JPH06261469A - Backup power equipment - Google Patents

Abstract

PURPOSE:To provide a backup power device which can be used for both long- time and short-time backup by using a storage battery for long-time discharging and a storage battery for short time discharging as a power supply, switching them depending on the use. CONSTITUTION:In a backup power device for memory backup of an information processing unit, a storage battery for short-time discharging 18 is connected to the information processing unit 14 through a diode 17 and a storage battery for long time discharging 16 is connected through an on/off circuit 15 to a line which supplies power to the information processing unit 14. The on/off circuit 15 is on/off controlled by a voltage detecting circuit 19 which detects a voltage level of the storage battery for short-time discharging 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backup power supply device, and more particularly to a backup power supply device for memory backup of an information processing device.

In recent years, the data processing amount of information processing devices has been increasing, and along with this, the data storage amount of external storage devices such as disk devices for accumulating and storing data is mainly from several gigabytes to several tens of gigabytes. ing.

Such an information processing apparatus internally has a volatile storage device such as a semiconductor memory, and when data processing is performed, it is based on the data stored in the internal volatile storage device. Perform processing.

Therefore, in order to execute data processing after the information processing apparatus is powered on, it is necessary to first read data from the stored nonvolatile disk device to the volatile storage device. At this time, when the data amount changes from several gigabytes to several tens of gigabytes, the read time may be several tens of minutes to sometimes exceed one hour. Further, when the power is turned off, it is necessary to write the data in the non-volatile disk device similarly, and the same time is required.

This requires a considerable amount of time for reading or saving data every time the power is turned on and off, which is an operational problem.

Therefore, when the power is turned off normally, data of several gigabytes to several tens of gigabytes is stored in an internal storage device such as a semiconductor device having low power consumption, and when the power is turned off, power is supplied from a backup power supply device using a storage battery or the like. By supplying and holding the data, the reading time at power-on and the data saving time at power-off are shortened.

It is required that such a backup power supply device be easy to maintain and manage.

[0008]

2. Description of the Related Art FIG. 10 is a block diagram showing an example of a conventional backup power supply device. In the figure, 31 indicates a main power source. The main power supply 31 is composed of an AC power supply and supplies an AC voltage to a power distribution unit (Power Distribution Unit).
nit; PDU) 32. PDU 32 is the main power source 31
The AC voltage supplied from is converted into a DC voltage and output. The output DC voltage of the PDU 32 is supplied to the converter 33.

The converter 33 converts the DC voltage supplied from the PDU 32 into a predetermined voltage and outputs it. The output DC voltage of the converter 33 is supplied to the information processing device 34.

The information processing device 34 is operated by the DC voltage supplied from the converter 33, and various data processing is performed.

The converter 33 is supplied with the output DC voltage of the PDU 32 and is connected to a battery 35 via an on / off circuit 36. ON / OFF circuit 3
6 is composed of a diode or the like, and is set to be ON when the main power supply 1 is disconnected by setting the output DC voltage of the battery 35 to a value smaller than the output DC voltage of the PDU 32, and connecting the anode to the battery 35 side and the cathode to the converter 33 side. Then, the battery 35 is connected to the converter 33, and is turned off when the main power supply 31 is turned on to disconnect the battery 35 and the converter 33. At this time, the battery 35 is connected to the PDU 32 via the charging circuit 37 and is charged by the output DC voltage of the PDU 32. The charging circuit 37 is composed of a diode and the like. The anode is connected to the PDU 32 side and the cathode is connected to the battery 35 side.
Prevents backflow to the 2 side.

With the above configuration, when the main power supply 31 is disconnected from the information processing device 34, power is supplied from the battery 35, the data in the internal memory is held, and then the main power supply 3
Since the data is retained in the internal memory until 1 is turned on, there is no need to read the data from the disk device to the internal memory or write the data from the internal memory to the disk device when the main power is turned on and off. The operational efficiency of the system, such as when dealing with the data of, was improved.

At this time, conventionally, the backup is performed by one type of battery 35.

