JP2000116029A - Backup power supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the efficiency and reliability of a backup power supply device for feeding power from a battery when an AC power supply fails. SOLUTION: A backup power supply device includes a power factor improvement circuit 2 for improving a power factor by switching control and for supplying an output DC voltage to a single or a plurality of DC-DC converters 51-5n, a battery 3, and a converter 4 for backup for supplying an output DC voltage to the DC-DC converters 51-5n from the battery 3 when the AC power supply 1 fails. The converter 4 for backup is started or set to a normal operating state according to the power failure detection signal of the AC power supply 1, and the output DC voltage is set to a lower value than the output DC voltage of the power factor improvement circuit 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a single or a plurality of D
The present invention relates to a backup power supply that supplies a C-DC converter with DC power from a battery when an AC power supply fails. In various information processing devices, the operating voltage is
A configuration in which the power is stabilized and supplied by a single or a plurality of DC-DC converters is used. Normally, a commercial AC power supply is converted to DC power and used as a DC power supply for the DC-DC converter. When the AC power supply fails, the battery is used as a DC power supply for the DC-DC converter to perform data backup processing and the like at the time of power failure. Will be done. In this case, the battery requires only a short backup,
A relatively small capacity is required. There is a demand for improving the efficiency of a power supply device that performs backup during such a power failure.

[0002]

2. Description of the Related Art FIG. 11 is an explanatory view of a conventional example.
A DC voltage is applied to a converter 74 from an AC power supply 71 of an AC voltage such as V via a power factor improvement circuit 72, and the converter 74 causes, for example, 48V slightly higher than the DC voltage from the battery 73 via the diode 78. Thereby, the AC power supply 7 is connected to one or more DC-DC converters 75 ₁ to 75 _n via the diode 77.
1 to supply the load 76 with
It outputs a stabilized DC voltage of 2V, 5V, 3V or the like. The power factor improving circuit 72 controls the AC current from the AC power supply 1 so as to approximate a sine waveform by switching control, thereby improving the power factor for the AC power supply 1.

When the AC power supply 71 fails, the converter 7
4, the DC voltage through the diode 77 decreases, and the DC voltage of the battery 73 that is higher than the DC voltage causes the DC-DC converters 75 _{1 to} 75 7 through the diode 78.
5 _n can be supplied with DC power. Thus, even when the AC power supply 71 fails, a stabilized DC voltage can be supplied from the DC-DC converters 75 ₁ to 75 _n to the load 76.

If the load 76 is, for example, any of various information processing apparatuses, a configuration is generally employed in which the data being processed is saved to a non-volatile memory such as a disk device when the AC power supply 71 fails, and the saving process is performed in a relatively short time. Can be completed. In this case, by inputting a DC voltage from the battery 73 to the DC-DC converters 75 ₁ to 75 _n via the diode 78, it is possible to continue information processing during a power failure of the AC power supply 71, If the capacity of the power supply is increased, it is possible to cope with the case where the power outage time is long. However, in general, a battery 73 having a capacity capable of supplying power only for a time that allows the minimum necessary processing is prepared.

[0005]

In the conventional backup power supply, the AC voltage of the AC power supply 71 is, for example, 220V.
Then, the output DC voltage of the power factor improvement circuit 72 is about 38
It becomes 0V. This output DC voltage is reduced by the converter 74 to, for example, the voltage of the battery 73 of 48 V,
The power is supplied to the C-DC converters 75 ₁ to 75 _n, and in the event of a power failure, the 48 V voltage of the battery 73 is supplied to the DC-DC converters 75 ₁ to 75 _n to perform backup.

In such a conventional configuration, for example, the efficiency of the power factor improving circuit 72 is η ₁ , the efficiency of the converter 74 is η ₂ , and the efficiencies of the DC-DC converters 75 ₁ to 75 _n are η _3. Then, the efficiency η ₀ of this power supply device is η ₀ =
η ₁ × η ₂ × η ₃ and the respective efficiencies are not 100%, so the overall efficiency η ₀ is low. That is, there is a problem that power loss is relatively large.

The output DC voltage of the power factor correction circuit 72 is about 3
80V is reduced to 48V, and each DC-DC converter 7
5 ₁ to 75 _n , the converter 74 and D
The DC current flowing between the C-DC converters 75 ₁ to 75 _n has a relatively large value, and a power loss proportional to the square of the current occurs. SUMMARY OF THE INVENTION It is an object of the present invention to supply an output DC voltage of a power factor correction circuit to one or a plurality of DC-DC converters as it is, thereby preventing a decrease in efficiency.

