JPH08106922A - Charging device - Google Patents

Abstract

PURPOSE: To stably, surely charge a secondary battery independent of load variation during charge by repeating trickle charge and quick charge according to a detected value of battery voltage, and controlling charge so as to become full charge. CONSTITUTION: A charging control microcomputer 2 detects battery voltage VB of a battery pack 11 with a detecting signal 9, and controls a quick charge(QC) constant current circuit 3 and a trickle charge(TC) constant current circuit 4 to perform QC and TC. Mounting of the battery is detected to start an abnormality detecting timer 20, a charge display lamp 51 is lit, and when voltage VB is lower than 5.5V, TC is performed for one minute, then whether VB→VB1 >5.5V or not is judged. If not, QC is performed for 10 seconds, then TC is performed, and VB→VB2 >5.5V is judged. If not, VB2 -VB1 >1.5V is calculated and judged. If not and when the timer 20 elapsed for 24 minutes, a battery abnormality lamp 53 is lit, and charging is discontinued, but in the other case, QC is continued and when full charge is detected, a full charge lamp 52 is lit. Even if load variation arises during charge, a secondary battery is stably, surely charged.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device used for charging a secondary battery mounted on a mobile electronic device such as a mobile phone.

[0002]

2. Description of the Related Art In portable electronic devices such as mobile phones and laptop computers, a rechargeable secondary battery is mounted as a battery pack, and the charging terminal of the secondary battery is charged by a charging device connected to a commercial power source. Charging is done by connecting to the terminals. In this case, normally, charging is performed with the battery pack mounted in the main body of the portable electronic device.

FIG. 3 is a flowchart showing charge control performed by a conventional charger. Here, the secondary battery (1.2
The control operation performed by the charging control microcomputer for the charger for charging the required power source by connecting five V NiCd batteries in series will be described.

First, when it is detected that the battery pack is attached (S31), an abnormality detection timer is started (S32), and a message indicating that the battery is being charged is displayed (S33).
Then, it is confirmed whether or not the battery voltage V _B detected by the battery voltage detection circuit is smaller than 5.5 V (S34), 5.5.
If it is smaller than V (Yes in S34), trickle charging is performed (S35). Note that trickle charging means flowing a minute current of about 20 mA at the start of charging to protect the charger by avoiding rapid charging of a short-circuited battery.

If the battery voltage is still below 5.5V after 24 minutes by the abnormality detection timer (Yes in S36), it is determined that the battery to be charged is an abnormal battery. Then, the abnormality detection is displayed (S37), and the charging is immediately stopped (S38). on the other hand,
When the detected battery voltage exceeds 5.5 V (S34
In case of No), quick charging is performed (S4).
1). When the full charge is detected (Yes in S42), the full charge is displayed (S43).

It should be noted that there is a time limit for the detection of the full charge, and the abnormality detection is displayed, but the flow description is omitted because it is not directly related to the present invention.

[0007]

However, in the above-described conventional charging operation, for example, when an attempt is made to charge a mobile phone equipped with an overdischarge battery having a battery voltage of 2V,
At first, the battery voltage naturally rises due to trickle charging, but a certain voltage (for example, 4.
If the system starts once when the voltage reaches 5 V, the current (about 100 to 150 m) exceeding the trickle current is reached.
A) will be consumed by the mobile phone circuit, and all the charging current at that time will be consumed by the mobile phone circuit. As a result, the charging current to the secondary battery is completely lost, the battery voltage does not rise further, and there is a problem that an abnormality detection display is made when 24 minutes of the detection time has elapsed. .

The present invention has been made in order to solve such a problem, and it is possible to reliably and reliably charge a secondary battery mounted in a portable electronic device without being affected by load fluctuations during charging. It is an object of the present invention to provide a charging device that can be carried out.

[0009]

In order to achieve the above-mentioned object, the invention according to claim 1 is a charging device for charging a secondary battery mounted in a portable electronic device, wherein a charging time is reduced. A timer for measuring the time, a battery voltage detecting means for detecting the battery voltage for a predetermined detection time, and trickle charging for the first charging time when the detected battery voltage is lower than a first threshold value. A first charging means,
A second step of performing trickle charging subsequent to the rapid charging for a second charging time when the battery voltage is still below the first threshold value as a result of the charging by the first charging means.
And the result of charging by the second charging means,
The battery voltage has not yet exceeded the first threshold,
And, the charging voltage by the second charging means and the first voltage
Recharging instructing means for instructing the first charging means to recharge when the difference between the charging voltage by the charging means and the charging voltage does not exceed the second threshold value; and the second charging means. When the battery voltage exceeds the first threshold value as a result of the charging by the third charging means, a third charging means is provided for performing rapid charging until the battery reaches full charge.

