JP3571558B2 - Backup method and backup device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backup method and a backup device for detecting disconnection of a main power supply and switching supply of power to a load from a main power supply to a lithium ion secondary battery.
[0002]
[Prior art]
In preparation for the interruption of the main power supply in the event of a power outage, a large-scale system uses an uninterruptible power supply such as a UPS to back up equipment that operates 24 hours a day, while a small-scale system uses a battery or the like for 24 hours. Backing up operating devices. Batteries are broadly classified into non-rechargeable primary batteries and rechargeable secondary batteries such as nickel cadmium batteries and small lead storage batteries. Among these batteries, a secondary battery is used as a backup for devices (devices such as a controller and emergency lighting) in a small-scale system. In other words, the primary battery needs to be replaced by a single power failure, but the secondary battery can be used repeatedly, so that it is not necessary to replace it by a single power failure. In particular, nickel cadmium batteries have advantages such as easy charge / discharge circuits, low cost, and high heat resistance, and are widely used as backup batteries for equipment in small-scale systems. In this case, the nickel cadmium battery is always chargeable and is used while maintaining a fully charged state.
[0003]
[Problems to be solved by the invention]
However, nickel cadmium batteries contain cadmium, a pollution control substance, and it is necessary to take various pollution countermeasures. In addition, the energy density is low, which leads to an increase in the mass of the device.
Therefore, the present applicant has considered the use of a lithium ion secondary battery that does not contain a pollution control substance and has a high energy density. If a lithium ion secondary battery is used, it is not necessary to take measures against pollution, and the size and weight of the device can be reduced.
[0004]
However, when a lithium ion secondary battery is maintained in a fully charged state for a long period of time, it leads to battery deterioration and shortens its life. That is, as a characteristic of a lithium ion secondary battery, the battery voltage is fully charged when the battery voltage is higher than a certain voltage. At this time, the inside of the battery is extremely activated, and the electrolysis rate of the active material is high. If this continues, the battery will be degraded. That is, if a nickel cadmium battery is replaced with a lithium ion secondary battery and a lithium ion secondary battery is used while maintaining a fully charged state like a nickel cadmium battery, the battery deteriorates quickly, has a short life, and must be replaced frequently. Have to be.
[0005]
Note that a lithium ion secondary battery is a main battery for a cycle in which charging is performed once, then discharged by use of a device, and then charged again, as is often used in mobile phones and the like. That is, it is assumed that the battery is used within a certain period without maintaining the full charge state for a long period of time, and is not considered as a backup application used while maintaining the full charge state like a nickel cadmium battery.
[0006]
When a lithium ion secondary battery is used while being maintained in a fully charged state, the same applies to a nickel cadmium battery, but the life is difficult to judge, and no deterioration is recognized. For this reason, it is necessary to periodically replace the battery, and there is a problem that the battery is replaced early even though the battery life has not been reached.
[0007]
The present invention has been made in order to solve such problems, and an object, can be used lithium ion secondary battery as a secondary battery for backup in long life, and its lifetime Is to provide a backup method and a backup device capable of quantitatively determining the backup.
[0008]
[Means for Solving the Problems]
In order to achieve such an object, the first invention (the invention according to claim 1) and the third invention (the invention according to claim 3) provide a lithium-ion secondary battery during standby backup of the lithium-ion secondary battery. When the battery capacity of the battery becomes equal to or less than a predetermined value determined as a value equal to or more than the minimum required battery capacity of the load, charging of the lithium ion secondary battery from the main power supply is started. When the battery is fully charged, the charging is stopped, and when the battery capacity of the lithium ion secondary battery is reduced to a predetermined value or less by discharging after the charging is stopped, the charging is restarted. lithium-ion secondary battery based on charging time for charging interval and the lithium ion secondary battery from the charging stopping waiting for backup to the battery until the charge resumption Is obtained so as to determine the lifetime.