[0014]

When operating the information processing apparatus, the main power source is not always turned on, but is normally turned on only during its use time.

FIG. 11 is an explanatory view of a time zone in which the information processing apparatus is used. In the figure, the solid area indicates the usage time zone of the information processing apparatus, and the shaded area indicates the unused time zone. When the information processing device 34 is used in the time zone T ₃ from 9:00 am to 5:00 pm on weekdays (Monday to Friday), the main power is turned on only during that time.
Weekday from 5 pm to 9 am the next morning T ₄ (1
6 hours) and weekends from 5 pm on Friday to 9 am on Monday
The main power supply is cut off during the time period T ₅ (65 hours) until the time. Therefore, the battery will be charged from 5 pm on weekdays to 9 am on the next morning.
16 hours on time T ₄ and 5 pm on weekends Friday
It is necessary to make a backup for 65 hours in the time zone T ₅ from 9:00 am to 9:00 am on Monday.

If a battery backup of 16 hours is carried out every day, 1000 times of charging and discharging are carried out in about 3 years, so it is necessary to select a battery suitable for it.
As a storage battery that can be expected to have a cycle life of about 1000 times, there is a nickel-cadmium battery (hereinafter referred to as a nicad battery). However, since the nickel cadmium battery has a small amount of stored electricity per battery, it is suitable for discharging in a relatively short time. Figure 1 shows the relationship between the number of discharges and the discharge time of NiCd batteries.
2 is shown by a solid line.

However, if the power is cut off on weekends, if the power is turned off at 5 pm on Friday and the power is turned on at 9:00 am on the following Monday, a power off period of 65 hours occurs. In order to supply this with the current NiCd battery, a large number of batteries must be installed, leading to a decrease in reliability.

Therefore, when a lead acid battery having a relatively large amount of stored electricity per battery is used, the battery can be backed up for a power-off period of 65 hours on weekends.
In the case of a lead storage battery, the cycle life is as short as 200 to 300 times. In FIG. 12, the broken line shows the relationship between the number of discharges and the discharge time of the lead battery. Therefore, when a lead battery is used, if it is repeatedly charged and discharged every day, it will reach the end of its useful life in about one year, which is a problem in terms of maintenance and management.

Therefore, at present, a nickel cadmium battery is used, and at the time of power-off on weekends and at power-on at the beginning of the week, data is saved in the nonvolatile disk device and read out. Therefore, there is a problem in that it is impossible to completely shorten the time at the time of making and cutting because it requires a time exceeding the above.

The present invention has been made in view of the above points, and corresponds to both long-time and short-time backup by switching between a long-time discharge storage battery and a short-time discharge storage battery as a backup power source. It is an object of the present invention to provide a backup power supply device that operates.

[0021]

FIG. 1 shows a block diagram of the principle of the present invention. In the figure, 1 indicates a main power source. Main power supply 1
Supplies electric power to the load 2 when it is turned on.

The long-term discharge storage battery 3 is a storage battery suitable for long-time discharge, and supplies power to the load 2 when the main power supply unit 1 is disconnected.

The short-time storage battery 4 is a storage battery suitable for short-time discharge, and supplies power to the load 2 when the main power supply unit 1 is disconnected.

The connection control means 5 detects the disconnection of the main power source unit 1, and when the main power source unit 1 is disconnected, if the main power source unit 1 is disconnected for a long time, the long-time discharge The storage battery 3 is connected to the load 2, and the short-time discharging storage battery 4 is connected to the load 2 when the main power supply unit 1 is disconnected for a short time.

[0025]

[Operation] When the main power supply is disconnected for a short time, the load is backed up by the short-term storage battery, and when the main power supply is disconnected for a long time, the load is backed up by the long-term discharge storage battery, and the load is backed up by the main power supply. Since it uses a storage battery that fits the disconnection time, it is possible to reliably perform both short-time and long-time backup, and it is possible to use a storage battery that is suitable for both short-time and long-term conditions, so the minimum required The storage battery can be configured, the device can be downsized, and the reliability of backup can be improved.

