JPH0662538A - Battery apparatus - Google Patents

Abstract

PURPOSE:To successfully avoid over-discharge of a battery having a power consuming means. CONSTITUTION:A switch circuit 31 is provided between a terminal 1a for obtaining a terminal voltage Vcc of a battery 2 and a switch 13 which turns ON when a check button is depressed. The terminal voltage Vcc of the battery 2 is supplied, through the switch circuit, to a discharge detector 4, a charge detector 5, display detectors 10 to 12, a comparator 15, an oscillator 17 and light emitting diodes 21 to 23, etc. Moreover, the terminal voltage Vcc of the battery 2 is further supplied to a low voltage detector 32. The detected output thereof controls the switch circuit 31 to turn OFF when the terminal voltage Vcc becomes lower than 5V (Vcc is usually set to 6V). Thereby, a current supply path to a power consuming means such as discharge detector 4 and charge detector 5 from the battery 2 is cut off, further reduction of terminal voltage Vcc is prevented and over-discharge of the battery 2 can be avoided.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery device having a power consumption means such as a remaining capacity display means.

[0002]

2. Description of the Related Art Conventionally, a battery device having a remaining capacity display means has been proposed. FIG. 3 shows an example thereof. A series circuit of the battery 2 and the detection resistor 3 is connected between the terminals 1a and 1b. Battery 2
And the connection point of the resistor 3 is grounded. Battery 2
Is, for example, a nickel-cadmium (Ni-Cd) storage battery. A load or a charger is connected between the terminals 1a and 1b.

The terminal 1b is connected to the discharge detector 4 and the charge detector 5. When a load is connected between the terminals 1a and 1b and the battery 2 is in a discharged state, a positive voltage is obtained at the terminal 1b, so that the discharge detector 4 outputs a high level “H” signal. On the other hand, when the battery is charged by connecting the charger between the terminals 1a and 1b, a negative voltage is obtained at the terminal 1b, so that the charge detector 5 outputs a high level “H” signal. .

The output signal of the discharge detector 4 is supplied to the voltage corrector 8 via the resistor 6, and the output signal of the charge detector 5 is supplied to the voltage corrector 8 via the resistor 7. And
The voltage obtained at the terminal 1a, that is, the terminal voltage Vcc of the battery 2 is supplied to the voltage corrector 8. The terminal voltage Vcc of the battery 2 is lower during discharging and higher during charging than when left unattended.

At the time of discharging and charging, the voltage corrector 8 corrects the terminal voltage Vcc of the battery 2 to be equal to that at the time of leaving. The corrected voltage Vcc ^* output from the voltage corrector 8 during discharging and charging is the diode 9
Is supplied as a voltage to be compared to the display detectors 10 to 12 via. Further, the terminal voltage Vcc of the battery 2 is supplied to the display detectors 10 to 1 through the switch 13 and the diode 14.
2 is supplied as a compared voltage and is also supplied as an operation control signal.

FIG. 4 shows the battery 2 itself or a storage case of the battery 2, but light emitting diodes 21 to 23 as a display element and a check button 24 are provided. The switch 13 described above is turned on by pressing the check button 24.

The terminal voltage Vcc of the battery 2 is supplied to the constant voltage circuit 18. The constant voltage output from the constant voltage circuit 18 is supplied to the display detectors 10 to 12 as a reference voltage.

The output signal of the charge detector 5 is supplied to the display detectors 10 to 12 as an operation control signal via the resistor 7. In addition, the voltage V output from the voltage corrector 8
cc ^* and the constant voltage output from the constant voltage circuit 18 are supplied to the comparator 15, which outputs a high level “H” signal when the voltage Vcc ^* is less than or equal to a predetermined voltage, for example, 5.9V or less. Is output. The output signal of the comparator 15 is supplied to one input terminal of the AND circuit 16, and the output signal of the discharge detector 4 is supplied to the other input terminal of the AND circuit 16 via the resistor 6. The output signal of 16 is supplied to the display detector 12 as an operation control signal.

The display detectors 10 to 12 are configured to operate when any one of the operation control signals becomes high level "H". That is, the display detectors 10 to 12 are in the operating state when the battery 2 is charged and the switch 13 is turned on (when the check button 24 is pressed). Further, the display detector 12 is configured to detect the voltage Vcc when the battery 2 is discharged.
^{When *} is 5.9V or less, it becomes the operating state.

The detection output of the display detector 10 controls the light emitting diode 21, the detection output of the display detector 11 controls the light emitting diode 22, and the detection output of the display detector 12 controls the light emitting diode 23 via the oscillator 17. Is controlled. That is, the display detectors 10 to 10
When the compared voltage (Vcc or Vcc ^* ) supplied to 12 is 5.9V or less, the light emitting diode 23 is made to blink, and when it is larger than 5.9V and smaller than 6.1V, the light emitting diodes 22 and 23 are Is made to glow,
When the voltage is 6.1 V or more, all the light emitting diodes 21 to 23 emit light. Battery 2
It is assumed that five Ni-Cd storage batteries (nominal voltage 1.2V) are connected in series.