[0008]

The backup power supply of the present invention comprises: (1) a single or a plurality of DC-DC converters 5 from an AC power supply 1 via a power factor improvement circuit 2 for improving a power factor by switching control. _1-5 DC power is supplied to the _n, DC-DC converter 5 ₁ when the interruption of the AC power supply 1 -
5 A backup power supply device having a supply battery 3 DC power to _n, supplying an output DC voltage of the power factor improving circuit 2 in a single or multiple DC-DC converter 5 ₁ to 5 _n, and a battery 3 is provided with a backup converter 4 for making the output DC voltage of the power factor correction circuit 2 substantially the same as the output DC voltage. That is, the efficiency is improved by omitting the converter 74 of the conventional example that operates constantly, and the output DC voltage of the power factor correction circuit 2 is input to the DC-DC converter,
Power loss can be reduced.

Further, in the backup power supply, (2)
A configuration can be provided in which the backup converter 4 is activated by a power failure detection signal of the AC power supply 1.

In the backup power supply, (3)
A single or multiple DC-DC converters are connected to the power factor correction circuit 2 and the backup converter 4 via diodes 7 and 8, respectively.
Connect to DC converter 5 ₁ to 5 _n, with a constantly operating state the backup converter 5 ₁ to 5 _n,
The output DC voltage can be set lower than the output DC voltage of the power factor correction circuit.

In the backup power supply, (4)
A startup circuit for activating the backup converter 4 in response to a power failure detection signal of the AC power supply 1 and periodically activating the backup converter 4 for a predetermined time, and a backup converter when activated by the activation circuit And a voltage determination circuit for determining whether or not the output DC voltage is normal.

In the backup power supply, (5)
A startup circuit for activating the backup converter 4 in response to a power failure detection signal of the AC power supply 1 and periodically activating the backup converter 4 for a predetermined time, and a backup converter when activated by the activation circuit 4 to the power factor correction circuit 2
And a voltage determination circuit that supplies DC power from the battery 3 and determines whether the output DC voltage of the backup converter 4 is normal or not.

In the backup power supply, (6)
A startup circuit for activating the backup converter 4 in response to a power failure detection signal of the AC power supply 1 and periodically activating the backup converter 4 for a predetermined time, and a backup converter when activated by the activation circuit 4 to the power factor correction circuit 2
And a voltage determination circuit that supplies DC power from the battery 3 to determine whether the output DC voltage of the backup converter 4 is normal and whether the DC power supply from the battery is normal or not. And a configuration for checking the life of the device.

In the backup power supply, (7)
The backup converter 4 can be an insulating converter.

[0015]

FIG. 1 is an explanatory diagram of a first embodiment of the present invention, wherein 1 is an AC power supply, 2 is a power factor improvement circuit, 3
The battery, 4 backup converter, 5 ₁ to
5 _n is a DC-DC converter, 6 is a load, and 7 and 8 are diodes.

When the AC voltage of the AC power supply 1 is, for example, 220 V, the output DC voltage of the power factor correction circuit 2 is about 380 V. Single or multiple DC-DC converter 5 ₁ to 5
_n has a function of stabilizing the output DC voltage supplied to the load 6 even when the input DC voltage fluctuates. The backup converter 4 is configured so that, when the DC voltage of the battery 3 is, for example, 48 V, the output DC voltage approximates the output DC voltage of the power factor correction circuit 2.

For example, on the input side of the power factor improving circuit 2, a power failure detecting section having various known structures is provided.
Is determined to be a power failure of the AC power supply 1, the power failure detection signal is used as a start-up signal for the backup converter 4, and when the load 6 is an information processing device, the power failure is detected by the power failure detection signal. The processing of saving the data being processed is performed.

[0018] That is, if a configuration for starting the backup converter 4 during a power failure of the AC power supply 1 is inputted DC output voltage of the backup converter 4 via the diode 8 to the DC-DC converter 5 ₁ to 5 _n, each DC-
Stabilized DC voltage is subsequently supplied to the load 6 DC converter 5 ₁ to 5 _n.

When the backup converter 4 is always operated, a DC output voltage slightly lower than, for example, 380 V of the output DC voltage of the power factor improving circuit 2 is used. 2 from through the diode 7 DC-DC converter 5 ₁ to 5 _n, for example 3
An output DC voltage of 80 V is input, and at the time of a power failure, the output DC voltage of the power factor correction circuit 2 decreases.
It will be applied to the C-DC converter 5 ₁ to 5 _n.

