JP3464694B2 - Charger and charge control circuit - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device for charging a battery provided in an electronic computer or the like. 2. Description of the Related Art In recent years, an increasing number of electronic computers have backup batteries to preserve data. In such applications, lead acid batteries are often used with continuous trickle charging. However, since lead acid batteries are vulnerable to overcharging, the life of the batteries may be shortened depending on the usage conditions such as the charging method and the environmental temperature. In such a case, it becomes necessary to replace the battery frequently, which increases the cost burden on the user. Therefore, there is a need for a charging method capable of charging the battery without excess or deficiency and fully utilizing the life of the battery.

[0002]

2. Description of the Related Art FIG. 13 shows a configuration example of a power supply unit of a computer to which a conventional charging circuit is applied. In FIG.
The power supply device is a filter 201 and a circuit breaker 20.
The AC power is input to the AC / DC converter 203 via 2 and converted into DC, and the obtained DC power is supplied to the load 205 via the DC / DC converter 204 and to the charging circuit 210. Battery 101 provided inside
It is configured to charge.

Further, in FIG. 13, the power supply control unit 206
Is configured to control the operations of the AC / DC conversion unit 203, the DC / DC conversion unit 204, and the charging circuit 210 according to ON / OFF of the AC power supply. In FIG. 13, the charging circuit 210, when the AC voltage is applied,
In response to the instruction from the power supply control unit 206 described above, the transistor 212 is turned off, and the AC / DC conversion unit 203
The battery 101 is charged through the constant voltage circuit 213, the constant current circuit 214, and the diode 215 by receiving the direct current from the battery. On the other hand, when the AC voltage is off, the transistor 212 described above is turned on, and the discharge current from the battery 101 is supplied to the load 205 via the diode 216 and the DC / DC converter 204. ing.

As described above, the charging circuit 210 configured to charge the lead storage battery 211 via the constant voltage circuit 213 and the constant current circuit 214 does not need to control the charging current in particular, and the charging circuit 210 can be configured with a simple structure. Since it can be realized, it is often used in laptop computers and the like. This is because, when the charging circuit 210 having this configuration is used, the battery 101 is charged with a constant current when the terminal voltage of the battery 101 is low, and then the battery 10 is charged.
This is because when 1 approaches full charge, the battery 101 can be automatically maintained in full charge as the impedance of the battery 101 increases, and trickle charge is automatically switched to a minute current.

[0005]

When the charging circuit having the above configuration is used, the battery 101 is trickle charged as long as the AC voltage is applied to the power supply device. Therefore, if the charging current during trickle charging exceeds the self-discharging current of the battery 101, the battery 101 will be in an overcharged state. Therefore, conventionally, the capacity of each part of the charging circuit 210 is designed so that the charging current during trickle charging becomes substantially equal to the discharging current due to self-discharge.

However, since the operating characteristics of the lead storage battery greatly depend on its own temperature, the charging current during trickle charging exceeds the discharging current when used at a temperature different from the environmental temperature assumed at the time of design. Therefore, there is a possibility that the life of the lead storage battery may be shortened. On the other hand, as a technique for preventing overcharge due to trickle charge, Japanese Patent Laid-Open No.
There is a technique disclosed in Japanese Unexamined Patent Publication No. 70239, "Automatic Charging Method for Unmanned Vehicles".

This technique monitors the charging current flowing into the lead storage battery from the charging circuit having the above-described configuration and the terminal voltage of the lead storage battery, and when the charging current is below a predetermined threshold value, the lead storage battery is in a fully charged state. When the voltage between the terminals of the lead storage battery becomes equal to or lower than a predetermined threshold value, the charging is stopped and the charging is restarted. As described above, by stopping / restarting charging depending on the state of charge of the lead storage battery, it is possible to prevent overcharging and to keep the lead storage battery in a substantially fully charged state.

However, since the charging current flowing during trickle charging is a minute current of, for example, about 1 mA, it is very difficult to measure such minute current with high accuracy. Further, this technique does not consider the temperature dependence of the operating characteristics of the lead storage battery. Therefore, even when the above-mentioned technique is applied, there is a possibility that the overcharge state is overlooked due to an error in measuring the charging current or a difference in the charging current due to a difference in environment where the battery is used. there were.

An object of the present invention is to provide a charging device which keeps a storage battery in a state close to full charge while preventing overcharge.

[0010]

FIG. 1 shows the principle configuration of a charging device according to the present invention. The invention according to claim 1 is provided with a charging means 102 for charging the battery 101 with a constant voltage / constant current according to the power input, and supplies the discharge current from the battery 101 to the load when the power input is stopped. In the charging device for charging, charging control means 111 for instructing stop and restart of the operation of the charging means
And a temperature measuring means 11 for measuring the temperature of the battery 101.
5 and the charging current of the battery 101 is the temperature measuring means 11
5, the current detection means 113 for detecting that the current value is lower than the reference current value according to the measurement result, and the time measurement operation is started according to the detection result by the current detection means 113, and after a predetermined time elapses, the charging control means 111 is notified. It is characterized in that it is provided with a clock means 114 for instructing stop.

