electric power based on the residual voltage of the secondary battery 40 of each acquired portable terminal device 2. FIG.

  In step S <b> 4, the CPU 11 determines whether there is a remaining voltage equal to or lower than a specified voltage (4.1 V) among the acquired remaining voltage. If there is a remaining voltage equal to or lower than the specified voltage (Yes), the process proceeds to step S5. On the other hand, when there is no remaining voltage equal to or lower than the specified voltage (No), the process returns to step S3.

  In step S <b> 5, the CPU 11 determines the order of the secondary batteries 40 that supply power among the secondary batteries 40 that have acquired the remaining voltage, in ascending order of the remaining voltage. Then, the CPU 11 switches the switch SW1, switch SW2,... SW10 to the lowest state by turning on any one switch corresponding to the secondary battery 40 of the mobile terminal device 2 from which the lowest remaining voltage is acquired. The power supply unit 30 starts supplying power to the secondary battery 40 of the mobile terminal device 2 from which the remaining voltage has been acquired.

  In step S <b> 6, the CPU 11 determines whether or not the remaining voltage in the secondary battery 40 of the mobile terminal device 2 that is supplying power by the power supply unit 30 has reached a specified voltage. When the remaining voltage reaches the specified voltage (Yes), the process proceeds to step S7. On the other hand, when the remaining voltage does not reach the specified voltage (No), the process of step S6 is repeated.

In step S7, the CPU 11 switches the switch that was turned on in step S5 to the off state, and stops charging the secondary battery 40 whose remaining voltage has reached the specified voltage.
In step S <b> 8, the CPU 11 starts supplying power by the power supply unit 30 to the secondary battery 40 having the second lowest remaining voltage after the secondary battery 40 that has reached the specified voltage.

  In step S <b> 9, the CPU 11 determines whether or not the remaining voltage in the secondary battery 40 of the mobile terminal device 2 that is supplying power by the power supply unit 30 has reached a specified voltage. When the remaining voltage reaches the specified voltage (Yes), the process proceeds to step S10. On the other hand, when the remaining voltage does not reach the specified voltage (No), the process of step S9 is repeated.

In step S10, the CPU 11 stops charging the secondary battery 40 whose remaining voltage has reached the specified voltage. Then, when the charging of all the secondary batteries 40 whose remaining voltage does not reach the specified voltage is completed, the CPU 11 returns to step S2 again.
In this way, the CPU 11 sequentially supplies power to each of the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30.

FIG. 6 is a flowchart illustrating processing in the time limit designation mode by the CPU 11 according to the first embodiment.
In step S11, when the AC adapter 8 is connected to an external power supply, the CPU 11 turns on all the switches SW1, SW2,. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 12, the CPU 11 determines whether or not a change in current is detected by the current amplifier 15, that is, the CPU 11 determines whether or not the mobile terminal device 2 is connected to the connection unit 4. When the portable terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S13. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), the process of step S12 is repeated again.

  In step S <b> 13, the CPU 11 acquires the remaining voltage in the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4.

  In step S <b> 14, the CPU 11 determines whether or not the time limit designation mode is set by the switch 6. If the time limit designation mode is set (Yes), the process proceeds to step S15. On the other hand, when the time limit designation mode is not set (No), the process proceeds to step S16.

  In step S <b> 15, the CPU 11 determines whether there is a remaining voltage equal to or lower than a specified voltage (4.1 V) among the acquired remaining voltage. If there is a remaining voltage equal to or lower than the specified voltage (Yes), the process proceeds to step S19. On the other hand, when there is no remaining voltage equal to or lower than the specified voltage (No), the process of step S15 is repeated.

In step S <b> 16, the CPU 11 determines whether or not the full charge designation mode is set by the switch 6. If the full charge designation mode is set (Yes), the process proceeds to step S17. On the other hand, when the full charge designation mode is not set (No), the process proceeds to step S18.
In step S17, the CPU 11 shifts to the full charge designation mode.
In step S18, the CPU 11 shifts to the standard mode.

