JPH1141835A - Power supply device for uninterruptibe power supply work - Google Patents

Abstract

PROBLEM TO BE SOLVED: To supply electric power with less voltage fluctuation without interrupting the power system voltage, by supplying a sinusoidal drive control signal of fixed amplitude synchronizing with the power system voltage to a correction circuit block, and controlling the output voltage of an inverter with the drive control signal through a correction circuit block. SOLUTION: A drive control part 10 of an inverter 4 is provided with a main control block 11, and a sinusoidal correction block 12 which corrects the amplitude of the drive control signal for driving the inverter 4 of fixed amplitude outputted by the sinusoidal circuit 9 of the block 11. The output voltage of the inverter 4 phase-synchronizes with the system voltage, and is corrected so as to follow the system voltage when the system power source 1 is normal and is controlled so as to be the lower limit of the system voltage when the system power source 1 is in a power failure condition, by a closed loop control through the correction circuit block 12. It is thus possible to keep inverter voltage at the system voltage without having an adverse effect if a load change occurs, thereby supplying stable electric power to the load 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply unit for an uninterruptible power supply having an inverter structure, which is used when performing an uninterruptible power distribution work such as replacement of a sectional switch or an integrated wattmeter of each house. Related to inverter control.

[0002]

2. Description of the Related Art Conventionally, when power distribution work such as replacement of a classifying switch and an integrated wattmeter of each house is performed without interruption, the size of the device is reduced.
In order to reduce the weight and the like, it has been considered to use an uninterruptible power supply having an inverter configuration.

Next, this conventional power supply device for uninterrupted work will be described with reference to FIG. 1 showing an embodiment of the present invention.

[0004] As shown in FIG. 1, at the time of power distribution work, a commercial system power supply 1 is supplied to a load 3 at a work place via a disconnection switch 2.

[0005] The output side of the inverter 4 is connected to the load 3 via the interconnection switch 5. Before the disconnection switch 2 is opened, the interconnection switch 5 is turned on and the inverter 4 is connected to the system power supply 1.

At this time, conventionally, an instrumentation transformer 6 for measuring system voltage, a phase detection circuit 7, a synchronization circuit 8, a sine wave circuit 9
Thus, the inverter 4 is controlled to open and its output voltage is synchronized with the voltage of the system power supply 1 (system voltage).

That is, the voltage (system voltage) on the power supply side of the disconnection switch 2 is measured by the instrument transformer 6, and based on the measurement signal of the system voltage on the secondary side of the instrument transformer 6, the phase detection circuit 7 is operated. To detect the phase of the system voltage.

On the basis of the result of the detection, the synchronizing circuit 8 forms a synchronizing signal which coincides with, for example, the zero-cross timing of the system voltage. The generator is reset and its constant amplitude, sine waveform output signal is phase-synchronized with the system voltage.

Further, an output signal of the sine wave circuit 9 phase-synchronized with the system voltage is supplied to the inverter 4 as a drive control signal, and the drive control signal is driven, for example, as a PWM control carrier signal. The drive control signal is controlled to a magnitude and phase determined by the amplitude and phase.

[0010] During construction such as replacement of the integrated wattmeter of the load 3, the disconnection switch 2 is opened to disconnect the load 3 from the system power supply 1. However, the drive of the inverter 4 is performed by the drive control signal. The power of the system voltage is continuously supplied from the inverter 4 to the load 3 via the interconnection switch 5,
Construction will be carried out without interruption.

[0011]

In the case of this type of power supply unit for uninterruptible construction having the conventional inverter configuration, the inverter 4 is only operated by open control so that its output voltage is synchronized with the phase of the system voltage. The magnitude (amplitude) of the output voltage of the inverter 4 is not controlled.

For this reason, if the load 3 fluctuates (load fluctuation) while the disconnection switch 2 is opened and power is supplied from only the inverter 4 to the load 3, the magnitude of the output voltage of the inverter 4 fluctuates easily. Therefore, there is a problem that stable power cannot be supplied to the load 3.

If the system voltage fluctuates during the interconnection operation of the inverter 4 in which the disconnection switch 2 is kept turned on, the magnitude of the output voltage of the inverter 4 follows the system voltage. Since it does not change, power may flow from the system power supply 1 to the inverter 4 in some cases, and the inverter 4 may be damaged.

