JP2006246610A - Method of charging instantaneous voltage drop compensator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To downsize the constitution of a device at large by contriving the method of charging an electric double layer capacitor before its initial start thereby reducing the capacitor of a chopper. <P>SOLUTION: In a condition that a breaker 8 is opened and a switch 9 is opened, a switch 12 is switched on to charge a DC capacitor 7 by means of a precharge circuit 11. Then, the breaker 8 is switched on and the switch 12 is opened, and a capacitor 10 is charged by a chopper 13 while controlling the DC voltage of the power converter 6 to be constant. Then, the chopper 13 is stopped and the switch 9 is switched on, and a capacitor 10 is charged with DC power that is obtained by operating the power converter 6 as a converter. Since the charge by the chopper 13 is only in the initial stage of the charge, the chopper 13 gets off with small capacity, and the device configuration is downsized. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for charging an instantaneous voltage drop compensator using an electric double layer capacitor in a DC power storage unit, and a device by devising a method for charging an electric double layer capacitor at the initial startup of the instantaneous voltage drop compensator. It is devised so that downsizing can be achieved.

  In recent years, with the spread of IT-related equipment and the increase of high-quality, high-value-added production lines such as semiconductors and precision equipment, the impact on these equipment due to instantaneous voltage drop (hereinafter referred to as “instantaneous drop”) is a problem. It has become.

  The instantaneous drop is a voltage drop that occurs while the power transmission and substation equipment cuts off this abnormal section so that when the abnormal current is generated by lightning strike to the power transmission tower, this abnormal current does not spread to others. This instantaneous drop occurs in an extremely short time of 70 [msec] to 2 [sec].

When such a momentary drop occurs,
(1) Computer malfunction (the computer automatically stops when a voltage drop occurs),
(2) Turn off the high-pressure mercury lamp,
(3) Stopping the motor using the magnet switch (the motor stops because the magnet switch is disconnected due to the voltage drop),
Such problems occur.

Many uninterruptible power supply devices are used as a measure against a sag. Lead storage batteries are often used for the power storage unit of this UPS, but recently, maintenance and inspection is not required compared to lead storage batteries, charging / discharging cycle life is long, and high speed and high efficiency charging / discharging is possible. The development of possible electric double layer capacitors is progressing rapidly. This electric double layer capacitor is a power storage element suitable for a purpose of charging / discharging for several seconds to several minutes.
Thus, focusing on these characteristics of the electric double layer capacitor, an instantaneous voltage drop compensation device using the electric double layer capacitor has been developed.

Here, a circuit configuration example of the instantaneous voltage drop compensator will be described with reference to FIG.
This instantaneous voltage drop compensator supplies power to the important load 2 when an instantaneous drop occurs in the commercial power supplied from the commercial power source 1 to the important load 2.

A high-speed switch 3 formed of GTO or the like is interposed in a power line L1 that supplies commercial power from the commercial power source 1 to the important load 2. The bypass circuit breaker 4 is interposed in the power line L1 so as to be in parallel with the high-speed switch 3.
Furthermore, a sag detector 5 that detects a sag is provided between the commercial power source 1 and the high-speed switch 3 (bypass circuit breaker 4) in the power line L1.

A DC capacitor (electrolytic capacitor) 7 is connected to the DC side of the power converter 6. The power converter 6 includes an inverter that can perform a reverse conversion operation (inverter operation) and a forward conversion operation (converter operation).
For this reason, at the time of reverse conversion operation, when DC power is supplied from the DC side (the left side of the power converter 6 in FIG. 1, that is, the side to which the DC capacitor 7 is connected), the inverter operates and the AC side ( In FIG. 1, AC power is output from the right side of the power converter 6, and during forward conversion operation, when AC power is supplied from the AC side, the converter operates to output DC power from the DC side.

  The AC side of the power converter 6 is connected to the important load 2 via the power line L2. A power converter input circuit breaker 8 is interposed in the power line L2.

  An electric double layer capacitor 10 that functions as a DC power storage unit is connected to the DC side of the power converter 6 via a power converter DC unit switch 9.

  The preliminary charging circuit 11 includes a rectifier circuit and a resistor, and the AC input side is connected to the power line L1 via the preliminary charging switch 12, and the DC output side is connected to the DC capacitor 7. For this reason, when the preliminary charging switch 12 is turned on and AC power is supplied from the commercial power source 1 to the preliminary charging circuit 11, the preliminary charging circuit 11 rectifies the AC power and outputs DC power. The DC capacitor 7 can be charged.

