JPH08186941A - Charge control system - Google Patents

Abstract

PURPOSE: To prevent the trouble of the charging stop before the completion of charging by discriminating the decrease in charging voltage caused by the completion of charging from the decrease in charging voltage caused by driving of equipment. CONSTITUTION: This system is constituted of a charging device 10, a battery pack 20 and a portable telephone 30. A CPU 32 built in the portable telephone judges the decrease in charging voltage caused by the driving of the portable telephone and output a -ΔV cancel signal to the side of the charging device through signal lines 17 and 37. Meanwhile, when a CPU 15 built in the charging device receives the above described -ΔV cancel signal, the CPU 15 can identify that the decrease is not the decrease in battery voltage caused by the completion of the charging. Thus, the trouble of stopping the charging before the completion of the charging can be prevented.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging control system for a battery which is a driving source for electronic equipment, and more particularly,
It is used for control to determine the timing of completion of charging.

[0002]

2. Description of the Related Art When a nickel-cadmium battery or a nickel-hydrogen battery is charged, as shown in FIG. 4, the voltage rises with the progress of charging, and once the voltage reaches a peak value, it drops slightly. have. Therefore,
The charger utilizes this characteristic to detect that the battery voltage has dropped from the peak value, that is, the battery charging voltage drop, determine the completion of charging, and stop charging.

[0003]

However, recently, there are some mobile phones, notebook computers, and the like which are used with a battery set in the device, and these are driven even during charging. Therefore, the battery voltage drops due to the load current due to this drive, and as a result, the charger erroneously detects the voltage drop due to the drive of the device as the voltage drop due to the completion of charging, and charging is performed before the completion of charging. There is a problem of stopping it.

Therefore, the present invention has been made in view of the above problems, and prevents the battery voltage drop due to the completion of charging and the battery voltage drop due to driving of the device, and prevents the charging from being stopped before the completion of charging. An object of the present invention is to provide a charging control system that operates.

[0005]

Therefore, the present invention is based on FIG.
As shown in, an electronic device (30), a battery pack (20) connected to the electronic device, and a charger that charges the battery built in the battery pack and also serves as a power supply for the electronic device ( 10), wherein the electronic device includes a load circuit (31), a signal output unit (37) for outputting a signal to the charger via a signal line, and a load circuit of the load circuit. An electronic device side control unit (3) that controls the load circuit and the signal output unit according to the state
2) and the electronic device-side control section includes a current consumption determining means (S40) for determining whether or not the magnitude of the current value consumed by the load circuit is larger than a predetermined value, and the current consumption Signal output instructing means (S50) for instructing to output a predetermined signal from the signal output section when the determination means determines that the battery is built in the battery pack. A charging circuit (11) for controlling a charging current to be supplied, a battery voltage detection resistor (13) for generating a voltage according to the battery voltage, and a signal input for inputting a signal from the electronic device via the signal line. Division (17)
And a charger-side control unit (15) that controls the charging circuit based on the voltage value and the signal from the battery voltage detection resistor and the signal input unit, wherein the charger-side control unit is
A storage unit (S220) for storing the peak value of the battery voltage from the battery voltage detection resistor, and the storage unit when the predetermined signal from the electronic device is input to the signal input unit. Reset means (S270, S280) for resetting the peak value, and a battery built in the battery pack when it is detected that the battery voltage from the battery voltage detection resistor has dropped from the peak value of the battery voltage by a certain value. Is a full-charged state, and full-charge determination means (S290, S300), and charging for stopping the charging operation of the charging circuit when the full-charge determination means determines that the full-charged state is The control means (S310) is adopted.

Further, the charger has a charger-side signal output section (16) for outputting a signal to the electronic device via a signal line, and the electronic device receives the signal from the charger-side signal output section. The electronic device side signal input section (36) for inputting is provided, and two independent communication lines including the signal output section and the signal input section are configured, and bidirectional communication is possible. Further, the charger is provided with a display unit (18) which is connected to the charging device side control unit and displays a charging state under the control of the charging device side control unit. Further, the electronic device is connected to the electronic device side control section (34),
An information display unit that displays information is configured under the control of the electronic device-side control unit.

[0007]

With the above structure, the current consumption determining means determines whether or not the magnitude of the current value consumed by the load circuit is larger than a predetermined value. A predetermined signal is output from the signal output section by the output instructing means. That is, the electronic device determines that the battery voltage has dropped due to the driving of the electronic device, and outputs to the charger side via the signal line that the battery voltage has not dropped due to full charge.