  In step S19, the CPU 11 divides a designated period (for example, 5 hours) designated in advance by the number of portable terminal devices 2 having the secondary battery 40 having a remaining voltage equal to or lower than a specified voltage. The chargeable time per mobile terminal device 2 is calculated. And CPU11 determines the order of the secondary battery 40 which supplies electric power among the secondary batteries 40 which acquired the residual voltage from the low residual voltage.

  In step S20, the CPU 11 turns on one of the switches SW1, SW2... SW10 corresponding to the secondary battery 40 of the mobile terminal device 2 from which the lowest remaining voltage is acquired. The power supply unit 30 starts supplying power to the secondary battery 40 of the mobile terminal device 2 for which the lowest remaining voltage is acquired.

  In step S21, the CPU 11 determines whether or not the chargeable time calculated in step S19 has elapsed. If the chargeable time has elapsed (Yes), the process proceeds to step S22. On the other hand, when the chargeable time has not elapsed (No), the process of step S21 is repeated.

In step S <b> 22, the CPU 11 switches the switch turned on in step S <b> 20 to the OFF state, and stops charging the secondary battery 40 after the chargeable time has elapsed.
In step S23, the CPU 11 switches any one of the switches SW1, SW2... SW10 corresponding to the secondary battery 40 having the lowest remaining voltage after the secondary battery 40 whose chargeable time has elapsed. In the ON state, the power supply unit 30 starts supplying power to the secondary battery 40.

  In step S24, the CPU 11 determines whether or not the chargeable time calculated in step S19 has elapsed. When the chargeable time has elapsed (Yes), the switch that was turned on in step S23 is switched to the OFF state, and charging of the secondary battery 40 after the chargeable time has elapsed is stopped. On the other hand, when the chargeable time has not elapsed (No), the process of step S24 is repeated. And CPU11 will return to step S12 again, if chargeable time of all the secondary batteries 40 in which residual voltage does not reach a regulation voltage passes.

  In this manner, the CPU 11 sequentially supplies power to each of the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30 until the chargeable time has elapsed.

  FIG. 7 is a flowchart illustrating processing in the full charge designation mode by the CPU 11 according to the first embodiment.

  In step S31, when the AC adapter 8 is connected to an external power supply, the CPU 11 turns on all the switches SW1, SW2,. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 32, the CPU 11 determines whether or not a current change is detected by the current amplifier 15, that is, the CPU 11 determines whether or not the mobile terminal device 2 is connected to the connection unit 4. When the portable terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S33. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), the process of step S32 is repeated again.

In step S <b> 33, the CPU 11 acquires the remaining voltage in the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4.
In step S <b> 34, the CPU 11 determines whether or not the full charge designation mode is set by the switch 6. When the full charge designation mode is set (Yes), the process proceeds to step S38. On the other hand, when the full charge designation mode is not set (No), the process proceeds to step S35.

In step S <b> 35, the CPU 11 determines whether or not the time limit designation mode is set by the switch 6. If the time limit designation mode is set (Yes), the process proceeds to step S36. On the other hand, when the time limit designation mode is not set (No), the process proceeds to step S37.
In step S36, the CPU 11 shifts to the time limit designation mode.
In step S37, the CPU 11 shifts to the standard mode.

  In step S38, CPU11 determines the order of the secondary battery 40 which supplies electric power among the secondary batteries 40 which acquired the residual voltage from the low residual voltage. Then, the CPU 11 stores the determined order in the RAM 12.

  In step S39, the CPU 11 turns on one of the switches SW1, SW2... SW10 corresponding to the secondary battery 40 of the mobile terminal device 2 from which the lowest remaining voltage is acquired. The power supply unit 30 starts supplying power to the secondary battery 40 of the mobile terminal device 2 for which the lowest remaining voltage is acquired.

  In step S40, the CPU 11 determines whether or not the remaining voltage has reached full charge. If the remaining voltage reaches full charge (Yes), the process proceeds to step S41. On the other hand, when the remaining voltage has not reached full charge (No), the process of step S40 is repeated.

In step S41, the CPU 11 switches the switch that was turned on in step S39 to the off state, and stops charging the secondary battery 40 whose remaining voltage has reached full charge.
In step S42, the CPU 11 selects one of the switches SW1, SW2... SW10 corresponding to the secondary battery 40 having the lowest remaining voltage next to the secondary battery 40 whose remaining voltage has reached full charge. The switch is turned on, and the power supply unit 30 starts supplying power to the secondary battery 40 having the lowest remaining voltage next to the secondary battery 40 whose remaining voltage has reached full charge.

