JP2019075933A - Battery unit and control method of battery unit - Google Patents

Abstract

To reduce a cost required for a setup work of a battery unit.SOLUTION: A battery unit according to an embodiment has a precharge control portion 4 capable of switching resistance of a path through which discharge current from a battery pack BT and charge current to the battery pack BT flow and an electrical connection state, a charge/discharge control portion 5 capable of switching the electrical connection state of the path, capable of switching the electrical connection state of the path, and a control portion CTR obtaining current detected by a current sensor CSS, voltage of a plurality of battery cells detected by a detection circuit, and external voltage, and controlling an operation of the precharge control portion 4 and the charge/discharge control portion 5. The control portion CTR, at the time of activation, enables charge and discharge of the battery pack BT by increasing the resistance of the path, when the voltage of a plurality of battery cells is smaller than the external voltage, intercepts the charge current to the battery pack BT, and when the resistance of the path is decreased by the precharge control portion 4 and the reduction of the external voltage is determined, enables the charge of the battery pack BT.SELECTED DRAWING: Figure 3

Description

  Embodiments of the present invention relate to a battery unit and a control method of the battery unit.

  Power supply devices that convert alternating current power supplied from a commercial power source or the like into predetermined direct current power and supply it to a load are widely used. For example, in order to prevent the power supply to the load from being suddenly stopped when the power supply from the commercial power source or the like is stopped, the battery unit for backup is used to supply the power to the load. ing.

  When the battery unit is connected to the main circuit in a state where the load is connected to the power supply device and power is supplied from the power supply device to the load, the battery unit is connected according to the difference between the output voltage of the power supply device and the voltage of the battery unit Excessive current may flow into the For example, when the resistance of the battery cell mounted in the battery unit is small, after the voltage of the battery assembly of the battery unit is detected on the power supply side, the voltage of the main circuit is reduced to avoid excessive charging current. Even then, there is a possibility that the battery unit may break down because the control on the power supply side is not in time.

JP, 2013-102595, A

  Conventionally, in order to prevent excessive current from flowing into the battery unit, for example, a method of supplying charging current to the assembled battery via a precharge resistor is used. However, when the difference between the output voltage of the power supply device and the voltage of the battery unit is large, the time until releasing the precharge is long, making it difficult to shorten the time required for setting the power supply device. .

  The embodiment of the present invention has been made in view of the above circumstances, and aims to shorten the setting time when attaching the battery unit to the power supply device and to reduce the cost required for setting the battery unit. .

  A battery unit according to an embodiment includes a battery assembly including a plurality of battery cells and a detection circuit that detects a voltage of the plurality of battery cells, a current sensor that detects a current flowing through the plurality of battery cells, A precharge control unit configured to be capable of switching between resistance and electrical connection of a path through which a discharge current from the assembled battery and a charging current to the assembled battery flow, and an electrical connection of the path being switchable; A charge / discharge control unit configured to be able to switch an electrical connection state of the path, a current detected by the current sensor, voltages of the plurality of battery cells detected by the detection circuit, and an external voltage , And the control unit capable of controlling the operation of the pre-charge control unit and the charge / discharge control unit, the control unit increasing the resistance of the path at the time of start-up to increase the resistance of the path. of The charge / discharge control unit compares the voltage of the plurality of battery cells with the external voltage, and when the voltages of the plurality of battery cells are smaller than the external voltage, the charge / discharge control unit The charge current to the battery is cut off, the resistance of the path is reduced by the precharge control unit, and the external voltage is requested to be reduced externally, and it is determined that the external voltage is reduced, the charge / discharge The control unit enables charging of the battery pack.

FIG. 1 is a diagram for describing one configuration example of a power supply system including the battery unit of the embodiment. FIG. 2: is a figure which shows roughly one structural example of the battery apparatus which mounts the battery unit of embodiment. FIG. 3: is a figure which shows roughly one structural example of the battery unit of embodiment. FIG. 4 is a flowchart for explaining an example of the operation of the battery unit of the embodiment. FIG. 5 is a view schematically showing another configuration example of the battery unit of the embodiment.

