JP3277871B2 - Rechargeable battery pack - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a detachable secondary battery pack used as a power source for personal computers, office automation equipment, mobile phones, and the like.

[0002]

2. Description of the Related Art FIG. 4 is a circuit diagram showing an example of a conventional secondary battery pack.

This battery pack is composed of a plurality of unit cells (cells).
Are connected in series to form a battery pack, and a load device (not shown) connected in series to the secondary battery 21.
Overdischarge prevention switch 22 for turning on / off the battery output to the battery
And an overdischarge prevention switch 23 for turning on / off a charge input to the secondary battery 21 and a power supply monitoring circuit 24 for monitoring overdischarge and overcharge of the secondary battery 21.

In the battery pack having the above configuration, when the power supply monitoring circuit 24 detects an overdischarge of the secondary battery 21 during a discharging operation, the overdischarge prevention switch 22 is turned off by a detection output Dout at that time. When the battery output Vc (that is, the discharge current) to the load device is cut off, and the overcharge of the secondary battery 21 is detected during the charging operation, the overcharge prevention switch 2 is detected by the detection output Cout at that time.
By turning off the battery 3 and turning off the charging input (that is, charging current) to the secondary battery 21, performance deterioration and destruction of the secondary battery 21 due to overdischarge or overcharge are prevented.

However, in the secondary battery pack having such a configuration, the battery output Vc is not shut off unless overdischarge detection or overcharge detection is performed. Therefore, even when the secondary battery pack is detached from the load device, the output terminal of the secondary battery pack is not disconnected. This means that the battery voltage is constantly applied to T1. Therefore, if the output terminal T1 is short-circuited by a metal body such as a key by mistake while the secondary battery pack is being carried, the pack interior parts generate abnormal heat due to the discharge current at that time, and in particular, the performance of the secondary battery 21 deteriorates. And risk of damage.

FIG. 5 shows a circuit which is improved in view of the above-mentioned disadvantages.
FIG. 5 is a circuit diagram of a secondary battery pack having a so-called remote-on function for controlling on / off of power supply to a load device based on a power control signal (OUTon signal) from a power supply control unit 5;

That is, according to this circuit, when the secondary battery pack is mounted on the load device, the remote-on circuit 2
5 detects the control power supply Vs supplied from the secondary battery 21 via the terminal T3, and outputs the OUTon signal “L” to the terminal T4.
, The overdischarge prevention switch circuit 22 is turned on to start supplying power to the load device. On the other hand, when the secondary battery pack is removed, the terminal T4
Is changed to the "H" state, the overdischarge prevention switch 22 is turned off, and the power supply to the load device is stopped.

As described above, unlike the secondary battery pack shown in FIG. 4, in the case of this example, no voltage is generated at the output terminal T1 when the secondary battery pack is left alone,
Even if the output terminal T1 is temporarily short-circuited by mistake, no electrical inconvenience occurs in the secondary battery pack.

Of course, if the power supply monitoring circuit 24 detects overdischarge even when the secondary battery pack is mounted,
The overdischarge prevention switch 22 is turned off by the detection output Dout at that time, and the power supply to the load device is stopped.

[0010]

However, such a secondary battery pack having a remote-on function has a power supply terminal Vcc of the power supply monitoring circuit 24 and a remote-on circuit 2 of a load device.
5, the control power supply Vs is supplied directly from the secondary battery 21. Therefore, even if the power supply to the load device is cut off due to the detection of overdischarge, As shown by the middle broken line, the secondary battery 21
From the power supply monitoring circuit 24 and the remote-on circuit 25, and the battery discharge is continued with a slight leak current I0 to each load. The overdischarge of 21 further proceeds.

SUMMARY OF THE INVENTION The present invention has been made in order to solve such inconveniences after overdischarge detection, and it is an object of the present invention to provide a secondary battery pack which achieves safety and improves the life of a secondary battery. The purpose is.

[0012]

That is, in the present invention,
ON / OFF of power supply based on a power supply control signal (OUTon) from a load device (RL) and control from an internal control circuit.
A rechargeable battery pack that can be turned off. The rechargeable battery (1) is connected in series with the rechargeable battery (1), and turns on / off a battery output (Vc) to the load device (RL). A first switch circuit (2) to be turned off, and a direct connection to the secondary battery (1).
Connected to a column, the internal control circuit and the load device
Turns on / off the control power supply (Vs) supplied to (RL)
A second switch circuit (5) and the control power supply (Vs)
H / L power supply output from the load device (RL)
The control signal (OUTon) is used as the base input and the output
ON / OFF control of the first switch circuit (2)
Control circuit consisting of a switching transistor (Q7)
And (3) a power supply for monitoring the voltage of the secondary battery (1) and controlling the first switch circuit (2) and the second switch circuit (5) to an off state when a predetermined voltage is detected. It comprises a monitoring circuit (4) and an activation circuit (6) for turning on the second switch circuit (5) with a voltage externally applied by a charging device or the like.