  In step S43, the CPU 11 determines whether or not the remaining voltage has reached full charge. When the remaining voltage reaches full charge (Yes), the charging of the secondary battery 40 whose remaining voltage has reached full charge is stopped. On the other hand, when the remaining voltage has not reached full charge (No), the process of step S43 is repeated. Then, when the remaining voltage of all the secondary batteries 40 reaches full charge, the CPU 11 returns to step S32 again.

  Thus, the CPU 11 sequentially supplies power to the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30 until the remaining voltage reaches full charge.

Second Embodiment
Next, 2nd Embodiment of the charging device of this invention is described. About 2nd Embodiment, a different point from 1st Embodiment is mainly demonstrated, the same code | symbol is attached | subjected about the structure similar to 1st Embodiment, and description is abbreviate | omitted. For the points that are not specifically described in the second embodiment, the description of the first embodiment is applied as appropriate.

The charging device 1a of the second embodiment is different from the first embodiment in that the wireless communication unit 51 performs wireless communication with the mobile terminal device instead of the switching unit 20 of the first embodiment.
FIG. 8 is a block diagram showing an internal configuration of the charging device 1a of the second embodiment.
As shown in FIG. 8, the charging device 1a includes a connecting portion 4 (4a, 4b, 4c,... 4j), a changeover switch 6, LEDs 7a, 7b, 7c, an AC adapter 8, and a power input terminal 9. A control IC 10, a regulator 19, a current detection resistor Rd, and a wireless communication unit 51.

  The connection unit 4 (4a, 4b, 4c,... 4j), the changeover switch 6, the LEDs 7a, 7b, 7c, the AC adapter 8, the power input terminal 9, the control IC 10, the regulator 19, and the current detection resistor Rd Since it is the same structure as 1 embodiment, description is abbreviate | omitted.

  The wireless communication unit 51 includes an antenna 52 and a short-range wireless IC 53. The wireless communication unit 51 performs wireless communication with a plurality of portable terminal devices 2 in accordance with a predetermined wireless standard (for example, Bluetooth (registered trademark)).

The antenna 52 communicates with a plurality of portable terminal devices 2 in a frequency band compliant with a predetermined wireless standard.
The short-range wireless IC 53 demodulates the signal received by the antenna 52 and supplies the processed signal to the CPU 11. Further, the short-range wireless IC 53 modulates the signal supplied from the CPU 11 and transmits it to the mobile terminal device 2 via the antenna 52.

  The CPU 11 acquires the remaining voltage of the secondary battery in each of the plurality of portable terminal devices 2 for each predetermined period T by the wireless communication unit 51. CPU11 determines the one portable terminal device 2 which satisfy | fills the predetermined condition regarding a residual voltage based on each acquired residual voltage of the secondary battery 40. FIG.

  Then, the CPU 11 electrically connects the determined secondary battery 40 of the one portable terminal device 2 and the power supply unit 30 to connect the secondary battery 40 of the one portable terminal device 2 to another portable terminal device. Power is supplied by the power supply unit 30 in preference to 2, and the secondary battery 40 is charged.

  Specifically, the CPU 11 uses the wireless communication unit 51 to transmit control information for one mobile terminal device 2 satisfying a predetermined condition relating to the remaining voltage to be charged by the main body of the charging device 1. Send. The mobile terminal device 2 receives the control information transmitted from the wireless communication unit 51 by a communication unit (not shown). Then, the mobile terminal device 2 supplies power to the secondary battery 40 from the charging device 1 by turning on the transistor switch TR (see FIG. 4) in the charging circuit 50 based on the received control information. Is done. Note that the wireless communication unit 51 may always perform wireless communication with the plurality of mobile terminal devices 2 or intermittently perform wireless communication with the plurality of mobile terminal devices 2.

  Here, the predetermined condition regarding the remaining voltage is the portable terminal device 2 having the secondary battery 40 from which the lowest remaining voltage is acquired among the remaining voltages of the secondary battery 40 acquired by the CPU 11. Is preferred.