According to the present invention, the inverter supplies stable power with little voltage fluctuation to the load regardless of the power failure of the system power supply, and the magnitude (amplitude) of the output voltage of the inverter during the interconnection operation is reduced to the system voltage. It is an object of the present invention to follow and change.

[0015]

In order to solve the above-mentioned problems, a power supply device for uninterruptible construction according to the present invention comprises a drive control unit of an inverter, which is connected to a power supply side of a disconnection switch between a system power supply and a load. A main control block that outputs a constant-amplitude, sine-wave signal synchronized with the system voltage of the inverter as a drive control signal for the inverter, and corrects the amplitude of the drive control signal that sets the magnitude of the output voltage of the inverter and supplies the signal to the inverter. A correction circuit block, a system voltage detection means for outputting a system voltage detection signal proportional to the magnitude of the system voltage, and an inverter voltage detection signal proportional to the magnitude of the output voltage of the inverter. An inverter voltage detecting means for outputting a system voltage detection signal as a reference signal when the system power supply is normal, and a reference signal when a power failure or voltage drop occurs in the system power supply. Reference signal output means for switching the reference voltage to a setting signal having a predetermined magnitude, and a correction process for correcting the amplitude of the drive control signal based on an error signal between the reference signal and the inverter voltage detection signal so that the inverter voltage detection signal matches the reference signal. Means for controlling the output voltage of the inverter by the output signal of the correction processing means.

Therefore, the main control block provided in the drive control section of the inverter forms a drive control signal having a constant amplitude and a sine waveform synchronized with the system voltage similar to the operation control signal of the conventional device.

Further, the drive control signal is supplied to a correction circuit block.
The amplitude of the drive control signal is corrected by following the change in the system voltage so that the magnitude of the output voltage of the inverter matches the magnitude of the system voltage. The amplitude of the drive control signal is corrected based on the lower limit of the system voltage so that the output voltage of the inverter matches the lower limit.

The output voltage of the inverter is controlled by the drive control signal via the correction circuit block. At this time, the magnitude of the output voltage of the inverter is controlled based on the amplitude correction of the drive control signal by the correction circuit block. (Feedback control).

With this closed loop control, when the system power supply is normal, the output voltage of the inverter is controlled to the magnitude following the fluctuation of the system voltage, and even if a power failure or a voltage drop of the system power supply occurs, the output voltage of the inverter is controlled. Is controlled, for example, to a constant voltage of the magnitude of the lower limit value of the system voltage.

Therefore, regardless of the state of the system power supply, stable power can be supplied from the inverter to the load with little voltage fluctuation due to load fluctuation and the like. In addition, when the system power supply is normal, the output voltage of the inverter is reduced to the system voltage. , The inverter is prevented from being damaged due to fluctuations in the system voltage.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to FIG. In FIG. 1, the main difference from the conventional device is that the drive control unit 10 of the inverter 4 includes a main control block 11 formed by an instrument transformer 6, a phase detection circuit 7, a synchronization circuit 8, and a sine wave circuit 9. Block 1
And a correction circuit block 12 for correcting the amplitude of the drive control signal of the inverter 4 having a constant amplitude and a sine waveform output from the sine wave circuit 9 for controlling the output voltage of the inverter 4 in synchronization with the system voltage. The point is that the size is controlled in a closed loop (feedback control).

In the correction circuit block 12, the measurement signal V ₁ of the system voltage on the secondary side of the instrument transformer 6 is obtained.
There is supplied to the voltage presence determining circuit 13 and the effective value conversion circuit 14 monitors the presence or absence of the system voltage from the change of the integrated value of each 1/4 cycle of the voltage presence determining circuit 13, for example the absolute value of the measurement signal V ₁ The determination is made in real time, and when the system voltage disappears or fluctuates due to a power failure or a voltage drop and falls below a determination threshold, the output signal of the system changes from a voltage determination level to a voltage non-determination level.

