JP2011250519A - Power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To charge respective battery blocks with a battery charger connected to one battery pack and prevent the overcharge of a battery cell while reducing the component cost.SOLUTION: In a power supply device, a plurality of battery packs 10 are connected in parallel. Each battery pack 10 has: a battery block 2 having a plurality of battery cells 1; a detection circuit 3 that detects a charge stop state of each battery cell 1; a discharge terminal 5 connected to the battery block 2; a charge terminal 6 connected to the battery block 2 via a switching element 4; and a communication circuit 7. Each battery pack 10 connects the communication circuit 7 with each other, does not connect the charge terminal 6 with each other, and connects the discharge terminal 5 in parallel. The power supply device transmits a charge stop signal to the detection circuit 3 of a battery pack 10A connected with a battery charger 20, via the communication circuit 7 when any of the detection circuit 3 detects the charge stop state. The detection circuit 3 turns the switching element 4 OFF to stop the charge.

Description

  The present invention relates to a large-capacity power supply device in which a plurality of battery packs are connected in parallel to increase output current.

  A power supply device that connects a plurality of battery packs in parallel to increase output current and capacity has been developed. (See Patent Document 1).

  The power supply device described in the gazette of Patent Document 1 has a plurality of battery packs connected in parallel to increase the output capacity. As shown in FIG. 1, the battery packs connected in parallel form a battery block 92 by connecting a plurality of battery cells 91 in series. The battery block 92 is connected to the output terminal 95 via a charge / discharge FET 94 that controls charge / discharge in order to prevent overcharge and overdischarge. In the charge / discharge FET 94, an FET for controlling the charge current and an FET for controlling the discharge current are connected in series. Each FET is controlled by a control circuit 93 that detects the state of the battery block 92. When the charged battery block 92 is fully charged, the control circuit 93 switches over the FET that controls the charging current to prevent overcharging. When the discharged battery block 92 is completely discharged, the FET for controlling the discharge current is switched off to prevent overdischarge.

  The battery pack 90 having the circuit configuration of FIG. 1 can increase the output capacity as a power supply device by connecting the output terminals 95 in parallel with each other. 1 is connected in parallel to a specific battery pack as a master battery pack, other battery packs as slave battery packs, and information on slave battery packs as master battery packs. Transmitting and preventing overcharging and overdischarging of the battery cells in a state where the battery packs are connected in parallel. When the battery block of any battery pack is overcharged or overdischarged, this power supply device switches the charge / discharge FET provided in each battery pack to OFF to overcharge the battery block. And prevent over-discharge.

JP 2000-294298 A

  1 is connected in parallel, the output terminal 95 is connected in parallel, the output terminal 95 is connected to a load, the battery block 92 is discharged, and the output terminal 95 is connected. A battery charger 92 is connected to charge the battery block 92. That is, the output terminal 95 is used in combination with the charging terminal and discharging terminal of the battery block 92. In the power supply device having this structure, when the discharge current becomes large, it is necessary to use an expensive FET that can withstand a large current as the charge / discharge FET 94, and the cost of the parts increases. In particular, a power supply device in which a plurality of battery packs are connected in parallel to increase the output current is characterized by being able to discharge the load with a large current. For example, the peak value of the discharge current, such as an electric motorcycle, etc. Is ideal for applications where the However, a battery pack that can be used for a high-current load needs to increase the current capacity of the charge / discharge FET, which increases the component cost.

  As shown in FIG. 2, the adverse effect is that a charging terminal 76 and a discharging terminal 75 are provided separately, and a battery block 72 is connected to the charging terminal 76 via a switching element 74 such as an FET. This can be solved by a circuit configuration that is directly connected to the battery block 72. Since the battery pack 70 does not include a large current FET for controlling the discharge current, the battery pack 70 has a feature that it can stably discharge with a large current while reducing the component cost.