  As described above, the charging device 1 a according to the second embodiment acquires the remaining voltage of the secondary battery 40 by the wireless communication unit 51. Thereby, the charging device 1a can acquire the residual voltage easily. In addition, since the charging device 1a performs wireless communication with the mobile terminal device 2 by the wireless communication unit 51 compliant with a predetermined wireless standard (for example, Bluetooth), each mobile terminal device 2 is registered by registering identification information in advance. Even with different models, it is possible to transmit and receive remaining voltage and control information.

  Moreover, the charging device 1a of 2nd Embodiment transmits the control information for the portable terminal device 2 to charge with the charging device 1 main body to the one portable terminal device 2 by the wireless communication part 51. FIG. Thereby, the portable terminal device 2 supplies power to the secondary battery 40 from the charging device 1 by turning on the transistor switch TR based on the received control information. Therefore, since the charging device 1a does not require the configuration of the switching unit 20 in the charging device 1 of the first embodiment, the configuration of the charging device 1a can be simplified and downsized.

  Further, the CPU 11 may perform wireless communication with each of the plurality of mobile terminal devices 2 by the wireless communication unit 51 to acquire user information in each of the plurality of mobile terminal devices 2. In this case, the CPU 11 changes the predetermined period T based on the acquired user information. Here, the user information refers to a user's schedule (student attending time, school leaving time, etc.) and the like.

  Specifically, in the charging device 1a, the predetermined period T is 5 minutes, the time when the student leaves the school is set to 15:00, and the student's school leaving time included in the acquired user information is 13:00. If it is, the CPU 11 changes the predetermined period T from 5 minutes to 3 minutes.

  As described above, the charging device 1a changes the predetermined period T to a shorter period, so that the frequency of acquiring the remaining voltage of each of the plurality of mobile terminal devices 2 is increased. The secondary batteries 40 of the plurality of mobile terminal devices 2 can be charged to an equal remaining voltage.

Moreover, CPU11 may determine the portable terminal device 2 which supplies electric power with the electric power supply part 30 based on the acquired user information.
Specifically, in the charging device 1a, the predetermined period T is 5 minutes, the time when the student leaves the school is set to 15:00, and the student's school leaving time included in the acquired user information is 13:00. If it is, the CPU 11 preferentially supplies power from the power supply unit 30 to the secondary battery 40 of the mobile terminal device 2 from which the user information has been acquired.
Thereby, the charging device 1a can charge the secondary battery 40 of the some portable terminal device 2 to an equal residual voltage more suitably using user information.

  In addition, the CPU 11 determines the remaining voltage of the secondary battery 40 in each of the plurality of mobile terminal devices 2 by the wireless communication unit 51 in a state where the connection unit 4 and the plurality of mobile terminal devices 2 are disconnected. Get every T. Based on the acquired remaining voltage of the secondary battery 40, the CPU 11 determines one or a plurality of portable terminal devices 2 in which the remaining voltage of the secondary battery 40 does not exceed a predetermined threshold S. Then, the CPU 11 may transmit information for the predetermined one or more mobile terminal devices 2 to perform predetermined notification to the one or more mobile terminal devices 2 by the wireless communication unit 51. Here, the predetermined threshold value S is preferably set to a value at which the remaining voltage of the mobile terminal device 2 becomes a voltage at which the function of the mobile terminal device 2 cannot be sufficiently exhibited.

  One or a plurality of portable terminal devices 2 whose remaining voltage does not exceed a predetermined threshold S receive information for performing a predetermined notification transmitted by the wireless communication unit 51 by a communication unit (not shown). Then, the mobile terminal device 2 displays a predetermined notification (for example, a message indicating that the remaining voltage is low, outputs a sound, or performs charging based on the received information for performing the predetermined notification. Display a prompt message or output a voice message).

  For this reason, the charging device 1a can prompt the user to charge by transmitting information for performing a predetermined notification to the mobile terminal device 2 that has a small remaining voltage and needs to be charged.