According to the present invention, during standby for backup of the lithium ion secondary battery, when the battery capacity of the lithium ion secondary battery becomes equal to or less than a predetermined value, charging of the lithium ion secondary battery from the main power supply is started. When the ion secondary battery is fully charged, the charging is stopped. If the battery capacity of the lithium ion secondary battery becomes equal to or less than a predetermined value due to the discharge (self-discharge or the outflow of a small current to the battery capacity monitoring unit) after the stop of the charging, the charging is restarted. Repeated.
Further, the life of the lithium ion secondary battery is determined based on the charging interval and the charging time for the lithium ion secondary battery. That is, when the lithium ion secondary battery deteriorates, the charging interval from the stop of charging to the restart of charging is shortened. In addition, the charging time becomes longer. Therefore, by monitoring the charging interval and charging time, it is possible to determine the life of the lithium ion secondary battery.
[0009]
In the second invention (the invention according to the second aspect) and the fourth invention (the invention according to the fourth aspect), the voltage value of the lithium ion secondary battery must be at least as low as possible during the backup standby of the lithium ion secondary battery. When the voltage becomes equal to or lower than a predetermined voltage value VL determined as a value equal to or higher than the voltage value VLL, charging of the lithium ion secondary battery from the main power supply is started by a constant current charging method. When the voltage value of the ion secondary battery becomes the full charge voltage value VH (VH> VL), the charging of the lithium ion secondary battery from the main power supply is switched to the constant voltage charging method, and the lithium ion secondary battery is charged by the constant voltage charging method. When the charging current value to the ion secondary battery reaches the charging completion current value IL indicating the fully charged state, the charging is stopped, and the discharge after the charging stop causes the lithium ion secondary battery to discharge. The voltage value so as to resume the charging by the predetermined voltage value VL follows familiar if constant current charging method and constant voltage charging method of the pond, further charged until the charging resumes charging stop of waiting for backup to lithium-ion secondary battery it is obtained so as to determine the lithium ion secondary battery life based on charging time by constant current charging method for spacing and lithium ion secondary batteries.
According to the present invention, when the voltage value of the lithium ion secondary battery becomes equal to or lower than the predetermined voltage value VL during standby for backup of the lithium ion secondary battery, charging of the lithium ion secondary battery from the main power supply is performed by the constant current charging method. Be started. When the voltage value of the lithium ion secondary battery reaches the full charge voltage value VH by the charging by the constant current charging method, the charging is switched to the charging by the constant voltage charging method. When the charging current value to the lithium ion secondary battery becomes the charging completion current value IL by the charging by the constant voltage charging method, the charging is stopped. When the voltage value of the lithium ion secondary battery becomes equal to or less than a predetermined voltage value VL due to the discharge (self-discharge or the outflow of a small current to the battery capacity monitoring unit) after the charging is stopped, the constant current charging method and the constant voltage charging. The charging by the method is restarted, and this charge / discharge cycle is repeated.
Further, the life of the lithium ion secondary battery is determined based on the charging interval for the lithium ion secondary battery and the charging time by the constant current charging method. That is, when the lithium ion secondary battery deteriorates, the charging interval from the stop of charging to the restart of charging is shortened. Further, the charging time by the constant current charging method becomes longer. Therefore, by monitoring the charging interval and charging time, it is possible to determine the life of the lithium ion secondary battery.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail based on embodiments. FIG. 1 is a block diagram of a backup device showing an embodiment of the present invention. This backup device 1 is housed in a device 4 and located between an AC power supply 2 and a load 3.
[0013]
The backup device 1 includes a lithium ion secondary battery 1-1 as a backup secondary battery, a DC power supply circuit 1-2, a power cutoff detection circuit 1-3, a backup switching unit 1-4, and a constant current. Constant voltage charging control section 1-5, switch section 1-6, current monitoring section 1-7, voltage monitoring section 1-8, timer section 1-9, life determination section 1-10, life notification 1-11.
