JP2000041346A - Uninterruptive power supply - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an uninterruptive power supply, capable of preventing in advance nonconformities of regenerating power of a storage battery under test to a commercial AC power supply side, resulting in attaining improvement of reliability by avoiding waste power consumption of the storage battery. SOLUTION: A diode 11 is provided in a current-carrying path from a PWM converter 2 over to a storage battery 3 and an inverter 4, a normally-closed contact 12 is connected in parallel to this diode 11, the output voltage of the PWM converter 2 is reduced on testing the battery 3, and also the normally- closed contact 12 is open when testing the storage battery 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an uninterruptible power supply that continues to supply power to devices regardless of a power failure of a commercial AC power supply.

[0002]

2. Description of the Related Art The configuration of a conventional uninterruptible power supply is shown in FIG. A PWM converter 2 is connected to a commercial AC power supply 1. The PWM converter 2 converts the voltage of the commercial AC power supply 1 into a DC voltage of an arbitrary level by switching using pulse width modulation (PWM).

A storage battery 3 and an inverter 4 are connected to an output terminal of the PWM converter 2. The storage battery 3 is used as a backup for a power failure of the commercial AC power supply 1, and is charged by the output voltage (DC voltage) of the PWM converter 2. Inverter 4 converts the output voltage of PWM converter 2 or the voltage of storage battery 3 into an AC voltage having a predetermined frequency by switching.

The output terminal of the inverter 4 has A
The C switch 5 is connected. A bypass circuit 6 is connected from the commercial AC power supply 1 to the AC switch 5.
The AC switch 5 selects and outputs one of the output voltage (AC voltage) of the inverter 4 and the commercial AC power supply voltage from the bypass circuit 6.

The operation will be described. The voltage of the commercial AC power supply 1 is converted into a DC voltage by the PWM converter 2. The storage battery 3 is float-charged by the DC voltage, and the DC voltage is supplied to the inverter 4. The DC voltage supplied to the inverter 4 is converted there into an AC voltage having a predetermined frequency, and output to the outside through the AC switch 5.

When the commercial AC power supply 1 fails,
The output voltage of M converter 2 becomes zero. When the output voltage of the PWM converter 2 becomes zero, the storage battery 3 is discharged, and the discharged voltage (DC voltage) is supplied to the inverter 4. The discharge voltage supplied to the inverter 4 is converted there into an AC voltage having a predetermined frequency, and output to the outside through the AC switch 5. With this external output, the operation of the load can be continued regardless of the power failure of the commercial AC power supply 1.

When a failure occurs in the PWM converter 2 or the inverter 4, the voltage of the commercial AC power supply 1 is directly output to the outside by switching the AC switch 5. There are two types of switching of the AC switch 5, that is, automatic operation based on failure detection and manual operation by maintenance personnel.

In such an uninterruptible power supply, when performing a deterioration judgment test of the storage battery 3, an operation of lowering the output voltage of the PWM converter 2 is performed, thereby discharging the storage battery under an actual load and discharging characteristics at that time. , The deterioration state of the storage battery is determined, and the discharge circuit is checked. It should be noted that power supply to the load is continued regardless of the performance of the deterioration determination test.

[0009]

In a deterioration judgment test for the storage battery 3, the output voltage of the PWM converter 2 is reduced to discharge the storage battery 3 under an actual load. At this time, the voltage of the storage battery 3 is higher than that of the PWM converter 2. The voltage becomes higher than the output voltage, and a part of the electric power stored in the storage battery 3 is not output to the load side but regenerated to the commercial AC power supply 1 through the PWM converter 2. The power stored in the storage battery 3 is wasted by this regeneration.

[0010] The present invention has been made in view of the above circumstances,
The purpose is to prevent a problem that the power of the storage battery is regenerated to the commercial AC power supply side during the test of the storage battery, thereby avoiding wasteful power consumption of the storage battery and improving reliability. It is to provide a power failure power supply.

[0011]

According to a first aspect of the present invention, there is provided an uninterruptible power supply which converts a voltage of a commercial AC power supply into a DC voltage, a storage battery connected to an output terminal of the converter, and the converter. An inverter connected to the output end of the battery and the storage battery to convert the output voltage of the converter or the voltage of the storage battery into an AC voltage; a backflow prevention means provided in a current path from the converter to the storage battery and the inverter; A contact connected in parallel with the prevention means; and means for reducing the output voltage of the converter when testing the storage battery, opening the contact, and closing the contact except when testing the storage battery.