  The chopper 13 is connected in parallel with the power converter DC unit switch 9. The chopper 13 adjusts the voltage by performing chopping control on the DC power output from the power converter 6 to the DC side (DC capacitor 7 side), and supplies the voltage-adjusted DC power to the electric double layer capacitor 10. Charge the battery.

The control unit 20 controls the overall control operation of the instantaneous voltage drop compensation device.
When the sag detector 5 detects a sag, this sag detection signal is input to the controller 20.
In addition, the controller 20 performs on / off control of the switches (switches and circuit breakers) 3, 4, 8, 9, and 12. Further, the control unit 20 performs control to change the operation mode of the power converter 6.

  FIG. 2 shows another circuit configuration example of the instantaneous voltage drop compensation device. The instantaneous voltage drop compensator shown in FIG. 2 is different from that shown in FIG. 1 and does not have a chopper. The structure of other parts is the same as that shown in FIG.

  The operation / control mode of the instantaneous voltage drop compensator having the above configuration is roughly divided into the following five.

(1) Electric double layer capacitor initial charge control mode (2) Standby state mode (3) Instantaneous voltage drop compensation operation mode (4) Electric double layer capacitor charge control mode (5) Electric double layer capacitor full discharge control mode

Here, each control mode will be briefly described.
The electric double layer capacitor initial charge control mode is a mode in which the electric double layer capacitor 10 is charged at the initial startup of the apparatus. The detailed operation will be described later.

  The standby state mode is a mode after charging the electric double layer capacitor 10 to a predetermined rated voltage, and this apparatus normally maintains this state (a state in which no instantaneous drop occurs). In the standby state mode, the power converter 6 performs constant control of the rated voltage of the electric double layer capacitor while performing the voltage sag detection by the voltage sag detector 5.

In the voltage sag compensation operation mode, when the voltage sag detector 5 detects a voltage sag, the controller 20 opens the high-speed switch 3 and controls the power converter 6 from the constant voltage rating of the electric double layer capacitor to AC voltage control. The electric double layer capacitor 10 supplies power to the important load 2 instantaneously.
When the commercial power source 1 recovers, the AC output voltage of the power converter 6 and the system (commercial power source) voltage are synchronized, and the high-speed switch 3 is turned on when the phases match.

  In the electric double layer capacitor charge control mode, the power converter 6 performs electric double layer capacitor charge control so that the next instantaneous voltage drop can be dealt with as soon as the voltage drop compensation operation ends and the power supply from the system is switched. .

  The electric double layer capacitor complete discharge control mode is a mode in which the electric double layer capacitor 10 is completely discharged when performing maintenance of the apparatus or the like.

  The conventional charging method of the electric double layer capacitor at the initial startup of the instantaneous voltage drop compensator (the procedure of the electric double layer capacitor initial charge control mode) will be described separately for the device shown in FIG. 1 and the device shown in FIG. To do.

The charging method in the apparatus shown in FIG. 1 is as follows.
The initial state (stop state) of the instantaneous voltage drop compensator is as follows.
・ High-speed switch 3 ・ ・ ・ ・ ・ ・ ・ ・ ・ Open ・ Bypass circuit breaker 4 ・ ・ ・ ・ Input ・ Power converter input circuit breaker 8 ・ Open ・ Power converter DC switch 9 ... Open / pre-charge switch 12 ... Open

The equipment is started up according to the following procedure.
(1) The preliminary charging switch 12 is turned on and the DC capacitor 7 is charged by the preliminary charging circuit 11.
(2) The power converter input circuit breaker 8 is turned on.
When the power converter input circuit breaker 8 is turned on, the power converter 6 operates as a rectifier circuit, and a voltage about 1.35 times the system voltage is applied to the DC capacitor 7 on the DC side. At this time, before the power converter input circuit breaker 8 is turned on, the DC capacitor 7 is charged by the preliminary charging circuit 11 in advance (by the operation (1) above), and the voltage of the DC capacitor 7 is set to 1 of the system voltage. The voltage is about 35 times. For this reason, even if the power converter input circuit breaker 8 is turned on, no inrush current flows through the power converter 6 and it is safe.
If the power converter input circuit breaker 8 is turned on without precharging the DC capacitor 7, an inrush current flows through the power converter 6 and the power converter 6 is broken.
(3) The preliminary charging switch 12 is opened.
(4) The electric double layer capacitor 10 is charged by the chopper 13. In other words, the chopper 13 adjusts the voltage by performing chopping control on the DC power output to the DC side (DC capacitor 7 side) by the power converter 6 operating the rectifier circuit, and the voltage-adjusted DC power is The double layer capacitor 10 is supplied and charged.
(5) When charging is performed until the voltage of the electric double layer capacitor 10 reaches the capacitor rated voltage (for example, 400 V), the chopper 13 is stopped.
(6) Turn on the power converter DC switch 9.
(7) The power converter 6 is linked to the system. That is, the power converter 6 is set in a standby state in a state where the AC voltage generated from the power converter 6 is synchronized with the system voltage of the commercial power supply 1 (at this time, no AC current is output).
(8) Turn on the high speed switch 3 to open the bypass circuit breaker 4. Thereby, the start-up of the apparatus is completed.