[0014]
The DC power supply circuit 1-2 converts AC from the AC power supply 2 into DC. The power cut-off detection circuit 1-3 monitors the DC output of the DC power supply circuit 1-2 as a main power supply, and connects the backup switching unit 1-4 to the main power supply line LM when the main power supply is not detected. The connection mode (main mode) is set, and when the disconnection of the main power supply is detected, the backup switching unit 1-4 is set to the connection mode (backup mode) with the backup power supply line LB.
[0015]
The backup switching section 1-4 has one switching terminal 1-4a connected to the DC power supply circuit 1-2 via the main power supply line LM, and the other switching terminal 1-4b connected to the lithium ion secondary battery 1-1. The common terminals 1-4c are connected to the load 3. In the main mode, the common terminal 1-4c and the switching terminal 1-4a are connected. In the backup mode, the common terminal 1-4c and the switching terminal 1-4b are connected.
[0016]
The voltage monitoring unit 1-8 monitors a voltage value (battery voltage) V of the lithium ion secondary battery 1-1. The current monitoring unit 1-7 monitors a charging current I to the lithium ion secondary battery 1-1. The switch section 1-6 is provided between the constant current / constant voltage charging control section 1-5 and the current monitoring section 1-7, and its ON / OFF is controlled by the constant current / constant voltage charging control section 1-5. .
[0017]
The constant current / constant voltage charging control unit 1-5 operates by a DC output from the DC power supply circuit 1-2, and outputs the monitoring voltage V of the voltage monitoring unit 1-8 and the monitoring current I of the current monitoring unit 1-7. Based on this, the charging of the lithium ion secondary battery 1-1 from the DC power supply circuit 1-2 is controlled by a constant current / constant voltage method (constant current charging method + constant voltage charging method) described later.
[0018]
When the constant current / constant voltage charging control section 1-5 controls the charging of the lithium ion secondary battery 1-1, the timer section 1-9 charges from the charging time (constant current charging time) T1 by the constant current charging method and the charging stop. The charging interval T2 until the restart is measured. The life determining unit 1-10 determines the life of the lithium ion secondary battery 1-1 from the charging time T1 and the charging interval T2 measured by the timer unit 1-9, and sends the determination result to the life notifying unit 1-11. send. The life notification unit 1-11 visually notifies the operator (equipment operator) of the determination result from the life determination unit 1-10, for example, by turning on an LED.
[0019]
[Supply power to the load during non-power failure]
At the time of non-power failure, the power cut-off detection circuit 1-3 does not detect the cut-off of the main power, so the backup switching unit 1-4 is set to the main mode. As a result, the DC power supply circuit 1-2 and the load 3 are connected via the main power supply line LM, and the DC output from the DC power supply circuit 1-2 is supplied to the load 3.
[0020]
[Supply power to the load during a power outage]
At the time of a power failure, the power-off detection circuit 1-3 detects the main power-off, so that the backup switching section 1-4 is set to the backup mode. Thereby, the lithium ion battery 1-1 and the load 3 are connected via the backup power supply line LB, and the DC output from the lithium ion battery 1-1 is supplied to the load 3. That is, the power supply to the load 3 is backed up by the lithium-ion battery 1-1, and data loss or the like in the load 3 is prevented.
[0021]
[Charging of lithium ion secondary battery during backup standby]
At the time of non-power failure, the lithium ion battery 1-1 and the load 3 are disconnected from each other and the lithium ion battery 1-1 is backed up in a state in which the power failure detection circuit 1-3 does not detect the disconnection of the main power. Waiting. In this case, the constant current / constant voltage charging control unit 1-5 operates by the DC output from the DC power supply circuit 1-2, and controls the charging of the lithium ion secondary battery 1-1.
