JPH08103036A - Apparatus to cope with instantaneous voltage drop - Google Patents

Abstract

PURPOSE: To enable compensating operation of an inverter and eliminate control failure due to the false detection of load current, by providing a re-arc- extinguishing circuit that supplies arc-extinguishing pulses of the polarity opposite to a latched polarity from the inverter to a thyristor bypass switch again when the overcurrent in inverter output is detected. CONSTITUTION: An inverter overcurrent detecting circuit 8 judges whether there is overcurrent in an inverter 3. If an inverter overcurrent is detected, the present polarity of load current iL, judged by a current transformer CT, is latched into a latch circuit 11, and a thyristor is subjected to re-arc extinguishing with arc-extinguishing pulses of the polarity opposite to the latched polarity. Thereafter, it is judged whether the overcurrent detection by the inverter overcurrent detecting circuit 8 has ceased. If no overcurrent is thereby detected, it is started to supply the inverter 3 with a compensation voltage according to the command from a voltage detecting circuit 7. This maintains a rated load voltage by means of compensation voltage through an injection transformer 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention is
Regarding an instantaneous voltage drop countermeasure device that compensates for the shortage of voltage by an inverter inserted and connected in series to the power supply line, especially for the thyristor bypass switch that short-circuits the output side of the inverter during normal operation, The present invention relates to an arc extinguishing system that surely shuts off the wire in order to enable it.

[0002]

2. Description of the Related Art When a voltage of a power supply line is temporarily reduced due to a large-capacity load or an instantaneous ground fault, a semiconductor manufacturing line or the like suffers great damage due to line stoppage, defective product generation, restoration work, or the like. Sometimes. When operating a production facility or the like in which the amount of damage increases due to an instantaneous voltage drop, an instantaneous voltage drop countermeasure device 1 as shown in FIG. 3 is used for the purpose of compensating for the insufficient voltage and maintaining the system at the rated voltage. used.

This is because when the voltage of the power supply line 2 drops, the voltage of the capacitor C for power storage is synchronized by the inverter 3 with the system power supply E _S and becomes an AC compensation voltage of a magnitude corresponding to the undervoltage. Convert and through injection transformer 4,
This capacitor C is supplied in series to the power supply line.
It is slowly charged with the system voltage via the rectifier 5 in normal times.

In the above-mentioned device 1, when the voltage of the system is normal, the thyristor bypass switches A and B connected in antiparallel to the output terminal of the compensation voltage (secondary side of the injection transformer 4) are turned on, and the load 6 Power is directly supplied from the regular power source E _S.

However, when the instantaneous voltage drop is detected and the compensation voltage is output from the inverter 3, the thyristor bypass switches A and B must be cut off in advance. For this reason, conventionally, the procedure as shown in FIG. 4 is performed before the output of the inverter.

First, the presence or absence of an instantaneous voltage drop is determined. If there is an instantaneous voltage drop, the current transformer CT attached to the power supply line 2 determines the current polarity of the load current.
As a result, it can be known whether the conducting thyristor is A or B. The thyristor firing pulse is then stopped to prevent re-ignition.

Further, an arc extinguishing pulse is supplied from the inverter 3 to the thyristor to extinguish the arc. This arc extinguishing pulse is performed by supplying a reverse voltage of a constant level to both ends of the thyristor in the conductive state via the injection transformer 4, and its polarity is determined by the polarity of the load current determined above.

After that, it is output to the inverter, and it is determined whether or not this output is an overcurrent. This determination is
This is performed by an overcurrent detection circuit provided in the inverter for detecting a defect in the inverter itself.

If the overcurrent is not detected, the supply of the compensation voltage from the inverter 3 through the injection transformer 4 is started to maintain the voltage applied to the load 6 at the rated voltage. This is the case for successful compensation.

On the other hand, when the overcurrent of the inverter is detected as described above, the inverter is stopped and the inverter overcurrent signal (OC) is notified. This is the case if the compensation fails.

[0011]

In the above configuration, when the inverter overcurrent is detected after the thyristor is extinguished, the operation of the inverter is stopped and the compensation fails. Originally, the detection of the inverter overcurrent should be performed only as a countermeasure against the defect of the inverter itself such as the arm short circuit.