  Similarly to the first embodiment, the CPU 11 supplies the power supply unit to one mobile terminal device 2 that satisfies a predetermined condition regarding the remaining voltage, up to a voltage at which the one mobile terminal device 2 can execute a predetermined function. A standard mode (first mode) in which power is supplied by 30 and a time limit specifying mode in which power is supplied by the power supply unit 30 to one mobile terminal device 2 that satisfies a predetermined condition within a specified period specified in advance. (2nd mode) and the full charge which supplies electric power to the one portable terminal device 2 which satisfy | fills predetermined conditions until the secondary battery 40 of this one portable terminal device 2 becomes fully charged. A designated mode (third mode) can be set.

  Next, specific processing in the standard mode, the time limit designation mode, and the full charge designation mode in the second embodiment will be described with reference to FIGS. 9 to 11. In the standard mode, the time limit designation mode, and the full charge designation mode in the second embodiment, identification information for identifying the mobile terminal device 2 by the charging device 1a (wireless communication unit 51) in a predetermined wireless standard is provided. It is assumed that it is stored (registered) in the RAM 12 in advance.

FIG. 9 is a flowchart illustrating processing in the standard mode by the CPU 11 according to the second embodiment.
In step S51, the CPU 11 starts wireless communication by the wireless communication unit 51 when the AC adapter 8 is connected to an external power source. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 52, the CPU 11 determines whether or not the mobile terminal device 2 whose identification information is registered in the RAM 12 exists in an area where the wireless communication unit 51 can perform wireless communication. If there is a registered mobile terminal device 2 (Yes), the process proceeds to step S53. On the other hand, when the registered mobile terminal device 2 does not exist (No), the process of step S52 is repeated.

In step S <b> 53, the CPU 11 acquires the remaining voltage of the secondary battery 40 in each of the plurality of portable terminal devices 2 using the wireless communication unit 51.
In step S <b> 54, the CPU 11 determines whether there is a remaining voltage equal to or lower than a specified voltage (4.1 V) among the acquired remaining voltage. If there is a remaining voltage equal to or lower than the specified voltage (Yes), the process proceeds to step S55. On the other hand, when there is no remaining voltage equal to or lower than the specified voltage (No), the process of step S52 is repeated.

In step S <b> 55, the CPU 11 transmits information for performing a predetermined notification to the mobile terminal device 2 whose remaining voltage is equal to or lower than the specified voltage, by the wireless communication unit 51.
In step S <b> 56, the CPU 11 determines whether or not a change in current is detected by the current amplifier 15, that is, the CPU 11 determines whether or not the mobile terminal device 2 is connected to the connection unit 4. When the portable terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S57. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), it returns to step S52 again.

  In step S57, the CPU 11 transmits to the mobile terminal device 2 control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 first (first). Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 first (first). Power is supplied by 30.

  In step S <b> 58, the CPU 11 determines whether or not the remaining voltage in the secondary battery 40 of the mobile terminal device 2 that is supplying power by the power supply unit 30 has reached the specified voltage. If the remaining voltage has reached the specified voltage (Yes), the process proceeds to step S59. On the other hand, when the remaining voltage does not reach the specified voltage (No), the process of step S58 is repeated.

  In step S59, the CPU 11 transmits control information for turning off the transistor switch TR turned on in step S57 to the mobile terminal device 2. Then, by turning off the transistor switch TR of the mobile terminal device 2, the charging device 1a stops supplying power to the secondary battery 40 whose remaining voltage has reached the specified voltage.

  In step S <b> 60, control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 second (next to the earliest) is transmitted to the mobile terminal device 2. Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 by the power supply unit 30. Supply.

  In step S <b> 61, the CPU 11 determines whether the remaining voltage in the secondary battery 40 of the mobile terminal device 2 that is supplying power by the power supply unit 30 has reached a specified voltage. When the remaining voltage reaches the specified voltage (Yes), the supply of power is stopped. On the other hand, when the remaining voltage does not reach the specified voltage (No), the process of step S61 is repeated. Then, when the charging of all the secondary batteries 40 whose remaining voltage does not reach the specified voltage is completed, the CPU 11 returns to step S52 again.

  In this way, the CPU 11 sequentially supplies power to each of the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30.