[0022]
[Charging operation when an uncharged lithium ion secondary battery is set for the first time]
When the uncharged lithium ion secondary battery 1-1 is set, the voltage monitoring unit 1-8 determines that the voltage value V of the lithium ion secondary battery 1-1 is equal to or higher than the minimum required voltage value VLL of the load 3. (Step 201 shown in FIG. 2), and starts charging (constant-current charging) by the constant-current charging method to the constant-current / constant-voltage charging control unit 1-5. Command to do so.
[0023]
Upon receiving the command from the voltage monitoring unit 1-8, the constant current / constant voltage charging control unit 1-5 turns on the switch unit 1-6. As a result, the DC power supply to the lithium ion secondary battery 1-1 is performed by using the constant current / constant voltage charging control section 1-5, the switch section 1-6, the current monitoring section 1-7, and the voltage monitoring section 1-8 as charging paths. The charging from the circuit 1-2 is started (step 202: point t0 shown in FIG. 3). At this time, the timer unit 1-9 starts measuring the constant current charging time T1 (step 203). In this constant-current charging, the constant-current / constant-voltage charging control unit 1-5 sets the charging current I to the lithium ion secondary battery 1-1 to a predetermined constant value IH.
[0024]
By this constant current charging, the voltage value V of the lithium ion secondary battery 1-1 gradually increases, and eventually reaches a full charge voltage value VH indicating the completion of the constant current charging (point t1 shown in FIG. 3). In this case, assuming that the lithium-ion secondary battery 1-1 is brand-new and has not deteriorated, the constant current charging time T1 being measured by the timer unit 1-9 may not reach the fixed time TS1 set as the life determination time. (YES in step 204), the voltage value V of the lithium ion secondary battery 1-1 reaches the full charge voltage value VH.
[0025]
When the voltage value V of the lithium ion secondary battery 1-1 reaches the full charge voltage value VH, the voltage monitoring unit 1-8 instructs the constant current constant voltage charge control unit 1-5 to charge by the constant voltage charging method (constant voltage charging). A command is issued to switch to (charging) (YES in step 205).
[0026]
In response to the command from the voltage monitoring section 1-8, the constant current / constant voltage charging control section 1-5 sends a stop command to the timer section 1-9, and the constant current charging time T1 of the timer section 1-9 is measured. The measurement is stopped (step 206). Further, the constant current / constant voltage charging control unit 1-5 stops constant current charging of the lithium ion secondary battery 1-1 and starts constant voltage charging with the full charge voltage value VH (step 207: FIG. 3). Point t1 shown).
[0027]
Due to this constant voltage charging, the charging current I to the lithium ion secondary battery 1-1 gradually decreases, and eventually reaches a charging completion current value IL indicating completion of the constant voltage charging (full charge state) (see FIG. 3). T2 point shown). When the charging current I to the lithium ion secondary battery 1-1 reaches the charging completion current value IL, the current monitoring unit 1-7 instructs the constant current constant voltage charging control unit 1-5 to stop constant voltage charging. (YES in step 208).
[0028]
In response to the command from the current monitoring unit 1-7, the constant current / constant voltage charging control unit 1-5 turns off the switch unit 1-6 and stops charging the lithium ion secondary battery 1-1 ( Step 209). Thereby, the charging current I to the lithium ion secondary battery 1-1 is reduced to zero (point t2 shown in FIG. 3), and the charging to the lithium ion secondary battery 1-1 is completed. At this time, the timer unit 1-9 starts measuring the charging interval T2 (Step 210).
[0029]
[Discharge and recharge operation of lithium ion secondary battery]
When the charging current I to the lithium-ion secondary battery 1-1 is reduced to zero at the point t2 shown in FIG. 3, the lithium-ion secondary battery 1-1 is subjected to self-discharge and a minute discharge to the voltage monitoring unit 1-8. Due to the outflow of current, the battery capacity gradually decreases. Due to this decrease in the battery capacity, the voltage value V of the lithium ion secondary battery 1-1 gradually decreases, and eventually reaches the recharge start voltage value VL (point t3 shown in FIG. 3).
