JP5937364B2 - Charging device, charging method, and electronic device - Google Patents

Description

  The present invention relates to a charging device, a charging method, and an electronic device.

  Conventionally, rechargeable secondary batteries have been widely used as power sources for electronic devices such as portable terminals and notebook computers. A secondary battery can be charged by a charging device included in an electronic device using electric power from a commercial power source, and a constant current-constant voltage charging method is generally known as the charging method. ing. In the constant current-constant voltage charging method, charging is performed at a constant charging current when the battery capacity of the secondary battery is small, and charging is performed so that the charging current is reduced to a constant voltage when the secondary battery is charged to a predetermined voltage. It is a method.

  For example, Patent Document 1 discloses a charging method using a constant current-constant voltage charging method, in which a charging current is reduced stepwise according to a voltage value of a secondary battery.

  Patent Document 2 discloses a charging device, an electronic device, and a charging method that change a charging current based on a power supply voltage based on bus power.

JP 2011-124166 A JP 2010-154692 A

  Here, generally, a charging device included in an electronic device receives power from a commercial power supply via a power regulator such as an AC adapter that converts power from the commercial power supply to charge a secondary battery. The power regulators are becoming more and more diverse with the spread of electronic devices, and the power supply capability varies depending on the specifications. Therefore, as in the charging method disclosed in Patent Document 1, regardless of the supply capacity of the power conditioner connected to the charging device, the same charge method is used, and the range of the supply capacity of the power conditioner There is a problem that it becomes impossible to charge the secondary battery stably.

  Moreover, in the charging device and the charging method disclosed in Patent Document 2, even if the power regulators have different supply capacities, the same charging method is uniformly used as long as the power supply voltage is the same. There is a problem that the secondary battery cannot be stably charged within the range of the supply capacity.

  The present invention has been made to solve the above-described problems, and provides a charging device, a charging method, and an electronic apparatus that can stably charge a secondary battery within the range of the power regulator supply capability. The purpose is to provide.

In order to achieve the above-described object, according to one aspect of the present invention, the present invention is a charging device for charging a secondary battery using electric power supplied from a power regulator, which is supplied from the power regulator. A conversion circuit that converts the generated power and outputs a charging current for charging the secondary battery, an input current detection unit that detects an input current input from the power regulator to the conversion circuit, and a secondary battery from the conversion circuit A charging current detector for detecting the output charging current; and a control means for controlling the conversion circuit;
The control means disables the restriction on the input current and operates the conversion circuit to measure the maximum value of the input current detected from the input current detection unit, and the measured input current. Supply capability determining means for determining the supply capability of the power regulator based on the maximum value, input current limiting means for limiting the input current input to the conversion circuit according to the determined supply capability, and determined supply Conversion circuit control means for controlling the conversion circuit so that a charging current corresponding to the capability is output.

  Preferably, it further includes a storage unit that stores a plurality of charge pattern tables according to supply capacity according to the supply capacity of the power regulator, and the conversion circuit control unit is configured to determine the supply capacity of the power regulator determined by the supply capacity determination unit. Accordingly, one charging capability-specific charging pattern table is selected from among a plurality of charging capability-specific charging pattern tables, and the conversion circuit is controlled based on the selected charging capability-specific charging pattern table.

  Preferably, the battery further includes a battery voltage detection unit that detects a battery voltage of the secondary battery, the supply capacity-specific charge pattern table includes a plurality of charge patterns according to the battery voltage, and the conversion circuit control unit includes the battery voltage detection unit. The conversion circuit is controlled by switching a plurality of charge patterns based on the battery voltage detected by the above.

  Preferably, the input current measuring means measures the maximum value of the input current within a predetermined time when charging of the secondary battery is started.

According to still another aspect of the present invention, the present invention provides a charging method for charging a secondary battery using a charging current output by a conversion circuit that converts power supplied from a power regulator, The step of detecting the input current input from the regulator to the conversion circuit, the step of detecting the charging current output from the conversion circuit to the secondary battery, and operating the conversion circuit after invalidating the restriction on the input current And measuring the maximum value of the detected input current, determining the supply capacity of the power regulator based on the measured maximum value of the input current , and converting according to the determined supply capacity The method includes a step of limiting an input current input to the circuit, and a step of controlling the conversion circuit so that a charging current corresponding to the determined supply capability is output.

According to still another aspect of the present invention, the present invention provides an electronic device, a secondary battery, a load that operates on the secondary battery, a conversion circuit that converts electric power supplied from a power regulator, A charging device that charges the secondary battery using the charging current output by the conversion circuit, and the charging device converts the power supplied from the power regulator and outputs the charging current that charges the secondary battery. Controlling the conversion circuit, the input current detection unit for detecting the input current input from the power regulator to the conversion circuit, the charging current detection unit for detecting the charging current output from the conversion circuit to the secondary battery, and the conversion circuit And an input current measuring means for measuring the maximum value of the input current detected from the input current detecting section by operating the conversion circuit after invalidating the restriction on the input current. Of the measured input current Based on a large value, and determines supply capacity determining means supply capacity of the power regulator, according to the determined supply capacity, and input current limiting means for limiting an input current input to the conversion circuit, the determined supplied Conversion circuit control means for controlling the conversion circuit so that a charging current corresponding to the capability is output.