  The battery pack 70 having the circuit configuration of FIG. 2 can increase the output current by connecting the discharge terminals 75 in parallel. Further, the power supply device can charge the battery blocks 72 of all the battery packs 70 by connecting the charger 20 to the charging terminal 76 of the master battery pack 70 </ b> A to which the chargers 20 are connected. However, in this power supply apparatus, the battery block 72 of the slave battery pack 70B to which the charger 20 is not connected bypasses the built-in switching element 74 and is connected to the charger 20 via the switching element 74 of the master battery pack 70A. Circuit configuration. The battery block 72 of the slave battery pack 70B charged in this state turns off the switching element 74 of the master battery pack 70A even when any of the battery cells 71 constituting the battery block 72 is overcharged. Cannot switch. This is because the slave battery pack 70B cannot control the switching element 74 built in the master battery pack 70A by the detection circuit 73 that detects overcharge of the battery block 72. For this reason, there is a problem that the battery block 72 of the slave battery pack 70B cannot be charged in a normal state.

  As shown in FIG. 3, this problem is caused by a circuit configuration in which a diode 87 is connected between the battery block 72 and the discharge terminal 75 and the charger 20 is connected to the charge terminal 76 of each battery pack 80 for charging. Can be resolved. The diode 87 blocks the charging current from flowing from the charger 20 connected to the master battery pack 80A to the battery block 72 of the slave battery pack 80B to which the charger 20 is not connected. However, since this power supply device needs to connect the charger 20 to the charging terminal 76 of each battery pack 80 in order to charge all the battery packs 80, there is a drawback that it takes time to charge the battery packs 80. .

  Furthermore, since this power supply device is provided with a high-current diode in the battery pack, there are disadvantages that the cost of parts increases and the power loss due to the voltage drop of the diode also increases. Furthermore, in order to dissipate the diode that generates heat when a large current flows, it is necessary to provide a radiator having a large heat dissipation area, which further increases the component cost.

  The present invention has been developed for the purpose of solving this drawback. An important object of the present invention is that it can charge each battery block by connecting a charger to the charging terminal of one battery pack while omitting the large current diode connected to the discharging terminal to reduce the component cost. And it is providing the power supply device which can charge a battery pack, preventing the overcharge of the battery cell which comprises each battery block.

  Furthermore, another important object of the present invention is to charge one of the battery packs by charging while preventing overcharging of the battery cells constituting all the battery blocks with a switching element incorporated in the specific battery pack. An object of the present invention is to provide a power supply device that can normally charge all battery blocks even if a switching element fails.

Means for Solving the Problems and Effects of the Invention

  The power supply device of the present invention includes a plurality of battery packs 10 connected in parallel to each other and supplying power to a load. Each battery pack 10 includes a battery block 2 formed by connecting a plurality of battery cells 1 in series, a detection circuit 3 that detects a charge stop state of each battery cell 1 and outputs a charge stop signal, and this detection A switching element 4 controlled to be turned on and off by the circuit 3, a discharge terminal 5 connected to the battery block 2 without a diode, a charging terminal 6 connected to the battery block 2 via the switching element 4, And a communication circuit 7 for transmitting a charge stop signal detected by the detection circuit 3 to the detection circuit 3 of another battery pack 10. Each battery pack 10 connects the communication circuit 7 to each other, and connects the discharge terminals 5 in parallel without connecting the charge terminals 6 to each other. In the power supply device, the charging current of the charger 20 connected to the charging terminal 6 of the specific battery pack 10A passes through the switching element 4 of the battery pack 10A connected to the charger 20 and is connected in parallel. All the battery blocks 2 are charged by being supplied to the battery block 2 of another battery pack 10 </ b> B via the discharge terminal 5. Further, the power supply device outputs a charge stop signal when any one of the detection circuits 3 detects a charge stop state of the battery cell 1, and the output charge stop signal is transmitted via the communication circuit 7. Is transmitted to the detection circuit 3 of the battery pack 10A to which the charger 20 is connected, and the detection circuit 3 controls the switching element 4 to be OFF to stop charging.

  The power supply apparatus described above does not require the use of a large current diode having a large current capacity or a heat radiator having a large heat radiation area for cooling the diode, thereby reducing the component cost. In addition, a charger is connected to the charging terminal of one battery pack, and while charging the battery blocks of all the battery packs, while preventing overcharging of the battery cells constituting each battery block, You can charge the battery pack. It is a switching element of the battery pack connected to the charger, controls the charging of all the battery blocks, detects the charging stop state of the battery cells constituting the battery block of each battery pack, and Is transmitted to the detection circuit of the connected battery pack, and when the battery cell of any battery block is in a charge stop state with this detection circuit, the switching element is switched OFF, and the battery blocks of all battery packs This is because charging is stopped.