On the other hand, in the charger, the peak value of the battery voltage is stored in the storage means, and when the predetermined signal is input from the electronic device side in the reset means, the peak value stored in the storage means. Is to be reset. At this time, the full-charge determination means determines that the battery is in a fully-charged state when it detects that the value of the battery voltage has dropped from the peak value by a certain value. That is, when the above-described predetermined signal is input from the electronic device side, the peak value is in the reset state, and therefore full charge cannot be determined.

That is, when the battery voltage drops due to the driving of the electronic device, the charger can recognize from the signal from the electronic device that this is not the battery voltage drop due to the completion of charging, and before the completion of charging. It is possible to prevent the charging from being stopped. In addition, since the electronic device itself determines not the charger side that the battery voltage has dropped due to the driving of the electronic device, an accurate determination can be made.

Further, since two independent communication lines are formed and bidirectional communication is possible, it is possible to share the information obtained on the charger side or the information obtained on the electronic device side. For example, if the charger side determines that the battery is fully charged, the determination is transmitted to the electronic device side, and the electronic device side obtains the information on the full charge. Therefore, the electronic device side transmits this state to the charger side when current is consumed in the load circuit while the information on full charge is obtained. As a result, the charger side obtains the information that the current is consumed from the fully charged state, and if the charging operation is performed according to this information, the battery can always be maintained in the fully charged state.

Further, the charger is provided with a display section for displaying the state of charge, and the electronic device is also provided with an information display section for displaying information. Therefore, a user who uses this electronic device can accurately and easily obtain the information on the charging state and the electronic device.

[0012]

The present invention will be described below based on the embodiments shown in the drawings. FIG. 1 shows an example of a charging control device embodying the present invention. This device shows a charging system for a mobile phone, and as shown in FIG.
It is composed of a battery pack 20 and a mobile phone 30.
The mobile phone 30 is configured so that the battery pack 20 can be attached, and is driven by the power supply from the battery pack 20. Further, the charger 10 is connected to an external power source (AC / DC) and has a mounting portion for mounting the mobile phone 30, and supplies a current from the external power source to the battery pack 20 and the mobile phone 30. .

The charger 10 is mainly composed of a charging circuit 11, a charging current detecting circuit 12, a battery voltage detecting resistor 13, a battery temperature detecting resistor 14, and a microcomputer 15 (hereinafter referred to as CPU 15). The charging circuit 11 is controlled based on the signal from the detection unit. The charging circuit 11 is connected to an external power source, and the CPU
The magnitude of the charging current to the battery pack 20 is changed by the control from 15. Charging current detection circuit 1
2 is arranged between the charging current supply lines of the charging circuit 11 and the battery pack 20, and the current value flowing through the charging current supply line is input to the CPU 15. The battery voltage detection resistor 13 is connected to the charging current supply line of the charging circuit 11, and inputs the voltage value of the nickel-hydrogen battery 21 built in the battery pack 20 to the CPU 15. Further, the battery temperature detecting resistor 14 is divided into a thermistor 22 built in the battery pack 20,
A voltage according to the temperature of the battery pack 20 is input to the CPU 15. Since the signal from the detection unit is an analog value, the CPU 15 has a built-in A / D converter.

The charger 10 is also provided with signal lines 16 and 17 for enabling bidirectional communication with the mobile phone 30 via the battery pack 20, and is connected to the CPU 15. The charger 10 is covered with a plastic casing, and the casing surface has a display unit 18 for displaying the charging state of the battery pack 20 to the user.
Is provided, and its display state is changed under the control of the CPU 15.

The battery pack 20 includes a nickel-hydrogen battery 21 which is a secondary battery, a thermistor 22 for temperature measurement, a breaker 23 for preventing damage to the nickel-hydrogen battery 21 due to overcharging, a charger 10 and a mobile phone 30. The signal lines 26 and 27 for enabling the two-way communication are internally configured. The battery pack 20 is also covered with a plastic casing, and the charger 10 is provided on the outer surface thereof.
Also, the plurality of conductor plates are exposed so that the power supply line and the signal line contact each other when attached to the mobile phone 30.