[0026]

FIG. 2 is a block diagram of the first embodiment of the present invention.
In the figure, 11 indicates a main power source. The main power supply 11 is an AC power supply, and a power distribution unit (Powe
r Distribution Unit (hereinafter referred to as PDU) 12 is supplied with AC voltage. The PDU 12 supplies an input AC voltage of, for example, 29
Main power supply and PDU for converting to [V] DC voltage and outputting
Is the main power supply. The output DC voltage of the PDU 12 is supplied to the converter 13.

The converter 13 converts the output DC voltage of the PDU 12 into a predetermined DC voltage level required by the information processing device 14,
For example, it is converted into 5 [V] and output.

The output DC voltage of the converter 13 is supplied to the information processing device 14 to operate the information processing device 14 as a load.

A long-term storage battery 16 for backup is connected to a connection point between the PDU 12 and the converter 13 via an on / off circuit 15. Storage battery for long-term discharge 1
6 is a lead battery, for example, which is suitable for long-term discharge. Lead-acid batteries are suitable for long-term discharge, and can keep supplying a constant output voltage for a long time. However, it has a short cycle life due to repeated charging and discharging. Therefore, it is suitable for a backup such as a weekend where the charging frequency is long and the charging frequency is small.

Further, the converter 13 and the information processing device 14
A short-time storage battery 18 for backup is connected via a diode 17 to the connection point with. The storage battery 18 for short-time discharge is suitable for short-time discharge, for example, nickel-
It consists of cadmium batteries (hereinafter referred to as NiCad batteries). NiCd batteries are used for charging, have durability against repeated charging, and have a long cycle life. However, it has a short discharge time and is not suitable for a long backup such as a weekend, and is suitable for a backup that has a large number of charges due to a short discharge such as a weekday.

The on / off circuit 15 for connecting the storage battery 16 for a long time is composed of a transistor, the control terminal is connected to the voltage detection circuit 19, and it is turned on / off in response to a control signal from the voltage detection circuit 19 The connection of the time discharge storage battery 16 is controlled.

The voltage detection circuit 19 is composed of a reference voltage source and a comparator. The comparator compares the charging voltage of the short-time discharge storage battery 18 with the reference voltage, and when the charging voltage drops below a predetermined value, a high or low level. Is supplied to the on / off circuit 15, and the on / off circuit 15
Is turned on to switch to the long-term discharge storage battery 16.

The long-time discharge storage battery 16 and the short-time discharge storage battery 18 are connected to the output of the PDU 12 via the charging circuit 20. When the main power supply 11 is turned on, the charging circuit 20 uses the output of the PDU 12 to discharge the storage battery 16 for a long time
And the storage battery 18 for short-time discharge is charged.

Next, the operation of this embodiment will be described. First, the case where the main power supply 11 is turned on will be described.

When the main power source 11 is turned on, the PDU
A voltage of 29 [V] is output from 12 and the converter 1
It is converted into a voltage of 5 [V] or 3.3 [V] by 3 and supplied to the information processing device 14. At this time, the output voltage of the storage battery 18 for short-time discharge is equal to the output voltage 5 of the converter 13.
Value slightly smaller than [V] or 3.3 [V] 4.9 [V]
Alternatively, it is set to 3.2 [V] and the diode 17
Since a reverse voltage is applied to the storage device 18, the short-time discharge storage battery 18 is disconnected from the information processing device 14.

At this time, the charging circuit 20 has a PDU.
The output voltage of 12 is applied, whereby the charging circuit 20 operates, and the charging voltage substantially the same as the output voltage of each battery is applied to the long-time storage battery 16 and the short-time storage battery 18.

For this reason, a voltage substantially the same as the output voltage is applied to the short-time discharge storage battery 18, and a voltage higher than the reference voltage of the voltage detection circuit 19 is applied. An off signal is output from the voltage detection circuit 19.

Therefore, the on / off circuit 15 is turned off, the storage battery 16 for long-term discharge is disconnected from the information processing device 14, and the charging voltage is applied from the charging circuit 20 to perform charging.

