JP4774961B2 - Uninterruptible power system - Google Patents

Description

  The present invention relates to an uninterruptible power supply that supplies power to a load when a commercial power supply is abnormal.

In conventional uninterruptible power supplies, AC power is supplied to the load from an AC power source through a converter with a large-capacity capacitor connected between the DC output terminals and a voltage-type inverter with an antiparallel diode connected to each arm. In the uninterruptible power supply, the initial charge control means that controls the phase of the current so that the charge current of the large-capacity capacitor does not become excessive during the initial charge of the large-capacitance capacitor, and the complete discharge of the large-capacitance capacitor when the device stops Sometimes, there is provided a complete discharge control means for performing current control so that the discharge current of the large-capacity capacitor does not become excessive (see, for example, Patent Document 1).
When fully discharging the large-capacitance capacitor for the backup power supply, one or both of the following is selected. One of them turns on one of the switches, controls the current with a converter, and flows a regenerative current to the AC power supply. In the other case, the other switch is turned on, the inverter is controlled as a current control type inverter, and a regenerative current is supplied to the AC power supply. Then, after the large-capacitance capacitor is almost completely discharged, the other switches are turned off to completely discharge using the exciting impedance of the transformer.

Japanese Unexamined Patent Publication No. 7-244104

When the capacitor unit is maintained, it is necessary to completely discharge the capacitor unit. For this reason, the PN is eventually short-circuited. The following relationship needs to be satisfied between the capacitor capacitance C [F] and the capacitor voltage V [V] immediately before the short circuit. (UL1778 31.7)
0.5 × C × V ^ 2 ≦ 20 [J] (1)
For example, if C = 50 [F],
It is necessary to discharge the capacitor until V ≦ 0.89 [V].
In the conventional uninterruptible power supply, since the capacitor unit is discharged by the above method, when the capacitor voltage becomes low, the switch off time becomes long. In addition, when other switches are turned off and complete discharge is performed using the excitation impedance of the transformer, the discharge current decreases as the capacitor voltage decreases. Therefore, there is a problem that it takes time to discharge to a voltage satisfying the above expression (1).

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain an uninterruptible power supply device that can completely discharge a capacitor unit in a short time.

In the uninterruptible power supply according to the present invention, the commercial power supply normally supplies power to the load via the semiconductor switch, and the capacitor unit for backup power supply and one end are connected to the capacitor unit. The other end includes a transformer and a bidirectional converter connected to the power system via another switch, and the bidirectional converter charges the capacitor unit in a DC voltage controlled state, and an abnormality occurs in the commercial power supply. Detecting it, switching the bidirectional converter from the DC voltage control state to the AC voltage control state, and shutting off the semiconductor switch, when the capacitor unit is completely discharged, the bidirectional converter is switched to the current control state. When the regenerative current is supplied to the commercial power supply and the voltage of the capacitor unit falls below the set voltage 1 of the voltage on the bidirectional converter side of the transformer, When the switch is opened so that the capacitor unit is not charged from the power system, and is discharged by the excitation impedance of the transformer. When the voltage of the capacitor unit further decreases and becomes lower than the set voltage 2 lower than the set voltage 1 The capacitor unit is completely discharged by switching to a short-circuit control state in which all of the P-side element and N-side element of the bidirectional converter are simultaneously turned on and short-circuiting the PN of the capacitor unit.

According to the present invention, when the capacitor unit is discharged, the bidirectional converter is switched to the current control state , the regenerative current is supplied to the commercial power source, and the voltage of the capacitor unit is equal to or lower than the set voltage 1 of the voltage on the bidirectional converter side of the transformer. At that time, the other switch is opened so that the capacitor unit is not charged from the power system, and is discharged by the excitation impedance of the transformer. If the set voltage is lower than 2, the capacitor unit is completely discharged by switching to the short-circuit control state in which all of the P-side element and N-side element of the bidirectional converter are simultaneously turned ON, and shorting the PN of the capacitor unit. As a result, the complete discharge time of the capacitor unit can be shortened.