In the case of both, if the AC power supply 1 is normal, for example, 380V output DC voltage power factor correction circuit 2 is directly supplied to the DC-DC converter 5 ₁ to 5 _n,
Compared to the conventional example, by a DC voltage or higher is supplied to the DC-DC converter 5 ₁ to 5 _n, current decreases even if the same power consumption. Therefore, power loss proportional to the square of the current can be reduced. Further, by not using a converter for stepping down the output DC voltage of the power factor correction circuit 2, it is possible to prevent a decrease in the overall efficiency.

FIG. 2 is an explanatory diagram of a power factor improving circuit, wherein 1 is an AC power supply, 21 is a rectifier circuit, 22 is a choke coil, 2
3 is a diode, 24 is a switching transistor,
25 is a capacitor, 26 is a resistor, and 27 is a switching control unit. The current is detected by the resistor 26, and the on / off of the switching transistor 24 is controlled by the switching control unit 27 so that the pulsed current does not flow.

At this time, the switching transistor 24
When the switching transistor 24 is turned off, the capacitor 25 is charged via the diode 23 by using the energy stored in the choke coil 22 when the switch 25 is turned on. Therefore, the terminal voltage of the capacitor 25, that is,
The output DC voltage is similar to the peak value of the AC voltage of the AC power supply 1. For example, if the AC voltage is E ₀ (effective value)
Then, the output DC voltage becomes approximately 2 ^1/2 · E ₀ .
Since various configurations of the power factor improving circuit have already been proposed in addition to the configuration shown in FIG. 2, those configurations can be applied to the present invention.

FIGS. 3A and 3B are explanatory diagrams of the operation of the first embodiment of the present invention. FIG. 3A shows the AC voltage of the AC power supply 1, FIG. 3B shows the output DC voltage of the power factor correction circuit 2, and FIG. Represents the output DC voltage of the backup converter 4, and (d) represents the DC current supplied from the backup converter 4, and shows a case where the backup converter 4 is activated by detecting a power failure.

As shown in (a), when the AC power supply 1 loses power at time t0, as shown in (b), the output DC voltage V0 of the power factor correction circuit 2 gradually decreases and at time t1, V
When it becomes 1, the power failure detection is performed, the backup power converter 4 is activated by the power failure detection signal, and the output DC voltage of the backup power converter 4 rapidly rises as shown in (c).

Then, at time t2 when the output DC voltage of the power factor improvement circuit 2 drops below V2 and the output DC voltage of the backup converter 4 becomes higher than V2, the backup converter 4 passes through the diode 8 via the diode 8. DC-
DC power is supplied to DC converter 5 ₁ to 5 _n,
DC current flows as shown in FIG.

When the power is restored at time t3, the power factor improving circuit 2
Output DC voltage rises rapidly, and the operation of the backup converter 4 is stopped by a detection signal due to power recovery. Therefore, the output DC voltage of the backup converter 4 gradually decreases from V4, and at time t4 when the output DC voltage of the power factor improvement circuit 2 becomes V3 and becomes higher than the output DC voltage of the backup converter 4. The DC current from the backup converter 4 also becomes zero.

FIG. 4 is a diagram for explaining the operation of the second embodiment of the present invention, and shows a case where the backup converter 4 is always operated. Also (a) ~
3D shows the AC voltage of the AC power supply 1, the output DC voltage of the power factor correction circuit 2, the output DC voltage of the backup converter 4, and the output DC current, as in the case of FIG. .

As shown in (a), when the AC power supply 1 fails at time t0, as shown in (b), the power factor
Output DC voltage gradually decreases from V0 to V1, V2,... According to times t1 and t2. Further, since the backup converter 4 is always operating, its output DC voltage maintains the value of V4 as shown in FIG. At time t2, the output DC voltage V2 of the power factor improving circuit 2 and drops below the output DC voltage V4 of the backup converter 4, the backup converter 4 via the diode 8 to the DC-DC converter 5 ₁ to 5 _n , (D), a direct current is supplied.

When the AC power supply 1 is restored at time t3, the output DC voltage of the power factor correction circuit 2 rapidly rises, and at time t4
When the output DC voltage of the backup converter 4 becomes equal to or higher than V4, the power factor improving circuit 2 outputs the DC-DC converter 5
DC current is supplied to _{1 to} 5 _n via a diode 7,
Since the diode 8 is in a reverse bias state, the DC current from the backup converter 4 stops.