The discharge detector 4, the charge detector 5, the display detectors 10 to 12, the comparator 15, the oscillator 17, and the light emitting diodes 21 to 23 have the terminal voltage of the battery 2 at Vcc.
Is supplied.

In the above configuration, the terminals 1a and 1b
When a charger is connected between them and the battery 2 is in a charging state, the display detectors 10 to 12 are in an operating state, and the light emitting diodes 21 to 12 are in accordance with the corrected voltage Vcc ^* output from the voltage corrector 8. Since the light emission control of 23 is performed, the charge state of the battery 2 can be known.

Further, when the load is connected between the terminals 1a and 1b and the battery 2 is in a discharged state, when the corrected voltage Vcc ^* output from the voltage corrector 8 becomes 5.9 V or less, the display detector. 12, the light emitting diode 23 blinks.

Further, when the switch 13 is turned on (the check button 24 is pressed) while the charger and the load are not connected between the terminals 1a and 1b, the display detectors 10 to 12 are activated and the terminals of the battery 2 are connected. Since the light emitting diodes 21 to 23 are controlled to emit light according to the voltage Vcc, the state of the battery 2 (charged state or discharged state) can be known.

[0015]

In the battery device described above, the state of the battery 2 is not displayed by the light emitting diodes 21 to 23 unless the switch 13 is turned on when the battery device is left unattended. I don't know.

However, even when the battery is left as it is, current flows from the battery 2 to the discharge detector 4, the charge detector 5, etc. up to the cutoff voltage of the circuit. Therefore, if the battery 2 is left for a long time, the battery 2 may be inactivated due to over-discharge and it may take time to recover, or 100% recovery may be impossible.

The above-mentioned inconvenience is caused when the battery 2 is made of Ni.
The same applies to the case of a secondary battery other than the -Cd storage battery. Further, when the battery 2 is a primary battery, there is a problem that liquid leakage or the like occurs due to overdischarge.

Therefore, the present invention favorably prevents the battery from being over-discharged in the battery device having the power consumption means.

[0019]

SUMMARY OF THE INVENTION According to the present invention, a battery main body or a battery storage case has power consumption means, and battery voltage detection means for detecting that the terminal voltage of the battery has dropped below a predetermined value, and battery power detection means. Switch means for interrupting the current path to the consuming means, the switch means is driven by the detection output of the battery voltage detecting means, and the current path is interrupted by the switch means when the terminal voltage of the battery falls below a predetermined value. To do.

Further, the terminal voltage of the battery is supplied to the power consuming means, and the terminal voltage is converted into a constant voltage by the constant voltage circuit and supplied as the reference voltage. When the power consuming means does not need the reference voltage, the constant voltage circuit is provided. It stops the operation of.

[0021]

In the present invention, when the terminal voltage of the battery drops below a predetermined value, the switch means shuts off the current path from the battery to the power consuming means, so that further reduction of the terminal voltage of the battery is prevented. Therefore, the battery can be prevented from being over-discharged. Further, when the power consumption means does not need the reference voltage, the operation of the constant voltage circuit is stopped, so that the power consumption can be significantly reduced.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 3 are designated by the same reference numerals, and detailed description thereof will be omitted.

In this example, the terminal 1a and the switch 13
The switch circuit 31 is inserted between and. The switch circuit 31 is configured electronically, for example, or using a relay.

Further, the terminal voltage Vcc of the battery 2 is supplied to the low voltage detector 32, and the low voltage detector 32 outputs a high level "H" signal when the terminal voltage Vcc is 5 V or less. The output signal of the low voltage detector 32 is supplied to the switch circuit 31 as a control signal. The switch circuit 31 is turned off when the control signal is at the high level "H", and is turned on when the control signal is at the low level "L".

Further, the terminal voltage Vcc of the battery 2 is transmitted through the switch circuit 31 to the discharge detector 4, the charge detector 5, the display detectors 10 to 12, the comparator 15, the oscillator 17,
It is supplied to the light emitting diodes 21 to 23 and the like.

The present example is constructed as described above, and the other parts are constructed similarly to the example of FIG.

In this example, when the terminal voltage Vcc of the battery 2 becomes 5 V or less, the switch circuit 31 is turned off by the output signal of the low voltage detector 32. Therefore, the current supply path from the battery 2 to the power consumption means such as the discharge detector 4 and the charge detector 5 is cut off, so that the battery 2
It is possible to prevent the terminal voltage Vcc from further lowering, and to avoid over-discharging the battery 2 even if it is left for a long time.

Strictly speaking, the low voltage detector 32 consumes a current for voltage detection, but this current is, for example, 3 μA or less at the maximum, which is 1/10 or less of the conventional value, and the terminal voltage of the battery 2 is reduced. The rate of decrease of Vcc becomes very slow.