Next, the case where the main power supply 11 is cut off will be described. When the main power supply 11 is cut off, the output voltage of the converter 13 drops.

When the voltage of the converter 13 drops to the output voltage of the short-time discharge storage battery 18 or less, the diode 1
7 turns on. At this time, the charging circuit 20 stops the supply of the charging voltage to the long-time discharging storage battery 16 and the short-time discharging storage battery 18 due to the decrease in the output voltage of the PDU 12. Further, a voltage is applied to the voltage detection circuit 19 from the short-time discharge storage battery, and this voltage is compared with the reference voltage. The on / off circuit 15 remains off by the off signal, and the long-term discharge storage battery 16 is connected to the information processing device 1.
4 is left disconnected.

Next, when the storage battery 18 for short-time discharge is exhausted and the output voltage drops below a predetermined voltage, the voltage detection circuit 19
Detects this and supplies an ON signal to the ON / OFF circuit 15. As a result, the on / off circuit 15 is turned on, and a voltage (about 29
[V]) is applied.

The output voltage of the long-term storage battery 16 is converted into a voltage of 5.0 [V] or 3.3 [V] by the converter 13 and applied to the information processing device 14. At this time, since the output voltage of the short-time discharge storage battery 18 is lowered, a reverse voltage is applied to the diode 17, and the diode 17 is turned off. Be disconnected.

As described above, when the main power supply 11 is disconnected, if the short-time discharge storage battery 18 can be backed up, it is backed up by the short-time discharge storage battery 18, and the short-time discharge storage battery 18 is used. When the backupable time is exceeded, the backup battery 16 is used for backup for a long time. For example, in a backup for a relatively short time of 16 hours from 5 pm on weekdays to 9 am on the next morning, backup is performed while charging / discharging the short-time storage battery 18 repeatedly, and from 5 pm to Friday on weekends. In the long time backup of 65 hours until 9 am, after the short-time discharge storage battery 18 is exhausted,
Backup is performed by the long-term storage battery 16.

Therefore, the rechargeable battery is often charged and discharged repeatedly, and a short-time storage battery 18 such as a NiCd battery suitable for these situations can be used for backup for a relatively short time. For the backup, a long-term storage battery 16 such as a lead battery suitable for these situations can be used, and both short-time and long-time backup can be performed.

Further, since it is possible to select a battery suitable for both short-time and long-time backup, it is necessary to install a large number of short-time discharge storage batteries to increase the capacity for long-time backup. Therefore, it is possible to reduce the size of the apparatus, and it is not necessary to use a storage battery for a long time discharge having a short cycle life in order to perform backup for a short time, and maintainability can be improved.

Further, since the battery is duplicated and held, a redundant function can be added to the power source, and the reliability of the system can be improved.

FIG. 3 shows a block diagram of the second embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In this embodiment, the connection of the storage battery 16 for long time discharge and the storage battery 18 for short time discharge to the information processing device 14 is controlled according to the backup schedule for the information processing device 14.

The configuration of this embodiment is the same as the voltage detection circuit 19 shown in FIG.
Instead of the diode 17, which is provided with a calendar timer 21 in which a backup schedule for the information processing device 14 is stored in advance, and the diode 17 for controlling the connection of the short-time discharge storage battery 18 is replaced by an on / off circuit 2 including a transistor or the like.
2 is provided, and an on / off circuit 22 for controlling the connection of the storage battery 16 for long time discharge by the calendar timer 21 and an on / off circuit 22 for controlling the connection of the storage battery 18 for short time discharge.
Is configured to control ON / OFF of.

The calendar timer 21 is supplied with a voltage from the connection point between the converter 13 and the information processing device 14, operates by the supplied voltage, and is turned on / off by the on / off circuits 15 and 22 in accordance with a preset calendar. It supplies an on signal or an off signal.

