JP2009177961A - Uninterruptible power supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an uninterruptible power supply device that supplies power to a load while executing separation of a power system by a non-self arc-extinguishing system linkage switch at a high speed regardless of the type of power system and circuit conditions when detecting an abnormality of the power system so as to make a load voltage quickly reach a normal value and to maintain the normal value. <P>SOLUTION: When a system voltage abnormality detection circuit 12 detects an abnormality of a power system 1, a voltage command value from a voltage control circuit 11 is transmitted to a power converter 4 as a control command signal. During a period from the time point when the system voltage abnormality detection circuit 12 detects the abnormality of the power system 1 until the time point when an OFF-detection circuit 19 detects OFF-operation of a system linkage switch 3, a value obtained by adding a current command value from a current control circuit 15 to the voltage command value is transmitted to the power converter 4 as a control command signal. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  In the present invention, when an AC power system (hereinafter simply referred to as a power system) is healthy, power is supplied to a load via a system interconnection switch, and an abnormality such as an instantaneous voltage drop or a power failure occurs in the power system. In this case, the grid connection switch is turned off, and the DC power output from the storage battery or the like is converted into AC power by the power converter and supplied to the load. A switching element that does not have a self-extinguishing capability, such as a thyristor, is used as a switch, which detects an abnormality in the power system, disconnects the power system at high speed, and outputs AC power to the load at high speed. The present invention relates to a power failure power supply device.

Due to recent advances in semiconductor technology, information communication devices and the like using this technology have become widespread. Since these devices are more sensitive to power system failures than conventional electrical devices, instantaneous voltage drops or short interruptions in the power system caused by lightning strikes cause malfunctions and shutdowns of the devices. ing. Therefore, recent uninterruptible power supplies are required not only to supply power during a power outage, but also to provide a high-speed response to an instantaneous voltage drop or short-time power outage.
FIG. 15 is a circuit diagram illustrating a configuration example of a conventional uninterruptible power supply device disclosed in Patent Document 1, for example. In FIG. 15, a load 2 is connected to the power system 1 via a grid interconnection switch 3 formed of a semiconductor element that does not have a self-extinguishing capability such as a thyristor. A power converter 4 is connected in parallel with the load 2, and a DC power supply 5 that can be charged and discharged is connected to the DC side of the power converter 4.

  When the power system 1 is normal, the grid connection switch 3 is conductive and supplies power to the load 2. At the same time, the power converter 4 performs the charging / discharging operation of the DC power supply 5. At this time, the converter control circuit 8 determines the voltage to be output from the power converter 4 so that the output of the converter current detector 6 is maintained at the current value set by the current reference value generation circuit 7A. To do. The output of the converter control circuit 8 is input to the gate drive circuit 9, and the power converter 4 is operated by the generated PWM signal to charge or discharge the DC power source 5. This state is referred to as an interconnection operation mode.

  On the other hand, when an abnormality such as a voltage drop or a power failure occurs in the power system 1, the system voltage abnormality detector 12 detects an abnormality in the power system 1 and the detection signal is input to the converter control circuit 8. In response to this, the converter control circuit 8 stops the output of the converter current detector 6 from following the signal from the current reference value generating circuit 7A, and the power system 1 and the grid interconnection switch 3 A command value for increasing or decreasing the current of the power converter 4 is generated according to the output of the grid-connected switch current detector 14 installed therebetween, and is sent to the gate drive circuit 9. Thereby, the electric current which flows into the grid connection switch 3 is set to zero rapidly, and it isolate | separates from the electric power grid | system 1.

  When the grid connection switch 3 is turned off and disconnected from the power system 1, power is supplied to the load 2 from the DC power source 5 through the power converter 4. At this time, the converter control circuit 8 gives a voltage command value to the power converter 4 such that the output of the load voltage detector 10 is maintained at the voltage value set by the voltage reference value generation circuit 11A. This state is referred to as a self-sustained operation mode.

  As described above, in Patent Document 1, when an abnormality occurs in the power grid 1 during operation in the grid operation mode, current control of the power converter 4 is performed based on the grid switch current until the grid switch 3 is turned off. By quickly setting the interconnection switch current to zero, the power system 1 is disconnected at high speed, and after the interconnection switch 3 is turned off, the operation is promptly shifted to the self-sustaining operation mode in which the voltage control of the power converter 4 is performed.