Next, another embodiment of the present invention will be described with reference to FIG. 2, parts corresponding to those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted.

In this example, the switch circuit 33 is inserted between the constant voltage circuit 18 and the ground. Like the switch circuit 31 described above, the switch circuit 33 is also configured electronically or using a relay.

The output signal of the discharge detector 4 is supplied to the switch circuit 33 as a control signal via the diode 34, and the output signal of the charge detector 5 is supplied to the diode 35.
Is supplied as a control signal via. Further, the switch circuit 33 is supplied with a signal obtained at the connection point of the switch 13 and the diode 14 as a control signal via the diode 36. The switch circuit 33 is turned on when any of these control signals is high level "H", and is turned off when all of them are low level "L".

The present example is constructed as described above, and the other parts are constructed similarly to the example of FIG.

In this example, when the battery 2 is being discharged,
The control signal supplied to the switch circuit 33 is at a high level “H” at either the charging time or the switch 13 is on (when the check button 24 is pressed), and the switch circuit 3 is turned on.
3 turns on. Therefore, the constant voltage circuit 18 is in the operating state, and the constant voltage circuit 18 causes the display detectors 10 to 1 to operate.
2. A constant voltage is supplied to the comparator 15 as a reference voltage, whereby the state of the battery 2 is displayed as described above.

On the other hand, the control signal supplied to the switch circuit 33 is at the low level "L" and the switch circuit 33 is off except when the battery 2 is discharged, charged and the switch 13 is turned on. The constant voltage circuit 18 is in an operation stop state. As described above, the state of the battery 2 is not displayed except when the battery 2 is being discharged, when the battery 2 is being charged, and when the switch 13 is on.
Since the constant voltage from the constant voltage circuit 18 is unnecessary, there is no problem even if the operation of the constant voltage circuit 18 is stopped.

In this example, the same effects as those of the example of FIG. 1 can be obtained, and the operation of the constant voltage circuit 18 is stopped when the constant voltage is not required, so that the power consumption is drastically reduced. It can be reduced. Incidentally, the constant voltage circuit 18 for producing a constant voltage (reference voltage) consumes a considerable amount of power during operation in order to improve the input / output characteristics.

In the above embodiment, the state of the battery 2 is displayed by the light emitting diodes 21 to 23, but the present invention uses a liquid crystal display element or the like to display characters, numerical values, figures and the like. It can also be applied to a device that displays the state of the battery 2, the number of times of use, and the like.

Further, in the above-mentioned embodiment, the one in which the state of the battery 2 is visually displayed has been shown, but the present invention is similarly applied to, for example, one in which a warning sound is generated in relation to the state of the battery 2. can do.

Further, in the above-mentioned embodiment, the battery 2 is an example of a Ni-Cd storage battery, but the present invention can be similarly applied to other secondary batteries and primary batteries.

[0039]

According to the present invention, when the terminal voltage of the battery drops below a predetermined value, the switch means cuts off the current path from the battery to the power consuming means, so that the terminal voltage of the battery drops further. It is possible to prevent the battery from being over-discharged. Also,
When the power consumption means does not need the reference voltage, the operation of the constant voltage circuit is stopped, so that the power consumption can be significantly reduced.

[Brief description of drawings]

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

FIG. 2 is a block diagram showing the configuration of another embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a conventional example.

FIG. 4 is a diagram showing an external appearance of a battery body or a storage case thereof.

[Explanation of symbols]

 1a, 1b Terminal 2 Battery 3 Detection resistor 4 Discharge detector 5 Charge detector 8 Voltage corrector 10-12 Display detector 13 Switch 15 Comparator 16 AND circuit 17 Oscillator 18 Constant voltage circuit 21-23 Light emitting diode 24 Check Button 31, 33 Switch circuit 32 Low voltage detector

Claims (5)

[Claims] 1. A battery main body or a battery accommodating case having power consumption means, a battery voltage detection means for detecting that the terminal voltage of the battery has dropped below a predetermined value, and a current from the battery to the power consumption means. A switch means for shutting off the current path, and driving the switch means by the detection output of the battery voltage detecting means, and shutting off the current path by the switch means when the terminal voltage of the battery falls below the predetermined value. A battery device characterized by: 2. The battery device according to claim 1, wherein the power consumption means includes display means for displaying a state of the battery. 3. The battery device according to claim 2, wherein the display means is configured by using a liquid crystal display element or a light emitting diode. 4. The battery device according to claim 1, wherein the power consumption means includes a warning sound generating means for generating a warning sound in relation to the state of the battery. 5. When the terminal voltage of the battery is supplied to the power consuming means, the terminal voltage is converted to a constant voltage by a constant voltage circuit and supplied as a reference voltage, and the power consuming means does not need the reference voltage. 2. The battery device according to claim 1, wherein the operation of the constant voltage circuit is stopped.