The calendar timer 21 is an on / off circuit 15
For the information processing device on Friday (5 pm) to the information processing device on Monday (9 am), the ON signal is supplied, and the OFF signal is supplied at other times to turn on / off. An ON signal is supplied to the circuit 22 from Monday to Thursday when the information processing apparatus 14 is off (5 pm) to the next morning when the information processing apparatus 14 is on (9 am).

FIG. 4 shows an operation explanatory diagram of the second embodiment of the present invention. In the figure, the solid area indicates the usage time of the information processing apparatus 14, and the shaded area indicates the backup time during which the information processing apparatus 14 is inactive and the memory is backed up. From 5 pm on Friday to 9 am on Monday. 65 hours long T
_The storage battery 16 for long time discharge is connected at the time of backup of ₁ , and the information processing apparatus 14 is backed up by the storage battery 16 for long time discharge.

Also, during backup for a short time T ₂ of 16 hours from 5 pm on Monday to Thursday on weekdays, and 9:00 am on the next morning, a short-time discharging storage battery 18 is connected and the information processing device 14 is for short-time discharging. It is backed up by the storage battery 18.

Therefore, according to the present embodiment, it becomes possible to perform backup for a long time and a backup with a battery suitable for a short time as in the first embodiment, and the same effect as in the first embodiment can be obtained.

FIG. 5 shows a block diagram of the third embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In this embodiment, the storage battery 16 for long time discharge and the storage battery 18 for short time discharge are switched according to the integrated amount of discharge current of the storage battery for short time discharge.
This utilizes the property that the discharge capacity of a battery can be calculated by the integrated amount of discharge current.

In this embodiment, a set time timer 23 and a discharge current detecting circuit 2 are used instead of the calendar timer 21 in FIG.
4 is provided.

The discharge current detection circuit 24 is provided between the connection point between the converter 13 and the information processing circuit 14 and the ON / OFF circuit 22, detects the discharge current from the short-time discharge storage battery 18, and outputs the timer start signal. Is supplied to the set time timer 23.

The set time timer 23 operates by picking up a power source from between the converter 13 and the information processing circuit 14. The set time timer 23 is activated by a timer activation signal from the discharge current detection circuit 24 and supplies an off signal to the on / off circuit 22 and an on signal to the on / off circuit 15 after a preset fixed time has elapsed. .

The on / off circuit 22 is normally on,
It is configured to turn off when an off signal is input from the set time timer 23. On / off when main power supply 11 is disconnected
Since the off circuit 22 is normally on, the discharge current detection circuit 24 detects this and a current is supplied from the storage battery 18 for short-time discharge to the information processing device 14 according to the decrease in the output voltage of the converter 13, and the short-time discharge is performed. The backup is started by the storage battery 18.

A timer start signal is supplied to the set time timer 23 to start the set time timer 23. When the count value of the set time timer 23 reaches a preset time, that is, when the short-term discharge storage battery 18 reaches the end of its life, the set time timer 2
3 supplies an ON signal to the ON / OFF circuit 15 and turns ON the ON / OFF circuit 15 to store the long-term discharge storage battery 1.
6, the backup is started and an off signal is supplied to the on / off circuit 22 to turn off the on / off circuit 22 to disconnect the short-time discharge storage battery 18 from the circuit.

As described above, the time during which the short-time discharge storage battery 18 can be discharged is set in advance by the timer, and the switching control between the short-time discharge storage battery 18 and the long-time discharge storage battery 16 is performed. The same effect as the embodiment is obtained.

FIG. 6 is a block diagram of the fourth embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In this embodiment, the output voltage of the PDU 12 is detected and the set time timer 23 is activated in response to this.

In this embodiment, instead of the discharge current detection circuit 24 of FIG. 5, a power failure detection circuit 25 is connected to the output of the PDU 12. The power failure detection circuit 25 detects the output voltage of the PDU 12, and supplies a timer start signal to the set time timer 23 when the output voltage of the PDU 12 becomes a predetermined value or less.

