JP2017079565A - Power storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power storage device that can use safely a first battery that is weak in overcharge and overdischarge similarly to a second battery that is resistant to overcharge and overdischarge in a case where the first battery is used in a device that supports the second battery.SOLUTION: A power storage device 1 is configured to comprise: a switch 13 for connecting a battery 11 with a device 2 that is a charger or a load; and a battery control unit 12 that, when a voltage of the battery 11 becomes larger than a first overcharge threshold, turns off the switch 13 and changes an overcharge threshold from the first overcharge threshold to a second overcharge threshold higher than the first overcharge threshold, and when the voltage of the battery 11 becomes lower than a first overdischarge threshold, turns off the switch 13, and changes an overdischarge threshold from the first overdischarge threshold to a second overdischarge threshold lower than the first overdischarge threshold.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power storage device.

  There are various types of secondary batteries for driving motors included in vehicles such as hybrid cars, electric cars, and electric forklifts, such as lead-acid batteries and lithium ion batteries. In the following description, the secondary battery may be simply referred to as a battery.

  The characteristics of a battery vary depending on the type of battery. For example, lithium ion batteries are more susceptible to overcharge and overdischarge than lead acid batteries. For this reason, in a lithium ion battery, charge and discharge are strictly controlled compared with a lead acid battery.

  Patent Document 1 is known as a related technique.

JP 2011-93335 A

  When a first battery that is vulnerable to overcharge and overdischarge, such as a lithium ion battery, is used in a device that supports a second battery that is resistant to overcharge and overdischarge, such as a lead-acid battery, the first battery There is a risk of overdischarge.

  For example, since a lead storage battery is resistant to overcharge, a fully charged lead storage battery may be further recharged in an overcharged manner by a vehicle compatible with the lead storage battery. However, since lithium ion batteries are vulnerable to overcharge, if a fully charged lithium ion battery is further regeneratively charged by a vehicle that supports lead-acid batteries, the lithium ion battery may be overcharged.

  In addition, since lead storage batteries are resistant to overdischarge, a fully discharged lead storage battery may be further discharged by a vehicle compatible with lead storage batteries. However, since lithium ion batteries are vulnerable to overdischarge, if a fully discharged lithium ion battery is further discharged by a vehicle that supports lead-acid batteries, the lithium ion battery may not be recharged due to overdischarge.

  Therefore, in order to prevent overcharge and overdischarge, for example, the use of the first battery by the second battery compatible device is stopped before the first battery reaches overcharge and overdischarge. It is conceivable to constitute a power storage device including one battery.

  However, as a result of configuring the power storage device as described above, it is inconvenient for the user if the first battery cannot be used in a device compatible with the second battery with the same feeling as when the second battery is used. is there. For example, it is inconvenient for the user if the use of the lithium ion battery is stopped by the power storage device in a short time in order to prevent overcharging due to regeneration even though the lithium ion battery is fully charged. In addition, it is inconvenient for the user if the use of the fully discharged lithium ion battery is stopped by the power storage device in order to prevent overdischarge in order to move the vehicle close to the charger.

  An object according to one aspect of the present invention is to provide a first battery that is vulnerable to overcharge and overdischarge in the same manner as the second battery when used in a device compatible with the second battery that is resistant to overcharge and overdischarge. An object of the present invention is to provide a power storage device that can safely use a first battery.

A power storage device according to one embodiment of the present invention includes a switch and a battery control unit.
The switch connects or disconnects the battery to the charger or load device. The battery control unit turns off the switch when the voltage of the battery exceeds the first overcharge threshold, and overcharges from the first overcharge threshold to a second overcharge threshold that is higher than the first overcharge threshold. Change the threshold. Further, the battery control unit turns off the switch when the voltage of the battery falls below the first overdischarge threshold, and shifts from the first overdischarge threshold to a second overdischarge threshold lower than the first overdischarge threshold. Change the overdischarge threshold.