The invention according to claim 2 is the first invention.
Is set as a lower limit value of the secondary battery voltage sufficient to ensure normal circuit operation of the portable electronic device, and the second threshold value is provided by charging the second charging means. It is characterized in that it is set as a lower limit value of the amount of increase in the charging voltage. In the invention according to claim 3, the first charging time is set as a voltage rising time sufficient to charge a secondary battery in an over-discharged state, and the second charging time is the second charging time. It is characterized in that it is set as a time sufficient to rapidly charge the secondary battery while covering the current consumption that may occur during charging by the second charging means.

[0011]

According to the structure of the invention of claim 1, the time for charging the secondary battery is measured by the timer. Also,
By the battery voltage detection means, over a predetermined detection time,
The battery voltage is detected. Here, when the detected battery voltage is lower than the first threshold value, the trickle charging is performed by the first charging unit for the first charging time. Furthermore, as a result of charging by the first charging means, when the detected battery voltage is still below the first threshold value, the second charging means performs the rapid charging for the second charging time. , And then the Tokuriru charge is performed.

Then, as a result of charging by the second charging means, the detected battery voltage has not exceeded the first threshold value, and the voltage and the previous charging voltage by the first charging means have been exceeded. If the difference between and does not exceed the second threshold value, the recharging instruction means instructs the first charging means to recharge. When the detected battery voltage exceeds the first threshold value as a result of charging by the second charging means, the third charging means rapidly charges the secondary battery until it reaches full charge. Charging is done.

As a result of the above, when the secondary battery is charged while it is mounted on the portable electronic device, it is possible to reliably reach full charge even if there is a load change. If the battery voltage does not exceed the threshold value within the predetermined detection time, it is determined that the battery is abnormal and charging is stopped.
Further, according to the configuration of the invention of claim 2, in the charging device of claim 1, the first threshold value is a secondary battery voltage sufficient to ensure normal circuit operation of the portable electronic device. The second threshold value is set to the lower limit value, and the second threshold value is set to the lower limit value of the increase in the charging voltage that should be brought about by the charging of the second charging means.

According to the configuration of the invention of claim 3 above, in the charging device of claim 1 or 2,
The first charging time is set to a time that is necessary and sufficient for the voltage increase in consideration of the fact that the voltage increase due to the charging of the secondary battery in the over-discharged state does not progress easily. In addition, the second charging time is a time sufficient to rapidly charge the secondary battery while covering the current consumption in consideration of the fact that the portable electronic device starts up the system and current consumption occurs during charging. Is set to.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be specifically described below with reference to the drawings. FIG. 1 is a block diagram showing a circuit configuration of a charging device according to the present invention. As shown in the figure, the charging device 1 displays a charging control microcomputer 2 that receives a power supply and controls charging, a quick charging constant current circuit 3, a trickle charging constant current circuit 4, and a charging state. A display unit 5 (comprising a charge display lamp 51, a full charge display lamp 52, and an abnormal battery display lamp 53) is provided. Also, there are two types of charging modes, one is a trickle charging mode in which a minute current (about 20 mA) is supplied to avoid rapid charging of a short battery at the start of charging, and the other one is an original charging mode. A certain quick charge (about 650m
A current) mode. Then, the charge control microcomputer 2 switches between these two charging modes.

The charge control microcomputer 2 operates the trickle charge constant current circuit 4 by turning on the trickle charge ON signal 7 at the time of trickle charging, and turns on the quick charge ON signal 6 at the time of rapid charging to turn on the quick charge ON signal 6 rapidly. The charging constant current circuit 3 is turned on. On the other hand, as shown in the figure, here, the charging constant current circuits 3 and 4 are
The charging plus terminal is connected to the charging plus terminal of the battery pack 11. Then, when the battery pack 11 is attached to the mobile phone body 14, the secondary battery 12 (1.2V × 5 = 6.0V) provided inside the battery pack 11 is charged through the respective charging positive terminals. It is supposed to be charged. In addition, when the system is activated during charging, a part of the charging current is directly supplied to the mobile phone body 14.