[0012] The uninterruptible power supply of the invention according to claim 2 is:
A converter for converting the voltage of a commercial AC power supply to a DC voltage, a storage battery connected to the output terminal of the converter, and an output terminal of the converter and the storage battery connected to the storage battery. An inverter to be converted; a backflow prevention means provided in a current path from the converter to the storage battery and the inverter; a normally closed contact connected in parallel with the backflow prevention means; and an output of the converter when testing the storage battery. Test mode setting means for reducing the voltage; and control means for opening the contact when the output voltage of the converter decreases.

The uninterruptible power supply of the invention according to claim 3 is:
A converter for converting the voltage of a commercial AC power supply to a DC voltage, a storage battery connected to the output terminal of the converter, and an output terminal of the converter and the storage battery connected to the storage battery. An inverter to be converted; selecting means for selecting and outputting one of an output voltage of the inverter and a voltage of the commercial AC power supply; and a backflow preventing means provided on a current path from the converter to the storage battery and the inverter. A normally closed contact connected in parallel with the backflow prevention means; a test mode setting means for reducing the output voltage of the converter when testing the storage battery; and opening the contact when the output voltage of the converter is reduced. Operating control means. According to a fourth aspect of the present invention, in the uninterruptible power supply according to any one of the first to third aspects, the backflow prevention means is a diode.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. In the drawings, the same parts as those in FIG. 3 are denoted by the same reference numerals, and detailed description thereof will be omitted. As shown in FIG. 1, a diode 11 is provided as a backflow prevention means in a current path from the PWM converter 2 to the storage battery 3 and the inverter 4. The normally closed contact 12 is connected to the diode 11 in parallel.

As the normally closed contact 12, any of a mechanical contact of an electromagnetic contactor or a relay, a semiconductor contact element such as an IGBT, a MOSFET, an NPN transistor, and a PNP transistor may be used.

A test mode setting unit 1 is provided in the PWM converter 2.
0 is connected. The test mode setting unit 10 reduces the output voltage of the PWM converter 2 to a preset level for testing the storage battery 3 in response to a test mode setting operation by a clerk, and performs a PWM converter conversion in response to a test mode release operation by a clerk. 2 has the function of restoring the output voltage to the normal level.

A contact control unit 20 is connected to an output terminal of the PWM converter 2. The contact control unit 20 opens the normally closed contact 12 when the output voltage of the PWM converter 2 drops below a predetermined set value, and the output voltage of the PWM converter 2 is higher than the set value by a predetermined value or more. It has a function of restoring (closing) the normally closed contact 12 when it rises to the value.

Next, the operation of the above configuration will be described with reference to FIG. The voltage of the commercial AC power supply 1 is converted into a DC voltage by the PWM converter 2. Normally, the output voltage of the PWM converter 2 is higher than the set value by a predetermined value or more, so that the normally closed contact 12 is closed and a short circuit to the diode 11 is formed.

The output voltage of the PWM converter 2 is supplied to the storage battery 3 through the normally closed contact 12, and the storage battery 3 is float-charged. The output voltage of the PWM converter 2 is
The power is supplied to the inverter 4 through the normally closed contact 12, where it is converted into an AC voltage having a predetermined frequency. Then, the output voltage (AC voltage) of the inverter 4 is externally output through the AC switch 5. A load (not shown) is operated by this external output.

When the deterioration judgment test of the storage battery 3 is performed,
In the test mode setting unit 10, a test mode setting operation is performed by a staff member. When the test mode setting operation is performed,
The output voltage of the PWM converter 2 is reduced to a test level. With this reduction, the storage battery 3 starts real load discharge. The state of deterioration of the storage battery 3 can be determined by monitoring the discharge characteristics at this time with a measuring instrument or the like.
The discharge circuit can also be checked.

Regardless of the performance of the deterioration judgment test,
Power supply to the load is continued. In performing the deterioration determination test, a decrease in the output voltage of the PWM converter 2 is detected by the contact control unit 20, and the normally closed contact 12 is opened by the contact control unit 20.

When the normally closed contact 12 is opened, the diode 11 is turned on in the current path from the PWM converter 2 to the storage battery 3 and the inverter 4. Therefore, even in a situation where the voltage of the storage battery 3 becomes higher than the output voltage of the PWM converter 2, the action of preventing the backflow of the diode 12 works, and a part of the power stored in the storage battery 3 becomes P
It is possible to prevent a situation in which the power is regenerated to the commercial AC power supply 1 through the WM converter 2. Therefore, wasteful consumption of the power of the storage battery 3 can be avoided, and the power of the storage battery 3 can be effectively used for driving the load, and the reliability of the uninterruptible power supply can be improved.

When the attendant performs a test mode canceling operation in the test mode setting section 10, the output voltage of the PWM converter 2 is returned to the normal level. With this return, the discharge of the storage battery 3 ends, and the deterioration determination test ends.