[0030]
When the voltage value V of the lithium ion secondary battery 1-1 reaches the recharge start voltage value VL, the voltage monitoring unit 1-8 instructs the constant current constant voltage charge control unit 1-5 to start constant current charging. Is issued (step 211).
[0031]
In response to the command from the voltage monitoring section 1-8, the constant current / constant voltage charging control section 1-5 sends a stop command to the timer section 1-9 to measure the charging interval T2 in the timer section 1-9. It is stopped (step 212). Assuming that the lithium-ion secondary battery 1-1 is new and has not deteriorated, the charging interval T2 measured by the timer unit 1-9 is longer than a certain time TS2 set as the life determination time. Accordingly, the process proceeds to step 202 in response to YES in step 213, and the operation after step 202 is repeated. That is, the charging / discharging cycle in which the constant current charging is performed at points t3 to t4, the constant voltage charging is performed at points t4 to t5, and the charging is stopped at points t5 to t6 shown in FIG.
[0032]
As described above, according to the backup device 1 of the present embodiment, the lithium ion secondary battery 1-1 is charged during the backup standby of the lithium ion secondary battery 1-1, but reaches the fully charged state. Then, the battery is immediately released from the state by self-discharge or the like, so that the usage time while maintaining the fully charged state is extremely short, and the life of the lithium ion secondary battery 1-1 is extended. As a result, the lithium ion secondary battery 1-1 can be used as a backup secondary battery with a long service life, and the size and weight of the device can be promoted. Also, there is no need to take pollution measures.
[0033]
[Lifetime judgment and notification of lithium ion secondary battery]
As the use period of the lithium ion secondary battery 1-1 increases over time, the constant current charging time T1 increases, and the charging interval T2 from the stop of charging to the restart of charging decreases. Thus, in the present embodiment, in step 204, the constant current charging time T1 is compared with the life determination time TS1. In step 213, the charging interval T2 is compared with the life determination time TS2.
[0034]
That is, in the present embodiment, when the constant current charging time T1 is longer than the life determining time TS1 (T1> TS1), the life determining unit 1-10 determines that the life of the lithium ion secondary battery 1-1 has been reached. The determination result is sent to the life notifying section 1-11 (step 214). If the charging interval T1 is shorter than the life determination time TS2 (T2 <TS2), the life determination unit 1-10 determines that the lithium ion secondary battery 1-1 has expired, and reports the determination result to the life notification unit. Send to 1-11 (step 215). The life notification unit 1-11 visually notifies the operator of the determination result from the life determination unit 1-10, for example, by turning on an LED. As a result, the life of the lithium ion secondary battery 1-1 can be quantitatively determined, and periodic battery replacement is not required.
[0035]
[Measurement of constant current charging time T1 and charging interval T2 when power failure occurs]
When a power failure occurs (step 216), the power-off detection circuit 1-3 detects the main power-off, sets the backup switching unit 1-4 to the backup mode, and supplies power to the load 3 to the lithium-ion battery 1-1. Switch (step 217). In this case, the voltage value V of the lithium ion secondary battery 1-1 is in the range from the recharge start voltage value VL to the full charge voltage VH, that is, a value equal to or higher than the minimum voltage value VLL required by the load 3. Therefore, the load 3 can be backed up without any trouble.
[0036]
At this time, the DC output from the DC power supply circuit 1-2 is not supplied to the constant current / constant voltage charging control unit 1-5, and the constant current / constant voltage charging control unit 1-5 receives the DC output from the timer unit 1-9. Power supply is also interrupted. For this reason, the measurement operation itself of the constant current charging time T1 and the charging interval T2 in the timer unit 1-9 is not performed, and the life determination based on the constant current charging time T1 and the charging interval T2 is not performed.