The minus terminals of the charging device 1, the battery pack 11 and the mobile phone body 14 are connected to GND. The charging control microcomputer 2 also monitors the battery voltage, and the voltage at the positive terminal of the charging device 1 is divided by the resistors R1 and R2 and input as the battery voltage detection signal 9. Then, the abnormality detection timer 20 is used to measure a predetermined time (for example, 24 minutes), and the battery voltage is detected during that time. In addition, the charging timer 21 measures the charging time of the battery 12 by the charging constant current circuits 3 and 4. The battery temperature detection signal 8 from the thermistor 13 provided in the battery pack 11 is also input to the charge control microcomputer 2.

FIG. 2 is a flowchart showing charging control performed by the charging device 1 shown in FIG. First, whether or not the battery pack 11 is attached is detected by a battery attachment detection circuit (not shown) (S1). Then, when the battery pack 11 is mounted, subsequently, the timing operation of the abnormality detection timer 20 is started (S2), and the charging lamp 51 is turned on (S3).

Next, when it is detected by the input battery voltage detection signal 9 that the battery voltage V _B is lower than 5.5 V (Yes in S4), the charge timer 21 and the trickle charge constant are determined. The current circuit 4 is operated to perform trickle charging for 1 minute (S5). Here, regarding the value of 5.5V set as the battery voltage determination threshold value, the voltage value necessary for the circuit of the connected mobile phone body 14 to operate normally when using the battery of 6V specification Is a value that is empirically derived. Regarding the trickle charge time of 1 minute, in consideration of the fact that the voltage of the secondary battery 12 in the over-discharged state (for example, 4.5 V or less) does not rise easily even when charged, The time sufficient for the voltage to rise is set as an empirically derived value.

Next, the battery voltage immediately after the one-minute trickle charge is completed is detected and the voltage value is stored as V _B1 (S6). Then, it is confirmed whether or not this V _B1 exceeds 5.5 V (S7), and when it does not exceed (V7)
In No. 7), the charging timer 21 and the rapid charging constant current circuit 3 are further used to perform rapid charging for 10 seconds (S8).

Regarding the rapid charging time of 10 seconds,
When the system of the connected mobile phone body 14 is activated during charging and current (about 100 to 150 mA) is consumed, even if the current is consumed, sufficient rapid charging can be performed (for example, 650 mA ×). 10 seconds), which is an empirically derived value. Then, after the rapid charging for 10 seconds is completed, the trickle charging constant current circuit 4 is switched again to perform trickle charging (S9), and the battery voltage value at that time is stored as V _B2 (S10). Then, it is confirmed whether or not this V _B2 exceeds 5.5 V (S11), and if it still does not exceed 5.5 V (No in S11), V _B2- V _B1 is further calculated. (S12),
Check if the calculated value exceeds 1.5V (S1
2).

Here, with respect to the value of 1.5V which is set as the judgment threshold value of the battery voltage rise, the secondary battery which is in the over-discharged state (for example, 4.5V) as a result of performing rapid charging for 10 seconds Empirically, assuming that the battery to be charged is determined to be an abnormal battery when the battery 12 does not become fully charged (for example, 6V) despite the voltage increase (for example, 1.5V increase). The value is derived.

Then, the calculation result of V _B2- V _B1 is 1.5 V
If it exceeds the value (Yes in S12), it is determined that the battery is a normal battery, rapid charging is performed using the rapid charging constant current circuit 3 (S21), and full charge is detected (S21). S22). Furthermore, when the battery is fully charged (Yes in S22), the fully charged display lamp 52 is turned on (S23).

Further, the battery voltage is constantly monitored, and when the battery voltage exceeds 5.5 V (No in S4,
In the case of Yes in S7 and Yes in S11, quick charge is performed (S21), and full charge is detected (S2).
2). It should be noted that the trickle charging is performed after performing the rapid charging for 10 seconds when the battery is abnormal.
This is to prevent the charging device 1 from being destroyed.

On the other hand, even if the above charging operation is performed, V _B2 -V _B1
If the calculated value of does not exceed 1.5 V (No in S12), it is confirmed by the abnormality detection timer 20 that 24 minutes have not elapsed (No in S13), and Return to processing. Even when it is confirmed by the abnormality detection timer 20 that 24 minutes have passed (Yes in S13), if the conventional rapid charging is not possible, it is determined that the battery is abnormal and the abnormality display lamp 53 is displayed. It lights up (S14) and charging is stopped (S1).
5).