It is a figure which shows a mode that the power regulator in this Embodiment is connected to a portable terminal, and is charged. It is a figure which shows the internal structure of the portable terminal in this Embodiment. It is a figure which shows the internal structure of the charging device in this Embodiment. It is a figure which shows the circuit diagram of the conversion circuit in this Embodiment, and its peripheral circuit. (A) is a figure which shows the charge pattern table of the charge type A which the memory | storage part in this Embodiment memorize | stores. (B) is a figure which shows the charge pattern table of the charge type B which the memory | storage part in this Embodiment memorize | stores. It is a flowchart figure of the charge process which the control part in this Embodiment performs. (A) is a figure which shows the charge characteristic of the charge type A in this Embodiment. (B) is a figure which shows the charge characteristic of the charge type B in this Embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that the same or corresponding parts in the drawings are denoted by the same reference numerals and description thereof will not be repeated.

(1. Charge mode of mobile terminal)
FIG. 1 is a diagram illustrating a state in which the power regulator 50 according to the present embodiment is connected to the mobile terminal 10 for charging. As shown in FIG. 1, the mobile terminal 10 is charged by being connected to a commercial power source 60 via a power regulator 50 (in FIG. 1, the power regulator 50A or the power regulator 50B).

  The power adjuster 50 has a plug that can be connected to an outlet of a commercial power supply 60, as represented by an AC adapter, and the like, and AC power (for example, AC 100V) from the commercial power supply 60 is supplied to the mobile terminal 10 to be connected. It has a function of converting into combined DC power (for example, DC 5V). In the present embodiment, it is possible to charge the mobile terminal 10 by using the power regulator 50A or the power regulator 50B. However, the power regulator 50A and the power regulator 50B are capable of supplying power. Is different. For example, in the case of the power regulator 50A, it is possible to supply a current having a maximum current of 700 mA to the mobile terminal 10, whereas in the case of the power regulator 50B, a current having a maximum current of 1000 mA is supplied to the mobile terminal 10. Can be supplied. As described above, the mobile terminal 10 can be charged by connecting a wide variety of power regulators 50, but on the other hand, the maximum current that can be charged varies depending on the type and specifications of the power regulator 50. come. Therefore, if the control accuracy of the feedback control in the constant current-constant voltage charging method is poor, the charging current may fluctuate and enter an oscillation state, and a higher voltage than expected is applied to the power regulator 50 and the portable terminal 10. As a result, the power regulator 50 and the control circuit in the mobile terminal 10 may be destroyed. Therefore, it is necessary to perform charge control according to the supply capacity of the power regulator 50.

(2. Internal structure of mobile terminal)
As shown in FIG. 2, the mobile terminal 10 in the present embodiment includes a secondary battery 19, a load that operates using the secondary battery 19 as a power source, a storage unit 17, an operation unit 16, a display unit 13, The audio input / output unit 15, the wireless communication unit 12, the antenna 11, the camera unit 14, the control unit 18, and the charging device 20 are included.

  The storage unit 17 is a semiconductor memory such as a nonvolatile memory such as a ROM (Read Only Memory) or a flash memory, or a volatile memory such as a RAM (Random Access Memory). The storage unit 17 stores programs and data such as application programs for causing the control unit 18 to execute various functions of the mobile terminal 10. For example, in the present embodiment, the storage unit 17 stores a charging pattern table shown in FIG. 5 used when charging the secondary battery 19. In the present embodiment, the storage unit 17 stores a program related to the charging process shown in FIG. 6 executed by the control unit 18.

  The operation unit 16 has dial keys, cross operation keys, and other function keys for inputting numbers such as telephone numbers and various data, alphabets, and other characters. The operation unit 16 receives data input from the user and outputs the input data to the control unit 18.

  The display unit 13 is a liquid crystal display (hereinafter referred to as “LCD”). The display unit 13 may be another display device such as an EL (Electro Luminescence) display. Character data and image data received from the display unit 13 and the control unit 18 are displayed.

  The voice input / output unit 15 includes a microphone and a speaker. The voice input / output unit 15 converts the voice input from the outside into the microphone into an electrical signal, outputs the electrical signal to the control unit 18, converts the electrical signal from the control unit 18 into voice, and outputs it to the outside through a speaker.

  The wireless communication unit 12 outputs a signal received by the antenna 11 from another mobile terminal 10 or the like to the control unit 18 and causes the antenna 11 to output a signal to be transmitted from the control unit 18 to the other mobile terminal.

  The camera unit 14 captures an imaging target, converts the captured image into image data, and outputs the converted image data to the control unit 18.

  The secondary battery 19 supplies the stored power to loads such as the camera unit 14, the voice input / output unit 15, and the display unit 13 included in the mobile terminal 10. In this embodiment, a lithium ion battery is used. It is used. In addition, not only a lithium ion battery but other secondary batteries, such as a nickel-cadmium storage battery and a nickel-hydrogen storage battery, may be sufficient, for example.