FIG. 2 shows the principle configuration of another charging device according to the present invention. According to a second aspect of the invention, the battery 1 is provided with a charging unit 102 that charges the battery 101 with a constant voltage / constant current according to the power input, and supplies the discharge current from the battery 101 to the load when the power input is stopped.
In the charging device for 01, charging control means 111 for instructing stop and restart of the operation of the charging means 102, temperature measuring means 115 for measuring the temperature of the battery 101,
The charging current of the battery 101 is compared with a reference current value according to the value measured by the temperature measuring means 115, and when the charging current falls below the reference current value, a current comparing means 116 for instructing the charging control means to stop is provided. It is characterized by having.

According to the third aspect of the present invention, there is provided charging means 102 for charging the battery 101 with a constant voltage / constant current according to the power input, and the battery 1 is provided when the power input is stopped.
In the charging device for the battery 101 which supplies the discharge current from 01 to the load, the charging control means 111 for instructing stop and restart of the operation of the charging means 102, the temperature measuring means 115 for measuring the temperature of the battery 101, And a clocking unit 114 for starting a clocking operation in response to the output of the stop instruction from the charging control unit 111 and for instructing the charging control unit 111 to restart after a lapse of the stop time according to the measurement result by the temperature measuring unit 115. Is characterized by.

According to a fourth aspect of the present invention, there is provided a charging device for the battery, which comprises charging means for charging the battery with a constant current according to the power input, and supplies the discharge current from the battery to the load when the power input is stopped. In, charging control means for instructing stop and restart of the operation of the charging means, the terminal voltage of the battery, and a predetermined reference voltage value,
When the inter-terminal voltage reaches the reference voltage value, it is determined that the fully charged state of the battery is detected, the charge detection means for instructing the charge control means to stop, the temperature measurement means for measuring the temperature of the battery, and the charge control means. The present invention is characterized by further comprising: a clocking unit that starts a clocking operation in response to the output of the stop instruction and instructs the charging control unit to restart after a lapse of the stop time according to the measurement result of the temperature measuring unit.

FIG. 3 shows the principle configuration of another charging device according to the present invention. The invention according to claim 5 is provided with a charging means 102 for charging the battery 101 with a constant voltage / constant current according to a power supply input, and supplies a discharge current from the battery 101 to a load when the input of the AC power supply is stopped. In the charging device for 101, charging means 102
Control means 111 for instructing to stop and restart the operation of
The charging control means 111 instructs stop and restart according to the operating state of the load.

According to a sixth aspect of the invention, charging means for charging the battery with a constant voltage / constant current according to the power input, temperature measuring means for measuring the temperature of the battery, and charging current for the battery are temperature measuring means. A charging device having a current detection means for detecting that the current value has fallen below a reference current value according to the measurement result according to, and charging for a battery that supplies a discharge current from the battery to a load when the power input is stopped. In the charging control circuit for controlling the device, the operation of the charging means is started in response to the stop instruction of the time measuring means which starts the time counting operation according to the detection result of the current detecting means and stops the charging operation after the elapse of a predetermined time. It is characterized by stopping.

According to a seventh aspect of the present invention, there is provided a charging device having a charging means for charging a battery with a constant voltage / constant current in accordance with a power input, wherein a discharge current from the battery is loaded when the power input is stopped. In the charging control circuit for controlling the charging device for the battery to be supplied to the battery, the charging current of the battery is compared with the reference current value according to the value measured by the temperature measuring means for measuring the temperature of the battery. When the current value falls below the current value, the operation of the charging means is stopped in response to the stop instruction of the current comparing means for instructing the stop of the charging operation.

According to an eighth aspect of the present invention, there is provided a charging device comprising a charging means for charging a battery with a constant voltage / constant current according to a power input, wherein a discharge current from the battery is loaded when the power input is stopped. In the charging control circuit for controlling the charging device for the battery to be supplied to the charging device, the charging control circuit has a charging control means for instructing stop and restart of the operation of the charging means, and performs a timing operation in accordance with the output of the stop instruction by the charging control means. The charging control means restarts the operation of the charging means in response to the restart instruction of the clocking means for starting and for instructing the charging control means to restart after the stop time according to the measurement result by the temperature measuring means for measuring the battery temperature. It is characterized by instructing.

According to a ninth aspect of the present invention, a charging means for charging the battery with a constant voltage / constant current according to the power input, a temperature measuring means for measuring the temperature of the battery, a voltage between terminals of the battery, and a predetermined voltage. Comparing with a reference voltage value, when the inter-terminal voltage reaches the reference voltage value, the charging device provided with a charge detection means for instructing to stop, assuming that the full charge state of the battery is detected, A charging control circuit that controls a charging device for a battery that supplies a discharge current from the battery to a load when the power input is stopped has a charging control means for instructing stop and restart of the operation of the charging means. The timekeeping operation is started in response to the output of the stop instruction by the control means, and the charging operation is restarted after the stop time corresponding to the measurement result by the temperature measurement means for measuring the battery temperature. Depending on the restart instruction of the timing means for indicating the charging control means is characterized by resuming the operation of the charging means.

According to a tenth aspect of the present invention, depending on the power input,
A charging device for a battery, which is equipped with a charging means for charging the battery with a constant voltage / constant current, and which supplies a discharge current from the battery to the load when the input of the AC power supply is stopped, is for stopping and restarting the operation of the charging means. It has a charging control means for instructing, and the charging control means is characterized by instructing stop and restart of the operation of the charging means according to the operating state of the load.