  Further, as a technique similar to the above, there is a method in which the interconnection switch current is used for control and the distortion of the load voltage is reduced (for example, see Patent Document 2). In an uninterruptible power supply that adds the current control command and the voltage control command to obtain the command value of the power converter, when an abnormality occurs in the power system, the grid switch current is input to the current control circuit. A value obtained by subtracting the current flowing to the load from the input current command value is used as a command value for the power converter. As a result, the interconnection switch current decreases as the power system voltage decreases and the current control command decreases, so that distortion of the output voltage can be reduced.

JP-A-11-341686 JP 2002-101575 A

  As described above, in the related art, for example, in Patent Document 1, when an abnormality occurs in the power system, the current flowing through the grid connection switch is intended to be disconnected from the power system at high speed by the grid connection switch. Only the current control of the power converter is performed in order to quickly reduce the power to zero, and the voltage supplied to the load is not controlled until the system interconnection switch is turned off. As a result, the voltage applied to the load immediately before the grid connection switch is turned off differs greatly from the normal voltage depending on the type of power system abnormality and circuit conditions. When voltage control by the power converter is started after the turn-off is completed, there is a problem that it takes a long time to reach a target normal voltage.

  Moreover, in the uninterruptible power supply of Patent Document 2, voltage control is performed even when the power system is abnormal, so that distortion of the load voltage can be reduced. However, the output current of the power converter is changed from the interconnection switch current to the load. Since the current is controlled to a value that is subtracted, there is no action to make the interconnection switch current positively zero, and the time until the interconnection switch current becomes zero and the interconnection switch is turned off becomes long There was a point.

  The present invention has been made to solve the above-described problems. When an abnormality in the power system is detected, the non-self-extinguishing system interconnection switch can be operated at high speed regardless of the type or circuit condition. The purpose of the present invention is to obtain an uninterruptible power supply capable of disconnecting the electric power system and supplying electric power to the load so that the load voltage can be quickly reached and maintained at a normal value.

The uninterruptible power supply according to the present invention is a grid-connected switch composed of a switching element having no self-extinguishing capability, inserted between the AC power system and the load, and connected between the DC power supply and the load. A power converter that converts power between DC and AC based on the control command signal, a system abnormality detection circuit that detects an abnormality in the AC power system, a system connection switch current detector that detects a current of the system connection switch, Off-detection circuit that detects the off operation of the system switch, connected time command value generation circuit that creates a connected time command value when the power converter is connected to the AC power system without abnormality, and load A voltage control circuit for creating a voltage command value for controlling the voltage of the current to a desired value and a current command value for reducing the current of the grid connection switch to zero based on the output of the grid connection switch current detector A current control circuit for forming,
When the AC power system is not abnormal, the command value at the time of connection from the command value generation circuit at the time of connection is sent to the power converter as a control command signal,
When the system abnormality detection circuit detects an abnormality in the AC power system, the voltage command value from the voltage control circuit is sent to the power converter as a control command signal, and the system abnormality detection circuit detects an abnormality in the AC power system. Between the time point when the off detection circuit detects the off operation of the grid connection switch, a value obtained by adding the current command value from the current control circuit to the voltage command value is sent as a control command signal to the power converter. It is a thing.

  According to the present invention, when an abnormality of the power system is detected, the control of making the voltage of the load a predetermined value as well as the control of making the current flowing through the system connection switch zero, and the turning off of the system connection switch is completed. Since the fluctuation of the load voltage is suppressed before the operation is performed, the load voltage after the completion of the disconnection of the electric power system can be quickly recovered to a desired value.