Hereinafter, a battery unit and a control method of the battery unit of the embodiment will be described with reference to the drawings.
FIG. 1 is a diagram for describing one configuration example of a power supply system including the battery unit of the embodiment.

  In this example, the power supply system is described as an example that supplies power to facilities operating 24 hours a day, such as a base station of a communication device. The power supply system of the present embodiment includes a power supply device (SMPS: Switch Mode Power Supply) 20 and a battery device BS.

  AC power is supplied to the power supply device 20 from the power interface 10. The power interface 10 is electrically connected to a commercial power supply (Grid) and a diesel generator (DG). AC power supplied from a commercial power source or a diesel generator is converted into AC power that can be input to the power supply device 20 by the power interface 10, and is supplied to the power supply device 20. The power supply device 20 converts AC power supplied from the power interface 10 into DC power and supplies the DC power to the load 30. In the present embodiment, the power supply device 20 outputs, for example, a DC voltage of about 48 [V].

The power supply device 20 includes a plurality of rectifiers 22 and a controller 24.
Each of the plurality of rectifiers 22 is connected between the high potential side main circuit wiring MCP and the low potential side main circuit wiring MCN. Each of the plurality of rectifiers 22 includes, for example, a switching element such as a MOSFET or an IGBT. The plurality of rectifiers 22 are capable of converting AC power into DC power by switching the switching elements at high speed, and supplying DC power to the load 30 via the main circuit wirings MCP and MCN.

The controller 24 controls the operation of the plurality of rectifiers 22 to control the voltage and current of DC power supplied to the load 30 and the battery device BS.
The controller 24 and the battery device BS may be configured to be able to perform serial communication based on a CAN (control area network) protocol, RS485 standard, or the like. The controller 24 may control the current supplied to the load 30 and the battery device BS based on the information obtained from the battery device BS. In addition, the controller 24 may be configured to be able to notify the outside (NOC: network operations center) of data and an alarm acquired from the battery device BS.

  The controller 24 is an arithmetic circuit including, for example, at least one processor such as a central processing unit (CPU) or a micro processing unit (MPU), and a memory in which a program executed by the processor is stored.

  The battery device BS is connected in parallel to the load 30 to the main circuit wirings MCP and MCN. The battery device BS can supply a discharge current to the load 30 via the main circuit interconnections MCP and MCN. In addition, the battery device BS can charge the built-in assembled battery (shown in FIG. 3) by the charging current supplied via the main circuit wirings MCP and MCN.

FIG. 2: is a figure which shows roughly one structural example of the battery apparatus which mounts the battery unit of embodiment.
Battery device BS includes a terminal P electrically connected to main circuit wiring MCP on the high potential side of power supply device 20, a terminal N electrically connected to main circuit wiring MCN on the low potential side, and at least one battery unit With UNT. The battery device BS of the present embodiment includes a plurality of battery units UNT.

The plurality of battery units UNT are connected between the high potential side charge / discharge circuit electrically connected to the terminal P and the low potential side charge / discharge circuit electrically connected to the terminal N.
In addition, since several battery unit UNT is the same structure, below, the example of a structure of one battery unit UNT is demonstrated, and the description about the structure of the other battery unit UNT is abbreviate | omitted.

FIG. 3: is a figure which shows roughly one structural example of the battery unit of embodiment.
The battery unit UNT of the present embodiment includes a plurality of battery cells of the battery pack BT, a battery management circuit BMU, a positive electrode terminal TP, and a negative electrode terminal TN. The battery management circuit BMU includes an address switch 1, a power switch 2, a display unit 3, a detection circuit for a battery pack BT, a precharge control unit 4, a charge / discharge control unit 5, a fuse F, and a current sensor CSS. And a control unit CTR.

The positive electrode terminal TP is electrically connected to the terminal P of the battery device BS through the charge / discharge circuit on the high potential side.
The negative electrode terminal TN is electrically connected to the terminal N of the ionizer BS via the charge / discharge circuit on the low potential side.