[0020]

According to the first aspect of the present invention, the battery 1 is controlled by controlling the charging means 102 by the charging control means 111.
01 is intermittently charged. In this manner, the overcharged state of the battery 101 can be released by providing a period for suspending charging, and then the battery 101 can be held in a state close to full charge by restarting charging.

Further, the current detection means 113 stops the charging means 102 by the charging control means 111 when the time set in the time counting means 114 elapses after detecting the charging current below the reference current value. As the above-mentioned reference current value, it is possible to use a current value that is larger than the minute current during trickle charging. Thereby, the current detection means 1
13 can surely detect the time point which is the reference of the timekeeping operation regardless of the measurement error of the charging current.

When the battery 101 is charged with a constant voltage / constant current, the charging current monotonously decreases, so the battery 101 becomes full after a predetermined time from when the charging current falls below the above-mentioned reference current value. It can be expected to be charged. Therefore, by setting an appropriate time in the time measuring means 114, the time point at which the battery 101 is fully charged can be reliably detected by the combination of the current detecting means 113 and the time measuring means 114.

Further, the current detecting means 113 detects the starting point of the time counting operation by using the reference current corresponding to the value measured by the temperature measuring means 115, so that the temperature dependency of the characteristics of the battery 101 is taken into consideration. It is possible to accurately detect the time when charging is performed and control the charging means 102. According to the second aspect of the present invention, the current comparison unit 116 detects the charging current that is lower than the reference current according to the value measured by the temperature measurement unit 115, so that the temperature dependency of the characteristics of the battery 101 is taken into consideration. The charging state can be accurately evaluated, and the charging means 102 can be stopped when the battery is fully charged.

According to the third aspect of the present invention, the charging control means 111 operates according to the instruction from the timing means 117, so that the charging operation can be resumed after a predetermined time has elapsed since the charging operation was stopped. Furthermore, by adjusting the stop time according to the measurement result by the temperature measuring means 115,
Since the charging stop period can be changed according to the variation of the discharge current due to the temperature, the battery 101 can always be maintained in a state close to full charge.

According to the fourth aspect of the invention, the charging control means stops the operation of the charging means in response to the instruction from the charging detection means, so that the charging means can be stopped when the battery is fully charged. it can. Thereafter, the charging control means operates in response to the instruction from the time counting means, so that the charging operation can be restarted after a predetermined time has elapsed since the charging operation was stopped. Further, by adjusting the stop time according to the measurement result by the temperature measuring means, the charge stop period can be changed according to the fluctuation of the discharge current due to the temperature, so that the battery is maintained at a constant current without excess or deficiency. It can be charged.

According to the fifth aspect of the present invention, the battery 101 can be charged when the load 103 is in the operating state, and the charging of the battery 101 can be stopped when the load 103 is not in the operating state. In the invention of claim 6, the current detecting means 1
13 detects the start point of the timekeeping operation by using the reference current corresponding to the value measured by the temperature measuring means 115,
It is possible to accurately detect the time point at which the battery is fully charged in consideration of the temperature dependence of the characteristics of the battery 101, and control the stop and restart of the charging operation by the charging unit 102.

In the invention of claim 7, the current comparison means 116.
However, by detecting the charging current below the reference current according to the value measured by the temperature measuring means 115, the battery 10
The state of charge of the battery 101 can be accurately evaluated in consideration of the temperature dependence of the characteristic of No. 1. Therefore, the charging means 102 can be stopped at the time point when the battery is fully charged by the stop instruction from the current comparison means 116 described above.

According to the eighth aspect of the present invention, the charging control means 111 causes the charging means 102 to operate in response to an instruction from the timing means 117.
By restarting the operation of, the charging operation can be restarted after the charging operation is stopped and after a lapse of the stop time adjusted according to the measurement result by the temperature measuring unit 115. As a result, the charging stop period can be changed according to the change in the discharge current due to the temperature, so that the battery 101 can always be maintained in a state close to full charge.

In the ninth aspect of the invention, the charge detection means 112.
In response to an instruction from the charging control means 111, the charging control means 111
By stopping the operation of No. 2, the charging unit 102 can be stopped when the battery 101 is fully charged. After that, the charging control unit 111 operates according to the instruction from the time counting unit 117 to stop the charging operation, and then the charging operation is performed after the stop time adjusted according to the measurement result by the temperature measuring unit 115. It can be restarted. As a result, the charging stop period can be changed according to the change in the discharge current due to the temperature.
It is possible to charge the battery 101 with a constant current without excess or deficiency.

In the tenth aspect of the invention, the charge control means 11
1, the charging means 10 when the load 103 is in the operating state
2 is operated to charge the battery 101, and when the load 103 is not in the operating state, the charging means 102 can be stopped to stop the charging of the battery 101.