  According to the power storage device according to the embodiment, when the first battery that is vulnerable to overcharge and overdischarge is used in a device that supports the second battery that is resistant to overcharge and overdischarge, Similarly, the first battery can be used safely.

It is a figure which shows the structural example of the electrical storage apparatus according to embodiment. It is a figure explaining the structural example of the electrical storage apparatus side connector, conversion connector, and apparatus side connector according to embodiment. It is a figure explaining an example of the voltage control of the battery which the electrical storage apparatus according to embodiment performs.

Hereinafter, embodiments will be described in detail with reference to the drawings.
FIG. 1 is a diagram illustrating a configuration example of a power storage device according to the embodiment. In the example illustrated in FIG. 1, the power storage device 1 includes a battery 11, a battery control unit (ECU: Electronic Control Unit) 12, a switch 13, a voltage sensor 14 (141 to 14 N), a power storage device side connector 15, and a permission switch 16. Prepare.

  The battery 11 is a first battery. The first battery is a battery that is vulnerable to overcharge and overdischarge, and is, for example, a lithium ion battery. In the example shown in FIG. 1, the battery 11 is a battery block in which N (N is an integer of 2 or more) single cells 111 to 11N are connected in series, but the number and connection of the single cells constituting the battery 11 are the same. The relationship may be arbitrary.

  The battery control unit 12 is, for example, a processor such as a CPU (Central Processing Unit), an FPGA (Field Programmable Gate Array), or a PLD (Programmable Logic Device). Battery control unit 12 monitors the state of battery 11 and controls the overall operation of power storage device 1. The battery control unit 12 operates as described below, for example.

  Battery control unit 12 detects that power storage device 1 is connected to device 2. The device 2 is a load or a charger. The load is a vehicle that uses electricity as a power source, such as a hybrid car, an electric vehicle, and an electric forklift. The device 2 is a device corresponding to the second battery. The second battery is a battery that is resistant to overcharge and overdischarge, and is, for example, a lead storage battery.

The switch 13 is connected to the battery 11 in series.
When the power storage device 1 is connected to the device 2, the signal line Ls is connected by connecting the power storage device side connector 15 to the conversion connector 3, and the battery control unit 12 transmits the connection detection signal transmitted to the signal line Ls. It is detected by receiving via FIG. 2 is a diagram illustrating a configuration example of the power storage device side connector, the conversion connector, and the device side connector according to the embodiment. The conversion connector 3 is a connector for connecting the power storage device 1 including the battery 11 to the device 2. As shown in FIG. 2, the conversion connector 3 is attached in advance to a device-side connector 21 included in the device 2 before the battery 11 is used by the device 2. In the following description, “use” of the battery 11 refers to “charge” of the battery 11 by the device 2 when the device 2 is a charger, and by the device 2 when the device 2 is a load. It refers to “discharge” and “charge” of the battery 11.

  When battery control unit 12 detects that power storage device 1 is connected to device 2, battery control unit 12 turns on switch 13 that connects or disconnects battery 11 to device 2. The switch 13 is, for example, a relay. When the switch 13 is turned on, the positive power line Lp1 and the negative power line Lp2 are connected between the battery 11 and the device 2, and the battery 11 is connected to the device 2. 2, the positive power line Lp1 and the negative power line Lp2 may be included in the first cable C1 between the power storage device side connector 15 and the power storage device 1 together with the signal line Ls. . Further, the positive power line Lp1 and the negative power line Lp2 may be included in the second cable C2 between the device-side connector 21 and the device 2.

  The battery control unit 12 detects the voltage of the cells 111 to 11N measured by the voltage sensor 14 (141 to 14N) and monitors the charge / discharge state of the battery 11. In order to monitor the charge / discharge state of the battery 11, the battery control unit 12 also detects the current and temperature of the cells 111 to 11N measured by a current sensor (not shown) or a temperature sensor (not shown). It may be configured to.