The set time timer 23 operates by picking up a power source from between the converter 13 and the information processing device 14. The set time timer 23 supplies an ON signal to the ON / OFF circuit 22 when a timer start signal is input, supplies an OFF signal to the ON / OFF circuit 22 after a predetermined time has elapsed after starting, and the ON / OFF circuit 15 Supply an ON signal to.

Therefore, when the main power supply 11 is cut off, the output voltage of the PDU 12 drops, and the power failure detection circuit 25 detects this, and first supplies an ON signal to the ON / OFF circuit 22 to turn ON / OFF the circuit 22. It is turned on and the backup is started by the short-time storage battery 18. At this time, the set time timer 23 is activated at the same time. When the count value of the set time timer 23 reaches the end of life of the short-time discharge storage battery 18,
The set time timer 23 supplies an on signal to the on / off circuit 15, and when the on / off circuit 15 is turned on, backup is started by the storage battery 16 for long-term discharge, and an off signal is supplied to the on / off circuit 22. , The on / off circuit 22 is turned off, and the short-time discharge storage battery 18 is disconnected from the circuit.

As described above, by setting the dischargeable time of the short-time discharging storage battery in advance by the timer and controlling the switching between the short-time discharging storage battery and the long-time discharging storage battery, the first embodiment can be realized. Similar effects are obtained.

FIG. 7 shows a block diagram of the fifth embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In this embodiment, the charging circuits 26 and 27 are separately provided for the long-time discharging storage battery 16 and the short-time discharging storage battery 18, respectively.
Is provided so that the short-time discharge storage battery 18 can be charged by the long-time discharge storage battery 16 while the backup is performed by the long-time discharge storage battery 16.

The charging circuit 26 is composed of a diode or the like, and is configured to apply the output voltage of the PDU 12 to the long-term discharging storage battery 16 when the main power source is turned on to charge the long-time discharging storage battery 16.

The charging circuit 27 is composed of a switching unit with a control terminal of a transistor and is connected between the output of the converter 13 and the short-term storage battery 18, and its control terminal is the same as that of the on / off circuits 15 and 22. Is connected to the calendar timer 21 and is turned on / off by a charging control signal from the calendar timer 21.

The charging circuit 27 is turned on when the main power is turned on and when the on / off circuit 15 is on, that is, when the long-time discharging storage battery 16 is performing backup, and the long-time discharging storage battery 16 causes the short-time discharging storage battery 16 to operate. Charge 18

Therefore, the same effect as that of the first embodiment can be obtained, and when the backup is switched to the long-time discharge storage battery 16 after the backup by the short-time discharge storage battery 18, the backup is performed by the long-time discharge storage battery 16. Is performed and the short-time discharge storage battery 18 is charged, the next time the main power supply 11 is turned on, the short-time discharge storage battery is already charged to some extent by the long-time discharge storage battery. The charging time can be shortened.

In the present embodiment, the example applied to the second embodiment has been described, but it is needless to say that the present invention is not limited to this and can be applied to the first embodiment and the third and fourth embodiments.

FIG. 8 shows a block diagram of the sixth embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In the present embodiment, both the long-time discharge storage battery 16 and the short-time discharge storage battery 18 in the first embodiment are PDU.
It is connected between the converter 12 and the converter 13, and has the same effect as that of the first embodiment. However, at this time, the voltage of the short-time discharge storage battery 18 needs to be about the output voltage of the PDU 12.

In the present embodiment, the example applied to the first embodiment has been described, but it goes without saying that the present invention is not limited to this, and the second to fifth embodiments can have the same configuration.

FIG. 9 shows a block diagram of the seventh embodiment of the present invention. In the figure, the same components as those in FIG.
The description is omitted.

In the present embodiment, both the long-time discharge storage battery 16 and the short-time discharge storage battery 18 in the first embodiment are connected between the information processing device 14 and the same effect as in the first embodiment. . However, at this time, the voltage of the storage battery 16 for long-term discharge needs to be about the output voltage of the converter 13.

In the present embodiment, the example applied to the first embodiment has been described. However, the present invention is not limited to this, and it goes without saying that the second to fifth embodiments can also be configured with similar connections. .