FIG. 10 is a flowchart illustrating processing in the time limit designation mode by the CPU 11 according to the second embodiment.
In step S <b> 71, when the AC adapter 8 is connected to an external power source, the CPU 11 starts wireless communication by the wireless communication unit 51. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 72, the CPU 11 determines whether or not the mobile terminal device 2 whose identification information is registered in the RAM 12 exists in an area where the wireless communication unit 51 can perform wireless communication. If the registered mobile terminal device 2 exists (Yes), the process proceeds to step S73. On the other hand, when the registered mobile terminal device 2 does not exist (No), the process of step S72 is repeated.

  In step S73, the CPU 11 determines whether or not the time limit designation mode is set by the switch 6. If the time limit designation mode is set (Yes), the process proceeds to step S77. On the other hand, when the time limit designation mode is not set (No), the process proceeds to step S74.

In step S <b> 74, the CPU 11 determines whether or not the full charge designation mode is set by the switch 6. When the full charge designation mode is set (Yes), the process proceeds to step S75. On the other hand, when the full charge designation mode is not set (No), the process proceeds to step S76.
In step S75, the CPU 11 shifts to the full charge designation mode.
In step S76, the CPU 11 shifts to the standard mode.

In step S <b> 77, the CPU 11 acquires the remaining voltage of the secondary battery 40 in each of the plurality of mobile terminal devices 2 by the wireless communication unit 51.
In step S <b> 78, the CPU 11 determines whether there is a remaining voltage equal to or lower than a specified voltage (4.1 V) among the acquired remaining voltage. If there is a remaining voltage equal to or lower than the specified voltage (Yes), the process proceeds to step S79. On the other hand, when there is no remaining voltage equal to or lower than the specified voltage (No), the process returns to step S72.

In step S <b> 79, the CPU 11 transmits information for performing a predetermined notification to the mobile terminal device 2 whose remaining voltage is equal to or lower than the specified voltage, by the wireless communication unit 51.
In step S <b> 80, the CPU 11 determines whether a current change is detected by the current amplifier 15, that is, the CPU 11 determines whether the mobile terminal device 2 is connected to the connection unit 4. When the portable terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S81. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), it returns to step S72 again.

  In step S <b> 81, the CPU 11 divides a designated period (for example, 5 hours) designated in advance by the number of portable terminal devices 2 having the secondary battery 40 having a remaining voltage equal to or lower than a specified voltage, The chargeable time per mobile terminal device 2 is calculated.

  In step S <b> 82, the CPU 11 transmits control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 first (first) to the mobile terminal device 2. Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 first (first). Power is supplied by 30.

  In step S83, the CPU 11 determines whether or not the chargeable time calculated in step S82 has elapsed. If the chargeable time has elapsed (Yes), the process proceeds to step S84. On the other hand, when the chargeable time has not elapsed (No), the process of step S83 is repeated.

  In step S <b> 84, the CPU 11 transmits control information for turning off the transistor switch TR turned on in step S <b> 57 to the mobile terminal device 2. Then, by turning off the transistor switch TR of the mobile terminal device 2, the charging device 1 a stops supplying power to the secondary battery 40 whose chargeable time has elapsed.

  In step S <b> 85, control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 second (next to the earliest) is transmitted to the mobile terminal device 2. Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 by the power supply unit 30. Supply.

  In step S86, the CPU 11 determines whether or not the chargeable time calculated in step S82 has elapsed. When the chargeable time has elapsed (Yes), the power supply is stopped. On the other hand, when the chargeable time has not elapsed (No), the process of step S86 is repeated. And CPU11 will return to step S72 again, if chargeable time of all the secondary batteries 40 whose residual voltage does not reach a regulation voltage passes.

  In this manner, the CPU 11 sequentially supplies power to each of the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30 until the chargeable time has elapsed.

FIG. 11 is a flowchart illustrating processing in the full charge designation mode by the CPU 11 according to the second embodiment.
In step S91, the CPU 11 starts wireless communication by the wireless communication unit 51 when the AC adapter 8 is connected to an external power source. Further, the CPU 11 uses the current amplifier 15 to start detecting that the portable terminal device 2 is connected to the connection unit 4 using the current amplifier 15.