  The control unit 18 has a CPU (Central Processing Unit). The control unit 18 processes the data input from the storage unit 17, the operation unit 16, the voice input / output unit 15, the wireless communication unit 12, or the camera unit 14 according to the program stored in the storage unit 17, and stores the storage unit 17, the display unit 13, the voice input / output unit 15, the wireless communication unit 12, the camera unit 14, or the charging device 20. Moreover, the control part 18 in this Embodiment makes it possible to charge the secondary battery 19 with the charging current according to the supply capability of the power regulator 50 by performing the charging process shown in FIG.

(3. Internal structure of the charging device)
As shown in FIG. 3, the charging device 20 is connected to the commercial power supply 60 via the power regulator 50 to charge the secondary battery 19, and the charging control circuit 25, the input current detection circuit 21, A charging current detection circuit 22, a battery voltage detection circuit 23, and an AD conversion unit 24 are included.

  The charging control circuit 25 includes a conversion circuit 30, converts the input power supplied from the power regulator 50, and outputs a charging current for charging the secondary battery 19 to the secondary battery 19. In the present embodiment, the conversion circuit 30 is a switching control type step-down circuit that steps down the input power supplied from the power regulator 50 to a predetermined charging voltage and supplies it to the secondary battery 19.

  The input current detection circuit 21 is connected between the power regulator 50 and the conversion circuit 30 and is also connected to the AD conversion unit 24. The input current detection circuit 21 detects an input current input from the power regulator 50 to the conversion circuit 30 and outputs the detected input current to the AD conversion unit 24.

  The charging current detection circuit 22 is connected between the conversion circuit 30 and the secondary battery, and is also connected to the AD conversion unit 24. The charging current detection circuit 22 detects the charging current output from the conversion circuit 30 to the secondary battery 19, and outputs the detected charging current to the AD conversion unit 24.

  The battery voltage detection circuit 23 is connected to the secondary battery 19 and also to the conversion unit 24. The battery voltage detection circuit 23 detects the battery voltage of the secondary battery 19 and outputs the detected battery voltage to the AD converter 24.

  The AD conversion unit 24 is connected to the input current detection circuit 21, the charging current detection circuit 22, and the battery voltage detection circuit 23, and is also connected to the storage unit 17. The AD conversion unit 24 converts the analog value of the input current detected by the input current detection circuit 21 into a digital value so that the storage unit 17 can process it, and outputs it to the storage unit 17. Further, the AD conversion unit 24 converts the analog value of the charging current detected by the charging current detection circuit 22 into a digital value so that the storage unit 17 can process it, and outputs it to the storage unit 17. Further, the AD conversion unit 24 converts the analog value of the battery voltage detected by the battery voltage detection circuit 23 into a digital value so that the storage unit 17 can process it, and outputs it to the storage unit 17.

  In the charging device 20 having the above configuration, detection of the input current detected by the input current detection circuit 21, the charging current detected by the charging current detection circuit 22, and the battery voltage detected by the battery voltage detection circuit 23. The value is fed back to the control unit 18 through the AD conversion unit 24. Upon receiving the feedback, the control unit 18 limits the input current based on the detected value, and controls the conversion circuit 30 to switch the setting value of the charging current. As a result, oscillation can be prevented by suppressing current fluctuation, and the secondary battery 19 can be charged with a charging current according to the supply capability of the power regulator 50.

(4. Circuit configuration of conversion circuit)
Next, the circuit configuration of the conversion circuit 30 in the present embodiment will be described. FIG. 4 is a diagram showing a circuit diagram of conversion circuit 30 and its peripheral circuits in the present embodiment.

  The conversion circuit 30 is connected in series between the input current detection circuit 21 and the charging current detection circuit 22. The conversion circuit 30 is a chopper type step-down converter composed of a field effect transistor (FET), a coil, a diode, and a capacitor. The current control unit 35 is connected to the drain side of the FET, and the cathode side of the diode and one side connection point of the coil are connected to the source side of the FET. A control unit 18 is connected to the gate side of the FET. One side connection point of the capacitor is connected to the other side connection point of the coil, and the other side connection point of the capacitor is connected to the anode side of the diode. A charging current detection circuit 22 is connected in series to the connection point between the other side connection point and the one side connection point of the coil.

  In the conversion circuit 30 having such a configuration, the voltage applied between the gate and the source of the FET is adjusted by the action of the control unit 18 connected to the gate of the FET to control the drain current flowing between the drain and the source. To do. Thereby, the FET is controlled to be switched on or off. When the FET is turned on, a voltage is generated in the subsequent coil, and a voltage lower than the input voltage Vin is generated in the output voltage Vout. On the other hand, when the FET is turned off, the magnetic field energy stored in the coil through the diode is discharged as electric energy, and a stable output voltage Vout is generated in the capacitor by the electric energy. The control unit 18 controls the ratio (duty ratio) between the time when the FET is turned on and the time when the FET is turned off so that the charging current output to the secondary battery 19 becomes a predetermined value. It can be done.

  In the input current detection circuit 21, a resistor and an ammeter are connected in series, and the input current detected by the ammeter is measured by the control unit 18 through the AD conversion unit 24. In the charging current detection circuit 22, a resistor and an ammeter are connected in series, and the charging current detected by the ammeter is measured by the control unit 18 through the AD conversion unit 24. The battery voltage detection circuit 23 detects the battery voltage with a voltmeter, and the detected battery voltage is measured by the control unit 18 through the AD conversion unit 24.