The charging method in the apparatus shown in FIG. 2 is as follows.
The initial state (stop state) of the instantaneous voltage drop compensator is as follows.
・ High-speed switch 3 ・ ・ ・ ・ ・ ・ ・ ・ ・ Open ・ Bypass circuit breaker 4 ・ ・ ・ ・ Input ・ Power converter input circuit breaker 8 ・ Open ・ Power converter DC switch 9 ... Open / pre-charge switch 12 ... Open

The equipment is started up according to the following procedure.
(1) The power converter DC section switch 9 is turned on.
(2) The preliminary charging switch 12 is turned on, and the DC capacitor 7 and the electric double layer capacitor 10 are charged by the preliminary charging circuit 11.
(3) When the voltage of the DC capacitor 7 becomes about 1.35 times the system voltage by charging, the power converter input circuit breaker 8 is turned on.
(4) The preliminary charging switch 12 is opened.
(5) The power converter 6 is operated as a converter, and the DC power generated on the DC side of the power converter 6 is supplied to the electric double layer capacitor 10 for charging.
(6) When charging is performed until the voltage of the electric double layer capacitor 10 reaches the capacitor rated voltage (for example, 400 V), the converter operation of the power converter 6 is stopped.
(7) The power converter 6 is linked to the system. That is, the power converter 6 is set in a standby state in a state where the AC voltage generated from the power converter 6 is synchronized with the system voltage of the commercial power supply 1 (at this time, no AC current is output).
(8) Turn on the high speed switch 3 to open the bypass circuit breaker 4. Thereby, the start-up of the apparatus is completed.

  By the way, since the electric double layer capacitor 10 used as the DC power storage unit has a larger capacitance (charging capacity) than an electrolytic capacitor or the like, a large capacity charging device is required to charge the electric double layer capacitor 10. become.

  In the case of starting up the instantaneous voltage drop compensator shown in FIG. 1 by the above-described conventional method, the electric double layer capacitor 10 is charged only by the chopper 13, so that the chopper 13 has a large capacity. This is necessary, and the overall configuration of the instantaneous voltage drop compensator is increased.

  In addition, when the instantaneous voltage drop compensator shown in FIG. 1 is started up by the above-described conventional method, the voltage of the direct-current capacitor 7 becomes equal after the chopper 13 completes the charging of the electric double layer capacitor 10. The voltage is about 1.35 times the system voltage (a value obtained by diode rectifying the voltage of the commercial power supply). However, in order for the power converter 6 to perform grid-linked operation, the voltage on the DC side of the power converter 6 must be larger than the diode rectified value, but is actually a diode rectified value. For this reason, when the power converter 6 is started for system linkage operation, the power converter 6 is burdened and easily damaged.

  When the apparatus for starting up the instantaneous voltage drop compensation shown in FIG. 2 is started up by the above-described conventional method, the preliminary charging circuit 11 charges the DC capacitor 7 and the electric double layer capacitor 10. 11 has a large capacity, which increases the size of the entire instantaneous voltage drop compensator.

  An object of the present invention is to provide a charging method for an instantaneous voltage drop compensator capable of reducing the size of the apparatus in view of the above-described prior art.

