JP2002208443A - Battery pack - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery pack which is in a state of very low power consumption when detached from an equipment, and enabled to safely use by preventing the flow of big current caused by short-circuited output terminals. SOLUTION: The battery pack comprises a main switch 3 serially connected to a cell 1, a control circuit 4 controlling the connection and disconnection of the main switch 3, and a bypass discharge circuit 10 connected to the main switch in parallel. The bypass discharge circuit 10 has a protection element 12 restricting output current. The control circuit 4 keeps the main switch 3 in the state of off, when the pack is not connected to an equipment 9. When the pack is connected to the equipment 9, and a start signal is inputted from the equipment 9, the control circuit 4 switched the main switch 3 from the state of turned off to the state of turned on.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery pack that can be safely used in a state where it is detached from equipment.

[0002]

2. Description of the Related Art In a battery pack, when an output terminal is short-circuited in a state where the battery is detached from a device, a large short-circuit current flows. A large short-circuit current is not preferable because it not only significantly reduces the battery performance but also heats the battery and the lead wires. In order to prevent this state, a battery pack having a main switch 3 provided between a battery 1 and an output terminal 2 has been developed as shown in the circuit diagram of FIG. When the battery pack is removed from the device 9, the main switch 3
Hold off. Therefore, even if the output terminal 2 is short-circuited by disconnecting from the device 9, no short-circuit current flows. However, since the main switch 3 is kept off, even when the main switch 3 is attached to the device 9, the discharge cannot be performed and power cannot be supplied to the device 9. For this reason, this battery pack is
Unless is turned on, the device 9 cannot be started with the battery pack.

The illustrated battery pack includes a control circuit 4 for switching a main switch 3 from off to on. The control circuit 4 includes a detection unit 5 that detects that the battery pack is mounted on the device 9, and a control unit 6 that outputs a signal for turning on the main switch 3 based on a signal from the detection unit 5. The control unit 6 is set in an operation state and is on standby. When the battery pack is attached to the device 9, the detecting unit 5 in the operating state is activated.
Then, the control unit 6 switches the main switch 3 from off to on to switch to a state where discharge is possible. The detection unit 5 is connected to the device 9 via a dedicated mounting detection terminal 14 to detect that the device 9 has been mounted. On the device side, the mounting detection terminal 14 of the mounted battery pack is connected to ground. When the attachment detection terminal 14 is connected to the ground, the detection unit 5 and the control unit 6 of the battery pack switch the main switch 3 from off to on.

[0004]

In the battery pack shown in FIG. 1, the main switch 3 is kept off when the battery 9 is detached from the device 9, so that a short-circuit current when the output terminal 2 is short-circuited can be prevented. Further, in this battery pack, only the detection unit 5 and the control unit 6 can be put on standby and the protection unit 7 and the integration unit 8 can be put on standby and put on standby. For this reason, there is also a feature that the current consumption of the control circuit 4 can be made extremely small in a state where the battery pack is detached from the device 9 and an ultra-low power consumption state can be achieved. It is extremely important for a battery pack to reduce the power consumption of the battery pack removed from the device. This is to prevent the built-in battery from being over-discharged with the battery pack removed from the device for a long time. The battery pack removed from the device is not charged, and the remaining capacity gradually decreases with the power consumed by the control circuit. When the remaining amount becomes 0 and the battery pack is not further mounted on the device, the battery discharge proceeds and becomes overdischarged.
The performance of a battery is significantly reduced when it is overdischarged.

[0005] The battery pack of FIG. 1 has an excellent feature that power consumption can be reduced while short-circuit current is prevented.
However, this battery pack needs to be provided with a dedicated attachment detection terminal to detect that the battery is attached to the device. Since the attachment detection terminal is provided on both the battery pack and the device,
There are disadvantages that the manufacturing cost of the connector and the terminal increases, and the dimensions of the connection portion, the substrate, and the like increase.