  The battery control unit 12 turns off the switch 13 when the voltage of the battery 11 exceeds the first overcharge threshold, and the second overcharge threshold that is higher than the first overcharge threshold from the first overcharge threshold. Change the overcharge threshold. The first overcharge threshold and the second overcharge threshold are overcharge thresholds set in advance so that the battery 11 does not reach overcharge.

  In addition, the battery control unit 12 turns off the switch 13 when the voltage of the battery 11 is lower than the first overdischarge threshold, and the second overdischarge lower than the first overdischarge threshold from the first overdischarge threshold. Change the overdischarge threshold to the discharge threshold. The first overdischarge threshold and the second overdischarge threshold are overdischarge thresholds set in advance so that the battery 11 does not reach overdischarge.

  FIG. 3 is a diagram for explaining an example of battery voltage control executed by the power storage device according to the embodiment. Specifically, FIG. 3A and FIG. 3B are diagrams illustrating an example of charging control executed by the power storage device according to the embodiment. FIG. 3C and FIG. 3D are diagrams illustrating an example of discharge control executed by the power storage device according to the embodiment. In the graphs shown in FIGS. 3A to 3D, the vertical axis represents the voltage of the battery 11 and the horizontal axis represents time.

  First, in the example shown in FIGS. 3A and 3B, the battery 11 is charged by the device 2 that is a charger. When the voltage of the battery 11 exceeds the first overcharge threshold Vcth1 at time t1, the battery control unit 12 turns off the switch 13. When the switch 13 is turned off, the battery 11 is disconnected from the device 2 and the use (charging) of the battery 11 by the device 2 is stopped. As a result, in the period from time t1 to time t5, the voltage of the battery 11 is controlled to be approximately equal to or lower than the first overcharge threshold Vcth1. Time t5 is a time at which use of the battery 11 by the same or different device 2 is resumed after use of the battery 11 by the device 2 is stopped at time t1. Thus, since the voltage of the battery 11 is controlled to approximately the first overcharge threshold Vcth1 or less, the battery 11 can be prevented from being overcharged.

  In the example shown in FIGS. 3A and 3B, the power storage device 1 is disconnected from the device 2 that is a charger at time t2 after time t1. In addition, at time t3 after time t2, power storage device 1 is connected to device 2 that is a load. Then, at time t4 (FIG. 3A) or time t3 (FIG. 3B) after time t3, the battery control unit 12 operates from the first overcharge threshold Vcth1 to the second overcharge threshold Vcth2. Change the overcharge threshold. When the voltage of the battery 11 falls below the overcharge threshold due to the change of the overcharge threshold, the battery control unit 12 turns on the switch 13 again. Then, at time t5 after time t4 (FIG. 3A) or time t3 (FIG. 3B) when the overcharge threshold is changed, the battery 11 is used by the device 2 as a load. Since the overcharge threshold is changed to the second overcharge threshold Vcth2, even if the battery 11 charged to the first overcharge threshold Vcth1 is further charged by regeneration after time t5, the battery 11 is overcharged. It does n’t come. That is, even when the battery 11 fully charged to the first overcharge threshold Vcth1 by the device 2 as a charger is used in the device 2 as a load, in order to prevent overcharge due to regeneration during traveling. The use of the battery 11 is not stopped in a short time. For this reason, the user can safely use the battery 11 with the device 2 with a feeling of use similar to that of the second battery.

  Next, in the example illustrated in FIGS. 3C and 3D, the battery 11 is discharged by the device 2 that is a load. When the voltage of the battery 11 falls below the first overcharge threshold at time ta, the battery control unit 12 turns off the switch 13. When the switch 13 is turned off, the battery 11 is disconnected from the device 2 and the use (charging and discharging) of the battery 11 by the device 2 is stopped. As a result, during the period from time ta to time td, the voltage of the battery 11 is controlled to be approximately equal to or higher than the first overdischarge threshold Vdth1. The time td is a time when the use of the battery 11 by the same or different device 2 is resumed after the use of the battery 11 by the device 2 is stopped at the time ta. Thus, since the voltage of the battery 11 is controlled to be approximately equal to or higher than the first overdischarge threshold Vdth1, it is possible to prevent the battery 11 from being overdischarged.