  The current control unit 35 is provided between the input current detection circuit 21 and the conversion circuit 30, and the input current input to the conversion circuit 30 under the control of the control unit 18 according to the supply capability of the power regulator 50. Limit. In the present embodiment, the current control unit 35 disables the restriction on the input current from the power regulator 50 at the start of charging under the control of the control unit 18, thereby disabling the input current detection circuit in the subsequent stage. A maximum current is supplied to 21. At this time, the input current detection circuit 21 detects the maximum value of the input current within a predetermined time, and the control unit 18 measures the maximum value of the input current. The “predetermined period” is a period in which at least an excessive current does not flow through the conversion circuit 30 after the restriction on the input current from the power regulator 50 is invalidated. That is, the “predetermined period” indicates an instantaneous period in which current fluctuation does not occur in the circuit by invalidating the restriction on the input current from the power regulator 50.

(5. Charging pattern table)
Next, the charge pattern table stored in the storage unit 17 will be described. As shown in FIG. 5, in the present embodiment, two types of charge pattern tables are stored separately for charge type A and charge type B. The charge type is based on the maximum value of the input current detected from the input current detection circuit 21 when the conversion circuit 30 is operated after invalidating the restriction on the input current from the power regulator 50. 18 determines the supply capacity of the power regulator 50, and is classified according to the determination result. The control unit 18 controls the conversion circuit 30 based on the charging pattern table to cause the secondary battery 19 to output a charging current having a predetermined value.

  The charge pattern table in charge type A has charge pattern A1 and charge pattern A2. The charging pattern A1 is set so that I2 is output to the secondary battery 19 as a charging current. The charging pattern A1 is set to be switched to the next charging pattern (charging pattern A2) when the battery voltage becomes Vp. The charging pattern A2 is set so that I1 is output to the secondary battery 19 as a charging current. The charging pattern A2 is set to be switched to the next charging pattern (constant voltage charging) when the battery voltage becomes Vchg.

  The charge pattern table in the charge type B has a charge pattern B1, a charge pattern B2, and a charge pattern B3. The charging pattern B1 is set so that I3 is output to the secondary battery 19 as a charging current. The charging pattern B1 is set to be switched to the next charging pattern (charging pattern B2) when the battery voltage becomes Vp. The charging pattern B2 is set such that I2 is output to the secondary battery 19 as a charging current. The charging pattern B2 is set to be switched to the next charging pattern (charging pattern B3) when the battery voltage becomes Vp. The charging pattern B3 is set so that I1 is output to the secondary battery 19 as a charging current. The charging pattern B3 is set to be switched to the next charging pattern (constant voltage charging) when the battery voltage becomes Vchg.

(6. Charging process)
Next, the charging process executed by the control unit 18 will be described. FIG. 6 is a flowchart of the charging process.

  As shown in FIG. 6, when the charging process is executed, the control unit 18 first disables the restriction on the input current from the power regulator 50 by controlling the current control unit 35 in step S1. Thereafter, the control unit 18 operates the conversion circuit 30 to start charging the secondary battery 19 in step S2.

  Next, in step S <b> 3, the control unit 18 measures the maximum value of the input current detected from the input current detection circuit 21 and determines the supply capacity of the power regulator 50 connected to the charging device 20. When the control unit 18 determines that the connected power adjuster 50 is the charge type A based on the determination result of the supply capability in step S3, the control unit 18 includes the charge pattern table stored in the storage unit 17 in step S4. A charge pattern table for charge type A is selected and set. Thereafter, in step S5, the control unit 18 first sets the charging pattern A1 to the charging pattern A1, and controls the conversion circuit 30 to charge the secondary battery 19 based on the charging pattern A1.

  Next, the control part 18 determines whether the battery voltage of the secondary battery 19 detected by the battery voltage detection circuit 23 is Vp at step S6. When the control unit 18 determines in step S6 that the battery voltage of the secondary battery 19 is not Vp (NO in step S6), the control unit 18 sets the charge pattern A1 again and controls the conversion circuit 30 to control the secondary battery. 19 is charged. On the other hand, when it is determined in step S6 that the battery voltage of the secondary battery 19 is Vp (YES in step S6), the control unit 18 determines the charge pattern A2 among the charge patterns in the charge type A in step S7. And the conversion circuit 30 is controlled on the basis thereof to charge the secondary battery 19.

  Next, the control part 18 determines whether constant current charge was completed by step S8. That is, the control unit 18 determines whether or not the battery voltage of the secondary battery 19 is Vchg. When it is determined in step S8 that the constant current charging is not completed (NO in step S8), the control unit 18 sets the charging pattern A2 again and controls the conversion circuit 30 to control the secondary battery 19. Charge. On the other hand, if it is determined in step S8 that constant current charging has been completed (YES in step S8), control unit 18 executes constant voltage charging in step S16 and ends the charging process.