Embodiment 1 FIG.
1 is a configuration diagram showing an uninterruptible power supply according to Embodiment 1 of the present invention. In the figure, between the power system 1 and the load 2, a grid interconnection switch 3 composed of a switching element having no self-extinguishing capability such as a thyristor is connected. A power converter 4 that performs power conversion between DC and AC based on a control command signal is connected between the DC power supply 5 and the load 2. Furthermore, an abnormality of the power system 1, for example, a system voltage abnormality detection circuit 12 that detects an abnormality of the voltage, a system connection switch current detector 14 that detects a current of the system connection switch 3, and the system connection switch 3 are turned off. An off-detection circuit 19 for detecting the operation, a command value generating circuit 7 for connecting time for generating a command value for connecting time when the power system 1 is not abnormal and the power converter 4 is connected to the power system, and load 2 A voltage control circuit 11 for creating a voltage command value for controlling the voltage to a desired value, and a current command for reducing the current of the grid interconnection switch 3 to zero based on the output of the grid interconnection switch current detector 14 A current control circuit 15 for creating a value is provided.

In the uninterruptible power supply according to Embodiment 1 of the present invention, as shown in FIG. 1, the current control circuit 15 uses the interconnection switch current based on the interconnection switch current detected by the interconnection switch current detector 14. A current command value in the direction opposite to the current is calculated, input to the adder 17 through the open / close switch 16, added to the output of the voltage control circuit 11, and output from the adder 17.
The output of the adder 17 is connected to the input of the selection switch 18 together with the output of the connection time command value generation circuit 7. The selection switch 18 operates in accordance with the output of the system voltage abnormality detection circuit 12. When the power system 1 is normal, the selection switch 18 selects the output from the connection time command value generation circuit 7 and selects the converter control circuit. 8 and when the abnormality of the power system 1 is detected, the output from the adder 17 is selected. The open / close switch 16 opens and closes according to the output of the off detection circuit 19 that detects the off state of the grid connection switch 3, and is closed when the grid connection switch 3 is on, such as when the power system 1 is healthy. In this state, when the off of the grid connection switch 3 is detected, the open / close switch 16 is opened, and as a result, the adder 17 outputs the input from the voltage control circuit 11 as it is.

  As shown in FIG. 2, the current control circuit 15 is configured by an amplifier that multiplies an input by a predetermined positive constant (gain K) and outputs the result. Since the current command value output from the current control circuit 15 is the command value of the current output from the power converter 4, the direction is opposite to the detected system switch current, the magnitude is K times, and the system switch current is zero. Then, the current command value becomes zero.

  Next, the operation will be described. When the power system 1 is normal and not abnormal, the grid connection switch 3 is conductive in the above-described connected operation mode, and power is supplied from the power system 1 to the load 2 at the same time as the power converter. 4 also works. The power converter 4 performs, for example, the following operation based on the connection time command value from the connection time command value generation circuit 7.

That is, the DC power supply 5 is used as a chargeable / dischargeable power storage device, and for example, a voltage detection unit (not shown) for detecting the voltage of the DC power supply 5 is provided to detect the amount of power stored in the power storage device. The command value generation circuit 7 controls the charge / discharge current by the power converter 4 so that the amount of power stored in the power storage device is held at a predetermined value.
This corresponds to a case where the present apparatus is operated only as its original uninterruptible power supply. That is, when the power system 1 is normal, no operation is performed on the load 2, and the first operation is performed at the time of a power failure to supply power to the load 2. However, the power storage device that is the DC power source 5 needs to store sufficient power in preparation for a power failure, and the power is charged from the power system 1 when the power system is normal. Therefore, the connection time command value generation circuit 7 determines the charging current command value as the connection time command value according to the state of charge of the DC power supply 5. By sending the charging current command value to the converter control circuit 8 via the selection switch 18, the power converter 4 performs an operation in which the current of the converter current detector 6 follows the charging current command value. Is stored at a predetermined value.

As another example, depending on the type of the load 2, there is one that generates a harmonic current, and when the power system 1 is normal, the apparatus may be operated as a so-called active filter for canceling out the harmonic current. is there. Since the connection configuration of the power converter is the same as in the above case, a current detection unit (not shown) for detecting the current of the load 2 is provided, and the power converter 4 is operated as an active filter when the power system is normal. For the purpose, the interconnection time command value generation circuit 7 detects the harmonic current flowing out from the load 2 to the power system 1 and outputs a current command value for canceling and compensating the harmonic current as an interconnection time command value. 4 is operated.
As described above, when the power system is normal, the charge / discharge control and the harmonic current compensation control described above are combined based on the connection time command value generated by the connection time command value generation circuit 7, and the both are combined. Control action is performed.

