JP2000184610A - Battery overdischarge preventing device and battery pack having the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a device of high performance at a low cost which prevents overdischarge of a battery or a battery pack. SOLUTION: This over discharge preventing device is equipped with a battery BT1; a field effect transistor Q1 which supplies power source of the battery BT1 to a load circuit or interrupts the power supply of the battery BT1 to the load circuit according to a control signal applied to a gate; a voltage detecting element IC1, and diodes D1, D4, D5 which detect a battery voltage inputted in the drain of Q1 from the battery BT1 and a load voltage inputted in a load circuit from the source of Q1; a transistor Q2 which applies a control signal for interrupting the power supply of the battery BT1 to the load circuit to the gate of Q1 when the load voltage becomes lower than 5 V, and applies a control signal for supplying power source of the battery BT1 to the load circuit to the gate of the Q1 when the battery voltage becomes higher than 5.7 V.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for preventing overdischarge of a battery and a battery pack having the device for preventing overdischarge.

[0002]

2. Description of the Related Art When power is supplied from a battery or a battery pack to a load circuit such as a mobile phone or a portable audio device, when a failure such as a short circuit occurs in the load circuit, an excessively large amount of power is supplied from the battery or the battery pack. An overdischarge phenomenon in which a current flows occurs. Such overdischarge may cause damage to the battery, and the normal function may not be restored even if the charging process is performed thereafter. For this reason, on the load circuit side, a protection circuit for detecting a fault such as a short circuit is separately provided to take measures to prevent overdischarge of the battery.

[0003]

However, since the protection circuit for detecting a fault such as a short circuit is complicatedly coupled to the configuration of the load circuit, the higher the performance, the higher the cost. This has led to an increase in the cost of products such as audio devices. An object of the present invention is to provide a high-performance and inexpensive device for preventing overdischarge of a battery or a battery pack.

[0004]

According to the present invention, there is provided a battery over-discharge prevention device, comprising: switch means for supplying a battery power to a load circuit or stopping the battery power to a load circuit in response to a control signal; A voltage detecting means for detecting a battery voltage inputted to the switch means from the switch and a load voltage inputted to the load circuit from the switch means; and as a result of the detection by the voltage detecting means, the load voltage becomes a first predetermined value. When the value becomes smaller than the value, a control signal for stopping the power supply of the battery to the load circuit is given to the switch means, and as a result of the detection by the voltage detecting means, the battery voltage becomes larger than a second predetermined value. Control to supply a control signal for supplying the power of the battery to the load circuit to the switch processing. Has a configuration in which and a No. generator.

A battery pack having an overdischarge prevention device according to the present invention comprises a battery, and switch means for supplying power of the battery to a load circuit in response to a control signal or for stopping power of the battery to the load circuit. Voltage detection means for detecting a battery voltage input from the battery to the switch means and a load voltage input to the load circuit from the switch means; and as a result of the detection by the voltage detection means, the load voltage When the voltage becomes smaller than the predetermined value, a control signal for stopping the power supply of the battery to the load circuit is given to the switch means, and as a result of the detection by the voltage detecting means, the battery voltage becomes lower than the second predetermined value. When it becomes larger, the control signal for supplying the power of the battery to the load circuit is transmitted to the switch. It has a configuration which includes a control signal generating means for supplying to the switch processing, the.

According to the present invention, when the voltage detecting means detects that the load voltage has become smaller than the predetermined value, the control means controls the switch means to stop the power supply of the battery to the load circuit. .

[0007]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram showing a configuration of a battery pack having an overdischarge prevention device. The battery BT1 has a rated voltage of Vs and a maximum discharge current of Im.
Is a rechargeable battery. The plus side of BT1 is MOS
FET (field effect transistor) Q1 is connected to the drain, and the source of Q1 is connected to the plus terminal of connector J1. The negative side of BT1 is grounded, and the negative terminal of J1 is also grounded. And J
I is connected to a load circuit (not shown). Therefore, Q
When 1 is on, BT1 is connected to the load circuit and supplies a discharge current to the load circuit.

The anode of the diode D1 is connected to the line of the positive terminal of J1, that is, the source of Q1,
One cathode is connected to one of the resistors R1. R1
The other is connected to the input terminal of the voltage detection element IC1, connected to one of the cathode of the constant voltage diode D2 and the capacitor C1, and further connected to the resistor R2. The common terminal of IC1, the anode of D2 and the other of C1 are grounded. The output terminal of IC1 is connected to one of the resistors R5, and the other of R5 is connected to the base of the switching transistor Q2.
The emitter of Q2 is grounded, and the collector is connected to one of the resistors R3.

The other of R3 is a gate of Q1 and a resistor R4.
And the other of R4 is connected to the drain of Q1, that is, to the positive side of BT1, and to the cathode of diode D3. The anode of D3 is connected to the source of Q1. That is,
D3 is connected in parallel between the drain and source of Q1.