[0037]
[Charging of lithium ion secondary battery at power recovery]
When the power is restored (step 218), the power cutoff detection circuit 1-3 sets the backup switching section 1-4 to the main mode, and switches the power supply to the load 3 to the main power supply from the DC power supply circuit 1-2 (step 219). ). At this time, if the voltage value V of the lithium ion secondary battery 1-1 is equal to or less than the recharge start voltage value VL (V ≦ VL), the voltage monitoring unit 1-8 sends the voltage to the constant current constant voltage charge control unit 1-5. A command is issued to start constant current charging (step 201).
[0038]
In the present embodiment, the recharge start voltage value VL is equal to or higher than the minimum required voltage value VLL of the load 3. However, the recharge start voltage value VL may be a current consumption of the load 3, a backup time, or the like. Depends on. That is, the recharge start voltage value VL is determined as an appropriate value equal to or higher than VLL according to the current consumption of the load 3 and the backup time.
[0039]
Further, in the present embodiment, the constant current charging time T1 and the charging interval T2 are measured, and the life of the lithium ion secondary battery 1-1 is determined for each battery. However, the constant current charging time T1 and the charging interval T2 are determined. May be used to determine the life of the lithium-ion secondary battery 1-1. In addition, the life of the lithium-ion secondary battery 1-1 may be determined in one of the constant current charging time T1 and the charging interval T2. May be performed. Further, the sum of the constant current charging time T1 and the constant voltage charging time T3 may be used as the charging time T4, and the life may be determined based on the charging time T4.
[0040]
Further, in the present embodiment, the lithium ion secondary battery 1-1 is charged by the constant current / constant voltage method (constant current charging method + constant voltage charging method). However, the constant current / constant voltage method is always used. It is not necessary. Generally, the lithium ion secondary battery 1-1 is charged by a constant current and constant voltage method.
[0041]
【The invention's effect】
According to the onset bright As apparent from the above description, waiting for backup of a lithium ion secondary battery, although the charging of the lithium ion secondary battery is performed, immediately the like self-discharge reaches a fully charged state Thus, the battery is released from such a state, and the usage time is extremely short while maintaining the fully charged state, and the life of the lithium ion secondary battery is prolonged. As a result, a lithium ion secondary battery can be used as a backup secondary battery with a long service life, and the size and weight of the device can be promoted. Also, there is no need to take pollution measures.
Further, according to this onset bright, it is possible to quantitatively determine lithium ion secondary battery life, it is possible to eliminate the need for periodic battery replacement.
[Brief description of the drawings]
FIG. 1 is a block diagram of a backup device according to an embodiment of the present invention.
FIG. 2 is a flowchart illustrating the operation of the backup device.
FIG. 3 is a waveform diagram of a voltage value and a current value showing a charging / discharging state of the lithium ion secondary battery in a backup standby state in the backup device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Backup device, 2 ... AC power supply, 3 ... Load, 4 ... Equipment, 1-1 ... Lithium ion secondary battery, 1-2 ... DC power supply circuit, 1-3 ... Power-off detection circuit, 1-4 ... Backup Switching unit, 1-5: constant current / constant voltage charging control unit, 1-6: switch unit, 1-7: current monitoring unit, 1-8: voltage monitoring unit, 1-9: timer unit, 1-10: life Judgment unit, 1-11: Life notification unit, LM: Main power supply line, LB: Backup power supply line.