The configuration of the present invention for solving the above problems is as follows.
A power converter that supplies AC power to the load via a power line when a voltage drop of a commercial power supply that supplies power to the load occurs;
A power converter input circuit breaker interposed in the power line;
A DC capacitor connected to the DC side of the power converter;
An electric double layer capacitor connected to the DC side of the power converter via a power converter DC switch;
A precharging circuit that converts commercial power received from the commercial power source through a precharging switch to DC power and charges the DC capacitor;
A chopper connected in parallel with the DC converter switch of the power converter, and supplying DC power adjusted in voltage by chopping control of DC power output to the DC side by the power converter to the electric double layer capacitor; A method for charging an instantaneous voltage drop compensator having:
Open the power converter input circuit breaker, open the power converter DC unit switch, turn on the preliminary charging switch and charge the DC capacitor by the preliminary charging circuit,
Turn on the power converter input circuit breaker, open the preliminary charging switch,
The electric power converter operates the rectifier circuit and supplies the electric power to the electric double layer capacitor with the DC power adjusted by the chopping control of the DC power output to the DC side by the chopper.
The chopper is stopped, the power converter DC switch is turned on, the power converter is operated as a converter, and the DC power output to the DC side is supplied to the electric double layer capacitor for charging. .

The configuration of the present invention is as follows.
A power converter that supplies AC power to the load via a power line when a voltage drop of a commercial power supply that supplies power to the load occurs;
A power converter input circuit breaker interposed in the power line;
A DC capacitor connected to the DC side of the power converter;
An electric double layer capacitor connected to the DC side of the power converter via a power converter DC switch;
A precharging circuit that converts commercial power received from the commercial power source through a precharging switch to DC power and charges the DC capacitor;
A chopper connected in parallel with the DC converter switch of the power converter, and supplying DC power adjusted in voltage by chopping control of DC power output to the DC side by the power converter to the electric double layer capacitor; A method for charging an instantaneous voltage drop compensator having:
Open the power converter input circuit breaker, open the power converter DC unit switch, turn on the preliminary charging switch and charge the DC capacitor by the preliminary charging circuit,
Turn on the power converter input circuit breaker, open the preliminary charging switch,
The power converter is operated with constant DC voltage control, and the DC power output to the DC side of the power converter is chopped and controlled by the chopper to supply DC power to the electric double layer capacitor for charging. And
The chopper is stopped, the power converter DC switch is turned on, the power converter is operated as a converter, and the DC power output to the DC side is supplied to the electric double layer capacitor for charging. .

  In the present invention, at the initial startup of the instantaneous voltage drop compensator, when charging the electric double layer capacitor that is a DC power storage unit, instead of charging only with a chopper, initially charging with a chopper, then, Since the electric double layer capacitor is charged by the DC power output from the power converter by the converter operation, the capacity of the chopper can be reduced, and the overall device configuration of the instantaneous voltage drop compensator can be reduced. Is possible.

  In addition, when charging the electric double layer capacitor with the chopper, not only the power converter is operated as a rectifier circuit, but also the power converter can be charged at a higher speed by operating with a constant DC voltage control.

The best mode for carrying out the present invention will be described below in detail based on examples.
The apparatus used in each embodiment is as shown in FIG. 1, and the apparatus itself is the same as the prior art.

The charging method according to Example 1 is as follows.
The initial state (stop state) of the instantaneous voltage drop compensator is as follows.
・ High-speed switch 3 ・ ・ ・ ・ ・ ・ ・ ・ ・ Open ・ Bypass circuit breaker 4 ・ ・ ・ ・ Input ・ Power converter input circuit breaker 8 ・ Open ・ Power converter DC switch 9 ... Open / pre-charge switch 12 ... Open

The apparatus start-up according to the first embodiment is performed according to the following procedure.
(1-1) The preliminary charging switch 12 is turned on and the DC capacitor 7 is charged by the preliminary charging circuit 11.
(1-2) The power converter input circuit breaker 8 is turned on.
When the power converter input circuit breaker 8 is turned on, the power converter 6 operates as a rectifier circuit, and the DC capacitor 7 on the DC side has a voltage about 1.35 times the system voltage (the voltage of the commercial power supply is a diode). The voltage of the rectified value is applied.
(1-3) The preliminary charging switch 12 is opened.
(1-4) The electric double layer capacitor 10 is charged by the chopper 13. In other words, the chopper 13 adjusts the voltage by performing chopping control on the DC power output to the DC side (DC capacitor 7 side) by the power converter 6 operating the rectifier circuit, and the voltage-adjusted DC power is The double layer capacitor 10 is supplied and charged.
(1-5) When the voltage difference between the voltage of the DC capacitor 7 and the voltage of the electric double layer capacitor 10 becomes small, the chopper 13 is stopped and the power converter DC switch 9 is turned on.
(1-6) The power converter 6 is operated as a converter, and the DC power generated on the DC side of the power converter 6 is supplied to the electric double layer capacitor 10 for charging.
(1-7) When charging is performed until the voltage of the electric double layer capacitor 10 reaches the capacitor rated voltage (for example, 400 V), the high-speed switch 3 is turned on to open the bypass circuit breaker 4. Thereby, the start-up of the apparatus is completed.