[0031]

Embodiments of the present invention will now be described in detail with reference to the drawings. FIG. 4 shows a configuration example of a charging device to which the present invention is applied. In FIG. 4, the same parts as those of the power supply device shown in FIG. 13 are designated by the same reference numerals. 4, the charging device includes a current detection circuit 220 and a timer 231 in addition to the charging circuit 210 shown in FIG.
And a charge control unit 232 are added, and the charge control unit 232 sets the timer 231 according to the detection result of the current detection circuit 220.
The charging control unit 232 activates the constant voltage circuit 213 and the constant current circuit 21 in response to the notification from the timer 231.
4 is configured to control the operation of the charging means 102.

The above-mentioned current detection circuit 220 corresponds to the current detection means 113. The amplifier 222 amplifies the voltage drop due to the resistor 221, and the output of this amplifier 222 and the reference voltage Vf1 from the voltage generator 223 are obtained. Comparator 2
The charging control unit 232 uses the result of comparison by 24 as the detection result.
It is configured to be sent to. Here, as described above, the charging current when the lead storage battery is charged with a constant voltage / constant current is, as shown in FIG. 5, a constant value ic until the terminal voltage of the lead storage battery reaches a predetermined value V1. After that, the impedance of the lead storage battery decreases monotonically with an increase in impedance, and after the battery is fully charged, it becomes a minute current of about 1 mA (indicated by a dotted line in FIG. 5).

Since the change in the charging current shown in FIG. 5 is due to the operation characteristics of the lead storage battery, if the time when the charging current falls below a predetermined value (for example, 50 mA) is detected, a predetermined time is elapsed from that time. It can be inferred that the battery will be fully charged when is passed. In this case, the voltage generation unit 223 described above generates a voltage value corresponding to a current value (for example, 50 mA) larger than the charging current during trickle charging as the reference voltage Vf1 and inputs the reference voltage Vf1 to the comparator 224, and then the comparator 224. May be configured to output a logic "1" when the output of the amplifier 222 falls below the reference voltage Vf1 to indicate that the corresponding current is detected.

The charging control section 232 corresponds to the charging control means 111, and sets a predetermined time T1 to the timer 2 according to the input of the detection result indicating that the corresponding current is detected.
Set to 31 and start this timer 231.
When the notification that the time T1 has elapsed is received from the timer 231, it may be configured to instruct the stop of the operations of the constant voltage circuit 213 and the constant current circuit 214.

That is, the charge controller 232 uses the timer 23.
By controlling 1, the function of the timer means 114 is achieved. The above-mentioned time T1, as shown in FIG. 5, sets a value charging current is equivalent to the time required for the change from the current value i _th corresponding to the threshold Vf1 described above to small current i _tr during trickle charge do it.

In this way, the charging control unit 232 and the timer 231 are selected according to the detection result of the current detection circuit 220.
By operating the and, the time at which the battery is fully charged is estimated by the combination of the value of the charging current and the elapsed time, and the battery 10
Since the charging of No. 1 can be stopped, the battery 101
Can be prevented from being overcharged. In this case, as shown by the solid line in FIG.
_{When the} time T1 elapses after _th becomes _th , the current value of the charging current becomes “0”.

Here, in general, a current value of about 50 mA can be accurately detected, and as shown in FIG. 5, the charging current changes sharply in the vicinity of the current value. The detection circuit 220 can detect the corresponding time point with high accuracy and reliability. Therefore,
The time point at which the battery is fully charged can be estimated with high accuracy and detected reliably.

After the charging is stopped in this way, the charging control unit 232 sets another time T2 in the timer 231 and starts the timer 231 again.
In response to the notification indicating that the time T2 has elapsed from 31, the charging control unit 232 instructs the constant voltage circuit 213 and the constant current circuit 214 to restart their operations. As a result, the charging controller 232
The function of the time measuring means 117 can be realized by the timer 231 and the charging of the battery 101 can be resumed after a predetermined time has elapsed since the charging was stopped.

As the above-mentioned time T2, for example, the voltage between terminals is 95 when fully charged due to self-discharge of the battery 101.
The battery 101 can be maintained in a substantially fully charged state by setting the time required for the battery 101 to decrease to about%. By intermittently charging the battery 101 as described above, it is possible to maintain the battery 101 in a substantially fully charged state and prevent overcharging.

In this case, it is not possible to always keep the battery fully charged as in the case where the trickle charging is continued, but if the battery is charged to about 95% of the capacity of the battery, it is sufficient for normal use. On the other hand, according to this technique, it is possible to reliably prevent overcharging, and therefore, there is an effect that it is possible to fully utilize the life of the battery.
It is possible to reduce the number of times the battery is replaced and to reduce the cost burden on the user.

Further, by controlling the charging stop / restart depending on the temperature of the battery, it is possible to more surely prevent the overcharge in consideration of the operating environment of the battery. Figure 6
FIG. 1 shows an embodiment of a charging device according to the present invention. Figure 6
In the charging device, instead of the timer 231 of the charging device shown in FIG.
0 is added, and the reference voltages Vf1 and Vf2 used in the current detection circuit 220 and the voltage detection circuit 240 are changed according to the measured value by the temperature measurement unit 250. Further, the charging control unit 232 is configured to control the operations of the constant voltage circuit 213 and the constant current circuit 214 according to the detection results of the current detection circuit 220 and the voltage detection circuit 240.