  In the example shown in FIGS. 3C and 3D, the battery control unit 12 changes from the first overdischarge threshold value Vdth1 to the second overdischarge threshold value Vdth2 at time tc after time ta. Change the overdischarge threshold. When the voltage of the battery 11 exceeds the overdischarge threshold due to the change of the overdischarge threshold, the battery control unit 12 turns on the switch 13 again. And use of the battery 11 by the apparatus 2 which is load is restarted at the time td after the time tc. Since the overdischarge threshold is changed to the second overdischarge threshold Vdth2, even if the battery 11 discharged to the first overdischarge threshold Vdth1 is further discharged by the device 2 after time td, the overdischarge is performed in a short time. Not reached. That is, for example, even when the battery 11 that has been completely discharged to the first overdischarge threshold Vdth1 is used to move the device 2 that is a load to the vicinity of the charger, the battery is used to prevent overdischarge. The use of 11 is not stopped in a short time. For this reason, the user can safely use the battery 11 with the device 2 with a feeling of use similar to that of the second battery.

  Thus, according to the power storage device according to the embodiment, when the first battery that is vulnerable to overcharge and overdischarge is used in the second battery-compatible device that is resistant to overcharge and overdischarge, the second battery The first battery can be used safely as in the case of the battery.

  When the voltage of the battery 11 exceeds the second overcharge threshold Vcth2, the switch 13 is turned off again by the battery control unit 12, and charging of the battery 11 is stopped. For this reason, the battery 11 does not reach overcharge. Further, when the voltage of the battery 11 is lower than the second overdischarge threshold Vdth2, the switch 13 is turned off again by the battery control unit 12, and the discharge of the battery 11 is stopped. For this reason, the battery 11 does not reach overdischarge.

  Next, the change of the overcharge threshold or the overdischarge threshold described above may be performed when the battery control unit 12 detects that the permission switch 16 is turned on. The permission switch 16 is a switch that permits the use of the battery 11 after the switch 13 is turned off, for example, a push button switch.

  For example, as shown in FIG. 3A, when the permission switch 16 is turned on by the user at time t4 after time t3, a permission signal permitting use of the battery 11 is transmitted from the permission switch 16. The When the battery control unit 12 receives the permission signal, the battery control unit 12 changes the overcharge threshold from the first overcharge threshold Vcth1 to the second overcharge threshold Vcth2.

  As shown in FIG. 3C, when the permission switch 16 is turned on by the user at time tc, a permission signal is transmitted from the permission switch 16. When the battery control unit 12 receives the permission signal, the battery control unit 12 changes the overdischarge threshold from the first overdischarge threshold Vdth1 to the second overdischarge threshold Vdth2.

As described above, according to the power storage device according to the embodiment, the first battery can be used in the second battery compatible device according to the user's request.
Further, the overcharge threshold value or the overdischarge threshold value may be changed by the following configuration instead of or in addition to the configuration using the permission switch 16 as described above. That is, when the battery control unit 12 detects that the power storage device 1 is disconnected from the device 2 and the power storage device 1 is connected to the device 2, the overcharge threshold value or the overdischarge threshold value may be changed.

  For example, as shown in FIG. 3B, the power storage device side connector 15 is disconnected from the conversion connector 3 by the user at time t2. At time t2, conversion connector 3 is attached in advance to device-side connector 21 provided in device 2 that is a charger. The battery control unit 12 first detects that the power storage device 1 has been disconnected from the device 2 by not receiving the connection detection signal transmitted via the signal line Ls. Subsequently, at time t3, the power storage device side connector 15 is connected to the conversion connector 3 by the user. At time t3, the conversion connector 3 is attached in advance to the device-side connector 21 provided in the device 2 that is a load. Battery control unit 12 next detects that power storage device 1 is connected to device 2 by receiving a connection detection signal transmitted via signal line Ls. Therefore, the battery control unit 12 changes the overcharge threshold value from the first overcharge threshold value Vcth1 to the second overcharge threshold value Vcth2.