In the first embodiment, when the electric double layer capacitor 10 is charged to some extent by the chopper 13, the chopper 13 is stopped, and then the electric double layer capacitor 10 is charged by the power converter 6, so that the capacity of the chopper 13 is reduced. Thus, the device configuration of the instantaneous voltage drop compensator can be reduced in size.
For example, in the case of a device of 2000 kVA, when the electric double layer capacitor 10 is charged only by the chopper 13, the chopper 13 needs to have a capacity of 2000 kVA. Since it is not used, 100 kVA is sufficient as the capacity of the chopper 13.

  In the instantaneous voltage drop compensator shown in FIG. 2, since the DC capacitor 7 and the electric double layer capacitor 10 are charged by the precharge circuit 11, a large capacity is required as the precharge circuit 11. In Example 1, since the precharge circuit 11 only needs to charge the DC capacitor 7, the precharge circuit 11 having a small capacity can be adopted, and the overall configuration of the instantaneous voltage drop compensator can be reduced. Can do.

  Further, since the electric power converter 6 is operated as a converter to charge the electric double layer capacitor 10, the voltage of the DC capacitor 7 is 1.35 of the system voltage after the charging of the electric double layer capacitor 10 is completed. It is higher than about twice (value obtained by diode rectification of commercial power supply voltage). For this reason, when starting the power converter 6 for grid connection operation, a burden is not applied to the power converter 6 and the deterioration of the power converter 6 can be prevented.

The charging method according to Example 2 is as follows.
The initial state (stop state) of the instantaneous voltage drop compensator is as follows.
・ High-speed switch 3 ・ ・ ・ ・ ・ ・ ・ ・ ・ Open ・ Bypass circuit breaker 4 ・ ・ ・ ・ Input ・ Power converter input circuit breaker 8 ・ Open ・ Power converter DC switch 9 ... Open / pre-charge switch 12 ... Open

The apparatus start-up according to the second embodiment is performed according to the following procedure.
(2-1) The preliminary charging switch 12 is turned on and the DC capacitor 7 is charged by the preliminary charging circuit 11.
(2-2) The power converter input circuit breaker 8 is turned on.
When the power converter input circuit breaker 8 is turned on, the power converter 6 operates as a rectifier circuit, and the DC capacitor 7 on the DC side has a voltage about 1.35 times the system voltage (the voltage of the commercial power supply is a diode). The voltage of the rectified value is applied.
(2-3) The preliminary charging switch 12 is opened.
(2-4) The power converter 6 is operated with DC voltage constant control. That is, the power converter 6 is operated as a converter so as to make the DC side voltage constant. In this case, the DC side voltage is set to a value larger than a voltage about 1.35 times the system voltage (a voltage obtained by diode-rectifying a commercial power supply voltage). Thereby, the charging voltage of the DC capacitor 7 can be set to a value larger than a voltage about 1.35 times the system voltage (a voltage obtained by diode-rectifying the voltage of the commercial power supply).
(2-5) The electric double layer capacitor 10 is charged by the chopper 13. In other words, the chopper 13 adjusts the voltage by performing chopping control on the DC power output to the DC side (DC capacitor 7 side) by the power converter 6 performing the DC voltage constant control operation, and the voltage-adjusted DC power Is supplied to the electric double layer capacitor 10 for charging.
(2-6) When the voltage difference between the voltage of the DC capacitor 7 and the voltage of the electric double layer capacitor 10 becomes small, the chopper 13 is stopped and the power converter DC switch 9 is turned on.
(2-7) The power converter 6 is operated as a converter, and DC power generated on the DC side of the power converter 6 is supplied to the electric double layer capacitor 10 for charging.
(2-8) When charging is performed until the voltage of the electric double layer capacitor 10 reaches the capacitor rated voltage (for example, 400 V), the high-speed switch 3 is turned on to open the bypass circuit breaker 4. Thereby, the start-up of the apparatus is completed.