  On the other hand, if the control unit 18 determines that the connected power regulator 50 is the charge type B based on the determination result of the supply capability in step S3, the control unit 18 stores the charge pattern table stored in the storage unit 17 in step S9. Among these, the charge pattern table in charge type B is selected and set. Thereafter, in step S10, the control unit 18 first sets the charging pattern B1 to the charging pattern B1, controls the conversion circuit 30 based on the charging pattern B1, and charges the secondary battery 19.

  Next, the control part 18 determines whether the battery voltage of the secondary battery 19 detected by the battery voltage detection circuit 23 is Vp at step S11. When the control unit 18 determines in step S11 that the battery voltage of the secondary battery 19 is not Vp (NO in step S11), the control unit 18 sets the charge pattern B1 again and controls the conversion circuit 30 to control the secondary battery. 19 is charged. On the other hand, when it is determined in step S11 that the battery voltage of the secondary battery 19 is Vp (YES in step S11), the control unit 18 determines the charge pattern B2 among the charge patterns in the charge type B in step S12. And the conversion circuit 30 is controlled on the basis thereof to charge the secondary battery 19.

  Next, the control part 18 determines whether the battery voltage of the secondary battery 19 detected by the battery voltage detection circuit 23 is Vp at step S13. When determining that the battery voltage of the secondary battery 19 is not Vp in step S13 (NO in step S13), the control unit 18 sets the charge pattern B2 again and controls the conversion circuit 30 to control the secondary battery. 19 is charged. On the other hand, when it is determined in step S13 that the battery voltage of the secondary battery 19 is Vp (YES in step S13), the control unit 18 determines the charge pattern B3 among the charge patterns in the charge type B in step S14. And the conversion circuit 30 is controlled on the basis thereof to charge the secondary battery 19.

  Next, the control part 18 determines whether constant current charge was completed by step S15. That is, the control unit 18 determines whether or not the battery voltage of the secondary battery 19 is Vchg. When it is determined in step S15 that the constant current charging is not completed (NO in step S15), the control unit 18 sets the charging pattern B3 again and controls the conversion circuit 30 to control the secondary battery 19. Charge. On the other hand, if it is determined in step S15 that constant current charging has been completed (YES in step S15), control unit 18 executes constant voltage charging in step S16 and ends the charging process.

  When the control unit 18 executes the charging process described above, even when the power regulator 50 having a different supply capability is connected, current fluctuation can be suppressed and oscillation can be prevented, and the supply capability of the power regulator 50 can be prevented. The secondary battery 19 can be charged with a charging current according to the above.

(7. Example of charging characteristics)
Next, with reference to FIG. 7, an example of charging characteristics in the present embodiment will be described separately for charging type A and charging type B.

  FIG. 7A is a diagram showing the charge characteristics of charge type A in the present embodiment. In the graph showing the charging characteristics, the vertical axis represents charging current and battery voltage, and the horizontal axis represents time. First, during a predetermined period t1 from the start of charging, the control unit 18 controls the current control unit 35 to invalidate the restriction on the input current from the power regulator 50. As a result, the input current becomes maximum, and the maximum current ImaxA flows as the charging current. As a result, the battery voltage rapidly increases during the predetermined period t1. The predetermined period t1 is an instantaneous period in which no current fluctuation occurs in the circuit.

  During the predetermined period t1, the control unit 18 determines the supply capability of the power regulator 50, and sets the charging pattern A1 after t1 based on the determination result. As a result, the charging current is set to I2. Then, as the charging current I2 flows through the secondary battery 19, the battery voltage gradually increases, and the battery voltage becomes Vp at the timing t5. Then, at the timing when the battery voltage becomes Vp, the control unit 18 sets the charging pattern A1 by switching to the charging pattern A2. As a result, the charging current is set to I1. As the charging current I1 flows through the secondary battery 19, the battery voltage begins to rise again, and the battery voltage becomes Vchg, which is a constant voltage, at time t7. The control unit 18 switches the charging pattern from constant current charging to constant voltage charging at the timing when the battery voltage becomes Vchg. In the constant voltage charging, the control unit 18 controls the conversion circuit 30 to adjust and output the value of the charging current so that the battery voltage becomes a constant Vchg. By performing this constant voltage charging, the charging current is gradually reduced, and the charging current becomes a predetermined I0 at the timing t8. When the charging current becomes equal to or lower than the predetermined I0, the secondary battery 19 is no longer charged, and the charging of the secondary battery 19 is completed at the timing t8.

  Next, an example of charge type B will be described. FIG. 7B is a diagram showing the charge characteristics of charge type B in the present embodiment. First, during a predetermined period t1 from the start of charging, the control unit 18 controls the current control unit 35 to invalidate the restriction on the input current from the power regulator 50. As a result, the input current becomes maximum, and the maximum current ImaxB flows as the charging current. As a result, the battery voltage rapidly increases during the predetermined period t1. Note that the maximum value ImaxB of the charging current in the charging type B is higher than the maximum value ImaxA of the charging current in the charging type A, and the power regulator 50 determined as the charging type B is the power adjustment determined as the charging type A. It can be said that the supply capacity is higher than that of the vessel 50.