At the end of this operation, an increase in the output voltage of the PWM converter 2 is detected by the contact control unit 20, and the normally closed contact 12 returns (closes). When the normally closed contact 12 returns, a short circuit to the diode 11 is formed, and PW
The output voltage of the M converter 2 passes through the normally closed contact 12 without passing through the diode 11 and the storage battery 3 and the inverter 4
Supplied to

A comparison between the conduction loss of power in the diode 11 and the conduction loss of power in the normally closed contact 12 shows that:
The diode 11 is larger than the normally closed contact 12. In order to minimize the conduction loss, a conduction path via the normally closed contact 12 is formed except during the test.

On the other hand, when the commercial AC power supply 1 is out of power, the output voltage of the PWM converter 2 becomes zero. PWM
When the output voltage of converter 2 becomes zero, storage battery 3 is discharged, and the discharged voltage (DC voltage) is supplied to inverter 4. The discharge voltage supplied to the inverter 4 is converted there into an AC voltage having a predetermined frequency, and output to the outside through the AC switch 5. With this external output, the commercial AC power supply 1
Regardless of the power failure, the operation of the load can be continued.

When a failure occurs in the PWM converter 2 or the inverter 4, the voltage of the commercial AC power supply 1 is output as it is by switching the AC switch 5. There are two types of switching of the AC switch 5, that is, automatic operation based on failure detection and manual operation by maintenance personnel.
The present invention is not limited to the above embodiment, and various modifications can be made without changing the gist.

[0028]

As described above, according to the present invention,
A backflow prevention means is provided in the current path from the converter to the storage battery and the inverter, and a contact is connected in parallel with the backflow prevention means.In testing the storage battery, the output voltage of the converter is reduced and the contact is opened. Since the contact is closed, it is possible to prevent a problem that the power of the storage battery is regenerated to the commercial AC power supply during the test of the storage battery, thereby avoiding wasteful power consumption of the storage battery and improving reliability. An uninterruptible power supply can be provided.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment.

FIG. 2 is a view for explaining the operation of the embodiment.

FIG. 3 is a diagram showing a configuration of a conventional device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Commercial AC power supply 2 ... PWM converter 3 ... Storage battery 4 ... Inverter 5 ... AC switch 11 ... Diode (backflow prevention means) 12 ... Normally closed contact 10 ... Test mode setting part 20 ... Contact control part

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Yuji Kawagoe 3-4-1 Shibaura, Minato-ku, Tokyo F-term in NTT Facilities (reference) 2G016 CA00 CB05 CC00 CC12 CC18 CC23 CD04 CD06 CD08 CD09 5G015 FA18 GA04 HA16 JA23 JA55 5G066 HA30 HB09 JA02 JB03 5H007 AA05 AA06 BB05 CC12 DA06 EA02 FA12 FA18

Claims (4)

[Claims] A converter for converting a voltage of a commercial AC power supply into a DC voltage; a storage battery connected to an output terminal of the converter; a storage battery connected to an output terminal of the converter and the storage battery;
An inverter for converting the output voltage of the converter or the voltage of the storage battery into an AC voltage; a backflow prevention means provided on a current path from the converter to the storage battery and the inverter; and a contact connected in parallel with the backflow prevention means. Means for reducing the output voltage of the converter when testing the storage battery, opening the contact, and closing the contact except during the test of the storage battery. A converter for converting a voltage of a commercial AC power supply into a DC voltage; a storage battery connected to an output terminal of the converter; an output terminal of the converter and the storage battery connected to the storage battery;
An inverter for converting the output voltage of the converter or the voltage of the storage battery into an AC voltage; a backflow prevention means provided on a current path from the converter to the storage battery and the inverter; a normally closed parallel connection with the backflow prevention means A contact, a test mode setting means for reducing the output voltage of the converter when testing the storage battery, and a control means for opening the contact when the output voltage of the converter decreases. Uninterruptible power system. A converter for converting a voltage of a commercial AC power supply into a DC voltage; a storage battery connected to an output terminal of the converter; a storage battery connected to an output terminal of the converter and the storage battery;
An inverter that converts the output voltage of the converter or the voltage of the storage battery to an AC voltage; a selection unit that selects and outputs one of the output voltage of the inverter and the voltage of the commercial AC power supply; Backflow prevention means provided in an energization path to an inverter; a normally closed contact connected in parallel with the backflow prevention means; test mode setting means for reducing the output voltage of the converter when testing the storage battery; and the converter Control means for opening the contact when the output voltage of the uninterruptible power supply decreases. 4. The uninterruptible power supply according to claim 1, wherein said backflow prevention means is a diode.