The voltage detection circuit 240 comprises the voltage comparison means 11
The comparator 241 compares the inter-terminal voltage of the battery 101 with the reference voltage Vf2 from the voltage generator 242, and when the inter-terminal voltage falls below the reference voltage Vf2, a logical “1” is obtained. It is configured to output and send to the charge control unit 232. In the voltage detection circuit 240, one end of the above-mentioned voltage generation unit 242 is grounded, and the reference voltage Vf2 is output from the other end and input to the comparator 241. In addition, the voltage generator 242
A voltage value corresponding to the measurement result of the temperature measuring unit 250 is applied to the ground point of No. 2, and the value of the reference voltage Vf2 is changed by changing the potential of this ground point.

In addition, the voltage generator 2 of the current detection circuit 220
The output of the above-mentioned temperature measuring unit 250 is also applied to the grounding point of 23, and the value of the above-mentioned reference voltage Vf1 is similarly varied. In addition, in FIG.
The temperature measuring unit 250 corresponds to the temperature measuring unit 115, and outputs the output of the thermistor 251 and a predetermined reference voltage Vf.
The differential amplifier 252 amplifies the difference from the difference 3 and outputs the output of the differential amplifier 252 to the current detection circuit 220 and the voltage detection circuit 240.

As the reference voltage Vf3, for example, a voltage value corresponding to the output voltage of the thermistor 251 at a normal room temperature (about 20 degrees Celsius) may be set. In addition, the voltage generation unit 242 of the voltage detection circuit 240 described above, when the potential of 0 V is applied to the ground point, sets the reference voltage Vf2 to, for example, a terminal voltage corresponding to 95% of full charge at normal room temperature. The value of should be generated.

On the other hand, the voltage generator 2 of the current detection circuit 220
23, in a state where the potential of 0V is applied to the ground, as the reference voltage Vf1, for example, may generate a voltage value corresponding to the charging current i _tr during trickle charging at normal room temperature. In this case, the output voltage of the differential amplifier 252 monotonously decreases as the temperature of the battery 101 increases, and the reference voltages Vf1 and Vf2 both increase accordingly. On the other hand, since the output voltage of the differential amplifier 252 rises as the temperature of the battery 101 drops, the reference voltages Vf1, Vf
Conversely, f2 decreases.

As described above, the current detecting circuit 220 and the voltage detecting circuit 240 respectively perform the functions of the current comparing means 116 and the voltage comparing means 118, respectively.
Even when the charging current value at the time of trickle charging and the terminal voltage that can be determined to be fully charged fluctuate due to the temperature change of the battery 101, the time point at which the battery is fully charged and the time point at which recharging is necessary are surely achieved. It is possible to detect.

Further, the charging control section 232 responds to the input of the detection result indicating that the charging current at the time of trickle charging is detected.
If the operation of the constant voltage circuit 213 and the constant current circuit 214 is instructed, and the operation of the constant voltage circuit 213 and the constant current circuit 214 is restarted in response to the input of the detection result indicating that the inter-terminal voltage has dropped, Good. In this way, the battery 10
Considering the temperature dependence of the operating characteristics of No. 1, the current detection circuit 2
By changing the thresholds for charge detection and discharge detection by the voltage detection circuit 240 and the voltage detection circuit 240, the charging operation of the battery 101 can be appropriately controlled in accordance with various environments. As a result, regardless of the environment in which the battery is used, the battery can always be kept in a state close to full charge, and overcharge can be reliably prevented, so that the life of the battery can be fully utilized.

It is also possible to estimate the time at which the battery is fully charged and the time at which recharging should be started in consideration of the battery temperature. FIG. 7 shows a configuration diagram of another embodiment of the charging device according to the present invention. In FIG. 7, the charging device is obtained by adding the temperature measuring unit 250 described above to the charging device shown in FIG.
The charging control unit 232 is configured to change the value of the time T2 set in the timer 231 according to the output of the temperature measuring unit 250.

Further, similarly to the embodiment shown in FIG. 6,
The output voltage of the temperature measurement unit 250 is applied to the ground point of the voltage generation unit 223 of the current detection circuit 220, and the reference voltage Vf1 is changed according to the measurement result of the temperature measurement unit 250. In this case, the voltage generator 223 described above is used.
In the state where the potential at the ground point is 0 V, the voltage Vbs corresponding to the current value (50 mA) serving as a reference when estimating the time when the battery is fully charged at normal room temperature may be generated as the reference voltage Vf1.

As described above, by varying the current value serving as the reference for estimation according to the temperature of the battery 101, the time point at which the battery is fully charged can be estimated while considering the change in the charging current depending on the temperature of the battery 101. Therefore, regardless of the environment in which the battery is used, it is possible to reliably prevent overcharging by stopping the charging at the estimated time.

In addition, the charging control section 232 has a temperature measuring section 2
The time T2 may be shortened when 50 notifies that the temperature of the battery 101 is higher than the normal room temperature, and conversely, the time T2 may be extended when notified that the temperature is low. For example, the value obtained by adding the value obtained by multiplying the output value of the temperature measuring unit 250 by a predetermined constant c to the reference time T0 is the time.
It should be T2.

As a result, the time at which charging is restarted can be adjusted according to the difference in discharge current due to temperature, so that the battery 101 can always be maintained in a state close to full charge. In addition, the timer 231 and the charging control unit 232
It is also possible to roughly control stop and restart of charging by and.