In the second embodiment, when the electric double layer capacitor 10 is charged to some extent by the chopper 13, the chopper 13 is stopped, and then the electric double layer capacitor 10 is charged by the power converter 6, so that the capacity of the chopper 13 is reduced. Therefore, the device configuration of the instantaneous voltage drop compensation device can be reduced in size.
For example, considering a 2000 kVA device, when the electric double layer capacitor 10 is charged only by the chopper 13, the chopper 13 needs to have a capacity of 2000 kVA. Since it is not used, a capacity of 100 kVA is sufficient.

  In the instantaneous voltage drop compensator shown in FIG. 2, since the DC capacitor 7 and the electric double layer capacitor 10 are charged by the precharge circuit 11, a large capacity is required as the precharge circuit 11. In Example 2, since the precharge circuit 11 only needs to charge the DC capacitor 7, the precharge circuit 11 having a small capacity can be adopted, and the overall configuration of the instantaneous voltage drop compensator can be reduced. Can do.

  Furthermore, since the electric power converter 6 is operated as a converter to charge the electric double layer capacitor 10, the voltage of the DC capacitor 7 is 1.35 of the system voltage after the charging of the electric double layer capacitor 10 is completed. It is higher than about twice (the value obtained by diode rectifying the voltage of the commercial power supply). For this reason, when starting the power converter 6 for grid connection operation, a burden is not applied to the power converter 6 and the deterioration of the power converter 6 can be prevented.

  Moreover, in Example 2, since the power converter 2 is drive | operated by DC voltage constant control, the charge of the electric double layer capacitor 10 by the chopper 13 can be performed rapidly.

The circuit block diagram which shows an instantaneous voltage drop compensation apparatus. The circuit block diagram which shows the other example of an instantaneous voltage drop compensation apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Commercial power supply 2 Important load 3 High speed switch 4 Pibus circuit breaker 5 Instantaneous voltage drop detection part 6 Power converter 7 DC capacitor (electrolytic capacitor)
DESCRIPTION OF SYMBOLS 8 Power converter input circuit breaker 9 Power converter DC part switch 10 Electric double layer capacitor 11 Precharge circuit 12 Precharge switch 20 Control part

Claims (2)

A power converter that supplies AC power to the load via a power line when a voltage drop of a commercial power supply that supplies power to the load occurs;
A power converter input circuit breaker interposed in the power line;
A DC capacitor connected to the DC side of the power converter;
An electric double layer capacitor connected to the DC side of the power converter via a power converter DC switch;
A precharging circuit that converts commercial power received from the commercial power source through a precharging switch to DC power and charges the DC capacitor;
A chopper connected in parallel with the DC converter switch of the power converter, and supplying DC power adjusted in voltage by chopping control of DC power output to the DC side by the power converter to the electric double layer capacitor; A method for charging an instantaneous voltage drop compensator having:
Open the power converter input circuit breaker, open the power converter DC unit switch, turn on the preliminary charging switch and charge the DC capacitor by the preliminary charging circuit,
Turn on the power converter input circuit breaker, open the preliminary charging switch,
The electric power converter operates the rectifier circuit and supplies the electric power to the electric double layer capacitor with the DC power adjusted by the chopping control of the DC power output to the DC side by the chopper.
The chopper is stopped, the power converter DC switch is turned on, the power converter is operated as a converter, and the DC power output to the DC side is supplied to the electric double layer capacitor for charging. Charge method of instantaneous voltage drop compensation device. A power converter that supplies AC power to the load via a power line when a voltage drop of a commercial power supply that supplies power to the load occurs;
A power converter input circuit breaker interposed in the power line;
A DC capacitor connected to the DC side of the power converter;
An electric double layer capacitor connected to the DC side of the power converter via a power converter DC switch;
A precharging circuit that converts commercial power received from the commercial power source through a precharging switch to DC power and charges the DC capacitor;
A chopper connected in parallel with the DC converter switch of the power converter, and supplying DC power adjusted in voltage by chopping control of DC power output to the DC side by the power converter to the electric double layer capacitor; A method for charging an instantaneous voltage drop compensator having:
Open the power converter input circuit breaker, open the power converter DC unit switch, turn on the preliminary charging switch and charge the DC capacitor by the preliminary charging circuit,
Turn on the power converter input circuit breaker, open the preliminary charging switch,
The power converter is operated with constant DC voltage control, and the DC power output to the DC side of the power converter is chopped and controlled by the chopper to supply DC power to the electric double layer capacitor for charging. And
The chopper is stopped, the power converter DC switch is turned on, the power converter is operated as a converter, and the DC power output to the DC side is supplied to the electric double layer capacitor for charging. Charge method of instantaneous voltage drop compensation device.

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