[0013]

FIG. 1 is a block diagram showing a basic structure of a secondary battery pack according to the present invention.

First, the configuration of the present invention will be described with reference to FIG. 1. Reference numeral 1 denotes a secondary battery built in a battery pack, which is composed of a plurality of unit cells B1. It is what it was. The positive electrode of the secondary battery 1 is drawn out to the terminal T1 as the battery output Vc via the first switch circuit 2, and is supplied to the control power supply Vs via the second switch circuit 5.
Is drawn out to the terminal T3. On the other hand, the secondary battery 1
Is drawn out to the terminal T2 as the ground G. When the battery pack is mounted, the load device RL is connected to these terminals T1 and T2, and power is supplied from the secondary battery 1 to the load device RL. The control power supply Vs drawn to the terminal T3 is used for driving a remote-on circuit (not shown) on the load device RL side.

In the figure, reference numeral 4 denotes a power supply monitoring circuit for monitoring the overdischarge of the secondary battery 1. The positive electrode of each of the cells B1... It is configured such that each cell voltage can be monitored individually.
The output Dout of the power supply monitoring circuit 4 is connected to the input of the first switch circuit 2 and is OR-coupled with the output of a start circuit 6 to be described later. Connected to input.

A power supply terminal Vcc of the power supply monitoring circuit 4 is connected to a control power supply Vs drawn from the secondary battery 1 via the second switch circuit 5.

3 is a power control signal (O) from the load device RL.
Uton signal) based on the first switch circuit 2
The input side is pulled up to the control power supply output Vs by a resistor R1.

Reference numeral 6 denotes a starting circuit for returning the OFF state of the second switch circuit 5 to the ON state.
The battery output Vc supplied through the switch circuit 2 is input, and the output is OR-coupled with the output Dout of the power supply monitoring circuit 4 as described above.

Next, the control operation of the above embodiment will be described with reference to the sequence diagram of FIG.

When the battery pack is mounted on the load device RL, the control power supply Vs supplied from the terminal T3 is detected, and the load device RL outputs the signal OUTon of "L".
(Power-on command) is output. The remote control circuit 3 detects this "L" state via the terminal T4, turns on the first switch circuit 2, and starts power supply to the load device RL via the terminals T1 and T2 (section). .

When the battery pack is removed, the terminal T4 is pulled up to the control power supply output Vs by the resistor R1, and "H" (that is, a power supply disconnection command) is supplied to the remote control path 3. The first switch circuit 2 is turned off to cut off the battery output Vc and stop supplying power to the load device RL. As a result, the activation circuit 6 is turned off but not in the overdischarge detection state, so that the second switch circuit 5 maintains the on state, and supplies power to the power supply monitoring circuit 4 and the terminal T3 (supply of the control power supply Vs). Is continued as it is. The same operation is performed when an "H" signal is input from the load device RL to the remote control circuit 3 via the terminal T4 (section).

When the battery pack is mounted again, the terminal T4
Is supplied with the signal “L”, the first switch circuit 2 returns to the ON state, and the power supply to the load device RL is restarted. The same operation is performed when an “L” signal is input to the remote control circuit 3 from the load device RL via the terminal T4 (section).

When the discharge of the secondary battery 1 proceeds and one of the cell voltages drops below the discharge end voltage VL, the power supply monitoring circuit 4
Operates, the first switch circuit 2 is turned off by the overdischarge detection output Dout, and the power supply to the load device RL is stopped. At this time, the activation circuit 6 is turned off, and the second switch circuit 5 is turned off by the OR output of the off output of the activation circuit 6 and the overdischarge detection output Dout of the power supply monitoring circuit 4, and the power supply monitoring circuit Since the power supply path to the terminal 4 and the terminal T3 is cut off, leakage current from the secondary battery 1 is eliminated, and further discharge after overdischarge detection is prevented.

A charger (not shown) is connected between the terminals T1 and T2, the starting circuit 6 is returned to the on state by the charging input, and the second switch circuit 5 is turned on, so that the power supply monitoring circuit By supplying the drive voltage Vcc to 4, it is possible to recover from the overdischarge state.

FIG. 2 shows an embodiment of a specific electronic circuit of the present battery pack, which is provided with a function of protecting against overcharge in addition to overdischarge.