FIG. 8 shows a structural example of a charging device to which the present invention is applied. The charging device shown in FIG. 8 includes a timer 231 and a charging controller 232 in addition to the conventional charging circuit 210 shown in FIG.
And the charge control unit 232 causes the constant voltage circuit 213 and the constant current circuit 214 to be added in response to the notification from the timer 231.
It is configured to instruct stop and restart of the operation of.

In this case, the charge control section 232 may set the charge time T3 and the stop time T2 in the timer 231 alternately in response to the notification from the timer 231. For example,
Based on the change in the charging current shown in FIG. 5, the battery 10
The time required to charge 1 to the fully charged state may be obtained in advance, and this value may be set as the charging time T3.
Further, the charging / stop switching time T4 may be set in advance in the timer 231, and the charging control unit 232 may alternately instruct stop and restart of charging in response to the notification from the timer 231.

In this way, the charging control unit 232 and the timer 2
When the charge control unit 111 is formed with 31 and the charging is stopped and restarted simply and periodically, the charging device can be realized with a very simple circuit configuration. Further, in this case, since the charging state of the battery 101 is not detected, overcharging itself cannot be reliably prevented, but the overcharging state can be released by periodically stopping charging, and By periodically charging, the battery 101 can be kept in a substantially fully charged state.

Further, the battery may be charged according to the operating state of the load. FIG. 9 shows a configuration diagram of another embodiment of the charging device according to the present invention. In FIG. 9, the charging device has a charging control unit 232 added to the conventional charging circuit 210 shown in FIG. 13, and the charging control unit 232 operates in response to a power supply state signal indicating the state of a power switch provided in the load 103. It is configured to instruct stop and restart of the operations of the constant voltage circuit 213 and the constant current circuit 214.

Further, the charging control section 232 stops the operation of the constant voltage circuit 213 and the constant current circuit 214 when the power supply state signal described above indicates that the power supply switch of the load 103 is in the off state. And load 10
It is sufficient to give an instruction to restart the operation when it is indicated that 3 is in the operating state. In this way, the charging control unit 232 causes the constant voltage circuit 213 and the constant current circuit 21 to respond to the power state signal.
By controlling the operation of No. 4, the function of the charging control means 111 described in claim 7 can be realized, and the stop and restart of charging can be controlled according to the operating state of the load 103.

In this case, since the battery 101 is charged only when the load 103 is in operation, the battery 101 is overcharged even if the power plug of a laptop computer or the like is left unplugged. It will not be left as it is. Also, in this case,
Since the charging control unit 232 only needs to perform a simple operation according to the power supply state signal, the charging device can be realized with a simple configuration.

A charging operation is performed by adding a switch to the charging path of the conventional charging circuit 210 instead of the above-mentioned charging control section 232 and turning on / off this switch according to the above-mentioned power supply state signal. May be controlled to stop and restart. By the way, the battery is used as a constant current circuit 21.
In the case of charging only with 4, it is essential to control stop and restart of the charging operation.

Hereinafter, the battery 101 is connected to the constant current circuit 214.
The case of charging only will be described. FIG. 10 shows a configuration example of a charging device to which the present invention is applied. In FIG. 10, the charging device removes the constant voltage circuit 213 from the conventional charging circuit 210 shown in FIG. 13, adds a timer 231, a charging control unit 232, and a voltage detection circuit 240 instead of the conventional voltage detection circuit 240. In response to the detection result by the timer 231 and the notification from the timer 231, the charging controller 232 causes the constant current circuit 21 to
4 is configured to control the operation.

In this case, the voltage generation unit 242 of the voltage detection circuit 240 generates the voltage value Vm corresponding to the fully charged state of the battery 101 as the reference voltage Vf2, and the comparator 241.
When the inter-terminal voltage of the battery 101 reaches the reference voltage Vf2, the logic “1” is output to notify the charging control unit 232. In addition, according to this notification, the charging control unit 232
Operates as the charging control unit 111, instructs the constant current circuit 214 corresponding to the charging unit 104 to stop the charging operation, sets the timer 231 for a predetermined time T2, and activates the timer 231. Accordingly, the constant current circuit 214 may be instructed to restart the charging operation.

Here, as the time T2 set in the timer 231, as in the example shown in FIG. 4, the terminal voltage of the battery 101 is a value at which charging should be started (for example, 9 when fully charged).
It is sufficient to set the time required to decrease to 5%).
In this case, the constant current im flows into the battery 101 as indicated by the dotted line in FIG. 11, and accordingly, as shown by the thick solid line in FIG. 11, when the charging is started, the inter-terminal voltage becomes linear. When the voltage value increases and reaches the above-described voltage value Vm, it is determined that the battery is fully charged, and the charging is immediately stopped. After that, when the time T2 elapses and the voltage between terminals decreases due to self-discharge of the battery 101, charging is started again.

In this way, the voltage detection circuit 240 functions as the charge detection means 112, and the voltage detection circuit 2
The charging control unit 232 operates in response to the notification from the control unit 40, so that the constant current circuit 214 corresponding to the charging unit 104.
It is possible to charge the battery 101 without excess or deficiency by controlling the operation of. By controlling the constant current circuit in this way, it is possible to always keep the battery close to full charge and prevent overcharging, so it is possible to fully utilize the life of the battery and The cost burden can be reduced.