  Furthermore, the above power supply device uses a switching element built in the battery pack connected to the charger to charge all battery blocks without overcharging normally. Even if an element breaks down, all battery blocks can be charged normally. This is because all the battery packs can be charged by connecting the charger to the battery pack of the switching element that operates normally without connecting the charger to the battery pack in which the switching element has failed.

In the power supply device of the present invention, the battery constituting the battery cell 1 is a lithium ion battery, and the detection circuit 3 can detect the voltage of the battery cell 1 to detect the charge stop state.
Since the above power supply device uses a lithium ion battery as the battery constituting the battery cell, it can detect the voltage of the battery cell and accurately detect the charge stop state. Therefore, each battery pack can be charged while preventing overcharging of all battery cells.

In the power supply device of the present invention, the battery cell 1 can connect a plurality of unit cells in parallel.
In the above power supply device, a plurality of unit cells are connected in parallel to form a battery cell, and further, this battery cell is connected in series to form a battery block, so that the maximum current that can be discharged by the battery block is large and the battery block Can increase the output of the battery pack.

In the power supply device of the present invention, the total capacity of the battery packs 10 connected in parallel with each other can be set to 1 KVA to 100 KVA.
Since the total capacity of the power supply device described above is as extremely large as 1 KVA to 100 KVA, it can be optimally used for applications requiring high output such as electric motorcycles and electric vehicles.

In the power supply device of the present invention, the switching element 4 can be an FET.
In the above power supply device, since the switching element is an FET, the electric resistance in the ON state can be reduced and the battery block can be charged efficiently.

It is a block diagram of the conventional power supply device. It is a block diagram of the other conventional power supply device. It is a block diagram of the other conventional power supply device. It is a block diagram of the power supply device concerning one Example of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the embodiment described below exemplifies a power supply device for embodying the technical idea of the present invention, and the present invention does not specify the power supply device as follows. In addition, the member shown by the claim is not what specifies the member of embodiment. In particular, the dimensions, materials, shapes, relative arrangements, and the like of the constituent members described in the embodiments are not intended to limit the scope of the present invention only to the description unless otherwise specified. It's just an example. In addition, the size, positional relationship, and the like of members illustrated in each drawing may be exaggerated for clarity of explanation. Furthermore, in the following description, the same name and symbol indicate the same or the same members, and detailed description thereof will be omitted as appropriate. Furthermore, each element constituting the present invention may be configured such that a plurality of elements are constituted by the same member and the plurality of elements are shared by one member, and conversely, the function of one member is constituted by a plurality of members. It can also be realized by sharing. In addition, the contents described in some examples and embodiments may be used in other examples and embodiments.

  FIG. 4 shows a power supply device according to an embodiment of the present invention. The power supply device shown in this figure includes a plurality of battery packs 10 connected in parallel to each other and supplying power to a load. The power supply device of FIG. 4 has three sets of battery packs 10 connected in parallel. The power supply device can increase the maximum current that can be output and increase the current capacity by increasing the number of battery packs 10 to be connected. The power supply device of the present invention is most suitable for a high power source such as an electric motorcycle, a hybrid car, a plug-in hybrid car, an electric vehicle, an uninterruptible power supply, and the like. The power supply device used as such a power supply adjusts the number of battery packs to be connected so that the total capacity is 1 KVA to 100 KVA. However, the power supply device of the present invention does not specify the total capacity, but adjusts the capacity of the battery pack itself or the number of battery packs connected in parallel to make it smaller or larger than the above total capacity. You can also.

  Each battery pack 10 includes a battery block 2 in which a plurality of battery cells 1 are connected in series, a detection circuit 3 that detects a charge stop state of each battery cell 1 and outputs a charge stop signal, and this detection Switching element 4 controlled to be turned on and off by circuit 3, discharge terminal 5 connected to each battery block 2 without a diode, and charging terminal 6 connected to battery block 2 via switching element 4 And a communication circuit 7 for transmitting a charge stop signal detected by the detection circuit 3 to the detection circuit 3 of another battery pack 10.