  Further, as shown in FIG. 3D, the power storage device side connector 15 is disconnected from the conversion connector 3 by the user at a time tb after the time ta. At time ta, the conversion connector 3 is attached in advance to the device-side connector 21 provided in the device 2 as a load. The battery control unit 12 first detects that the power storage device 1 has been disconnected from the device 2 by not receiving the connection detection signal transmitted via the signal line Ls. Subsequently, at time tc after time tb, the power storage device side connector 15 is connected to the conversion connector 3 by the user. At time tc, the conversion connector 3 is attached in advance to the device-side connector 21 provided in the same device 2 as that at time tb. Battery control unit 12 next detects that power storage device 1 is connected to device 2 by receiving a connection detection signal transmitted via signal line Ls. Therefore, the battery control unit 12 changes the overdischarge threshold from the first overdischarge threshold Vdth1 to the second overdischarge threshold Vdth2.

  As described above, the first battery can be changed to the second battery according to the user's request by the above-described configuration using the disconnection and connection of the power storage device according to the embodiment and the second battery compatible device. Can be used with battery-compatible devices.

  Next, when the battery control unit 12 determines that the battery 11 is being charged by the battery charger 2 after the overcharge threshold is changed to the second overcharge threshold, the battery control unit 12 sets the overcharge threshold to the first overcharge threshold. You may return to the overcharge threshold. Further, when the battery control unit 12 determines that the battery 11 is charged by the device 2 that is a charger after the overdischarge threshold is changed to the second overdischarge threshold, the overdischarge threshold is set to the first overdischarge threshold. You may return to an overdischarge threshold value.

  In the example shown in FIG. 3A, the battery 11 is removed from the device 2 as a load at time t6 after the time t4 when the overcharge threshold is changed, and charging is performed at time t7 after the time t6. A battery 11 is connected to the device 2 which is a container. Then, the battery control unit 12 detects that the voltage of the battery 11 continuously increases during a predetermined time from time t7 to time t8. Here, the predetermined time is a time that can distinguish continuous charging by a charger from intermittent charging due to a load such as regenerative charging while the vehicle is running. When the battery control unit 12 detects that the voltage of the battery 11 continuously increases for a predetermined time, the battery control unit 12 determines that the battery 11 is charged by the device 2 that is a charger. If the battery 11 is charged by the charger, it is desirable to return the overcharge threshold value to the first overcharge threshold value Vcth1 in order to prevent the battery 11 from being overcharged. Therefore, when it is determined that the battery 11 is charged by the device 2 that is a charger, the battery control unit 12 returns the overcharge threshold value from the second overcharge threshold value Vcth2 to the first overcharge threshold value Vcth1.

  Moreover, in the example shown in FIG. 3C, the battery 11 is removed from the device 2 as a load at a time te after the time tc when the overdischarge threshold is changed, and at a time tf after the time te, A battery 11 is connected to the device 2 which is a charger. Then, the battery control unit 12 detects that the voltage of the battery 11 continuously increases during a predetermined time from the time tf to the time tg, and the battery 11 is charged by the device 2 that is a charger. judge. If the battery 11 is charged with a charger, it is desirable to return the overdischarge threshold to the first overdischarge threshold Vdth1 in order to prevent overdischarge of the battery 11. Therefore, when it is determined that the battery 11 is charged by the device 2 that is a charger, the battery control unit 12 returns the overdischarge threshold value from the second overdischarge threshold value Vdth2 to the first overdischarge threshold value Vdth1.