Further, by controlling the charging operation in consideration of the temperature of the battery, it is possible to prevent overcharging more reliably. FIG. 12 shows a configuration example of a charging device to which the present invention is applied. In FIG. 14, the charging device includes a temperature measuring unit 250 added to the charging device shown in FIG.
The reference voltage Vf2 of the voltage detection circuit 240 is changed and the value of the time T2 set in the timer 231 by the charging control unit 232 is changed according to the output of.

That is, similarly to the embodiment shown in FIG.
The output of the temperature detection unit 250 is applied to the ground point of the voltage generation unit 242 of the voltage detection circuit 240, and the output of the temperature detection unit 250 is notified to the charging control unit 232. In addition, the charge control unit 232 uses the temperature measuring unit 250 to charge the battery 10 in the same manner as in the embodiment shown in FIG.
If it is notified that the temperature of 1 is higher than the normal room temperature, the time T2 may be shortened, and conversely, if it is notified that the temperature is low, the time T2 may be extended.

As a result, the time at which charging is stopped and the length of the period during which charging is stopped can be adjusted in accordance with the difference in terminal voltage and discharge current due to temperature.
In this way, by controlling the charging operation of the battery according to the temperature of the battery, it is possible to reliably prevent overcharging and to keep the battery in a state close to full charge at all times. As a result, the life of the battery can be fully utilized regardless of the operating environment of the battery, so that the number of battery replacements can be reduced even when the computer is used in a harsh environment, and the user The cost burden can be reduced.

[0067]

As described above, according to the present invention, by intermittently charging the battery, it is possible to prevent the battery from being left in an overcharged state and to maintain the state close to full charge. Therefore, the battery life can be fully utilized, and the cost burden on the user can be reduced. Furthermore, by checking the voltage across the terminals of the battery, the charging current and the temperature, evaluating the state of charge of the battery, and controlling the stop and restart of the charging operation according to the evaluation result, it is possible to reliably prevent overcharging of the battery. , It becomes possible to keep the state very close to full charge.

Further, by detecting the fully charged state by the combination of the charging current and the elapsed time, the fully charged state can be detected without omission regardless of the measurement error of the current value.

[Brief description of drawings]

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

FIG. 2 is a diagram showing a principle configuration of another charging device according to the present invention.

FIG. 3 is a diagram showing a principle configuration of another charging device according to the present invention.

FIG. 4 is a diagram showing a configuration example of a charging device to which the present invention is applied.

FIG. 5 is a diagram showing changes in charging current.

FIG. 6 is a diagram showing an embodiment of a charging device according to the present invention.

FIG. 7 is a diagram showing another embodiment of the charging device according to the present invention.

FIG. 8 is a diagram showing a configuration example of a charging device to which the present invention is applied.

FIG. 9 is a diagram showing another embodiment of the charging device according to the present invention.

FIG. 10 is a diagram showing a configuration example of a charging device to which the present invention is applied.

FIG. 11 is a diagram showing a time change of a terminal voltage and a charging current of a battery.

FIG. 12 is a diagram showing a configuration example of a charging device to which the present invention is applied.

FIG. 13 is a configuration diagram of a power supply device of a computer to which a conventional charging circuit is applied.

[Explanation of symbols]

101 battery 102, 104 charging means 103 load 111 Charge control means 112 Charge detection means 113 Current detection means 114,117 clocking means 115 Temperature measuring means 116 Current comparison means 118 voltage comparison means 201 Filter 202 circuit breaker 203 AC / DC converter 204 DC / DC converter 206 Power control unit 210 charging circuit 212 transistor 213 constant voltage circuit 214 constant current circuit 215,216 diodes 220 Current detection circuit 221 resistance 222 amplifier 223, 242 voltage generation unit 224, 241 comparator 231 timer 232 Charge control unit 240 voltage detection circuit 250 temperature measurement unit 251 Thermistor 252 differential amplifier

─────────────────────────────────────────────────── ─── Continuation of the front page (72) Takashi Sato, 1015 Kamiodanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture, Fujitsu Limited (72) Inventor, Yuhiko Kizu, 1015, Kamikodanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture, Fujitsu Limited ( 72) Inventor Toshiaki Yamamoto 1015 Kamiodanaka, Nakahara-ku, Kawasaki City, Kanagawa Prefecture, Fujitsu Limited (72) Inventor Hiroshi Yamaki 1015, Kamedotachu, Nakahara-ku, Kawasaki City, Kanagawa Prefecture, Fujitsu Limited (56) Reference JP 51 -108249 (JP, A) JP-A 1-315227 (JP, A) JP-A 51-114646 (JP, A) JP-A 49-113134 (JP, A) JP-A 4-183232 (JP, A) ) Japanese Patent Laid-Open No. 2-273039 (JP, A) Actual Development 4-72842 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) H02J 7/00-7/12 H02J 7 / 34-7/36 H02J 9/00-9/08

Claims (10)