The anode of a diode D4 is connected to the drain of Q1, that is, to the positive side of BT1. The cathode of D4 is connected to the anode of diode D5, and the cathode of D5 is connected to the other end of resistor R2. That is, the source of Q1 is connected to the input terminal of IC1 via the series circuit of D1 and R1, and the drain of Q1 is connected to the IC via the series circuit of D4, D5 and R2.
1 input terminal. Note that D1, D4, D
5 is substantially the same (approximately 0.
6 volts).

The voltage detecting element IC1 has a high level at the output terminal when a voltage higher than a predetermined value is applied to the input terminal and a voltage lower than the predetermined value at the input terminal. The output terminal is at a low level voltage.
Now, assuming that the rated voltage Vs of the BT1 is 6 volts, the predetermined value is 4.5 volts. Therefore, when Q1 is in the ON state, when the voltage of BT1 is the rated voltage of 6 volts, a voltage of about 5.4 volts, which is a predetermined value or more, is applied to the input terminal of IC1 due to the voltage drop of D1. ,
The output terminal of IC1 is at a high level. On the other hand, B
When the voltage of T1 drops by 1 volt to 5 volts, IC
A voltage of about 4.4 volts, which is less than a predetermined value, is applied to the input terminal of No. 1 and the output terminal of IC1 goes low.

Next, the operation of the circuit shown in FIG. 1 will be described. Now, it is assumed that the battery BT1 is connected to the load circuit via the connector J1 while the field-effect transistor Q1 is on. In this case, 6 volts, which is the rated voltage of BT1, is applied to the load circuit, and a discharge current smaller than the maximum discharge current Im is supplied. Therefore, a voltage of about 5.4 volts, which is lower than the voltage of BT1 by the voltage drop of the diode D1, is applied to the input terminal of the voltage detection element IC1. In this case,
The output terminal of IC1 is at a high level voltage. Therefore, the transistor Q2 is in the ON state, and a voltage obtained by dividing the voltage of BT1 by the resistors R4 and R5 is applied to the gate of Q1. As a result, Q1 maintains the ON state, and maintains a state in which a normal discharge current is supplied from BT1 to the load circuit.

When an abnormal state occurs in the load circuit and an excessive discharge current flows in the load circuit, the voltage of BT1 decreases. When this voltage drop reaches 1 volt, IC
The voltage applied to one input terminal drops to about 4.4 volts. In this case, the output terminal of IC1 changes to a low level voltage. Therefore, the transistor Q2 is turned off, and the voltage of BT1 is applied to the gate of Q1. As a result, Q1 is turned off, and excessive discharge current from BT1 to the load circuit stops. Therefore, B
Overdischarge of T1 can be prevented.

D3 is a charging diode. When charging BT1 from the connector J1, BT1 and J1 are connected even when Q1 is off, and the charging current is changed to BT1.
To supply. Also, the series circuit of D4, D5 and R2 is
This is a circuit for returning Q1 to the ON state. When the voltage of the charged and recovered BT1 becomes greater than 5.7 volts, IC1 is connected through a series circuit of D4, D5 and R2.
A voltage higher than 4.5, which is lower than the voltage of BT1 by the voltage drop of D4 and D5, is applied to the input terminal of. Therefore, the output terminal of IC1 changes from the low level to the high level, and Q2 changes from the off state to the on state. Then, Q1 returns from the off state to the on state, and
A normal discharge current is supplied from T1 to the load circuit.

By the way, when the voltage of BT1 fluctuates at a value near 5 volts, assuming that there is only one return diode, the output terminal of IC1 frequently fluctuates to high level or low level, and Q1 Cannot maintain the steady state of the ON state or the OFF state. In order to avoid this unstable state, the return circuit is provided with a hysteresis characteristic by using two diodes D4 and D5. The constant voltage diode D2 is a protection circuit that prevents the IC1 from being destroyed when an excessive voltage is applied to the input terminal of the IC1 during charging. The capacitor C1 is an IC
This is to avoid malfunction due to noise input to one input terminal.

As described above, according to the above-described embodiment, the battery BT1 and the switch for supplying the power of the battery BT1 to the load circuit or stopping the power of the battery BT1 to the load circuit in accordance with the control signal given to the gate. means
(Field effect transistor Q1) and voltage detecting means (voltage detecting means) for detecting the battery voltage input from the battery BT1 to the switching means (drain of Q1) and the load voltage input from the switching means (source of Q1) to the load circuit. When the load voltage is smaller than a first predetermined value (for example, 5 volts) as a result of detection by the element IC1, the diodes D1, D4, and D5) and the voltage detection means, the power supply of the battery BT1 to the load circuit is performed. Is supplied to the switch means (gate of Q1), and if the battery voltage is higher than a second predetermined value (for example, 5.7 volts) as a result of detection by the voltage detection means, the load circuit Control signal generating means (transistor) for supplying a control signal for supplying power of the battery BT1 to the switch means (gate of Q1). Has a configuration which includes a static Q2), the.