FIG. 5 is an explanatory diagram of a third embodiment of the present invention. The same reference numerals as in FIG. 1 denote the same parts, 9 denotes a timer, and 10 denotes a voltage judgment circuit. In this embodiment, the backup converter 4 is configured to be activated by a power failure detection signal and periodically activated by a timer 9.

When started by the timer 9,
The voltage of the battery 3 is controlled so that the output DC voltage is lower than the output DC voltage of the power factor correction circuit 2, and the load current is not supplied. Also, when the power failure detection signal is activated, the output DC voltage can be configured to be lower than the output DC voltage of the power factor improvement circuit 2, and the output DC voltage of the power factor improvement circuit 2 decreases due to the power failure. , so that the output DC voltage of the backup converter 4 is supplied to the DC-DC converter 5 ₁ to 5 _n via the diode 8. It is also possible to configure so that the output DC voltage of the backup converter 4 becomes higher when activated by the power failure detection signal than when activated by the timer 9.

The voltage determination circuit 10 determines whether or not the output DC voltage of the backup converter 4 started by the timer 9 is within a predetermined range. Since this is due to a failure or a drop in the voltage of the battery 3, an alarm is sent out to notify a maintenance person. Therefore, when the AC power supply 1 is normal, it is possible to take an action such as repairing a failed portion at an early stage.

As described above, the backup converter 4 started by the timer 9 only when the AC power supply 1 is out of power.
Since the battery 3 and the battery 3 can be checked periodically, reliability can be improved. Also, at the time of this periodic check, the load 6
Since the current is not supplied to the battery 3, the normality can be economically checked without power consumption of the battery 3.

FIG. 6 is an explanatory view of the fourth embodiment of the present invention. The same reference numerals as in FIG. 5 denote the same parts, and reference numeral 11 denotes a battery life check circuit for the battery 3. This embodiment also has a configuration in which the backup converter 4 is activated by a power failure detection signal of the AC power supply 1, but when the backup converter 4 is activated by the timer 9, the power factor correction circuit 2 The output DC voltage is higher than the output DC voltage.

Therefore, the backup converter 4 started by the timer 9 is connected to the DC-
Some of the DC power is supplied to the DC converter 5 ₁ to 5 _n. The voltage determination circuit 10 determines whether or not the DC output voltage in a state where the current is supplied from the backup converter 4 is within a predetermined range. If the DC output voltage is within the predetermined range, it is determined that the DC output voltage is normal. However, in the case of this abnormality, a warning is sent to notify the maintenance person.

In this case, since the output DC voltage is checked while the load current is actually supplied from the backup converter 4, the normality check is performed in a state similar to that when the power supply is started by the power failure detection signal. It can be carried out.

The life check circuit 1 checks the voltage of the battery 3 while the load current is being supplied from the backup converter 4 periodically started by the timer 9.
1, the voltage when the load current is not supplied is compared with the voltage when the load current is supplied, and when the difference exceeds a predetermined range, the charge / discharge characteristics of the battery 3 are degraded. Judgment will be made and an alarm will be sent out. Therefore, it is possible to grasp the progress of the deterioration of the battery 3 and perform automatic maintenance so that the DC voltage can be reliably supplied to the DC-DC converters 51 to 5 _n even when the AC power supply ₁ fails.

FIG. 7 is an operation explanatory diagram of the third and fourth embodiments of the present invention. FIG. 7A is an explanatory diagram of the operation of the third embodiment shown in FIG. 5, in which the backup converter 4 is periodically started by the timer 9 and is operated only for the period T. The output DC voltage Va of the backup converter 4 rises rapidly but is controlled to a value lower than the output DC voltage V0 of the power factor correction circuit 2. Therefore, no load current is supplied.

Then, the voltage determination circuit 10 determines whether or not the output DC voltage Va of the backup converter 4 during the period T is within a predetermined range VA. If it is within the predetermined range VA, the backup converter 4 is determined to be normal. If it is not within the predetermined range VA, the backup converter 4 determines that it is abnormal and sends an alarm,
The maintenance person will be notified.

FIG. 7B is a diagram for explaining the operation of the fourth embodiment shown in FIG. 6, in which the backup converter 4 is periodically started by the timer 9 and is operated only for the period T. Then, the output DC voltage Vb of the backup converter 4 is controlled to be higher than the output DC voltage V0 of the power factor correction circuit 2. Therefore, the power factor improving circuit 2
The load current is supplied via the diode 8 during the period ta higher than the output DC voltage V0.