  During the predetermined period t1, the control unit 18 determines the supply capacity of the power regulator 50, and sets the charging pattern B1 after t1 based on the determination result. As a result, the charging current is set to I3. Then, as the charging current I3 flows through the secondary battery 19, the battery voltage gradually increases, and the battery voltage becomes Vp at the timing of t2. In addition, since the power regulator 50 determined as the charge type B has higher supply capability than the power regulator 50 determined as the charge type A, the charging current I3 set after t1 is t1 in the charge type A. It becomes higher than the charging current I1 set thereafter. As a result, the timing when the battery voltage becomes Vp is earlier in the power regulator 50 determined as the charging type B than in the power regulator 50 determined as the charging type A. At the timing when the battery voltage becomes Vp, the control unit 18 switches and sets the charging pattern B1 to the charging pattern B2. As a result, the charging current is set to I2. As the charging current I2 flows through the secondary battery 19, the battery voltage gradually rises again, and the battery voltage becomes Vp again at the timing t3. Then, at the timing when the battery voltage becomes Vp, the control unit 18 switches and sets the charging pattern B2 to the charging pattern B3. As a result, the charging current is set to I1. As the charging current I1 flows through the secondary battery 19, the battery voltage begins to rise again, and at time t4, the battery voltage becomes Vchg, which is a constant voltage. The control unit 18 switches the charging pattern from constant current charging to constant voltage charging at the timing when the battery voltage becomes Vchg. In the constant voltage charging, the control unit 18 controls the conversion circuit 30 to adjust and output the value of the charging current so that the battery voltage becomes a constant Vchg. By performing this constant voltage charging, the charging current is gradually reduced, and the charging current becomes a predetermined I0 at the timing t6. Note that the predetermined charging current value I0 is the same as the charging current value I0 at the timing when the charging characteristic T8 of the charging pattern A becomes t8. When the charging current becomes equal to or lower than the predetermined I0, the secondary battery 19 is no longer charged, and the charging of the secondary battery 19 is completed at the timing t6. The time t6 when the charging of the secondary battery 19 is completed is earlier than the time t8 when the charging of the secondary battery 19 is completed in the charging type A.

  As described above, in the present embodiment, the power adjuster 50 corresponding to the charge type B has a higher supply capacity than the power adjuster 50 corresponding to the charge type A, and the charge current value is set higher. In addition, the number of charge pattern switching is set to be large. That is, in the present embodiment, since the secondary battery 19 can be charged with a charging current according to the supply capacity of the power regulator 50, the supply capacity is low in the case of the power regulator 50 with high supply capacity. The secondary battery 19 can be charged in a shorter time than the power regulator 50. That is, the secondary battery 19 can be optimally charged with a charging time commensurate with the supply capacity. Furthermore, since the control of the conversion circuit 30 by the control unit 18 becomes unstable and the charging current does not fluctuate and as a result does not become an oscillation state, it is stable within the range of the power regulator 50 supply capability. The secondary battery 19 can be charged.

  As described above, according to the charging device 20, the charging method, and the mobile terminal 10 in the present embodiment, the following effects are exhibited.

  (1) The charging device 20 in the present embodiment is a charging device 20 that charges the secondary battery 19 using the power supplied from the power regulator 50, and converts the power supplied from the power regulator 50. Then, the conversion circuit 30 that outputs the charging current for charging the secondary battery 19, the input current detection circuit 21 that detects the input current input from the power regulator 50 to the conversion circuit 30, and the secondary battery from the conversion circuit 30 A charging current detection circuit 22 for detecting the charging current output to the control circuit 18 and a control unit 18 for controlling the conversion circuit 30. The control unit 18 operates the conversion circuit 30 after invalidating the restriction on the input current. Then, based on the input current measuring means for measuring the maximum value of the input current detected from the input current detection circuit 21 (steps S1 to S3 of the charging process in FIG. 6) and the measured maximum value of the input current, Supply capacity determination means for determining the supply capacity of the force adjuster 50 (step S3 of the charging process in FIG. 6), and a conversion circuit that controls the conversion circuit 30 so that a charging current corresponding to the determined supply capacity is output. Control means (steps S4 to S15 of the charging process in FIG. 6).

  According to this, since the secondary battery 19 can be charged with a charging current corresponding to the supply capacity of the power regulator 50, the secondary battery 19 can be stably charged within the range of the supply capacity of the power regulator 50. can do.

  (2) Moreover, the charging device 20 in the present embodiment further includes a storage unit 17 that stores a plurality of charging pattern tables according to supply capability (charging pattern table in FIG. 5) according to the supply capability of the power regulator 50. The conversion circuit control means (steps S4 to S15 of the charging process in FIG. 6) supplies a plurality of supplies according to the supply capacity of the power regulator 50 determined by the supply capacity determination means (step S3 of the charging process in FIG. 6). One charge capacity-specific charge pattern table is selected from the charge pattern by capacity (charge pattern table in FIG. 5), and the conversion circuit 30 is controlled based on the selected charge pattern table by supply capacity.

  According to this, since the secondary battery 19 can be charged on the basis of the charging pattern table (charging pattern table in FIG. 5) according to the supply capacity corresponding to the supply capacity of the power regulator 50, the supply of the power regulator 50 The secondary battery 19 can be charged stably within the capacity range.