Incidentally, some battery packs have an information terminal for transmitting information such as the remaining capacity of the battery to and from a device to be mounted. If the information terminal can be used as a dedicated mounting detection terminal,
The above operation can be performed. However, the information terminal cannot be used together with the dedicated mounting detection terminal. This is because the information terminal cannot be connected to the ground and the device can output a signal from the information terminal after it has been activated. The reason that the information terminal cannot be connected to the ground is that the information cannot be transmitted by connecting to the ground.
Further, in order to switch the device to the operating state, it is necessary to switch the main switch from off to on.
The signal cannot be output from the information terminal to the battery pack.

Therefore, as shown in FIG. 2, it is necessary to keep the main switch 3 in the on state with the information terminal used in combination with the attachment detection terminal, as shown in FIG. In this battery pack, when the output terminal 2 is short-circuited, a large short-circuit current flows. In order to protect this state, it is necessary to make the protection unit 7 of the control circuit 4 stand by in an operating state. For this reason, there is a drawback that the power is consumed by the protection unit 7 and the power consumption cannot be reduced to a very low level when the protection unit 7 is disconnected from the device 9.

[0008] The present invention has been developed for the purpose of solving such disadvantages. It is an important object of the present invention to provide a battery pack that can be used ultra-low power when it is detached from a device, and can be used safely by preventing a large short-circuit current from flowing by short-circuiting an output terminal. .

[0009]

The battery pack of the present invention comprises:
A main switch 3 connected in series with the battery 1, a control circuit 4 for turning the main switch 3 on and off,
Bypass discharge circuit 10 in parallel with main switch 3
And The bypass discharge circuit 10 has a protection element 12 for limiting an output current. The control circuit 4 disconnects the battery pack from the device 9 without attaching it to the main switch 3.
Hold off. When the battery pack is mounted on the device 9 and a start signal is input from the device 9, the control circuit 4 switches the main switch 3 from off to on.

The battery pack preferably has a communication terminal 13 connected to the control circuit 4. This battery pack is
A start signal can be input from the device 9 via the communication terminal 13. However, it is also possible to use the output terminal 2 instead of the communication terminal 13 to input the start signal from the device 9 to the control circuit 4 of the battery pack.

In this battery pack, the battery 1 is connected to the output terminal 2 via a bypass discharge circuit 10 having a protection element 12 in a state of being detached from the device 9, but the main switch 3 is kept off. You. In the battery pack in this state, a large current does not flow even if the output terminal 2 is short-circuited. This is because the battery 1 is discharged via the bypass discharge circuit 10 having the protection element 12. Further, the battery pack in this state cannot be discharged with a large current, but can supply a current to be mounted on the device 9 and start the device 9. Therefore, when mounted on the device 9, the device 9 can be started with the battery pack. The activated device 9 can output an activation signal to the battery pack via the communication terminal 13. The control circuit 4 switches on the main switch 3 of the battery pack that has detected the activation signal. In this state, the battery 1 is connected to the device 9 by the main switch 3.

The battery pack includes a bypass discharge circuit 10
Therefore, since a large short-circuit current when the output terminal 2 is short-circuited is prevented, there is no need to make the protection unit 7 incorporated in the control circuit 4 stand by in an operating state. Therefore, power consumption in a state where the battery pack is removed from the device 9 can be reduced.

The bypass discharge circuit 10 preferably has
An auxiliary switch 11 that is turned on by the control circuit 4 with the battery pack removed from the device 9 and a protection element 12 that limits the output current are connected in series. This bypass discharge circuit 10 can prevent the protection element 12 from flowing a large current when the output terminal 2 is short-circuited. After the main switch 3 is turned on, the auxiliary switch 11 is turned off so that the protection element 12 is not energized. PTC is preferably used for the protection element 12.

The control circuit 4 includes a control unit 6 for switching the main switch 3 on and off, a detection unit 5 for detecting a start signal input from the device 9 to control the control unit 6, and a battery 1
, And a protection unit 7 that detects the battery voltage and switches the main switch 3 on and off via the control unit 6. With the battery pack removed from the device 9, the control unit 6 and the detection unit 5 can be set to the operation state, and the integration unit 8 and the protection unit 7 can be set to the non-operation state.