The voltage determination circuit 10 determines whether or not the DC output voltage Vb of the backup converter 4 in a state where the load current is supplied is within a predetermined range VB. However, if it is not within the predetermined range VB, it is determined that the backup converter 4 is abnormal and an alarm is sent out to notify the maintenance person.

The life check circuit 11 detects the voltage of the battery 3 during the period T, and determines the life of the battery 3 by the difference between the voltage in the state where the current is supplied from the battery 3 and the voltage in the no-load state. Can be determined.

FIG. 8 is an explanatory view of a main part of an embodiment of the present invention using a non-insulated converter.
3 is a battery, 4 is a backup converter, 5 is a DC-DC converter, 31 is a choke coil, 32 is a diode, 33 is a capacitor, 34 is a transistor,
Reference numeral 35 denotes a switching control unit.

The case where the backup converter 4 is a non-insulated boost converter including a choke coil 31, a diode 32, a capacitor 33, a transistor 34, and a switching control 35 is shown. Is not insulated by a transformer or the like. This non-isolated boost converter includes a transistor 3
When the transistor 34 is turned off by the stored energy of the choke coil 31 when the switch 4 is turned on, the capacitor 33 is charged via the diode 32, and the terminal voltage of the capacitor 33 is used as the output DC voltage. .

It is also possible to detect the terminal voltage of the capacitor 33 in the path indicated by the dotted line in the switching controller 35 and control the ON period of the transistor 34 to control the output DC voltage within a predetermined range. It is. Backup converter 4 using this non-insulated converter
Has a relatively simple configuration and can increase the voltage of the battery 3.

FIG. 9 is an explanatory view of a main part of an embodiment of the present invention using an insulation type converter. The same reference numerals as those in FIG. 8 denote the same parts, 41 is a transformer, 42 is a diode, 43
Is a capacitor, 44 is a transistor, and 45 is a switching control unit. This backup converter 4
The induced voltage of the secondary winding of the transformer 41 when the transistor 44 is turned off is rectified by the diode 42 by the energy stored in the transformer 41 when the transistor 44 is turned on by the switching control unit 45 to charge the capacitor 43. This is equivalent to the case where an isolated flyback converter is used.

In this case as well, the terminal voltage of the capacitor 43 is set as the output DC voltage, and as shown by the dotted arrow, detected by the switching control unit 45, the ON period of the transistor 41 is controlled, and the output DC voltage is set to a predetermined value. Can be controlled to a range. When the insulated converter is used as described above, the battery 41 and the power factor correction circuit 2
Are insulated from each other, which facilitates handling such as replacement of the battery 3 as compared with the case where a non-insulated converter is used.

FIG. 10 is an explanatory view of a main part of an embodiment of the present invention using an insulation type converter. The same reference numerals as in FIG. 9 denote the same parts, 51 is a transformer, 52, 56, 57 are diodes, 53 Is a capacitor, 54 is a transistor, 5
5 is a switching control unit, and 58 is a choke coil. This backup converter 4 rectifies the induced voltage of the secondary winding of the transformer 51 when the transistor 54 is turned on by the switching control unit 55 with the diode 52, and the capacitor 53 through the choke coil 58.
When the transistor 54 is turned off and the transistor 54 is turned off, the charge of the capacitor 53 is continued via the diode 56 by the energy stored in the choke coil 58, which is equivalent to the case of using an insulated forward converter.

Also in this case, the terminal voltage of the capacitor 53 is used as the output DC voltage, and the output DC voltage can be detected by the switching control unit 55 to control the ON period of the transistor 54. It is. Since the battery 3 side and the power factor correction circuit 2 side are insulated by the transformer 51, the battery 3
Replacement and maintenance becomes easy.

The present invention is not limited to only the above-described embodiments, but can be a combination of the embodiments. For example, the normality check by periodically starting the backup converter 4 can be performed. In the above, it is also possible to perform a check in a no-load state and a check in a loaded state in combination at a predetermined ratio. When the normality check is performed by the timer 9 on the backup converter 4 which is always in operation, the output DC voltage is controlled to be higher than the output DC voltage of the power factor correction circuit 2. It is also possible to adopt a configuration in which a check is performed based on a loaded state.