As described above, according to the power storage device according to the embodiment, even when the first battery is repeatedly used by the device corresponding to the second battery, the first battery can be safely used in the same manner as the second battery. .
In addition to or in addition to the above-described configuration, the battery control unit 12 detects that the value of the current flowing through the battery 11 is continuously increasing for a predetermined time, so that the battery 11 can be connected to the battery 11 by the device 2 that is a charger. The battery may be determined to be charged. The effect mentioned above is acquired also by such a structure.

  In addition to or in addition to the above-described configuration, the battery control unit 12 returns the overcharge threshold to the first overcharge threshold and returns the overdischarge threshold to the first overdischarge threshold by the following configuration. Also good. That is, the battery control unit 12 may return the overcharge threshold value to the first overcharge threshold value when the voltage of the battery 11 changes by a predetermined voltage from the first overcharge threshold value. The battery control unit 12 may return the overdischarge threshold to the first overdischarge threshold when the voltage of the battery 11 changes from the first overdischarge threshold by a predetermined voltage.

  In the example shown in FIG. 3B, the battery control unit 12 sets the voltage of the battery 11 to the first overcharge at time t9 after time t5 when the use of the battery 11 is started by the device 2 as a load. It is detected that the predetermined voltage ΔV1 has dropped from the threshold value Vcth1. Here, the predetermined voltage ΔV1 is a difference value such that the voltage of the battery 11 does not exceed the first overcharge threshold value Vcth1 even by intermittent charging by a load such as regenerative charging while the vehicle is running. If the voltage of the battery 11 does not exceed the first overcharge threshold Vcth1 even by intermittent charging by the load, the overcharge threshold is returned to the first overcharge threshold Vcth1 in order to prevent the battery 11 from being overcharged. It is desirable. Therefore, the battery control unit 12 returns the overcharge threshold value from the second overcharge threshold value Vcth2 to the first overcharge threshold value Vcth1 when the voltage of the battery 11 changes from the first overcharge threshold value by the predetermined voltage ΔV1.

  In the example shown in FIG. 3C, the battery control unit 12 has the voltage of the battery 11 as the first voltage at the time th after the time tf when the charging of the battery 11 is started by the device 2 that is a charger. It is detected that the predetermined voltage ΔV2 has risen from the overdischarge threshold value Vdth1. Here, the predetermined voltage ΔV2 is a difference value such that the voltage of the battery 11 does not fall below the first overdischarge threshold value Vdth1 even if the voltage is discharged for a short time by the load. If the voltage of the battery 11 does not fall below the first overdischarge threshold Vdth1 even if the battery 11 is discharged for a short time by the load, the overdischarge threshold is returned to the first overdischarge threshold in order to prevent the battery 11 from being overdischarged. It is desirable. Therefore, the battery control unit 12 returns the overdischarge threshold value from the second overdischarge threshold value Vdth2 to the first overdischarge threshold value Vdth1 when the voltage of the battery 11 changes from the first overdischarge threshold value Vdth1 by the predetermined voltage ΔV2.

As described above, even when the first battery is repeatedly used by the second battery compatible device, the first battery can be safely used in the same manner as the second battery.
Further, instead of or in addition to the above-described configuration, the battery control unit 12 returns the overcharge threshold to the first overcharge threshold and returns the overdischarge threshold to the first overdischarge threshold by the following configuration. Also good. That is, the battery control unit 12 may return the overcharge threshold to the first overcharge threshold when a certain time has elapsed since the overcharge threshold was changed. Further, the battery control unit 12 may return the overdischarge threshold to the first overdischarge threshold when a certain time has elapsed since the overdischarge threshold was changed.