The communication terminal 13 provided on the battery pack includes:
A terminal for transmitting information between the battery pack and the device 9 when connected to the device 9. Therefore, this communication terminal 1
3 transmits information such as the remaining capacity of the battery 1 and the maximum charging capacity from the battery pack to the device 9.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below illustrate a battery pack for embodying the technical idea of the present invention, and the present invention does not specify the battery pack as follows.

Further, in this specification, in order to make it easier to understand the claims, the numbers corresponding to the members shown in the embodiments will be referred to as “claims” and “ In the column of “means”.
However, the members described in the claims are not limited to the members of the embodiments.

The battery pack shown in FIG. 3 includes a rechargeable battery 1, a main switch 3 connected in series with the battery 1, a control circuit 4 for turning the main switch 3 on and off, and a main switch 3. And a bypass discharge circuit 10 connected in parallel.

The battery 1 is a lithium ion secondary battery. However, a nickel-hydrogen battery or a nickel-cadmium battery can be used as the battery. One or a plurality of batteries 1 are incorporated in the battery pack.

The main switch 3 is connected in series between the battery 1 and the output terminal 2 of the battery pack. In the battery pack shown, a main switch 3 is connected to the battery 1 and the + terminal of the output terminal 2. The negative side of the battery 1 is directly connected to the output terminal 2. The main switch 3 is a transistor or F
It is a semiconductor switching element such as ET. However, a device having mechanical contacts such as a relay can also be used. The main switch 3 is turned on and off under the control of the control circuit 4. The main switch 3 is turned on when the battery pack is mounted on the device 9 under the control of the control circuit 4.
When it is removed from the device 9, it is switched off.

The bypass discharge circuit 10 has a protection element 12 for limiting the output current.
Connects the auxiliary switch 11 and the protection element 12 in series. The protection element 12 is a PTC. However, a fuse or a breaker that cuts off the current when an excessive current flows can be used as the protection element. The auxiliary switch 11, like the main switch 3, is a semiconductor switching element such as a transistor or an FET. Auxiliary switch 11
Is also switched on and off under the control of the control circuit 4. The auxiliary switch 11 is controlled by the control circuit 4 and is turned on when the battery pack is removed from the device 9 and is turned off when the main switch 3 is turned on when the battery is mounted on the device 9. Further, the auxiliary switch 11 is also turned off when preventing overcharging and overdischarging of the battery 1.

The control circuit 4 shown in the figure includes a control unit 6 for switching the main switch 3 on and off, a detection unit 5 for detecting a start signal input from the device 9 and controlling the control unit 6, and a remaining capacity of the battery 1. And a protection unit 7 that detects the battery voltage and switches the main switch 3 on and off via the control unit 6.

The control unit 6 outputs a signal for switching the main switch 3 on and off to a switching element, which is the main switch 3, based on signals input from the detection unit 5 and the protection unit 7. When a signal for turning on the main switch 3 is input from the detection unit 5 or the protection unit 7, the control unit 6 sends a control signal for turning on the main switch 3 to the main switch 3.
Output to For example, when an ON signal of the main switch 3 is input from the detection unit 5 or the protection unit 7, the control unit 6
High "is output to turn on a switching element such as a transistor or an FET which is the main switch 3.
When a signal for turning off the main switch 3 is input from the detection unit 5 or the protection unit 7, a “Low” signal is output to turn off the switching element that is the main switch 3.

Further, when the main switch 3 is turned on, the control unit 6 turns off the auxiliary switch 11, and when the main switch 3 is turned off, the control unit 6 uses the auxiliary switch 11 to output a signal to turn on the auxiliary switch 11. Output to a certain switching element. Therefore, the control unit 6 sets “High” and “Low” to the main switch 3 and the auxiliary switch 11.
And outputs the opposite signal.