However, the arc-extinguishing operation of the thyristor may fail, and in this case, an inverter overcurrent is detected due to a short circuit on the output side of the inverter, so that the same processing as when the inverter itself is defective and the inverter 3 operates normally. However, there was a problem that compensation was not provided.

The cause of the failure of the thyristor arc extinguishing is, as shown in FIG. 5, when the instantaneous voltage drop occurs near the zero point of the load current, due to the phase shift that the load current detecting CT has due to manufacturing restrictions. , By misjudging the polarity of the thyristor to be extinguished.

For example, assuming that the CT detection phase advances by θ, when the polarity of the actual load current i _L changes from positive (thyristor A conducts) to negative (thyristor B conducts),
The detection polarity of CT is changed from positive to negative by an amount of θ, and there is a time II of erroneous determination as negative although it is positive.

If an instantaneous voltage drop occurs at this time II, it is determined to be negative even though the polarity of the actual load current is positive, and the thyristor B is extinguished. This arc extinguishing pulse is caused by the conducting thyristor A.
However, since it becomes a forward voltage, the arc cannot be extinguished, and the compensation failure due to the inverter overcurrent will occur.

Therefore, according to the present invention, in the case of inverter overcurrent detection due to incorrect polarity determination, re-extinguishing enables inverter compensation operation, eliminating unnecessary inverter overcurrent notification and inverter stop, and instantaneous The purpose is to improve the reliability of the voltage drop countermeasure device.

[0017]

According to the present invention, an inverter for voltage compensation is inserted and connected in series to a power supply line, and an antiparallel thyristor bypass switch is provided on the output side of this inverter so that the power supply voltage to a load is reduced. When it is normal, the switch is kept short-circuited and power is directly supplied from the power source to the load.When the power supply voltage to the load drops, the supply of the ignition pulse to the switch is stopped and In the instantaneous voltage sag countermeasure device that supplies the extinguishing pulse corresponding to the polarity of the load current detected at this time from the inverter to extinguish, and then compensates and supplies the shortage of voltage by the inverter. When a decrease in the supply voltage to is detected, a latch circuit that latches the polarity of the load current detected at this time,

After the supply of the arc-extinguishing pulse based on this polarity,
When an overcurrent of the inverter output is detected, a re-extinguishing circuit for supplying an extinguishing pulse corresponding to the polarity opposite to the latched polarity from the inverter to the thyristor bypass switch again is provided. To do.

[0019]

When the inverter overcurrent is detected after the thyristor is extinguished, the inverter supplies the thyristor bypass switch with an arc extinguishing pulse having a polarity opposite to the polarity used for extinguishing the arc.

If the detection of the inverter overcurrent is due to the fact that the polarity of the arc extinguishing is wrong, the current arc extinguishing should succeed, and the inverter overcurrent will not be detected and the compensation will be successful. When the inverter overcurrent is detected despite the resupply of the arc-extinguishing pulse whose polarity has been changed, the inverter itself has a failure, and an alarm is issued to stop the inverter.

If the compensation is successful due to the re-supply of the arc-extinguishing pulse, the inverter overcurrent is not issued and the inverter is not stopped, so that the control failure due to the erroneous detection of the load current is eliminated. .

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention compensates for an instantaneous voltage drop in the instantaneous voltage drop countermeasure device 10 shown in FIG. 1 by the procedure shown in FIG.

FIG. 1 shows a conventional device shown in FIG. 3, in which a latch circuit 11 for storing the polarity of a load current detected at the time of instantaneous voltage drop, and a re-extinguishing for re-extinguishing by reversing the polarity when the extinguishment fails. The arc circuit 12 is added, and the same or equivalent parts as those of the apparatus of FIG. 3 are designated by the same reference numerals. Further, a voltage detection circuit 7 and an inverter overcurrent detection circuit 8 which are not shown in the circuit of FIG. 3 are also shown.

The voltage detection circuit 7 detects the voltage of the power supply line 2 and generates a detection signal of an instantaneous voltage drop and a command signal of the phase and magnitude of the compensation voltage. The inverter overcurrent detection circuit 8, which outputs when the output current of the inverter exceeds a predetermined reference value exceeding the rating, is usually provided in the inverter for detecting the failure of the inverter itself.