Next, an operation when an abnormality occurs in the power system 1, here, a voltage abnormality occurs will be described. When the system voltage abnormality detection circuit 12 detects this voltage abnormality, voltage control is performed by the power converter 4 and at the same time, a current in the direction opposite to the grid switch current is output from the power converter 4 by current control of the power converter 4. To do. As the interconnection switch current decreases, the current output from the power converter 4 also decreases. Therefore, the interconnection switch current can be quickly reduced to zero, and the distortion of the load voltage can be suppressed before the system interconnection switch 3 is completely turned off.
Here, the voltage control circuit 11 performs an operation of constantly monitoring the amplitude, frequency, and phase of the voltage detected by the load voltage detector 10 when the power system is normal. The voltage command value is output so that it can be maintained.

  Further, an operation for reducing the interconnection switch current with the current control circuit 15 as a center will be described. Although not shown in FIG. 1, normally, an inductance component exists between the power converter 4 and the interconnection point (the position of the load voltage detector 10). Then, the difference voltage between the output voltage of the power converter 4 and the load voltage (voltage at the connection point) is applied to the inductance component, whereby the current flowing through the inductance component can be controlled. Therefore, the voltage whose output is controlled by the power converter 4 can be regarded as a current whose output is controlled by the power converter 4 at the interconnection point.

  Here, when an accident such as a ground fault occurs on the system side of the grid connection switch 3, the voltage drops at the ground fault point, but the voltage remains almost unchanged while the grid connection switch 3 is on. Same as voltage. Therefore, even if the power converter 4 tries to maintain the load voltage, it can hardly be recovered as long as the grid connection switch 3 is on, and the voltage rises only after the grid switch 3 is turned off. Become. Therefore, the operation here is based on the idea that current is supplied from the power converter 4 to turn off the grid interconnection switch 3.

This operation will be described more specifically. When the output voltage of the power converter 4 is increased with respect to the reduced load voltage, as described above, a potential difference is generated in an inductance component (not shown), and a current is output from the power converter 4 to the interconnection point. The control command value of this current has already been switched from the output of the command value generating circuit 7 at the time of connection to the added value of the command value from the voltage control circuit 11 and the current control circuit 15, and immediately after the occurrence of a system abnormality, etc. While the current flowing through the interconnection switch 3 is large, the output of the current control circuit 15 is more dominant than the output of the voltage control circuit 11. A part of this current flows to the load 2. The load 2 usually has some inductance component, and since the current flowing through the load 2 does not change so much in a short time, a current corresponding to this flows into the load 2 and the remaining current flows into the power system 1. It will be.
Strictly speaking, if an amount of current more than what was flowing to the load 2 before the accident flows to the load 2, an induced electromotive force is generated by the inductance component of the load 2, the load voltage changes slightly, and the remaining current is It flows to the electric power system 1. This remaining current becomes a reverse current whose direction is different from that of the current flowing in the grid connection switch 3, and thus the switch-off of the grid switch current is accelerated.

FIG. 3 is a simulation result in which the uninterruptible power supply according to Embodiment 1 of the present invention is applied. In the case where a U-phase ground fault occurs when the UV line voltage of the power system 1 is near its maximum value, It is the figure which showed the waveform of the system voltage, the interconnection switch current, the load voltage, and the load current. In addition, in the electric power system 1 made into object here, V phase is always earth | grounded.
In FIG. 3, the gain K of the amplifier 20 is set to 1. However, about 1 ms after the occurrence of the accident, the interconnection switch current is cut off and the interconnection switch 3 is turned off. The load voltage is about 2 ms after the occurrence of the accident. Is a waveform without distortion.

FIG. 4 shows a similar simulation waveform when the gain K is set to 1 when a U-phase ground fault occurs when the UV line voltage of the power system 1 is near zero. The current continues to flow for about 10 ms from the occurrence of the accident. Thus, depending on the timing at which an accident occurs, the interconnection switch current may not be promptly interrupted. FIG. 5 shows a simulation waveform when the gain K is 3 under the same conditions. The grid connection switch current is cut off about 2 ms after the accident occurs, the grid connection switch 3 is turned off, and the output voltage has a waveform without distortion about 3 ms after the accident occurs.
FIG. 6 shows a simulation waveform when the gain K is 15 under the same conditions. Since the gain K is too large, the output voltage before the interconnection switch current is cut off greatly fluctuates, and the distortion time of the output voltage becomes longer from the occurrence of the accident. Accordingly, the response depends on the gain K of the amplifier 20.