  The address switch 1 is, for example, a dip switch exposed to the outside from the casing of the battery unit UNT and operable by the user, for example, a switch for setting an identifier such as an address used when the control unit CTR communicates. is there.

  The power switch 2 is, for example, a switch which is exposed to the outside from the housing of the battery unit UNT and can be operated by the user. When the user operates the power switch 2 to activate the battery unit UNT, for example, power is supplied from the charge / discharge circuit PC, NC to the control circuit CTR.

  The display unit 3 is, for example, exposed from the casing of the battery unit UNT to the outside to notify the user of the state of the battery unit UNT, and its operation is controlled by the control unit CTR. In the present embodiment, the display unit 3 includes, for example, one or more LEDs (light emitting diodes), and the control unit CTR controls the display unit 3 to light according to the charge state and discharge state of the battery pack BT, a failure, etc. Can inform the status of the battery unit UNT.

The battery assembly BT includes a plurality of battery cells (not shown) and a detection circuit (not shown) for detecting the voltage of the battery cells and the temperature of the battery assembly BT.
The detection circuit of the battery pack BT is configured to be communicable with the control unit CTR, and periodically outputs values corresponding to the detected voltage and temperature to the control unit CTR.

  Each of the plurality of battery cells is, for example, a lithium ion battery. In the present embodiment, the assembled battery BT includes, for example, 42 battery cells in which 21 battery cells connected in parallel are connected in series.

  The positive electrode terminal of the assembled battery BT can be electrically connected to the positive electrode terminal P via the charge / discharge control unit 5 (the discharge control switch DS and the charge control switch CS). The negative terminal of the battery pack BT can be electrically connected to the negative terminal N via the precharge control unit 4 (main switch MS or precharge switch PS) and the fuse F.

  The current sensor CSS detects the output current of the battery pack BT. A value corresponding to the current detected by the current sensor CSS is supplied to the control unit CTR.

  The precharge control unit 4 is provided in the charge / discharge circuit PC on the high potential side or the charge / discharge circuit NC on the low potential side, and the resistance and electricity of the path through which the discharge current from the assembled battery BT and the charge current to the assembled battery BT flow Target connection state can be switched. The precharge control unit 4 includes a main switch MS, a precharge switch PS, and a resistor R.

  The main switch MS is, for example, a field effect transistor (FET). Main switch MS is provided in charge / discharge circuit PC on the high potential side or charge / discharge circuit NC on the low potential side, and electrically connected to a path through which the discharge current from assembled battery BT and the charge current to assembled battery BT flow Switch. In the example shown in FIG. 3, the main switch MS is provided on a wire connecting the negative terminal of the battery pack BT to the negative terminal N of the battery unit UNT, and the negative terminal of the battery pack BT and the negative terminal N of the battery unit UNT. Switch the electrical connection state with The operation of the main switching device MS is controlled by the control unit CTR.

  The precharge switch PS is, for example, a field effect transistor, and is connected in series to the resistor R. The precharge switch PS and the resistor R are connected in parallel with the main switch MS. The operation of the precharge switching device PS is controlled by the control unit CTR.

  The charge / discharge control unit 5 includes a discharge control switch DS, a charge control switch CS, and backflow prevention elements D1 and D2. The charge / discharge control unit 5 is provided in the charge / discharge circuit PC on the high potential side or the charge / discharge circuit NC on the low potential side, and can switch the electrical connection state of the path through which the charging current to the assembled battery BT flows. The electrical connection state of the path through which the discharge current from the battery pack BT flows is switchable.

  The charge control switch CS is, for example, a field effect transistor. The charge control switch CS is provided in the charge / discharge circuit PC on the high potential side or the charge / discharge circuit NC on the low potential side, and is configured to be able to switch the electrical connection state of the path through which the charging current to the assembled battery BT flows. ing. In the example shown in FIG. 3, the charge control switch CS is provided in the charge / discharge circuit PC that connects the positive electrode terminal of the battery pack BT and the positive electrode terminal TP of the battery unit UNT. In the charge control switch CS, a backflow prevention element D2 is connected in parallel, with the direction in which the discharge current from the assembled battery BT flows is the forward direction. The backflow prevention element D2 is a diode. The operation of the charge control switch CS is controlled by the control unit CTR.