Embodiment 1 FIG.
A first embodiment of the present invention will be described below with reference to FIG. At all times, the commercial power supply 1 supplies power to the load 2 via the semiconductor switch 3. The bidirectional converter 4 is in a DC voltage control state and charges the capacitor unit 5.
When an abnormality occurs in the commercial power source 1, the voltage abnormality detection circuit 7 detects that the input voltage measured by the VT 6 is abnormal. When an abnormality is detected by the voltage abnormality detection circuit 7, a signal for switching the DC voltage control state to the AC voltage control state is output to the bidirectional converter 4. At the same time, a cutoff signal is sent to the switch 3.
When discharging the capacitor unit 5, the bidirectional converter 4 is switched to the current control state, and a regenerative current is supplied to the commercial power source 1. When the voltage of the capacitor unit 5 drops to the set voltage 1, the switch 9 is opened and discharged by the excitation impedance of the transformer 8. Also at this time, the bidirectional converter 4 operates in a current control state. When the voltage of the capacitor unit 5 further decreases and becomes the set voltage 2 or less, the bidirectional converter 4 is switched to a short-circuit control state in which the P-side element and the N-side element are simultaneously turned on, and the PN of the capacitor unit 5 is short-circuited. Discharge completely.

Next, the operation of the bidirectional converter 4 in the short-circuit control state will be described with reference to FIG. When the voltage of the capacitor unit 5 becomes equal to or lower than the set voltage 2, an ON command is simultaneously issued to each converter element 11, 12, 21, 22, 31, 32 of the bidirectional converter 4 to short-circuit the PN of the capacitor unit 5. To completely discharge.
As an example, the capacitance of the capacitor unit 5 is 50 [F], the internal resistance is 20 [mΩ], the rated line voltage on the bidirectional converter side of the transformer 8 is 300 [V], and each conversion of the bidirectional converter 4 is performed. The operation when the rated current of the device elements 11, 12, 21, 22, 31, 32 is 1000 [A] will be described.
The set voltage is
Setting voltage 1 = √2 × 300 = 424 [V]
Setting voltage 2 = 1000 × 20/1000 × 3 = 60 [V] (2)
Set to If the voltage on the bidirectional converter side of the transformer 8 is higher than the voltage of the capacitor unit 5, the capacitor unit 5 is charged through the diodes 13, 14, 23, 24, 33, 34 of the bidirectional converter 4. . Therefore, when the voltage of the capacitor unit 5 becomes equal to or lower than the maximum voltage 424V on the bidirectional converter side of the transformer 8, the switch 9 is opened so that the capacitor unit 5 is not charged from the system. The discharge is performed by the excitation impedance of the transformer 8.
If the P-side element and the N-side element of the bidirectional converter 4 are simultaneously turned on while the voltage of the capacitor unit 5 is high, the converter element is damaged due to overcurrent. From the internal resistance of the capacitor unit 5 and the rated current of the converter element, the voltage of the capacitor unit 5 that can simultaneously turn on the P-side element and the N-side element of the bidirectional converter 4 is obtained. The reason why it is multiplied by 3 in the above equation (2) is to turn on simultaneously for three phases. By simultaneously turning on the converter elements 11, 12, 21, 22, 31, and 32 of the bidirectional converter 4, the capacitor unit 5 can be completely discharged instantaneously from 60V.

It is a schematic block diagram which shows the uninterruptible power supply in Embodiment 1 of this invention. It is a block diagram which shows the detail of the uninterruptible power supply in Embodiment 1 of this invention.

Explanation of symbols

1 Commercial Power Supply 2 Load 3 Semiconductor Switch 4 Bidirectional Converter 5 Capacitor Unit 6 VT
7 Voltage Abnormality Detection Circuit 8 Transformer 9 Switch 11, 12, 21, 22, 31, 32 Converter Element 13, 14, 23, 24, 33, 34 Diode

Claims (1)

Normally, the commercial power supply supplies power to the load via a semiconductor switch. The capacitor unit for the backup power source, one end is connected to the capacitor unit, and the other end is connected to the transformer and other switches. A bidirectional converter connected to a power system via the bidirectional converter, the bidirectional converter charging the capacitor unit in a DC voltage controlled state, and detecting an abnormality in the commercial power supply to detect both In the uninterruptible power supply that switches the direction converter from the DC voltage control state to the AC voltage control state and shuts off the semiconductor switch,
When fully discharging the capacitor unit, the bidirectional converter is switched to a current control state, a regenerative current is supplied to the commercial power source, and the voltage of the capacitor unit is set to the voltage on the bidirectional converter side of the transformer. When it becomes 1 or less, the other switch is opened so that the capacitor unit is not charged from the electric power system, discharged by the excitation impedance of the transformer, and the voltage of the capacitor unit further decreases. By switching to a short-circuit control state in which all of the P-side element and N-side element of the bidirectional converter are simultaneously turned ON when the set voltage 2 is lower than the set voltage 1, and short-circuiting the PN of the capacitor unit, An uninterruptible power supply, wherein the capacitor unit is completely discharged.

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