  Thus, the current command value from the current control circuit 15 is between the time when the system abnormality detection circuit 11 detects the abnormality of the power system 1 and the time when the OFF detection circuit 19 detects the OFF operation of the system interconnection switch 3. Is controlled by the command value obtained by adding the voltage to the voltage command value from the voltage control circuit 11, so that the interconnection switch current flowing through the grid interconnection switch 3 is quickly made zero and the fluctuation of the load voltage is suppressed. Furthermore, since the power converter 4 is controlled in accordance with the output of the voltage control circuit 11 before the turning off of the grid connection switch 3 is completed, the load voltage after completion of the disconnection of the power system 1 can be quickly set to a desired value. Can be controlled.

Embodiment 2. FIG.
FIG. 7 is a diagram showing a configuration of a current control circuit 15A applied to the uninterruptible power supply according to Embodiment 2 of the present invention.
When a thyristor switch is applied, a certain amount of time is required to restore the forward blocking ability even after the forward current flowing through the thyristor becomes zero. It is desirable to pass a current in the reverse direction. That is, a current in the direction opposite to the grid switch current is output from the power converter 4 to reduce the grid switch current, but after the grid switch current becomes zero, the current is further reversed from the power converter 4. If current is output in the direction, the thyristor switch can be reliably turned off. In the configuration of the current control circuit 15 shown in FIG. 2, when the interconnection switch current becomes zero, the current command value also becomes zero. However, in the actual system, the detection delay of the grid interconnection switch current detector 14 and the output current control are controlled. Even if the interconnection switch current becomes zero due to the delay, the current output from the power converter 4 does not immediately become zero. However, depending on the design of the detector, control circuit, and main circuit, there may be a case where current does not continue to be output from the power converter 4 until the grid interconnection switch 3 is completely turned off.

  FIG. 7 shows the above countermeasures, and the current control circuit 15 A includes a delay circuit 21 after the amplifier 20. The detected interconnection switch current is multiplied by K by the amplifier 20, and the output is delayed by a predetermined time by the delay circuit 21. Therefore, as shown in FIG. 8, even if the flow direction of the interconnection switch current is reversed, the current command Since the direction of the value does not change, the interconnection switch current is quickly made zero and the thyristor switch is reliably turned off.

Embodiment 3 FIG.
In the second embodiment, the current control circuit 15A includes the delay circuit 21. However, as shown in the current control circuit 15B of FIG. 9, the delay circuit 21 is replaced with an output obtained by multiplying the output of a predetermined offset circuit 22 by a constant. The switch current may be added by the adder 23. In this case, the relationship between the interconnection switch current and the current command value is as shown in FIGS. 10 and 11, and the direction of the current command value does not change even if the direction of the interconnection switch current flows in the opposite direction. As a result, the interconnection switch current is quickly reduced to zero and the thyristor switch is reliably turned off.

Embodiment 4 FIG.
In the second embodiment, the delay circuit 21 is provided in the current control circuit 15A. However, as shown in the current control circuit 15C in FIG. 12, a minimum value limit circuit 24 may be provided instead of the delay circuit 21, and in this case As shown in FIG. 13, when the interconnection switch current multiplied by a constant is smaller than a predetermined value, the current is limited to a predetermined current value. As shown in FIG. Since the direction of the current command value does not change even if is reversed, the interconnection switch current is quickly made zero and the thyristor switch is reliably turned off.