  The battery block 2 connects battery cells 1 made of lithium ion batteries in series. However, any battery that can be charged, such as a nickel metal hydride battery or a nickel cadmium battery, can be used for the battery block in place of the lithium ion battery. In the battery block 2 for increasing the output current, a plurality of unit cells are connected in parallel to form a battery cell 1, and the battery cells 1 are connected in series. Since the output current of the battery block 2 is specified by the current capacity of the battery cell 1, the output current can be increased by connecting a large number of unit cells in parallel. Moreover, the battery block 2 can adjust an output voltage with the number of battery cells 1 connected in series, and can increase the output voltage by increasing the number of battery cells 1.

  The detection circuit 3 detects overcharge of the battery cells 1 constituting the battery block 2 and outputs a charge stop signal, and controls the switching element 4 with the charge stop signal. The detection circuit 3 detects the overcharge by detecting the voltage of each battery cell 1. This is because when the battery cell 1 is overcharged, the voltage becomes higher than the maximum voltage. The detection circuit 3 stores a maximum voltage for determining whether the battery cell 1 is overcharged. The detected voltage of the battery cell 1 is compared with the maximum voltage, and when the voltage of the battery cell 1 exceeds the maximum voltage, it is determined that the charging is stopped, and a charging stop signal is output. The detection circuit 3 can also detect the temperature of each battery cell 1 and output a charge stop signal. The detection circuit 3 switches the switching element 4 to OFF with a charge stop signal for charging. The battery pack 10 using the switching element 4 as an FET inputs a charge stop signal output from the detection circuit 3 to the gate of the FET, and switches the switching element 4 from ON to OFF to stop charging the battery block 2. Furthermore, the detection circuit 3 transmits a charge stop signal to be detected to the detection circuits 3 of the other battery packs 10 via the communication circuit 7. The battery pack 10 shown in the figure includes a communication terminal 8 connected to the communication circuit 7, and the detection circuit 3 of each battery pack 10 is connected via the communication terminal 8.

  Furthermore, the detection circuit 3 also switches the switching element 4 from ON to OFF in response to a charge stop signal input from the communication circuit 7 of another battery pack 10. When a plurality of battery packs 10 are connected in parallel and the battery blocks 2 are charged together, the detection circuit 3 of the battery pack 10B to which the charger is not connected may output a charge stop signal. . This charge stop signal is input to the detection circuit 3 of the battery pack 10 </ b> A connected to the charger 20 via the communication circuit 7. The detection circuit 3 that detects a charge stop signal input from another battery pack 10B switches the switching element 4 from ON to OFF also by this signal, and stops the charging of all the battery blocks 2. Therefore, the battery pack 10 turns the switching element 4 from ON to OFF not only by its own charge stop signal detected by the detection circuit 3 but also by a charge stop signal input from another battery pack 10 connected in parallel. Switch.

  The switching element 4 is an FET that cuts off the charging current. The switching element 4 of the FET is controlled to be turned on / off by a signal input from the detection circuit 3 to the gate. As the switching element 4, a switching element such as a transistor or a relay can be used instead of the FET. The switching element of the transistor is controlled to be turned on / off by a base input signal, and the switching element of the relay is turned on / off by controlling energization of the exciting coil. Therefore, the transistor switching element inputs the charge stop signal to the base and switches the transistor from ON to OFF, and the relay switching element stops the energization of the exciting coil by the charge stop signal and switches from ON to OFF. It is done. The switching element 4 is held in the ON state when the battery block 2 is charged. The FET switching element 4 is controlled to be in the ON state by controlling the gate voltage, the transistor switching element is controlled to be in the ON state by controlling the base current, and the relay is energized in the exciting coil and is maintained in the ON state.

  The discharge terminal 5 is directly connected to the battery block 2 without passing through the diode or the switching element 4. However, in order to prevent overcurrent of the battery block, an overcurrent of the battery block 2 can be prevented by connecting an element that cuts off the current due to overcurrent, such as a fuse or a breaker, in series with the battery block. .

  The charging terminal 6 is connected to the battery block 2 via the switching element 4. In the illustrated battery pack 10, the positive charging terminal 6 is connected to the positive side of the battery block 2 via the switching element 4. The switching element can also be connected to the charging terminal and the negative side of the battery block.

  The communication circuit 7 transmits the charge stop signal output from the detection circuit 3 to the detection circuit 3 of another battery pack 10 connected in parallel to each other, and outputs from the detection circuit 3 of another battery pack 10. The bidirectional communication circuit 7 inputs a charge stop signal to the detection circuit 3.