[0082]

As described above, according to the present invention, a short-time discharge storage battery can be used for short-time backup, and a long-time discharge storage battery can be used for long-time backup. In addition to being able to perform any backup, it can be configured with the minimum necessary storage battery, and has the features of being able to reduce the size and reliability of the device.

[Brief description of drawings]

FIG. 1 is a principle block diagram of the present invention.

FIG. 2 is a configuration diagram of a first embodiment of the present invention.

FIG. 3 is a configuration diagram of a second embodiment of the present invention.

FIG. 4 is an operation explanatory diagram of the second embodiment of the present invention.

FIG. 5 is a configuration diagram of a third embodiment of the present invention.

FIG. 6 is a configuration diagram of a fourth embodiment of the present invention.

FIG. 7 is a configuration diagram of a fifth embodiment of the present invention.

FIG. 8 is a configuration diagram of a sixth embodiment of the present invention.

FIG. 9 is a configuration diagram of a seventh embodiment of the present invention.

FIG. 10 is a configuration diagram of a conventional example.

FIG. 11 is an explanatory diagram of a usage time zone of the information processing device.

FIG. 12 is a discharge frequency-discharge time characteristic diagram of a storage battery.

[Explanation of symbols]

 1,11 Main power supply unit 2 Load 3,16 Long-term discharge storage battery 4,18 Short-time discharge storage battery 5 Switching means 12 PDU 13 Converter 14 Information processing device 15 On / off circuit 17 Diode 19 Voltage detection circuit 20 Charging circuit

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Toshiaki Yamamoto 1015 Kamiodanaka, Nakahara-ku, Kawasaki City, Kanagawa, Fujitsu Limited (72) Inventor, Yuhiko Kizu 1015 Kamedotachu, Nakahara-ku, Kawasaki, Kanagawa Prefecture, Fujitsu Limited

Claims (8)

[Claims] 1. A backup power supply device for supplying power to a load (2) when a main power supply section (1) is disconnected, and a long-term storage battery (3) suitable for long-term discharge and a short-time discharge. If the disconnection of the main battery (1) and the storage battery (4) for short-time discharge suitable for, and the main power supply (1) is disconnected, the disconnection time of the main power supply (1) is long. When it is time, the long-term discharge storage battery (3) is connected to the load (2), and when the main power supply unit (1) is disconnected for a short time, the short-time discharge storage battery (4) is A backup power supply device comprising a connection control means (5) for connecting to a load (2). 2. The backup power supply device according to claim 1, wherein the storage battery (3) for long-term discharge comprises a lead battery. 3. The storage battery (4) for short-time discharge comprises a nickel-cadmium battery.
Alternatively, the backup power supply device according to item 2. 4. The connection control means (5) detects the voltage of the short-time discharge storage battery (4), and when the voltage of the short-time discharge storage battery (4) drops below a predetermined value, 4. The backup power supply device according to claim 1, wherein connection is switched to the discharge storage battery (3). 5. The connection control means (5) is configured to store the long-time discharge storage battery (3) and the short-time discharge storage battery according to a time schedule stored in advance when the main power supply unit (1) is disconnected. 4. The backup power supply device according to claim 1, wherein the backup power supply device is switched to (4). 6. The connection control means (5) connects the storage battery (4) for short time discharge when the main power supply (1) is disconnected, and then the storage battery (3) for long time discharge after a lapse of a predetermined time. The backup power supply device according to claim 1, further comprising: 7. The connection control means (5) uses the output of the main power supply unit (1) when the main power supply unit (1) is turned on, so that the long-term discharge storage battery (3) and the short-time discharge storage battery (3). The backup power supply device according to any one of claims 1 to 5, wherein the connection is controlled so as to charge 4). 8. The connection control means (5) detects switching from the short-time discharge storage battery (4) to the long-time discharge storage battery (3) when the main power supply section (1) is disconnected, 8. The backup power supply device according to claim 7, wherein connection control is performed according to the switching operation so as to charge the short-time storage battery (4) by the long-time discharge storage battery (3).