  The discharge control switch DS is, for example, a field effect transistor. The discharge control switch DS is provided in the charge / discharge circuit PC on the high potential side or the charge / discharge circuit NC on the low potential side, and is configured to be able to switch the electrical connection state of the path through which the discharge current from the assembled battery BT flows. ing. In the example shown in FIG. 3, the discharge control switch DS is disposed in series with the charge control switch CS in the charge / discharge circuit PC connecting the positive terminal of the battery pack BT and the positive terminal TP of the battery unit UNT. It is done. In the discharge control switch DS, a backflow prevention element D1 is connected in parallel, with the direction in which the charging current to the assembled battery BT flows is the forward direction. The backflow prevention element D1 is a diode. The operation of the discharge control switch DS is controlled by the control unit CTR.

  The control unit CTR is configured to be able to communicate with the detection circuit of the battery pack BT and the controller 24. The control unit CTR is a main switch MS, a precharge switch PS, a discharge control switch DS, based on information obtained from the detection circuit of the battery pack BT, the current sensor CSS, and the charge / discharge circuits PC, NC. Also, the operation of the charge control switch CS can be controlled.

  The control unit CTR is an arithmetic circuit including, for example, at least one processor such as a CPU or an MPU and a memory in which a program executed by the processor is stored.

Below, an example of operation of the above-mentioned battery unit UNT is explained.
The power supply system including the battery unit UNT of the present embodiment, for example, converts the power supplied from the commercial power supply into predetermined DC power and supplies the power to the load 30 during normal operation. At this time, the negative terminal of the battery pack BT is electrically connected to the main circuit MCN of the power supply device 20 through the main switch MS, and the positive terminal of the battery pack BT is the switch DS for discharge control and the switch for charge control It is in a state of being electrically connected to the main circuit MCP via the CS.

  For example, when the power input from the commercial power supply to the power supply device 20 is stopped due to a power failure of the commercial power supply or the like, the voltages of the main circuits MCP and MCN decrease and power is supplied from the battery device BS to the load 30.

  Thereafter, when the commercial power supply recovers from the power failure, the power supply device 20 converts AC power supplied from the commercial power supply into DC power to supply power to the load 30, and charges the battery pack BT of the battery device BS.

  For example, when the battery device BS is connected to the main circuits MCP and MCN in a state where power is supplied from the power supply device 20 to which the battery device BS is not connected to the load 30, the voltage of the assembled battery BT of the battery unit UNT is When the voltage is lower than the voltage between the main circuits MCP and MCN, an excessive current may flow into the assembled battery BT.

  Further, the assembled battery BT of the battery unit UNT may not be fully charged at the time of shipping, but may be in a state of charge of, for example, about 50%. At this time, for example, when replacing one of the plurality of battery units of the battery device BS with a new battery unit UNT, the voltage of the assembled battery BT of the newly attached battery unit UNT is greater than the voltage between the main circuits MCP and MCN. Also, there is a possibility that an excessive current may flow into the battery pack BT.

  On the other hand, the battery unit UNT of this embodiment can avoid excessive current flow into the battery assembly BT by operating as follows.

FIG. 4 is a flowchart for explaining an example of the operation of the battery unit of the embodiment.
When the battery unit UNT is activated, the control unit CTR closes the precharge switch PS, the discharge control switch DS, and the charge control switch CS, and opens the main switch MS. The battery pack BT is brought into a precharged state (step S1). In the precharged state, the negative electrode terminal of the assembled battery BT is electrically connected to the negative electrode terminal TN through the resistor R, and it is possible to prevent an excessive current from flowing in the assembled battery BT.

  Subsequently, the control unit CTR compares the voltage of the battery pack BT (the voltage of the plurality of battery cells) with the external voltage (step S2). In the present embodiment, the external voltage is, for example, between the charge / discharge circuit PC (or terminal P, positive terminal TP) on the high potential side and the charge / discharge circuit NC (or terminal N, negative terminal TN) on the low potential side. It is a voltage. The external voltage may be a value calculated using the value of the current detected by the current sensor CSS, the value of the voltage of the assembled battery BT, the resistance value of the resistor R, or the like.