  The power supply device of FIG. 4 allows the charging current of the charger 20 connected to the charging terminal 6 of the specific battery pack 10A to pass through the switching element 4 of the battery pack 10A connected to the charger 20 in parallel. The battery block 2 of another battery pack 10B is supplied through the connected discharge terminal 5 to charge all the battery blocks 2. Therefore, this power supply device connects the charger 20 to the charging terminal 6 of one battery pack 10 to charge the battery blocks 2 of all the battery packs 10.

  When any one of the detection circuits 3 detects the charge stop state of the battery cell 1 with all the battery packs 10 charged, the switching element 4 is switched from ON to OFF by the charge stop signal, and all the batteries are Charging of block 2 is stopped. When the detection circuit 3 of the battery pack 10A connected to the charger 20 outputs a charge stop signal, the switching element 4 of the battery pack 10A is switched to OFF by this signal. When the detection circuit 3 of the battery pack 10B not connected to the charger 20 detects the charge stop signal, the charge stop signal is detected via the communication circuit 7 in the detection circuit 3 of the battery pack 10A connected to the charger 20. Is transmitted. The detection circuit 3 to which the charge stop signal is transmitted controls the switching element 4 to be OFF, and stops the charging of all the battery blocks 2.

DESCRIPTION OF SYMBOLS 1 ... Battery cell 2 ... Battery block 3 ... Detection circuit 4 ... Switching element 5 ... Discharge terminal 6 ... Charge terminal 7 ... Communication circuit 8 ... Communication terminal 10 ... Battery pack 10A ... Battery pack
10B ... Battery pack 20 ... Charger 70 ... Battery pack 70A ... Master battery pack
70B ... Slave battery pack 71 ... Battery cell 72 ... Battery block 73 ... Detection circuit 74 ... Switching element 75 ... Discharge terminal 76 ... Charge terminal 80 ... Battery pack 80A ... Master battery pack
80B ... Slave battery pack 87 ... Diode 90 ... Battery pack 91 ... Battery cell 92 ... Battery block 93 ... Detection circuit 94 ... FET for charge / discharge
95: Output terminal

Claims (5)

A power supply device comprising a plurality of battery packs (10) connected in parallel to each other and supplying power to a load,
Each battery pack (10)
A battery block (2) formed by connecting a plurality of battery cells (1) in series;
A detection circuit (3) for detecting a charge stop state of each battery cell (1) and outputting a charge stop signal;
A switching element (4) controlled on and off by the detection circuit (3);
A discharge terminal (5) connected to the battery block (2) without a diode;
A charging terminal (6) connected to the battery block (2) via the switching element (4);
A communication circuit (7) for transmitting a charge stop signal detected by the detection circuit (3) to the detection circuit (3) of another battery pack (10);
Each battery pack (10) connects the communication circuit (7) to each other, and without connecting the charging terminal (6) to each other, the discharge terminal (5) is connected in parallel,
The charging current of the charger (20) connected to the charging terminal (6) of a specific battery pack (10A) passes through the switching element (4) of the battery pack (10A) connected to the charger (20). Then, it is supplied to the battery block (2) of another battery pack (10B) through the discharge terminal (5) connected in parallel, and all the battery blocks (2) are charged,
In the state where any detection circuit (3) detects the charge stop state of the battery cell (1), this detection circuit (3) outputs a charge stop signal, and the output charge stop signal is a communication circuit (7). Is transmitted to the detection circuit (3) of the battery pack (10A) formed by connecting the charger (20) via this, and the detection circuit (3) controls the switching element (4) to be turned off to stop charging. A power supply unit configured to do so.   The power supply apparatus according to claim 1, wherein the battery constituting the battery cell (1) is a lithium ion battery, and the detection circuit (3) detects the voltage of the battery cell (1) to detect a charge stop state.   The power supply device according to claim 1 or 2, wherein the battery cell (1) is formed by connecting a plurality of unit cells in parallel.   The power supply device according to any one of claims 1 to 3, wherein a total capacity of the battery packs (10) connected in parallel with each other is 1 KVA to 100 KVA.   The power supply device according to any one of claims 1 to 4, wherein the switching element (4) is an FET.

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