  (3) In addition, the charging device 20 in the present embodiment further includes a battery voltage detection circuit 23 that detects the battery voltage of the secondary battery 19, and the charging pattern table by supply capacity (charging pattern table in FIG. 5) is: A plurality of charge patterns (charge pattern A1, charge pattern A2 in charge pattern A, charge pattern B1 in charge pattern B, charge pattern B2, charge pattern B3 in FIG. 5) according to the battery voltage, and conversion circuit control means (FIG. Steps S4 to S15) of the charging process in No. 6 control the conversion circuit 30 by switching a plurality of charging patterns based on the battery voltage detected by the battery voltage detection circuit 23.

  According to this, since the secondary battery 19 can be charged by switching the charge pattern included in the charge pattern table for each supply capacity (the charge pattern table in FIG. 5) based on the battery voltage of the secondary battery 19, The secondary battery 19 can be charged stably.

  (4) Moreover, in the charging apparatus 20 in this Embodiment, the control part 18 converts according to the supply capability of the power regulator 50 determined by the supply capability determination means (step S3 of the charging process in FIG. 6). It further includes input current limiting means for controlling the input current input to the circuit 30 (control of the current control unit 35 by the control unit 18).

  Accordingly, the input current input to the conversion circuit 30 can be limited based on the supply capacity of the power regulator 50.

  (5) Moreover, in the charging device 20 in the present embodiment, the input current measuring means (steps S1 to S3 of the charging process in FIG. 6) sets the maximum value of the input current for a predetermined time at the start of charging of the secondary battery 19. Measure within.

  According to this, the maximum value of the input current can be measured within a predetermined time at the start of charging of the secondary battery 19.

  (6) In addition, the charging method in the present embodiment is a charging method for charging the secondary battery 19 using the charging current output by the conversion circuit 30 that converts the power supplied from the power regulator 50. The step of detecting the input current input from the power regulator 50 to the conversion circuit 30, the step of detecting the charging current output from the conversion circuit 30 to the secondary battery 19, and the limitation on the input current are invalidated. A step of measuring the maximum value of the detected input current by operating the conversion circuit 30 above (steps S1 to S3 of the charging process in FIG. 6), and a power regulator based on the measured maximum value of the input current A step of determining the supply capacity of 50 (step S3 of the charging process in FIG. 6) and a step of controlling the conversion circuit 30 so as to output a charging current according to the determined supply capacity. Tsu and a flop (step S4~S15 the charging process in Fig. 6).

  According to this, since the secondary battery 19 can be charged with a charging current corresponding to the supply capacity of the power regulator 50, the secondary battery is stably charged within the range of the supply capacity of the power regulator 50. be able to.

  (7) In addition, the mobile terminal 10 according to the present embodiment includes a secondary battery 19 and loads (such as the camera unit 14, the voice input / output unit 15, and the display unit 13 illustrated in FIG. 2) that operate on the secondary battery 19. A portable terminal 10 including a conversion circuit 30 that converts power supplied from the power regulator 50 and a charging device 20 that charges the secondary battery 19 using the charging current output by the conversion circuit 30. The charging device 20 converts the power supplied from the power regulator 50 to output a charging current for charging the secondary battery 19, and the input current input from the power regulator 50 to the conversion circuit 30. An input current detection circuit 21 that detects the charging current, a charging current detection circuit 22 that detects a charging current output from the conversion circuit 30 to the secondary battery 19, and a control unit 18 that controls the conversion circuit 30. Is the input power An input current measuring means for operating the conversion circuit 30 after invalidating the restriction on the input and measuring the maximum value of the input current detected from the input current detection circuit 21 (steps S1 to S3 of the charging process in FIG. 6) Then, based on the measured maximum value of the input current, the supply capability determination means (step S3 of the charging process in FIG. 6) for determining the supply capability of the power regulator 50, and the charging current according to the determined supply capability Conversion circuit control means (steps S4 to S15 of the charging process in FIG. 6) for controlling the conversion circuit 30 so as to be output.

  According to this, since the secondary battery 19 can be charged with a charging current corresponding to the supply capacity of the power regulator 50, the secondary battery 19 can be stably charged within the range of the supply capacity of the power regulator 50. can do.

  Next, a modification of the above-described embodiment will be described. In the above-described embodiment, the mobile terminal 10 is used as an example of the electronic device. However, the present invention is not limited to this. For example, other electronic devices may be used as long as they use a rechargeable secondary battery as a power source, such as a notebook computer or a portable game machine.

  In the above-described embodiment, as an example of the power regulator, an AC adapter that has a function of converting AC power from a commercial power source into DC power, such as an AC adapter, needs to be limited to this. There is no. For example, it may be one that uses power from a personal computer as a power source instead of using power from a commercial power supply such as a USB-type portable charger, and other electronic devices connected to the electronic device. Any battery that can charge the internal secondary battery may be used.

  In the above-described embodiment, as shown in FIG. 3, the input current detection circuit 21, the charging current detection circuit 22, the battery voltage detection circuit 23, the AD conversion unit 24, the storage unit 17, and the control unit 18 are charged. Although the circuit 25 and the circuit 25 are separately provided, it is not necessary to be limited to this. For example, it may be a one-chip IC having all these functions, or may have other forms.