The detector 5 detects a start signal input from the device 9 and outputs an on / off signal to the controller 6.
In the illustrated battery pack, the detection unit 5 is connected to the communication terminal 13. In this battery pack, the detection unit 5 detects a start signal input to the communication terminal 13. The structure in which the start signal is transmitted from the device 9 to the battery pack through the communication terminal 13 allows the start signal to be accurately transmitted from the device 9 to the battery pack with a simple circuit. However, the battery pack of the present invention does not necessarily need to provide the communication terminal 13. This is because a start signal and an information signal can be transmitted from the device 9 to the battery pack via the output terminal 2. In order to transmit a start signal from the output terminal 2, for example, a carrier wave is modulated by a start signal or an information signal and transmitted from the device 9 to the battery pack, or a very short time that does not affect the device 9 on the device side. Then, the output terminal 2 of +-is switched to instantaneously change the voltage of the output terminal 2, and a start signal or an information signal is transmitted by the change in the voltage. The control unit 6 and the detection unit 5 detect that the battery pack is attached to the device 9 and switch the main switch 3 on.

The accumulator 8 operates with the battery pack attached to the device 9 to calculate the remaining capacity of the battery 1. Battery 1
Can be calculated by subtracting the integrated value of the discharge current from the integrated value of the charge current. The remaining capacity of the battery 1 accumulated by the accumulation unit 8 is transmitted to the device 9 via the communication terminal 13. This signal can also be transmitted to the device 9 via the output terminal 2. The battery pack provided with the integrating unit 8 in the control circuit 4 can transmit the remaining capacity of the battery 1 to the device 9, so that the device side can determine the usage time of the battery pack. This is important, for example, when the device 9 is a microcomputer. The reason is that when the remaining capacity of the battery pack decreases, the microcomputer can be terminated before the battery is completely discharged. The accumulating unit 8 does not need to inform the device 9 of the remaining capacity when the battery pack is removed from the device 9.
Is set to an operating state when attached, and a non-operating state when detached from the device 9.

The protection unit 7 detects the voltage of the battery 1 and protects the battery 1 from overcharge and overdischarge. When the battery voltage becomes higher than the set maximum voltage or becomes lower than the set minimum voltage, the protection unit 7 outputs a signal for turning off the main switch 3 and the auxiliary switch 11 to the control unit 6. Thus, overcharging and overdischarging of the battery 1 are prevented. When the battery voltage becomes higher than the maximum voltage, the main switch 3 and the auxiliary switch 11 are turned off to stop charging, but when the charging is stopped and discharged, the main switch 3 is turned on to supply power to the device 9. It is in a state where it can be done. Also, after the battery voltage is higher than the maximum voltage and the auxiliary switch 11 is turned off, the auxiliary switch 11 is turned on after the battery pack is detached from the device 9, so that the auxiliary switch 11 can be discharged.

The battery pack shown in FIG. 4 performs the following operations to prevent a large short-circuit current from flowing when the output terminal 2 is short-circuited in a state where the battery is detached from the device 9. To supply power to the device 9.

[When the output terminal is short-circuited while the battery pack is removed from the equipment] The battery pack in the state removed from the equipment 9 is controlled by the control circuit 4 so that the main switch 3 is turned off and the bypass discharge circuit 1
The auxiliary switch 11 of 0 is kept on. The output terminal 2 of the battery pack is short-circuited for some reason. Since the battery 1 is discharged through the bypass discharge circuit 10 having the protection element 12 in the battery pack in which the output terminal 2 is short-circuited, the protection element 12 prevents a large short-circuit current from flowing.

[When a battery pack is mounted on a device and power is supplied] The battery pack detached from the device 9 is turned off by the control circuit 4 and the bypass discharge circuit 1
The auxiliary switch 11 of 0 is kept on. The battery pack is mounted on the device 9. At this time, battery 1
Is discharged from the output terminal 2 via the bypass discharge circuit 10. The battery pack in this state cannot be discharged with a large current by the bypass discharge circuit 10 having the protection element 12, but can supply a current for starting the device 9. The device 9 is activated by the power supplied from the battery pack, and an activation signal is input from the device 9 to the battery pack. The activated device 9 is connected via the communication terminal 13 or
A start signal is output to the battery pack through the output terminal 2. When a start signal is input from the device 9, the control circuit 4
Switches the main switch 3 from off to on. In this state, the battery 1 is connected to the device 9 via the on-state main switch 3 and supplies power to the device 9.