  In step S <b> 92, the CPU 11 determines whether or not the mobile terminal device 2 whose identification information is registered in the RAM 12 exists in an area where the wireless communication unit 51 can perform wireless communication. If there is a registered mobile terminal device 2 (Yes), the process proceeds to step S93. On the other hand, when the registered mobile terminal device 2 does not exist (No), the process of step S92 is repeated.

  In step S <b> 93, the CPU 11 determines whether or not the full charge designation mode is set by the switch 6. When the full charge designation mode is set (Yes), the process proceeds to step S97. On the other hand, when the full charge designation mode is not set (No), the process proceeds to step S94.

In step S <b> 94, the CPU 11 determines whether or not the time limit designation mode is set by the switch 6. If the time limit designation mode is set (Yes), the process proceeds to step S95. On the other hand, when the time limit designation mode is not set (No), the process proceeds to step S96.
In step S95, the CPU 11 shifts to the time limit designation mode.
In step S96, the CPU 11 shifts to the standard mode.

In step S <b> 97, the CPU 11 acquires the remaining voltage of the secondary battery 40 in each of the plurality of mobile terminal devices 2 by the wireless communication unit 51.
In step S98, the CPU 11 determines whether or not the acquired remaining voltage of the secondary battery 40 has not yet reached full charge. If the full charge has not been reached (Yes), the process proceeds to step S99. On the other hand, if the full charge is not reached, that is, if it is full (No), the process returns to step S92.

In step S <b> 99, the CPU 11 transmits information for performing a predetermined notification to the mobile terminal device 2 having a remaining voltage equal to or lower than a specified voltage by the wireless communication unit 51.
In step S <b> 100, the CPU 11 determines whether or not a change in current is detected by the current amplifier 15, that is, the CPU 11 determines whether or not the mobile terminal device 2 is connected to the connection unit 4. When the portable terminal device 2 is connected to the connection unit 4 (Yes), the process proceeds to step S101. On the other hand, when the portable terminal device 2 is not connected to the connection part 4 (No), it returns to step S92 again.

  In step S <b> 101, the CPU 11 transmits control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 first (first) to the mobile terminal device 2. Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 first (first). Power is supplied by 30.

  In step S102, the CPU 11 determines whether or not the remaining voltage has reached full charge. If the remaining voltage reaches full charge (Yes), the process proceeds to step S103. On the other hand, when the remaining voltage has not reached full charge (No), the process of step S102 is repeated.

  In step S <b> 103, the CPU 11 transmits control information for turning off the transistor switch TR turned on in step S <b> 57 to the mobile terminal device 2. Then, by turning off the transistor switch TR of the mobile terminal device 2, the charging device 1 a stops supplying power to the secondary battery 40 whose chargeable time has elapsed.

  In step S <b> 104, control information for turning on the transistor switch TR of the mobile terminal device 2 connected to the connection unit 4 second (next to the earliest) is transmitted to the mobile terminal device 2. Then, by turning on the transistor switch TR of the mobile terminal device 2, the charging device 1 a supplies power to the secondary battery 40 of the mobile terminal device 2 connected to the connection unit 4 by the power supply unit 30. Supply.

  In step S105, the CPU 11 determines whether or not the remaining voltage has reached full charge. When the remaining voltage reaches full charge (Yes), the supply of power is stopped. On the other hand, when the remaining voltage has not reached full charge (No), the process of step S105 is repeated. Then, when the remaining charge voltage of all the secondary batteries 40 reaches full charge, the CPU 11 returns to step S92 again.

Thus, the CPU 11 sequentially supplies power to the secondary batteries 40 whose remaining voltage does not reach the specified voltage by the power supply unit 30 until the remaining voltage reaches full charge.
As described above, the charging device 1 can determine the mobile terminal device 2 to be charged in accordance with the remaining voltage of each secondary battery 40 acquired every predetermined period T. Therefore, the charging device 1 can charge the secondary batteries 40 of the plurality of mobile terminal devices 2 to an equal remaining voltage.

  As mentioned above, although embodiment of this invention was described, this invention is not restrict | limited to embodiment mentioned above, It can change suitably. For example, in the charging device 1a of the second embodiment described above, the switching unit 20 is not included. However, the charging device 1a may have the switching unit 20.