The flow chart of FIG. 2 will be described in order with reference to FIG. In the following description, ~ indicates that the process is the same as the process described with the same reference numeral in FIG.
"," Is a process unique to the present invention.

First, the voltage detection circuit 7 determines whether or not there is an instantaneous voltage drop. If there is an instantaneous voltage drop, power supply line 2
The current load current i _L
The polarity of is determined (determination of the conducting thyristors A and B). The thyristor firing pulse is then stopped to prevent re-ignition. Then, the current polarity of the load current i _L determined by the current transformer CT is latched in the latch circuit 11 to prepare for re-extinction.

Further, an arc-extinguishing pulse is applied to the thyristor from the inverter 3 via the injection transformer 4, and an arc-extinguishing voltage of reverse polarity is applied to both ends of the thyristor during energization. After this, check whether the inverter is overcurrent.
It is determined by the inverter overcurrent detection circuit 8.

If the overvoltage is not detected, the supply of the compensation voltage commanded by the voltage detection circuit 7 is started to the inverter. As a result, the load voltage can be maintained at the rated value by the compensation voltage that is inserted and compensated in series through the injection transformer 4. This is the case of successful compensation.

On the other hand, when the inverter overcurrent is detected at "," the thyristor is extinguished again by the extinguishing pulse having the opposite polarity to the latched pulse at "". After that, it is determined whether or not the overcurrent detection by the inverter overcurrent detection circuit 8 is stopped.

As a result, if the overcurrent is not detected, the state shifts to the above-mentioned state where the compensation voltage by the inverter is started. This is the case where compensation was successful due to re-extinguishing.

If an overcurrent is detected by "in spite of changing the polarity and extinguishing the arc again, it is considered that the inverter itself is not operating properly, rather than the error in the polarity determination of the load current. Current signal (OC) is issued,
Stop the output of the inverter. This is the case when the compensation operation fails.

[0032]

As described above, according to the present invention, by mistakenly determining the polarity of a conducting thyristor, the failure of the arc extinguishing operation of the thyristor bypass switch performed prior to the compensation operation of the inverter is re-extinguished with the opposite polarity. Resolve by
Therefore, it is possible to eliminate the occurrence of the inverter overcurrent and the inverter stop due to the above polarity determination error, and it is possible to improve the control accuracy of the instantaneous voltage drop countermeasure device.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an example of connection of an instantaneous voltage drop countermeasure device of the present invention to a system.

FIG. 2 is a flowchart showing an operation procedure at the start of compensation of the instantaneous voltage drop countermeasure device of the present invention.

FIG. 3 is a circuit diagram showing an example of connection of a conventional instantaneous voltage reduction countermeasure device to a system.

FIG. 4 is a flowchart showing an operation procedure at the time of starting compensation of the conventional instantaneous voltage drop countermeasure device.

5 is a waveform diagram showing the phase relationship between the load detection current by CT and the actual load current i _{L in} FIG.

[Explanation of symbols]

 2 Feed line 3 Inverter 4 Injection transformer 6 Load 7 Voltage detection circuit 8 Inverter overcurrent detection circuit 10 Instantaneous voltage drop countermeasure device 11 Latch circuit 12 Re-extinguishing circuit

Claims (1)

[Claims] 1. An inverter for voltage compensation is inserted and connected in series to a power supply line, and an antiparallel thyristor bypass switch is provided on the output side of this inverter, and when the power supply voltage to the load is normal, the switch is switched. When the power is directly supplied from the power supply to the load while the short-circuit state is maintained, and when the power supply voltage to the load drops, the supply of the ignition pulse to the switch is stopped and the switch detects it at this time. After the arc is extinguished by supplying an arc-extinguishing pulse that corresponds to the polarity of the load current, the inverter measures the shortage of the voltage and supplies the voltage to the load. Latch circuit that latches the polarity of the load current detected at this time, and after the arc extinguishing pulse is supplied based on this polarity, the inverter output When a current is detected, an arc extinguishing circuit that supplies an arc extinguishing pulse corresponding to the opposite polarity to the latched polarity from the inverter to the thyristor bypass switch again is provided. apparatus.