[0031]

The battery pack according to the present invention has a feature that, when the battery pack is detached from the device, the output terminal is short-circuited to prevent a large short-circuit current from flowing and can be used safely. that is,
The battery pack of the present invention includes a bypass discharge circuit formed in parallel with the main switch, the bypass discharge circuit has a protection element for limiting the output current, and the control circuit operates when the battery pack is not mounted on the device. This is because the main switch is kept off, and the control circuit switches the main switch from off to on when a start signal is input from the device with the battery pack attached to the device. In this battery pack, even if the output terminal is short-circuited, a large current does not flow because the battery is discharged via the bypass discharge circuit having the protection element. Therefore, even if the output terminal is short-circuited, a large short-circuit current can be reliably prevented from flowing.

In addition, a battery pack having a bypass discharge circuit cannot discharge with a large current, but can supply a current for starting the equipment when it is mounted on the equipment. Therefore, the main switch is turned on by the control circuit in accordance with a signal from the device to be activated, and power can be supplied to the mounted device so that the device can be used safely.

Further, in the battery pack of the present invention, since the bypass discharge circuit prevents a large short-circuit current, there is no need to make the protection section built in the control circuit stand by in the operating state, and the battery pack is removed from the device. Ultra low power consumption can be achieved by reducing power consumption in the state.

[Brief description of the drawings]

FIG. 1 is a schematic circuit diagram of a conventional battery pack.

FIG. 2 is a schematic circuit diagram of a conventional battery pack.

FIG. 3 is a schematic circuit diagram of a battery pack according to an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Battery 2 ... Output terminal 3 ... Main switch 4 ... Control circuit 5 ... Detection part 6 ... Control part 7 ... Protective part 8 ... Integration part 9 ... Equipment 10 ... Bypass discharge circuit 11 ... Auxiliary switch 12 ... Protective element 13 ... Communication Terminal 14: Mounting detection terminal

Claims (6)

[Claims] 1. A main switch (3) connected in series with a battery (1), a control circuit (4) for turning on and off the main switch (3), and a parallel connection with the main switch (3) The bypass discharge circuit (10) has a protection element (12) for limiting the output current, and the control circuit (4) mounts the battery pack on the device (9). Turn off the main switch (3) when the battery pack is not
A battery pack that is mounted on a battery and switches the main switch (3) from off to on when a start signal is input from the device (9). 2. A battery pack is supplied from a device (9) to a control circuit (4).
The battery pack according to claim 1, further comprising a communication terminal (13) for inputting a start signal to the battery pack. 3. An auxiliary switch (11) that is turned on by a control circuit (4) in a state where a battery pack is detached from a device (9), and a protection element (11) that limits an output current. 2. The battery pack according to claim 1, wherein the battery is a circuit formed by serially connecting the battery pack and the control circuit. 4. The battery pack according to claim 1, wherein the protection element is PTC. 5. A control circuit (4) for controlling a control unit (6) for switching a main switch (3) on and off and a start signal inputted from a device (9) to control the control unit (6). Detector (5)
An integrating unit (8) for detecting the remaining capacity of the battery (1), and a protection unit (7) for detecting the battery voltage and switching the main switch (3) on and off via the control unit (6). And a control unit (6) and a detection unit (5) in an operating state and a multiplication unit (8) and a protection unit (7) in a non-operation state in a state in which the battery pack is removed from the device (9). The battery pack described in 1. 6. The battery pack according to claim 2, wherein the communication terminal is a terminal for transmitting information between the battery pack and the device while the communication terminal is connected to the device.