It is a circuit diagram which shows the uninterruptible power supply by Embodiment 1 of this invention. It is a block diagram which shows the current control circuit 15 by Embodiment 1 of this invention. It is a simulation waveform when gain K is set to 1 in the uninterruptible power supply according to Embodiment 1 of the present invention. It is a simulation waveform when the accident occurrence time of the electric power grid | system 1 differs from FIG. 3 when the gain K is set to 1 with the uninterruptible power supply apparatus by Embodiment 1 of this invention. It is a simulation waveform when the gain K is set to 3 in the uninterruptible power supply according to Embodiment 1 of the present invention. It is a simulation waveform when the gain K is 15 in the uninterruptible power supply according to Embodiment 1 of the present invention. It is a block diagram which shows the current control circuit 15A by Embodiment 2 of this invention. It is a figure which shows the relationship between the interconnection switch electric current at the time of applying Embodiment 2 of this invention, and electric current command value. It is a block diagram which shows the current control circuit 15B by Embodiment 3 of this invention. It is a figure which shows the relationship between the connection switch current and current command value in the current control circuit 15B by Embodiment 3 of this invention. It is a figure which shows the relationship between the interconnection switch electric current at the time of applying Embodiment 3 of this invention, and electric current command value. It is a block diagram which shows the current control circuit 15C by Embodiment 4 of this invention. It is a figure which shows the relationship between the connection switch current and current command value in the current control circuit 15C by Embodiment 4 of this invention. It is a figure which shows the relationship between the interconnection switch electric current at the time of applying Embodiment 4 of this invention, and electric current command value. It is a circuit diagram which shows the structural example of the conventional uninterruptible power supply.

Explanation of symbols

1 power system, 2 loads, 3 grid connection switch, 4 power converter, 5 DC power supply,
6 Converter current detector, 7 Linkage command value generation circuit, 8 Converter control circuit,
9 Gate drive circuit, 10 Load voltage detector, 11 Voltage control circuit,
12 system voltage abnormality detection circuit, 13 system interconnection switch control circuit,
14 grid connection switch current detector, 15, 15A, 15B, 15C current control circuit,
16 open / close switch, 17 adder, 18 selection switch, 19 off detection circuit,
20 amplifier, 21 delay circuit, 22 offset circuit, 23 adder,
24 Minimum value limit circuit.

Claims (7)

A grid-connected switch composed of switching elements that do not have self-extinguishing capability, inserted between the AC power system and the load, connected between the DC power supply and the load, and connected between the DC and AC based on the control command signal A power converter that performs power conversion, a system abnormality detection circuit that detects an abnormality in the AC power system, a system connection switch current detector that detects a current of the system connection switch, and an off operation of the system connection switch. Off-detection circuit to detect, connected time command value generation circuit for creating a connected time command value when the AC power system is not abnormal and the power converter is connected to the AC power system, voltage of the load A voltage control circuit for generating a voltage command value for controlling the voltage to a desired value, and a current for reducing the current of the grid connection switch to zero based on the output of the grid connection switch current detector A current control circuit for generating a decree values,
When the AC power system is not abnormal, the connection time command value from the connection time command value generation circuit is sent to the power converter as the control command signal,
When the system abnormality detection circuit detects an abnormality in the AC power system, the voltage command value from the voltage control circuit is sent to the power converter as the control command signal, and the system abnormality detection circuit A value obtained by adding the current command value from the current control circuit to the voltage command value between the time when the abnormality of the AC power system is detected and the time when the off detection circuit detects the off operation of the grid interconnection switch. Is sent to the power converter as the control command signal. 2. The uninterruptible power supply according to claim 1, wherein the current control circuit comprises an amplifier that multiplies the output of the grid-connected switch current detector by a predetermined constant and outputs the result as the current command value. 3. The uninterruptible power supply according to claim 2, wherein the current control circuit includes a delay circuit that delays the output of the current command value for a predetermined time. 3. The uninterruptible power supply according to claim 2, wherein the current control circuit includes an offset circuit that adds a predetermined offset to the current command value and outputs the result. 3. The uninterruptible power supply according to claim 2, wherein the current control circuit includes a minimum value limit circuit that limits the output of the current command value so that the current command value does not become less than a predetermined minimum value. A power storage device capable of charging and discharging the DC power source,
The connection time command value generation circuit creates a command value for controlling the charge / discharge current by the power converter as the connection time command value so that the amount of charge of the power storage device is held at a predetermined value. The uninterruptible power supply according to any one of claims 1 to 5, wherein the uninterruptible power supply is configured. Means for detecting harmonic current flowing out of the load,
The interconnection time command value generation circuit is configured to create, as the interconnection time command value, a command value for controlling the harmonic compensation current by the power converter for canceling the harmonic current. The uninterruptible power supply according to any one of claims 1 to 5.

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