  In the example shown in FIG. 3B, the battery control unit 12 returns the overcharge threshold to the first overcharge threshold Vcth1 at time t9 when a certain time T1 has elapsed from time t3 when the overcharge threshold was changed. Here, the fixed time T1 is a time during which the battery 11 is discharged to the extent that the first overcharge threshold value Vcth1 is not exceeded even if intermittent charging is performed by a load such as regenerative charging while the vehicle is running. If the discharge time has passed so that the voltage of the battery 11 does not exceed the first overcharge threshold Vcth1 even if intermittent charging is performed by the load, the first overcharge threshold is set to prevent the battery 11 from being overcharged. It is desirable to return to the overcharge threshold value Vcth1. Therefore, the battery control unit 12 returns the overcharge threshold value from the second overcharge threshold value Vcth2 to the first overcharge threshold value Vcth1 when a certain time T1 has elapsed since the overcharge threshold value was changed.

  In the example shown in FIG. 3D, the battery control unit 12 changes the overdischarge threshold to the first overdischarge threshold Vdth1 at a time ti when a certain time T2 has elapsed from the time tc when the overdischarge threshold is changed. return. Here, the fixed time T2 is a time for allowing the battery 11 to be discharged by the load so as not to fall below the second overdischarge threshold Vdth2, and is allowed by the user to move the vehicle to the vicinity of the charger, for example. It's time. When the discharge allowable time that does not fall below the second overdischarge threshold Vdth2 has elapsed, it is desirable to return the overdischarge threshold to the first overdischarge threshold Vdth1 in order to prevent overdischarge of the battery 11. Therefore, the battery control unit 12 returns the overdischarge threshold value from the second overdischarge threshold value Vdth2 to the first overdischarge threshold value Vdth1 when a certain time T2 has elapsed since the overdischarge threshold value was changed.

As described above, even when the first battery is repeatedly used by the second battery compatible device, the first battery can be safely used in the same manner as the second battery.
The present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 1 Power storage device 11 Battery 111-11N Cell 12 Battery control unit 13 Switch 14, 141-14N Voltage sensor 15 Power storage device side connector 16 Permit switch 2 Device (load or charger)
21 Device side connector 3 Conversion connector Lp1 Positive power line Lp2 Negative power line Ls Signal line C1 First cable C2 Second cable

Claims (6)

A switch for connecting or disconnecting a battery to or from a device that is a charger or a load;
When the voltage of the battery exceeds a first overcharge threshold, the switch is turned off, and the overcharge threshold is increased from the first overcharge threshold to a second overcharge threshold that is higher than the first overcharge threshold. And when the voltage of the battery falls below a first overdischarge threshold, the switch is turned off, and a second overdischarge threshold lower than the first overdischarge threshold from the first overdischarge threshold And a battery control unit that changes the overdischarge threshold. The power storage device according to claim 1,
The battery control unit is configured to change the overcharge threshold or the overdischarge threshold when detecting that a permission switch permitting charging or discharging of the battery is turned on after the switch is turned off. The power storage device according to claim 1 or 2,
The battery control unit is a power storage device that changes the overcharge threshold or the overdischarge threshold when detecting that the power storage device is disconnected from the device and the power storage device is connected to the device. The power storage device according to any one of claims 1 to 3,
The battery control unit is
When it is determined that the battery is charged by the charger after the overcharge threshold is changed, the overcharge threshold is returned to the first overcharge threshold,
A power storage device that returns the overdischarge threshold to the first overdischarge threshold when it is determined that the battery is charged by the charger after the overdischarge threshold is changed. The power storage device according to any one of claims 1 to 4,
The battery control unit is
Returning the overcharge threshold to the first overcharge threshold when the voltage of the battery changes a predetermined voltage from the first overcharge threshold;
A power storage device that returns the overdischarge threshold to the first overdischarge threshold when the voltage of the battery changes by a predetermined voltage from the first overdischarge threshold. The power storage device according to any one of claims 1 to 5,
The battery control unit is
Returning the overcharge threshold to the first overcharge threshold when a fixed time has elapsed since the overcharge threshold was changed,
A power storage device that returns the overdischarge threshold to the first overdischarge threshold when a predetermined time has elapsed since the overdischarge threshold was changed.

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