  The control unit CTR compares the voltage of the assembled battery BT with the external voltage, and charges the assembled battery BT when the voltage of the assembled battery BT is larger than the external voltage or when the difference between them is smaller than a predetermined threshold. Then, the pre-charge state is released in a state in which discharge is possible, and the battery unit UNT is in a state in which normal operation is possible (step S3). That is, the control unit CTR closes the charge control switch CS, closes the discharge control switch DS, and closes the main switch MS. At this time, the control unit CTR may open the precharge switching unit PS or may close it.

  The control unit CTR compares the voltage of the assembled battery BT with the external voltage, and the voltage of the assembled battery BT is smaller than the external voltage, and the difference between the voltage of the assembled battery BT and the external voltage is equal to or greater than a predetermined threshold. At a certain time, the precharge state is released in a state where only discharge of the battery pack BT is possible (step S4). That is, the control unit CTR sets the charge control switch CS in an open state, sets the discharge control switch DS in a closed state, sets the main switch MS in a closed state, and opens the precharge switch PS. I assume. In this state, the negative terminal of the battery pack BT is electrically connected to the negative terminal TN through the main switch MS, and the positive terminal of the battery pack BT is the positive terminal through the backflow prevention element D2 and the discharge control switch DS. In order to electrically connect with the terminal TP, the charging current to the assembled battery BT is interrupted.

  In a state in which only the discharge of the battery pack BT is enabled, for example, the operation of the power supply device 20 is stopped (or the power supply from a commercial power supply etc. is stopped) and external request is made to lower the external voltage (step S5).

  For example, when the power supply device 20 stops its operation, the external voltage of the battery unit UNT decreases, and the battery assembly BT is automatically discharged. At this time, the control unit CTR may control the display unit 3 to display a request to restart after the operation of the power supply device 20 is stopped. In addition, when the power supply device 20 and the control unit CTR are configured to be communicable, a signal may be transmitted to the power supply device 20 to temporarily stop the operation.

  The control unit CTR can determine, for example, whether or not the external voltage is reduced, based on the value of the current detected by the current sensor CSS. Further, the control unit CTR can determine, for example, whether or not the external voltage has dropped by monitoring the voltage of the assembled battery BT and the external voltage. When the control unit CTR detects that the external voltage has dropped and discharge of the battery pack BT has been started (step S6), the charge control switch CS is closed, and the battery pack BT can be charged. (Step S7).

  At this stage, the control unit CTR may display a request for restarting the power supply device 20 by means of the display unit 3. Further, when the power supply device 20 and the control unit CTR are configured to be able to communicate, the control unit CTR may notify the power supply device 20 of a signal requesting a restart.

  In addition, the control unit CTR may control the display unit 3 to display that the assembled battery BT is in a state in which normal operation is possible. Further, when the power supply device 20 and the control unit CTR are configured to be communicable, the control unit CTR sends a signal to the power supply device 20 to notify that the assembled battery BT is ready for normal operation. It may be sent.

  In this state, when the power supply device 20 is restarted (or the supply of power from the commercial power supply to the power supply device 20 is resumed), the power supply device 20 converts AC power supplied from the commercial power supply into DC power. The DC power is supplied to the load 30 and the battery device BS via the circuits MCP and MCN.

  The assembled battery BT of the battery unit UNT is charged by the DC power supplied from the power supply device BS, and the charging is completed in a state where the voltage of the assembled battery BT and the external voltage are balanced.

  As described above, according to the battery unit UNT of the present embodiment, it is possible to limit an excessive charging current when connecting the power supply device 20 and the battery unit UNT, and to avoid equipment failure due to this.

  In addition, the battery unit UNT can be connected to the power supply device 20 to be in a normal operation possible state by stopping the power supply device 20 in a state where only the battery unit UNT can be discharged and then restarting it.