The mobile phone 30 has an internal circuit 31 which becomes a load when driven, a microcomputer 32 (hereinafter referred to as CPU 32) which controls the internal circuit 31, and a voltage value of a nickel hydrogen battery 21 incorporated in the battery pack 20. The battery voltage detection resistor 33 for inputting to the CPU 32, and the signal lines 36 and 37 for enabling bidirectional communication with the charger 10 via the battery pack 20. In addition, CPU
32 has a built-in A / D converter that can detect the current consumption of the internal circuit 31 and the CPU 32 itself and that converts the voltage value from the battery voltage detection resistor 33 into a digital value. In addition, the mobile phone 30 is also covered with a plastic casing, and on the surface of the casing, an operation unit necessary for a telephone function and a status display unit 34 including a liquid crystal display and the like are provided in addition to the operation unit. ,
The display content changes according to the control of the CPU 15.

Next, the operation of the above configuration is performed by the CPU 32, CP.
Each will be described based on the processing operation of U15. 2 is a flowchart showing the processing operation of the CPU 32, and FIG. 3 is a flowchart showing the processing operation of the CPU 15. In FIG. 2, the processing operation of the CPU 32 on the mobile phone 30 side will be described. First, a signal from the internal circuit 31 is input depending on whether the owner of the mobile phone 30 calls the other party or receives a call from the other party. Control various circuits (S10, 20). Next, the current consumed by the load circuit (internal circuit 31, CPU 32 itself) in accordance with this control is detected (S30). At this time, the charging current to the battery pack 20 decreases due to the consumption current of the load circuit, the battery voltage drops, and a battery voltage fluctuation curve similar to the battery charging voltage drop (−ΔV) occurs. (See FIG. 5) Here, based on the detected current consumption, whether or not the current consumption by driving the load circuit affects the −ΔV detection, that is, the current consumed by the load circuit is larger than a predetermined value. It is determined whether or not (S40). Then, if it is determined that the magnitude of the consumed current has an influence on the detection of −ΔV, a −ΔV cancel signal is transmitted from the signal line 37 to the charger 10 (S50).

Next, it is judged whether or not a signal regarding charging abnormality is received from the charger 10 side, and if it is received, the received signal regarding charging abnormality is decoded,
The decoded contents are displayed on the status display unit 34 (S6).
0,70). Next, the voltage value from the battery voltage detection resistor 33 is detected, and it is determined whether or not the battery voltage is abnormal according to the detected voltage value. The content of the battery voltage abnormality is displayed at 34 (S80-100).

In FIG. 3, the CPU 15 on the charger 10 side
The processing operation will be described. First, whether or not the mobile phone 30 including the battery pack 20 is set in the charger 10 depending on whether the input from the battery voltage detection resistor 13 or the input from the battery temperature detection resistor 14 is detected. Is determined (S200). If set, the voltage value of the nickel hydrogen battery 21 is detected based on the input from the battery voltage detection resistor 13 (S210). If the detected voltage value is larger than the peak value that has been set so far, the voltage value detected this time is updated as the peak value, and the voltage value detected this time has been set so far. If it is smaller than the peak value, the peak value set so far is retained as it is. If the peak value is in the reset state (not stored), the detected voltage value is set as it is (S220).

Next, the input from the battery temperature detecting resistor 14,
Further, the temperature and the charging current value of the battery pack 20 are detected based on the input from the charging current detection circuit 12. At this time, if the detected temperature and charging current value are not within the set predetermined range, the charging state is determined to be abnormal (S230 to 250). If a charge abnormality is determined in this determination, a charge abnormality signal is transmitted from the signal line 16 to the mobile phone 30 according to the state of the charge abnormality (S260, 270). On the other hand, if the charging is not abnormal, it is determined based on the input from the signal line 17 whether or not the mobile phone 30 is transmitting the -ΔV cancel signal (S280).

Here, if the -ΔV cancel signal is transmitted, the peak value of the battery voltage that has been set up to now is reset (S290). On the other hand, if the −ΔV cancel signal is not transmitted, the difference between the peak value of the battery voltage and the voltage value detected this time is set stepwise according to the battery charging voltage drop (−ΔV: the temperature of the battery pack 20). Threshold value), and if so, it is determined that the battery pack 20 is fully charged (S300). That is, even if the voltage drop of the battery pack 20 occurs during charging due to the driving of the mobile phone 30 and the same phenomenon as the battery charge voltage drop due to full charge occurs, the -ΔV cancel signal is input from the mobile phone 30. , The peak value of the battery voltage is reset, and the battery charging voltage drop is not judged.
Therefore, erroneous detection of −ΔV due to driving of the mobile phone 30 can be prevented, and accurate −ΔV detection can always be performed.