Claims (4)

A backup method for detecting a disconnection of a main power supply and switching supply of power to a load from the main power supply to a lithium ion secondary battery,
If the battery capacity of the lithium ion secondary battery is equal to or less than a predetermined value that is equal to or greater than the minimum required battery capacity of the load while the lithium ion secondary battery is on standby for backup, the lithium ion The charging of the secondary battery from the main power source is started, and when the lithium ion secondary battery is fully charged by this charging, the charging is stopped. Restarting the charging when the capacity becomes equal to or less than the predetermined value;
And a step of determining the life of the lithium ion secondary battery based on charging time for charging interval and the lithium ion secondary battery from charging stop in said backup waiting for the lithium ion secondary battery to charge resumption A backup method characterized in that: A backup method for detecting a disconnection of a main power supply and switching supply of power to a load from the main power supply to a lithium ion secondary battery,
If the voltage value of the lithium ion secondary battery becomes equal to or lower than a predetermined voltage value VL which is set to a value equal to or higher than the minimum voltage value VLL required by the load during the backup standby of the lithium ion secondary battery, Charging of the lithium ion secondary battery from the main power supply is started by a constant current charging method, and the voltage of the lithium ion secondary battery is set to a full charge voltage value VH (VH> VL) by the charging by the constant current charging method. If so, the charging of the lithium ion secondary battery from the main power supply is switched to a constant voltage charging method, and the charging by the constant voltage charging method causes the charging current value of the lithium ion secondary battery to indicate a fully charged state. When the current reaches the completion current value IL, the charging is stopped. The discharge after the stop of the charging causes the voltage value of the lithium ion secondary battery to reach the predetermined voltage value V Resuming step charging by following the familiar if the constant current charging method and constant voltage charging method,
Determining the lifetime of the lithium ion secondary battery based on charging time by constant current charging method for charging interval and the lithium-ion secondary battery until the charging resumes charging stop in said backup waiting for the lithium ion secondary battery A backup method. Main power interruption detection means for detecting a main power interruption,
Backup disconnection means for switching the supply of power to the load from the main power supply to a lithium ion secondary battery when the main power supply disconnection detection means detects the disconnection of the main power supply;
Battery capacity monitoring means for monitoring the battery capacity of the lithium ion secondary battery;
If the battery capacity of the lithium ion secondary battery is equal to or less than a predetermined value that is equal to or greater than the minimum required battery capacity of the load while the lithium ion secondary battery is on standby for backup, the lithium ion The charging of the secondary battery from the main power source is started, and when the lithium ion secondary battery is fully charged by this charging, the charging is stopped. Charge control means for restarting the charge when the capacity is equal to or less than the predetermined value;
And lifetime determination means for determining the lifetime of the lithium ion secondary battery based on charging time for charging interval and the lithium ion secondary battery from charging stop in said backup waiting for the lithium ion secondary battery to charge resumption A backup device comprising: Main power interruption detection means for detecting a main power interruption,
Backup disconnection means for switching the supply of power to the load from the main power supply to a lithium ion secondary battery when the main power supply disconnection detection means detects the disconnection of the main power supply;
Voltage monitoring means for monitoring a voltage value of the lithium ion secondary battery;
Current monitoring means for monitoring a charging current value to the lithium ion secondary battery;
If the voltage value of the lithium ion secondary battery becomes equal to or lower than a predetermined voltage value VL which is set to a value equal to or higher than the minimum voltage value VLL required by the load during the backup standby of the lithium ion secondary battery, Charging of the lithium ion secondary battery from the main power supply is started by a constant current charging method, and the voltage of the lithium ion secondary battery is set to a full charge voltage value VH (VH> VL) by the charging by the constant current charging method. If so, the charging of the lithium ion secondary battery from the main power supply is switched to a constant voltage charging method, and the charging by the constant voltage charging method causes the charging current value of the lithium ion secondary battery to indicate a fully charged state. When the current reaches the completion current value IL, the charging is stopped. The discharge after the stop of the charging causes the voltage value of the lithium ion secondary battery to reach the predetermined voltage value V Resuming charging control means charging by the if less constant current charging method and constant voltage charging method,
Determining the lifetime of the lithium ion secondary battery based on charging time by constant current charging method for charging interval and the lithium-ion secondary battery until the charging resumes charging stop in said backup waiting for the lithium ion secondary battery A backup device comprising:

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