Further, the effective value conversion circuit 14 outputs the measurement signal V ₁
Is converted into a signal having an effective value, and this signal is output to one input terminal of a voltage reference selection circuit 15 having a signal switch in a subsequent stage as a system voltage detection signal V ₁ ′ proportional to the magnitude of the system voltage.

The other input terminal of the voltage reference selection circuit 15 is provided with a voltage signal of a predetermined level of the voltage reference lower limit circuit 16, for example, a system voltage detection signal corresponding to a lower limit value which does not harm the load 3 of the system voltage. The signal set to the magnitude of V ₁ ′ is supplied as a predetermined setting signal _VL .

The lower limit of the system voltage is, for example, 180 V, which is 10% lower than the rating in the case of a 200 V system.

The voltage reference selection circuit 15 switches according to the binary change of the output signal of the voltage presence / absence determination circuit 13 and, based on the output signal of the voltage presence determination level of the voltage presence / absence determination circuit 13 when the system power supply 1 is normal. , RMS conversion circuit 14
And outputs the system voltage detection signal V ₁ 'as the reference signal Vr of the magnitude of the inverter voltage to the next stage of the subtracter 17.

When a power failure or voltage drop (voltage fluctuation) of the system power supply 1 occurs and the output signal of the voltage presence / absence determination circuit 13 changes to a voltage non-determination level in two values, the voltage reference selection circuit 1
The output signal (reference signal Vr) of No. 5 is switched to the setting signal _VL .

On the other hand, the output voltage of the inverter 4 on the power supply side of the interconnection switch 5 (hereinafter referred to as the inverter voltage) is measured by the instrument transformer 18 for measuring the inverter voltage, and the measurement signal V of the inverter voltage on the secondary side is measured. ₂ is supplied to an effective value conversion circuit 19, and a subtractor 17
To the inverter voltage detection signal V of the magnitude of the inverter voltage.
₂ 'will be supplied.

Then, the subtractor 17 calculates an error (deviation) between the reference signal Vr and the inverter voltage detection signal V ₂ ′ based on the magnitude of the reference signal Vr, and subtracts a signal ΔV of the magnitude of the error. The signal ΔV is supplied to the PI control unit 20 for feedback control from the unit 17, and the signal ΔV is subjected to proportional (P) and integral (I) processing according to the setting of the control response and the like.

Further, in order to stabilize the control or the like, the error signal ΔV via the PI calculator 20 is limited by a limiter 21 so that its amplitude change range is limited to a fixed range of, for example, 110% to 90%.

The output signal of the limiter 21 is supplied to the multiplier 22 as an amplitude correction signal. The multiplier 22 corrects the drive control signal of constant amplitude and sine waveform output from the sine wave circuit 9 and the amplitude correction of the limiter 21. The amplitude of the drive control signal is corrected to the amplitude of the amplitude correction signal and supplied to the inverter 4.

In the correction circuit block 12, the effective value conversion circuit 14 forms the system voltage detection means, the effective value conversion circuit 19 forms the inverter voltage detection means, the voltage presence / absence determination circuit 13, the voltage reference selection circuit 15 And the voltage reference lower limit circuit 16 form reference signal output means, and the subtracter 1
7, the PI calculator 20, the limiter 21, and the multiplier 22 form a correction processing unit. Then, the inverter 4 is driven by, for example, PWM control based on the drive control signal.

At this time, the output voltage of the inverter 4 is not only phase-synchronized with the system voltage by the same open control as in the prior art, but also
By closed loop control via the correction circuit block 12, when the system power supply 1 is normal, the following correction is performed so as to match the system voltage, and when the system power supply 1 is out of power, the lower limit value of the system voltage is controlled. .

Therefore, even if a load fluctuates while the disconnection switch 2 is opened and power supply from the inverter 4 alone to the load 3 is continued (during construction), the inverter voltage is not affected by the system voltage and is not affected by the load. Maintained and stable power is supplied to the load 3.

In addition, even if a power failure or the like occurs in the system power supply 1 during that time, the inverter voltage continues to be controlled in a closed loop to, for example, the lower limit value of the system voltage, and stable power supply to the load 3 is continued.

Further, the disconnection switch 2 and the interconnection switch 5
During the interconnection operation in which the power supply is kept in the on state, the inverter voltage matches the system voltage, and even if the system voltage fluctuates, the system power does not flow into the inverter 4 and so on. There is no breakage.