According to the configuration of the embodiment, when the voltage detecting means detects that the load voltage has become smaller than the predetermined value, the switch means is configured to stop the power supply of the battery to the load circuit. Control. Therefore, a high-performance and inexpensive device for preventing overdischarge of the battery pack can be provided.

In this case, the second predetermined value is a value larger than the first predetermined value, and the voltage detecting means calculates a difference obtained by subtracting the first predetermined value from the second predetermined value. Has appropriate hysteresis characteristics. Therefore, even when the voltage of the battery BT1 fluctuates at a value near the first predetermined value, the output terminal of the IC1 does not frequently fluctuate to a high level or a low level, and Q1 is in an on state or an off state. The state can be maintained stably.

Further, in this case, the battery BT
1 for supplying a charging current from outside (diode D
3) was further provided. Therefore, while the switch Q1 remains in the OFF state, the voltage of the battery
T1 can be easily charged.

In the above embodiment, the present invention has been described by taking a battery pack as an example. However, the overdischarge prevention device can be constituted only by the circuit excluding the battery BT1 in FIG. That is, the overdischarge prevention device according to the present invention is a switch means (field effect transistor Q1) for supplying power of the battery BT1 to the load circuit or stopping power of the battery BT1 to the load circuit according to the control signal given to the gate. And voltage detecting means (voltage detecting element IC1, diode D1,...) Detecting the battery voltage input from battery BT1 to the switch means (drain of Q1) and the load voltage input from the switch means (source of Q1) to the load circuit. D4, D
5) when the voltage detection means detects that the load voltage is lower than a first predetermined value (for example, 5 volts), the control signal for stopping the power supply of the battery BT1 to the load circuit is switched. (Gate of Q1), and as a result of detection by the voltage detecting means, when the battery voltage becomes larger than a second predetermined value (for example, 5.7 volts), power of the battery BT1 is supplied to the load circuit. Switch means (gate of Q1)
And a control signal generating means (transistor Q2).

In this case as well, when the voltage detecting means detects that the load voltage has become smaller than the predetermined value, the control means controls the switch means to stop the power supply of the battery to the load circuit. Therefore, a high-performance and inexpensive device for preventing overdischarge of the battery can be provided.

[0022]

According to the present invention, when the voltage detecting means detects that the load voltage has become smaller than the predetermined value, the switch means is configured to stop the power supply of the battery to the load circuit. Control. Therefore, a high-performance and inexpensive device for preventing overdischarge of a battery or a battery pack can be provided.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a configuration of a battery pack according to the present invention.

[Explanation of symbols]

 BT1 Battery Q1 Field-effect transistor IC1 Voltage detection element D1, D4, D5 Diode Q2 Switching transistor

Claims (6)

[Claims] 1. Switch means for supplying power of a battery to a load circuit or stopping power supply of a battery to a load circuit in response to a control signal, and a battery voltage input to the switch means from the battery and the switch means A voltage detecting means for detecting a load voltage inputted to the load circuit from a battery; and, as a result of the detection by the voltage detecting means, when the load voltage becomes smaller than a first predetermined value, a battery to the load circuit is provided. A control signal for stopping the power supply to the switch means, and when the battery voltage is higher than a second predetermined value as a result of the detection by the voltage detection means, the power supply of the battery to the load circuit is supplied. Control signal generating means for giving a control signal to the switch processing to cause the switch processing to be performed. Prevention device. 2. The method according to claim 1, wherein the second predetermined value is a value larger than the first predetermined value, and the voltage detection means responds to a difference obtained by subtracting the first predetermined value from the second predetermined value. The battery over-discharge protection device according to claim 1, wherein the device has a hysteresis characteristic. 3. The method according to claim 1, wherein
A battery over-discharge prevention device, further comprising means for externally supplying a charging current to the battery. 4. A battery, switch means for supplying power of the battery to a load circuit in response to a control signal or stopping power supply of the battery to the load circuit, and a battery inputted from the battery to the switch means. Voltage detection means for detecting a voltage and a load voltage inputted from the switch means to the load circuit; and, if the load voltage is smaller than a first predetermined value as a result of detection by the voltage detection means, A control signal for stopping the power supply of the battery to the load circuit is given to the switch means. As a result of the detection by the voltage detection means, when the battery voltage becomes larger than a second predetermined value, the control signal to the load circuit is given. Control signal generating means for providing a control signal for supplying power to a battery to the switch processing. Battery pack having overdischarge preventing device according to. 5. The second predetermined value is a value larger than the first predetermined value, and the voltage detection means responds to a difference obtained by subtracting the first predetermined value from the second predetermined value. The battery pack having the overdischarge prevention device according to claim 4, wherein the battery pack has a hysteresis characteristic. 6. The invention according to claim 4, wherein
A battery pack having an overdischarge prevention device, further comprising means for externally supplying a charging current to the battery.