According to the above charging method, when charging is performed with the over-discharged battery mounted on the mobile phone body 14, a current exceeding the trickle charging current (for example, about 100) is used.
(mA) is consumed by the mobile phone body 14,
Even if the voltage rise stops during the first 1-minute trickle charge, a current much larger than the circuit current of the mobile phone body 14 (about 65
Since the rapid charging by 0 mA) is started, the charging current surely flows in the secondary battery 12 and the voltage rises, so that the secondary battery 12 can be fully charged.

Even if the battery voltage does not rise sufficiently in the first 1 minute trickle charge and the current consumption of the mobile phone body 14 becomes large during the next 10 seconds of rapid charging, Due to the rapid charging, a sufficient charging current for increasing the battery voltage flows to the battery, so that the final rapid charging can be started and the battery can be fully charged. Furthermore, when there is almost no circuit current in the mobile phone main body 14, the battery voltage exceeds 5.5 V and rapid charging is started during trickle charging for one minute unless the battery is abnormal. Performs the same operation as the charging operation.

As described above, even if the current consumption of the mobile phone body 14 fluctuates and increases at any time when the voltage rises during charging, the secondary battery is surely charged. .

[0029]

As described above, according to the present invention, when the secondary battery mounted on the portable electronic device is charged while being over-discharged, the circuit current exceeding the trickle current is consumed during charging. Even so, since a current much larger than the circuit current is supplied to the secondary battery by quick charging, it is possible to reliably reach the fully charged state of the secondary battery.

Also, on the side of the portable electronic device, the secondary battery can be charged without problems even if the load changes during charging, so that even if the system is started during charging, the normal condition is maintained. Circuit operation is guaranteed. Therefore, when designing a system of a portable electronic device, the system design can be performed without noticing the problem of current consumption during charging, which greatly increases the degree of freedom in design.

Further, in the charging device according to the present invention, since it is possible to deal with it by simply changing the software without adding a new circuit, it is possible to perform effective charging control without increasing the price. Also effective.

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of a charging device according to the present invention.

FIG. 2 is a flowchart showing charging control performed by the charging device 1 shown in FIG.

FIG. 3 is a flowchart showing charging control performed by a conventional charger.

[Explanation of symbols]

 1 Charging Device 2 Charge Control Microcomputer 3 Quick Charge Constant Current Circuit 4 Trickle Charge Constant Current Circuit 5 Display 6 Quick Charge ON Signal 7 Tokryl Charge ON Signal 8 Temperature Detection Signal 9 Battery Voltage Detection Signal 11 Battery Pack 12 Secondary Battery 13 Thermistor 14 Mobile phone body 20 Abnormality detection timer 21 Charging timer 51 Charging indicator lamp 52 Full charge indicator lamp 53 Abnormal battery indicator lamp

Claims (3)

[Claims] 1. A charging device for charging a secondary battery mounted on a portable electronic device, comprising: a timer for measuring a charging time; and a battery voltage detecting means for detecting a battery voltage over a predetermined detection time. When the detected battery voltage is lower than a first threshold value, a first charging unit that performs trickle charging for a first charging time, and the result of the charging by the first charging unit is that the battery voltage is In addition, when it is below the first threshold value, the trickle charge is performed after the quick charge for the second charge time.
As a result of the charging performed by the charging means and the second charging means, the battery voltage has not yet exceeded the first threshold value, and the second voltage
If the difference between the charging voltage by the charging means and the charging voltage by the first charging means does not exceed the second threshold value, a recharging instruction is issued to the first charging means. Charging instruction means, and third charging means for performing rapid charging until full charge is reached when the battery voltage exceeds the first threshold value as a result of charging by the second charging means. A charging device characterized by being provided. 2. The first threshold value is set as a lower limit value of a secondary battery voltage sufficient to ensure normal circuit operation of a portable electronic device, and the second threshold value is the second threshold value. The charging device according to claim 1, wherein the charging device is set as a lower limit value of an increase in charging voltage that should be caused by charging of the charging means. 3. The first charging time is set as a voltage rising time sufficient to charge a secondary battery in an over-discharged state, and the second charging time is charged by the second charging means. The charging device according to claim 1 or 2, wherein the charging device is set as a time sufficient to rapidly charge the secondary battery while covering a current consumption that may occur during the charging.