  Further, in the standard mode, the time limit designation mode, and the full charge designation mode according to the first and second embodiments described above, a specified voltage and a chargeable period are applied to the secondary battery 40 once started to supply power. However, the present invention is not limited to this, although the power supply is continued until the battery is fully charged. For example, if a predetermined period T elapses during power supply and the remaining voltage is acquired again, the CPU 11 stops supplying power, acquires the remaining voltage, and relates to the remaining voltage. The mobile terminal device 2 having the secondary battery 40 that satisfies the predetermined condition is determined again. Then, the CPU 11 may supply power to the determined secondary battery 40 (for example, a secondary battery 40 that is the same as or different from the secondary battery 40 that has been supplying power until then).

DESCRIPTION OF SYMBOLS 1 Charging apparatus 2 Portable terminal device 4 Connection part 11 CPU (acquisition part, control part)
30 Power supply unit

Claims (10)

A connection part to which a plurality of portable terminal devices having secondary batteries are connected;
A power supply unit that supplies power to and charges the secondary battery of the mobile terminal device connected to the connection unit;
An acquisition unit that acquires a remaining voltage of the secondary battery of the mobile terminal device connected to the connection unit;
Based on the remaining voltage of the secondary battery acquired by the acquisition unit, determine one portable terminal device that satisfies a predetermined condition regarding the remaining voltage, and determine the determined secondary battery of the one portable terminal device, A charging device comprising: a control unit electrically connected to the power supply unit, wherein the power supply unit supplies power to the secondary battery of the one portable terminal device in preference to the other portable terminal device. . A wireless communication unit that performs wireless communication with the plurality of portable terminal devices in accordance with a predetermined wireless standard,
The charging device according to claim 1, wherein the acquisition unit acquires a remaining voltage of a secondary battery in each of the plurality of portable terminal devices at predetermined intervals by the wireless communication unit.   The mobile terminal device that satisfies the predetermined condition is a mobile terminal device that has a secondary battery in which the lowest remaining voltage of the secondary battery acquired by the acquiring unit is acquired. Or the charging device of 2.   4. The control unit according to claim 1, wherein the power supply unit supplies power to the one mobile terminal device satisfying the predetermined condition up to a voltage at which the one mobile terminal device can execute a predetermined function. 5. The charging device according to claim 1.   4. The control unit according to claim 1, wherein the control unit causes the one mobile terminal device that satisfies the predetermined condition to supply power by the power supply unit until a secondary battery of the one mobile terminal device is fully charged. 5. The charging device according to claim 1.   The control unit includes a time from when each of the plurality of mobile terminal devices is connected to the connection unit until the connection is released, and a secondary battery of each of the plurality of mobile terminal devices acquired by the acquisition unit. The charging device according to any one of claims 2 to 5, wherein the predetermined period is changed based on a remaining voltage.   A first mode in which the power supply unit supplies power to the one mobile terminal device that satisfies the predetermined condition up to a voltage at which the one mobile terminal device can execute a predetermined function; A second mode in which the power supply unit supplies power to the one mobile terminal device that satisfies the predetermined condition within the specified period, and the one mobile terminal device that satisfies the predetermined condition. The charging device according to any one of claims 1 to 6, wherein a third mode in which power is supplied by the power supply unit until a secondary battery of one mobile terminal device is fully charged can be set.   The charging according to claim 2, wherein the control unit transmits control information for charging the one mobile terminal device satisfying the predetermined condition by a charging device to the one mobile terminal device by the wireless communication unit. apparatus. The acquisition unit acquires user information in each of the plurality of mobile terminal devices by the wireless communication unit,
The charging device according to claim 2, wherein the control unit changes the predetermined period based on the user information acquired by the acquisition unit. In the state where the connection between the connection unit and the plurality of mobile terminal devices is released, the acquisition unit calculates the remaining voltage of the secondary battery in each of the plurality of mobile terminal devices by the wireless communication unit for the predetermined period. Get every
The control unit determines one or more portable terminal devices based on the remaining voltage of the secondary battery acquired by the acquiring unit, the remaining voltage of the secondary battery does not exceed a predetermined threshold, The charging device according to claim 9, wherein the wireless communication unit transmits information for the predetermined one or more portable terminal devices to perform predetermined notification to the one or more portable terminal devices.

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