Therefore, it is possible to provide an uninterruptible power supply having an inverter configuration with high reliability and safety. By the way, the configuration of each part is not limited to that of FIG.

In the first embodiment, the voltage presence / absence determination circuit 13 and the voltage reference selection circuit 15
Although the system voltage detection signal V ₁ ′ and the setting signal _VL are alternatively selected as the reference signal Vr, both the system voltage detection signal V ₁ ′ and the setting signal _VL are DC voltage signals. 1
A similar effect can be obtained by providing a diode OR circuit in place of 5 and selecting the higher voltage of the system voltage detection signal V ₁ ′ and the setting signal _VL by using a diode OR circuit or the like as the reference signal Vr.

The limiter 21 and the like may be provided as needed. Furthermore, each part is digitized and the inverter 4
May be digitally controlled.

[0040]

The present invention has the following effects. The main control block 1 is included in the drive control unit 10 of the inverter 4.
1 and the correction circuit block 12, a drive control signal having a constant amplitude and a sine waveform synchronized with the system voltage of the main control block 11 is supplied to the correction circuit block 12. The amplitude of the drive control signal is corrected by following the change in the system voltage so that the magnitude of the output voltage of the inverter 4 matches the magnitude of the system voltage. The amplitude of the drive control signal can be corrected such that the output voltage of the inverter 4 matches the lower limit based on the set lower limit of the system voltage, for example.

Further, the output voltage of the inverter 4 is controlled by the drive control signal via the correction circuit block 12. At this time, the magnitude of the output voltage of the inverter 4 is adjusted based on the amplitude correction of the drive control signal by the correction circuit block. Closed loop control (feedback control) can be performed.

By this closed loop control, when the system power supply 1 is normal, the output voltage of the inverter 4 can be controlled to the magnitude following the fluctuation of the system voltage, and a power failure or voltage drop of the system power supply occurs. Even so, the output voltage of the inverter 4 can be controlled, for example, to a constant voltage of the lower limit value of the system voltage.

Therefore, regardless of the state of the system power supply 1 or the like,
Inverter 4 can supply stable electric power with little voltage fluctuation due to load fluctuation or the like to load 3, and when the system power supply 1 is normal, the output voltage of the inverter coincides with the system voltage and the inverter due to the fluctuation of the system voltage Can be prevented, and an uninterruptible power supply for construction having an inverter configuration with high power supply quality and high reliability can be provided.

[Brief description of the drawings]

FIG. 1 is a circuit block diagram of one embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 System power supply 2 Disconnection switch 3 Load 4 Inverter 10 Drive control unit 11 Main control block 12 Correction circuit block

Claims (1)

[Claims] An inverter is connected to a load at a construction point of a system via an interconnection switch during power distribution work, and the inverter is connected to the system power supply while a disconnection switch between the system power supply and the load is turned on. A power supply unit for uninterruptible construction that performs an interconnected operation to the power supply from the inverter and continuously supplies power to the load when the disconnection switch is opened, wherein a drive control unit of the inverter includes a power supply side of the disconnection switch. A main control block for outputting a signal having a constant amplitude and a sine waveform synchronized with the system voltage as a drive control signal for the inverter; and correcting the amplitude of the drive control signal for setting the magnitude of the output voltage of the inverter by correcting the amplitude. A correction circuit block for supplying to the inverter; and a system voltage detection for outputting a system voltage detection signal proportional to the magnitude of the system voltage to the correction circuit block. And an inverter voltage detecting means for outputting an inverter voltage detection signal proportional to the magnitude of the output voltage of the inverter; and outputting the system voltage detection signal as a reference signal when the system power supply is normal, and causing a power failure of the system power supply. Or a reference signal output means for switching the reference signal to a setting signal of a predetermined magnitude when a voltage drop occurs, and the inverter voltage detection signal is converted to the reference signal by an error signal between the reference signal and the inverter voltage detection signal. And a correction processing means for correcting the amplitude of the drive control signal so that the output voltage of the inverter is controlled by an output signal of the correction processing means. apparatus.