  As described above, the setting time when the battery unit UNT is attached is almost the time required for stopping and restarting the power supply device 20, and the time required for setting can be shortened. As a result, it is possible to shorten the time until the battery unit UNT becomes capable of normal operation, and it is possible to shorten the working time (that is, work cost reduction).

Next, another configuration example of the battery unit UNT will be described with reference to the drawings.
FIG. 5 is a view schematically showing another configuration example of the battery unit of the embodiment.
In this example, the battery unit UNT includes a charge / discharge precharge control unit 6 instead of the precharge control unit 4 and the charge / discharge control unit 5. The charge / discharge precharge control unit 6 is configured to have the functions of the precharge control unit 4 and the charge / discharge control unit 5 of the battery unit UNT shown in FIG.

  The charge / discharge precharge control unit 6 is provided in the high potential side charge / discharge circuit PC or the low potential side charge / discharge circuit NC. Charge / discharge precharge control portion 6 is capable of switching the resistance and the electrical connection state of the path through which the discharge current from assembled battery BT and the charge current to assembled battery BT flow, and the charge current to assembled battery BT And the electrical connection state of the path through which the discharge current from the battery pack BT flows can be switched.

  The charge / discharge precharge control unit 6 includes a precharge switch PS, a resistor R, a discharge control switch DS, and a charge control switch CS.

  The charge control switch CS is, for example, a field effect transistor. The charge control switch CS is provided in the charge / discharge circuit PC that connects the positive electrode terminal of the battery pack BT and the positive electrode terminal TP of the battery unit UNT. In the charge control switch CS, a backflow prevention element D2 is connected in parallel, with the direction in which the discharge current from the assembled battery BT flows is the forward direction. The backflow prevention element D2 is a diode. The operation of the charge control switch CS is controlled by the control unit CTR.

  The discharge control switch DS is, for example, a field effect transistor. The discharge control switch DS is disposed in series with the charge control switch CS in the charge / discharge circuit PC connecting the positive electrode terminal of the battery pack BT and the positive electrode terminal TP of the battery unit UNT. In the discharge control switch DS, a backflow prevention element D1 is connected in parallel, with the direction in which the charging current to the assembled battery BT flows is the forward direction. The backflow prevention element D1 is a diode. The operation of the discharge control switch DS is controlled by the control unit CTR.

  The precharge switch PS is, for example, a field effect transistor, and is connected in series to the resistor R. The precharge switch PS and the resistor R are connected in parallel with the charge control switch CS and the discharge control switch DS. The operation of the precharge switching device PS is controlled by the control unit CTR.

  In this example, by opening or closing both of the discharge control switch DS and the charge control switch CS, the main switch MS of the battery unit UNT shown in FIG. 3 is used as the same function as opening or closing. There is. That is, the charge / discharge precharge control unit 6 includes the precharge control unit 4 including the charge / discharge control unit 5 instead of the main switch MS.

  For example, in this example, in step S1 shown in FIG. 4, the control unit CTR changes the main switch MS into the open state, and switches both the discharge control switch DS and the charge control switch CS. In the open state.

  Further, for example, in step S3 shown in FIG. 4, the control unit CTR closes both the discharge control switch DS and the charge control switch CS instead of setting the main switch MS to the closed state. Be in the

By controlling the operation of the discharge control switch DS and the charge control switch CS as described above, the same effect as the battery unit UNT shown in FIG. 3 can be obtained.
That is, the time until the normal operation of the battery unit UNT can be shortened, and the working time can be shortened (that is, the working cost can be reduced).

  While certain embodiments of the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, substitutions, and modifications can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

  In the above embodiment, each of the plurality of battery units UNT may be provided with a communication terminal (not shown). The battery unit UNT may be configured to be able to communicate with the controller 24 via a communication bus wire (for example, CAN bus wire) electrically connected to the communication terminal.

  BS: battery device, BT: assembled battery, MS: main switch, PS: precharge switch, CS: charge control switch, DS: discharge control switch, D1: backflow prevention element, D2: backflow prevention element , CTR ... control unit, CSS ... current sensor.