Next, the charging circuit 11 controls the magnitude of the charging current to the battery pack 20. At this time, when it is determined that the battery is fully charged by the above-described processing, when the battery is not set, or when the charging is abnormal, the charging circuit 11 shuts off the charging current to the battery pack 20. On the other hand, in other cases, that is, when the −ΔV cancel signal is input, or when the full charge is not determined by the −ΔV detection, the supply of the charging current is maintained or the charging is performed according to the battery voltage. Change the magnitude of the current (S
310). Then, the state at this time, that is, whether the battery is being charged or fully charged is displayed on the display unit 18 (S320).

Although the full charge is determined in S310,
When the determination that the battery is fully charged is transmitted to the mobile phone 30 side via the signal line 16, and after the mobile phone 30 receives the full charge determination, the mobile phone 30 consumes the current of the battery pack 20 by driving. A process of transmitting a signal requesting recharging from the mobile phone 30 side to the charger 10 via the signal line 37 is added. As a result, the charger 10 side is
Information that the current is consumed is obtained from the fully charged state, and if the charging operation is performed according to this information, the battery pack 2
0 can be always maintained in a fully charged state. When the mobile phone 30 is driven during charging, the mobile phone 30
A signal requesting further extension of charging may be output.

Regarding the signal line, the charging pack 20
Although the communication is performed via the inside, for example, the charger 10 and the mobile phone 30 may be connected by an external connector and may not be passed through the inside of the charging pack 20. Further, the two independent communication lines (16, 17) and (36, 37) may each be integrated. Further, although the breaker 23 is incorporated in the battery pack 20, the invention is not limited to this, and the poly switch,
A fuse or the like may be used.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of the present invention.

FIG. 2 is a flowchart showing a process of a CPU 32 shown in FIG.

FIG. 3 is a flowchart showing a process of a CPU 15 shown in FIG.

FIG. 4 is a characteristic diagram showing a voltage change with respect to a charging time of a nickel hydrogen battery.

FIG. 5 is a characteristic diagram showing a voltage change when an electronic device is used during charging.

[Explanation of symbols]

 10 Charger 11 Charging Circuit 13 Battery Voltage Detection Resistor 15 CPU 17 Signal Line 20 Battery Pack 30 Mobile Phone 31 Load Circuit 32 CPU 37 Signal Line

Claims (4)

[Claims] 1. A charging control system comprising: an electronic device; a battery pack connected to the electronic device; and a charger for charging a battery contained in the battery pack and also serving as a power supply for the electronic device. The electronic device includes a load circuit, a signal output unit that outputs a signal to the charger via a signal line, and an electronic device that controls the load circuit and the signal output unit according to a state of the load circuit. The electronic device-side control unit includes a current-consumption determining unit that determines whether or not a magnitude of a current value consumed by the load circuit is larger than a predetermined value, and the current-consumption determining unit. Signal output instructing means for instructing to output a predetermined signal from the signal output unit when it is determined that the charging current is supplied to the battery built in the battery pack. A charging circuit to control, a battery voltage detection resistor that generates a voltage according to the battery voltage, a signal input unit that inputs a signal from the electronic device via the signal line, the battery voltage detection resistor and the signal A charger-side control unit that controls the charging circuit based on a voltage value and a signal from an input unit, and the charger-side control unit stores a peak value of a battery voltage from the battery voltage detection resistor. Means, reset means for resetting the peak value stored in the storage means when the predetermined signal from the electronic device is input to the signal input section, and battery voltage from the battery voltage detection resistor A full-charge determination unit that determines that the battery built in the battery pack is in a fully-charged state when it is detected that the battery voltage falls from a peak value by a certain value, and a full-charge determination unit. Charge control system, characterized in that it and a charging control means for stopping the charging operation of the charging circuit when it is in a fully charged state by means determines. 2. The charging control system according to claim 1, wherein the charger has a charger-side signal output unit that outputs a signal to the electronic device via a signal line, and the electronic device is the charger. It has an electronic device side signal input section for inputting a signal from the side signal output section, and two independent communication lines are configured including the signal output section and the signal input section to enable bidirectional communication. A charging control system characterized by. 3. The charging control system according to claim 1, wherein the charger is connected to the charging device side control unit and displays a charging state according to the control of the charger side control unit. A charging control system comprising: 4. The charging control system according to claim 1, wherein the electronic device is connected to the electronic device-side control section,
A charging control system comprising an information display section for displaying information according to the control of the electronic device side control section.