The battery pack comprises a plurality of unit cells B1.
, A first switch circuit 2 composed of an FET Q4 and a transistor Q6, etc., a remote control circuit 3 composed of a transistor Q7 and the like, and over-discharge and over-discharge of the secondary battery 1. A power supply monitoring circuit 4 for monitoring charging (in this embodiment, an integrated circuit M1 for detecting overdischarge and overcharge is used), and FETs Q1... Qn connected in series to the cells B1. And a start circuit 6 including a transistor Q8 and the like, and an overcharge prevention switch circuit 7 including a FET Q5 and a transistor Q10 and the like. Further, the discharge detection signal Dout of the power supply monitoring circuit 4 is provided.
The output of the starting circuit 6 is OR-connected with the output of the diode D3 and the diode D4, respectively, and is connected to the input of the second switch circuit 5 (gates of the FETs Q1... Qn).

In the battery pack having the above-described structure, when the battery pack is mounted and the signal OUTon “L” is supplied to the terminal T4 from the load device (not shown), the transistor Q
7, Q6 is turned off and FET Q4 is turned on.
Electric power can be supplied to the load device.

When the battery pack is removed or the load device enters the suspend mode, the terminal T4 is set to the "H" state by the pull-up resistor R17, so that the transistors Q7 and Q8 are turned on and the FET Q4 is turned off. Then, the power supply to the load device is stopped. When the power supply is stopped, the input of the starting circuit 6 also shifts to the ground level, so that the transistor Q8 is turned off. However, since the overdischarge is not detected, the FETs Q1.
n maintains the ON state, and the power supply to the power supply monitoring circuit 4 and the terminal T4 is continued.

When overdischarge is detected, the FET Q4 is turned off by the discharge detection output Dout from the power supply monitoring circuit 4 to cut off the power supply to the load device, and the FETs Q1... Qn are turned off by turning off the transistor Q8.
At the same time, the power supply to the power supply monitoring circuit 4 and the terminal T4 is cut off.

When a charger (not shown) is connected to the battery pack in the overdischarge detection state, the transistor Q8 of the starting circuit 6 is turned on by the charging voltage, and the FET Q
1... Qn return to ON, the power supply monitoring circuit 4 is restarted.

At the time of overcharging, the overcharge prevention switch circuit 7 is turned off by an overcharge detection output Cout from the power supply monitoring circuit 4 and the charging path to the secondary battery 1 is cut off, so that the charging operation is performed. Stop.

[0032]

As described above, according to the present invention,
A second switch circuit is provided in the supply path of the control power, and when the overdischarge is detected, the second switch circuit is turned off to cut off the control power output to the internal control circuit and the external load device. Can be eliminated and further discharge of the secondary battery is prevented, so that the life of the secondary battery is improved.

[Brief description of the drawings]

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

FIG. 2 is a specific electronic circuit diagram of the secondary battery pack.

FIG. 3 is a sequence diagram showing a control operation of the secondary battery pack.

FIG. 4 is a circuit diagram of a conventional secondary battery pack.

FIG. 5 is a circuit diagram of a conventional secondary battery pack having a remote-on function.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Secondary battery 2 1st switch circuit 3 Remote control circuit 4 Power supply monitoring circuit 5 2nd switch circuit OUTon Power supply control signal RL Load device Vs Control power supply Vc Battery output

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Masami Miyamoto 5-36-11 Shimbashi, Minato-ku, Tokyo Inside Fuji Electric Chemical Co., Ltd. (72) Inventor Kazunari Suzuki 5-36-11 Shimbashi, Minato-ku, Tokyo No. Fuji Electric Chemical Co., Ltd. (56) Reference JP-A-9-199096 (JP, A) JP-A-9-205726 (JP, A) JP-A-9-215213 (JP, A) JP-A-6 -105458 (JP, A) JP-A-6-104015 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02J ^7/ 00-7/12 H02J ⁷ /34-7/36 G01R 31/36 H01M 2/10 H01M 10/44

Claims (1)

(57) [Claims] A secondary battery pack capable of on / off control of power supply based on a power control signal (OUTon) from a load device (RL) and control from an internal control circuit, comprising: ), And the load device (R) connected in series with the secondary battery (1).
L) a first switch circuit (2) for turning on / off a battery output (Vc) to the secondary control battery (1);
Power supply to supply path and load device (RL)
Second switch circuit for turning on / off (Vs) (5)
From the load device (RL) by the control power supply (Vs).
The output H / L power control signal (OUTon) is
The first switch circuit according to its output.
The transistor (Q7) that controls on / off of (2)
Ri becomes a remote control circuit (3), wherein the voltage of the secondary battery (1) is monitored, the to detect a predetermined voltage the first switching circuit (2) and said second
A power supply monitoring circuit (4) for controlling the switch circuit (5) to be in an off state;
And a starting circuit (6) for turning on the switch circuit (5).