(57) [Claims] 1. A charging device for charging a battery with a constant voltage / constant current according to a power supply input, wherein the battery supplies a discharge current from the battery to a load when the power supply input is stopped. In the device, charge control means for instructing stop and restart of the operation of the charging means, temperature measuring means for measuring the temperature of the battery, charging current of the battery is a reference according to the measurement result by the temperature measuring means. A current detection unit that detects that the current value is lower than the current value, and a time measurement unit that starts a time counting operation according to the detection result of the current detection unit and instructs the charging control unit to stop after a lapse of a predetermined time. Charging device characterized by that. 2. A charging device for charging a battery with a constant voltage / constant current according to a power supply input, and for supplying a discharge current from the battery to a load when the power supply input is stopped. In the device, charge control means for instructing stop and restart of the operation of the charging means, temperature measuring means for measuring the temperature of the battery, reference current according to a charging current of the battery and a measurement value by the temperature measuring means. And a current comparison means for instructing the charging control means to stop when the charging current falls below the reference current value. 3. Charging means for charging a battery with a constant voltage / constant current according to a power input, and supplying a discharge current from the battery to a load when the power input is stopped. In the device, charge control means for instructing stop and restart of the operation of the charging means, temperature measuring means for measuring the temperature of the battery, and start a timing operation according to the output of the stop instruction by the charge control means, A charging device comprising: a time measuring unit for instructing the charging control unit to restart after a lapse of a stop time according to a measurement result of the temperature measuring unit. 4. A charging device for a battery, comprising charging means for charging a battery with a constant current according to a power input, and supplying a discharge current from the battery to a load when the power input is stopped, Charge control means for instructing stop and restart of the operation of the charging means, the terminal voltage of the battery, and a predetermined reference voltage value is compared, when the terminal voltage reaches the reference voltage value, Assuming that the fully charged state of the battery has been detected, a charge detection means for instructing the charge control means to stop, a temperature measuring means for measuring the temperature of the battery, and a timing operation according to the output of the stop instruction by the charge control means. Charging, characterized by further comprising: a clocking means for starting and for instructing the charging control means to restart after a lapse of a stop time according to a measurement result by the temperature measuring means. apparatus. 5. A battery for charging the battery with a constant voltage / constant current according to a power input, for supplying the discharge current from the battery to a load when the input of the AC power is stopped. The charging device according to claim 1, further comprising a charging control unit that instructs stop and restart of the operation of the charging unit, wherein the charging control unit instructs stop and restart according to an operating state of the load. . 6. A charging means for charging a battery with a constant voltage / constant current according to a power input, a temperature measuring means for measuring the temperature of the battery, and a charging current of the battery measured by the temperature measuring means. A charging device having a current detection means for detecting that the current value is below a reference current value according to the result, wherein when the power input is stopped, the discharging current from the battery is supplied to the load. In the charging control circuit for controlling the charging device, in response to the stop instruction of the timing means for instructing to stop the charging operation after a predetermined time has elapsed while starting the timing operation according to the detection result by the current detection means, A charging control circuit characterized by stopping the operation of the charging means. 7. A charging device comprising a charging means for charging a battery with a constant voltage / constant current according to a power input, wherein a discharge current from the battery is supplied to a load when the power input is stopped. In a charging control circuit that controls the charging device for the battery, a charging current of the battery is compared with a reference current value according to a measurement value by a temperature measuring unit that measures the temperature of the battery. Is less than the reference current value, the operation of the charging means is stopped according to the stop instruction of the current comparing means for instructing the stop of the charging operation. 8. A charging device comprising a charging means for charging a battery with a constant voltage / constant current according to a power input, wherein a discharge current from the battery is supplied to a load when the power input is stopped. A charging control circuit for controlling the charging device for the battery, the charging control circuit having a charging control unit for instructing stop and restart of the operation of the charging unit, and a timing operation according to an output of a stop instruction by the charging control unit. In response to the restart instruction of the clocking means for instructing the charge control means to restart after the stop time according to the measurement result by the temperature measurement means for measuring the temperature of the battery, the charge control means is A charging control circuit for instructing the charging means to resume operation. 9. A charging means for charging a battery with a constant voltage / constant current according to a power input, a temperature measuring means for measuring the temperature of the battery, a terminal voltage of the battery, and a predetermined reference voltage value. Comparing with the above, when the inter-terminal voltage reaches the reference voltage value, it is determined that the full-charged state of the battery is detected, and a charging device provided with a charging detection means for instructing stop, In a charging control circuit that controls the charging device for the battery that supplies the discharge current from the battery to the load when the power input is stopped, a charging control unit that instructs stop and restart of the operation of the charging unit is provided. According to the measurement result by the temperature measuring means for measuring the temperature of the battery, the timing operation is started in response to the output of the stop instruction by the charging control means. Depending on the restart instruction of the timer means for instructing the restart of the charging operation after a stop time, the charging control unit, the charging control circuit, characterized in that to resume the operation of said charging means. 10. A battery for charging the battery with a constant voltage / constant current according to a power input, for supplying the discharge current from the battery to a load when the input of the AC power is stopped. The charging device includes a charging control unit that instructs stop and restart of the operation of the charging unit, and the charging control unit instructs stop and restart of the operation of the charging unit according to an operating state of the load. A charging control circuit characterized by the above.