  In the above-described embodiment, the conversion circuit 30 uses a chopper type step-down converter as shown in FIG. 4, but the present invention is not limited to this, and other circuits may be used. Further, the input current detection circuit 21, the charging current detection circuit 22, the battery voltage detection circuit 23, and the current control unit 35 may be included in the conversion circuit 30.

  In the above-described embodiment, as shown in FIG. 5, two types of charging pattern tables (charging pattern table in charging type A, charging pattern table in charging type B) are used for each supply capacity of power regulator 50. Although the charge pattern was distributed, it is not necessary to be limited to this. For example, a plurality of other types of charging pattern tables such as three types of charging pattern tables may be stored in the storage unit 17 and used by the control unit 18.

  In the embodiment described above, as shown in FIG. 5, two types of charging patterns (charging pattern A1 and charging pattern A2 and charging in charging type B if the charging pattern table in charging type A is used) based on the battery voltage. In the case of the pattern table, the control unit 18 switches the charging pattern B1 and the charging pattern B2) to charge the secondary battery 19, but it is not necessary to be limited to this. For example, the surface temperature of the secondary battery 19 may be detected, and the controller 18 may charge the secondary battery 19 by switching the charging pattern based on the detected surface temperature or the like. Further, the control unit 18 may charge the secondary battery 19 by switching the charging pattern based on the voltage drop when the battery voltage drops below the peak value. Further, the control unit 18 may charge the secondary battery 19 by switching the charging pattern based on the charging time. In addition to the two types of charge pattern tables, a plurality of other types of charge pattern tables such as three types of charge pattern tables may be set. Furthermore, the charging patterns set for each charging pattern table are not limited to two or three types, and other plural types of charging patterns may be switched in a plurality of stages according to the supply capacity of the power regulator 50. .

  It should be understood that the embodiment disclosed this time is illustrative in all respects and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 10 Portable terminal, 17 Memory | storage part, 18 Control part, 19 Secondary battery, 20 Charging apparatus, 21 Input current detection circuit, 22 Charging current detection circuit, 23 Battery voltage detection circuit, 25 Charging control circuit, 30 Conversion circuit, 35 Current Control unit, 50 power regulator.

Claims (5)

A charging device for charging a secondary battery using electric power supplied from a power regulator,
A conversion circuit that converts the power supplied from the power regulator and outputs a charging current for charging the secondary battery;
An input current detector for detecting an input current input from the power regulator to the converter circuit;
A charging current detector for detecting the charging current output from the conversion circuit to the secondary battery;
Control means for controlling the conversion circuit,
The control means includes
An input current measuring means for operating the conversion circuit after invalidating the restriction on the input current and measuring the maximum value of the input current detected from the input current detection unit;
Supply capability determination means for determining the supply capability of the power regulator based on the measured maximum value of the input current;
Input current limiting means for limiting the input current input to the conversion circuit according to the determined supply capability;
And a conversion circuit control means for controlling the conversion circuit so that a charging current corresponding to the determined supply capability is output. A storage unit that stores a plurality of charge pattern tables according to supply capacity according to the supply capacity of the power regulator;
The conversion circuit control means selects one charge capacity-specific charge pattern table from the plurality of supply capacity-specific charge pattern tables according to the supply capacity of the power regulator determined by the supply capacity determination means, The charging device according to claim 1, wherein the conversion circuit is controlled based on the selected charging pattern table by supply capacity. A battery voltage detector for detecting a battery voltage of the secondary battery;
The charging pattern table by supply capacity includes a plurality of charging patterns according to the battery voltage,
The charging device according to claim 2 , wherein the conversion circuit control means controls the conversion circuit by switching the plurality of charging patterns based on the battery voltage detected by the battery voltage detection unit. . A charging method for charging a secondary battery using a charging current output by a conversion circuit that converts electric power supplied from a power regulator,
Detecting an input current input from the power regulator to the conversion circuit;
Detecting the charging current output from the conversion circuit to the secondary battery;
Operating the conversion circuit after disabling the restriction on the input current and measuring the detected maximum value of the input current;
Determining the supply capacity of the power regulator based on the measured maximum value of the input current;
Limiting the input current input to the conversion circuit according to the determined supply capability;
Controlling the conversion circuit so that a charging current corresponding to the determined supply capability is output. A secondary battery, a load that operates on the secondary battery, a conversion circuit that converts the power supplied from the power regulator, and a charging device that charges the secondary battery using a charging current output by the conversion circuit An electronic device comprising:
The charging device is:
A conversion circuit that converts the power supplied from the power regulator and outputs a charging current for charging the secondary battery;
An input current detector for detecting an input current input from the power regulator to the converter circuit;
A charging current detector for detecting the charging current output from the conversion circuit to the secondary battery;
Control means for controlling the conversion circuit,
The control means includes
An input current measuring means for operating the conversion circuit after invalidating the restriction on the input current and measuring the maximum value of the input current detected from the input current detection unit;
Supply capability determination means for determining the supply capability of the power regulator based on the measured maximum value of the input current;
Input current limiting means for limiting the input current input to the conversion circuit according to the determined supply capability;
An electronic device comprising: a conversion circuit control unit that controls the conversion circuit so that a charging current corresponding to the determined supply capability is output.