Claims (7)

An assembled battery comprising: a plurality of battery cells; and a detection circuit that detects voltages of the plurality of battery cells.
A current sensor detecting a current flowing through the plurality of battery cells;
A precharge control unit configured to be capable of switching the resistance and the electrical connection state of a path through which the discharge current from the assembled battery and the charging current to the assembled battery flow;
A charge / discharge control unit capable of switching the electrical connection state of the path, and capable of switching the electrical connection state of the path;
The current detected by the current sensor, the voltages of the plurality of battery cells detected by the detection circuit, and the external voltage are acquired, and the operations of the precharge control unit and the charge / discharge control unit are performed. And a controllable control unit,
The control unit increases the resistance of the path at start-up to enable charging and discharging of the assembled battery, and compares the voltages of the plurality of battery cells with the external voltage, and the plurality of battery cells The charge / discharge control unit cuts off the charge current to the assembled battery, and the precharge control unit reduces the resistance of the path and lowers the external voltage when the voltage of the circuit is smaller than the external voltage. A battery unit capable of charging the assembled battery by the charge / discharge control unit when it is requested to the outside and it is determined that the external voltage is lowered. The precharge control unit is connected in parallel to the main switch for switching the electrical connection state of the path through which the discharge current from the assembled battery and the charging current to the assembled battery flow, and is connected in series with each other A resistor and a precharge switch connected to the
The charge / discharge control unit includes a charge control switch provided in the path, and a backflow prevention element connected in parallel to the charge control switch with a direction in which a discharge current from the assembled battery flows is a forward direction; The switch for discharge control provided in the said path | route, The backflow prevention element connected in parallel with the said switch for discharge control by making the direction into which the charging current to the said assembled battery flows is a forward direction is provided. Battery unit. The precharge control unit includes the charge / discharge control unit, and a resistor and a precharge switch connected in parallel to the charge / discharge control unit and connected in series with each other.
The charge / discharge control unit includes a charge control switch provided in the path, and a backflow prevention element connected in parallel to the charge control switch with a direction in which a discharge current from the assembled battery flows is a forward direction; A switch for discharge control provided in the path, a backflow prevention element connected in parallel with the switch for discharge control, with the direction in which the charging current to the assembled battery flows as a forward direction, the switch for charge control, The battery unit according to claim 1, further comprising: a resistor and a precharge switch connected in parallel to the discharge control switch and connected in series.   The control unit compares the voltage of the plurality of battery cells with the external voltage at the time of start-up, and when the voltages of the plurality of battery cells are larger than the external voltage, the charge / discharge control unit The battery unit according to any one of claims 1 to 3, wherein charge and discharge of the battery are enabled, and the resistance of the path is reduced by the precharge control unit. An assembled battery comprising: a plurality of battery cells; and a detection circuit that detects voltages of the plurality of battery cells.
A current sensor detecting a current flowing through the plurality of battery cells;
A precharge control unit configured to be capable of switching the resistance and the electrical connection state of a path through which the discharge current from the assembled battery and the charging current to the assembled battery flow;
A control method of a battery unit comprising: a charge / discharge control unit configured to be capable of switching an electrical connection state of the path and being capable of switching an electrical connection state of the path;
At start-up, the resistance of the path is increased by the precharge control unit, and the charge and discharge control unit is configured to be capable of charging and discharging the assembled battery,
Comparing voltages of the plurality of battery cells with an external voltage,
When the voltage of the plurality of battery cells is smaller than the external voltage, the charge / discharge control unit cuts off the charging current to the assembled battery, and the precharge control unit reduces the resistance of the path.
Request external to lower the external voltage,
The control method of the battery unit which enables charge of the said assembled battery by the said charging / discharging control part when it is judged that the said external voltage fell.   The control method of a battery unit according to claim 5, wherein it is determined whether the external voltage has decreased based on a detection value of a current sensor that detects a current flowing through the plurality of battery cells.   When the voltages of the plurality of battery cells are larger than the external voltage, the charge and discharge control unit enables charging and discharging of the assembled battery, and the precharge control unit reduces resistance of the path. Or the control method of the battery unit of Claim 6.