[0051]

As described above, according to the present invention, the power factor improving circuit 2 for improving the power factor of the AC power source 1 by switching control, and the output of the power factor improving circuit 2 from the battery 3 when the AC power source 1 fails. and a backup converter 4 for outputting an output DC voltage equivalent to the DC voltage, and supplies a DC voltage to a single or a plurality of DC-DC converter 5 ₁ to 5 _n, normally, power factor correction since it is intended to provide an output DC voltage to a single or a plurality of DC-DC converter 5 ₁ to 5 _n through the circuit 2, it is possible to reduce the power loss by the converter of the omission of the conventional example, the force by applying the output DC voltage of a relatively high voltage rate improving circuit 2 directly to the DC-DC converter 5 ₁ to 5 _n, the current is reduced for the same load power, it due to power loss There is an advantage that the reduction of it is possible.

The backup converter 4 operates only when the AC power supply 1 fails, and the power loss of the backup converter 4 can be ignored at all times.
There is an advantage that the efficiency as a whole can be improved.
Even when the backup converter 4 is always operated, by setting the output DC voltage lower than the output DC voltage of the power factor correction circuit 2, the no-load state is continued, and when the AC power supply 1 fails, the diode Power can be automatically supplied from the backup converter 4 to the DC-DC converters 5 _{1 to} 5 _n via the power converter 8.

Further, since the backup converter 4 is an insulated converter, the battery 3 can be insulated from the power factor correction circuit 2 side. Maintenance work such as replacement of 3 can be performed. In addition, the backup converter 4 is periodically started, and it is checked whether or not the output DC voltage of the backup converter is within a normal range by a voltage determination circuit or the like, thereby ensuring reliability. There is.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a first embodiment of the present invention.

FIG. 2 is an explanatory diagram of a power factor improvement circuit.

FIG. 3 is an operation explanatory diagram of the first embodiment of the present invention.

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

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

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

FIG. 7 is an operation explanatory diagram of the third and fourth embodiments of the present invention.

FIG. 8 is an explanatory view of a main part of an embodiment of the present invention using a non-insulated converter.

FIG. 9 is an explanatory view of a main part of an embodiment of the present invention using an insulating converter.

FIG. 10 is an explanatory view of a main part of an embodiment of the present invention using an insulation type converter.

FIG. 11 is an explanatory diagram of a conventional example.

[Explanation of symbols]

1 AC power supply 2 power factor correction circuit 3 Battery 4 backup converter 5 ₁ ~5 _n DC-DC converter 6 Load 7,8 diode

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference) EE10 EE54 EE61 FD01 FD11 FD41 FG05 FG26

Claims (7)

[Claims] 1. An AC power supply through a power factor improving circuit for improving a power factor by switching control.
A backup power supply device that supplies DC power to the DC converter and has a battery that supplies DC power to the DC-DC converter when the AC power supply fails; A backup power supply, comprising: a backup converter that supplies the DC voltage of the battery to one or more DC-DC converters and makes the DC voltage of the battery substantially the same as the output DC voltage of the power factor correction circuit. apparatus. 2. A power failure detection signal of the AC power supply,
2. The backup power supply according to claim 1, further comprising a configuration for activating the backup converter. 3. The power factor improving circuit and the backup converter are connected to the single or plural DC-DC converters via diodes, respectively, so that the backup converter is always in operation and the output DC 2. The backup power supply according to claim 1, wherein a voltage is set lower than an output DC voltage of the power factor correction circuit. 4. A power failure detection signal of the AC power supply,
A starting circuit for activating the backup converter periodically for a predetermined period of time, and whether or not an output DC voltage of the backup converter when activated by the starting circuit is normal; 2. The backup power supply device according to claim 1, further comprising: a voltage determination circuit for determining the power supply voltage. 5. A power failure detection signal of the AC power supply,
A starting circuit for activating the backup converter periodically for a predetermined period of time, and an output DC voltage of the backup converter when activated by the starting circuit, for improving the power factor. 2. A voltage determining circuit for setting a higher output DC voltage than a circuit to supply DC power from the battery and determining whether or not the output DC voltage of the backup converter is normal. The backup power supply as described. 6. A power failure detection signal of the AC power supply,
A starting circuit for activating the backup converter periodically for a predetermined period of time, and an output DC voltage of the backup converter when activated by the starting circuit, for improving the power factor. A voltage determining circuit for setting the output DC voltage higher than the circuit to supply DC power from the battery and determining whether the output DC voltage of the backup converter is normal; and determining whether the DC power supply from the battery is normal. 2. The backup power supply device according to claim 1, further comprising a configuration for performing a service life check. 7. The backup power supply device according to claim 1, wherein the backup converter is an insulated converter.