JP2006254602A - Voltage regulator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a voltage regulator that prevents the fluctuation of a system voltage by controlling the changeover operation of a tap when voltage oscillation is generated and prevents the wear of a tap changer. <P>SOLUTION: This voltage regulator which adjusts the system voltage by changing over the taps when voltage fluctuation exceeding the dead band width of the secondary voltage is detected is constituted of an oscillation detection determination portion 12 which determines oscillation when repeated up and down operations of the tap with almost the same periods within a predetermined period of time are detected; a tap selecting portion 7 which is connected to the oscillation detection judging portion 12 and outputs to the tap changer 9 a tap fixing signal that fixes the tap to a through tap or the present tap; and a timer 8 which resets the tap to a normal tap changeover state after the lapse of a predetermined period of time from a time when the tap selecting portion 7 is operated. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a voltage regulator having an improved mechanism for suppressing voltage oscillation.

The Japanese Electricity Business Law imposes an obligation to maintain 101V ± 6V at the power supply end, and voltage regulators are installed throughout the distribution lines. A typical step-type voltage regulator is called SVR, and adjusts the secondary voltage of the voltage regulator to a reference voltage of 6600 V, for example, by switching the tap of the transformer.

For example, as shown in FIG. 6, the conventional voltage regulator is provided with a transformer 3 between the primary side 2 </ b> A and the secondary side 2 </ b> B of the distribution line 2, and the voltage detection unit 4 detects the voltage on the secondary side. The detected voltage is compared with the reference voltage of the reference voltage unit 5 by the voltage comparison unit 6 to determine whether the voltage is increased or decreased, and the tap selection unit 7 is used to select the tap to be switched. 8, the switching signal is output to the tap changer 9 of the transformer 3 and the voltage is adjusted by switching the tap (for example, Patent Document 1).

The tap of the transformer 3 usually has a tap adjustment range of 600V on the top and 200V on the bottom, where 1 tap is 100V. When the detected voltage is in the dead band range (reference voltage band) of about 80 V above and below the reference voltage, the tap is maintained as it is, and when the dead band is exceeded, the tap is switched to fit in the reference voltage band. For example, when the reference voltage is 6600 V, if the detected secondary voltage is in the range from 6680 V to 6520 V, it is within the dead band range, so the tap remains as it is. However, when the secondary voltage fluctuates to 6681V, it is adjusted so that it is lowered by 1 tap to 6581V.

Such a voltage regulator 1 is generally installed at a plurality of locations on one distribution line 2. However, in recent years, with the diversification of energy, as shown in FIG. 7, a distributed power source 10 such as a wind power or a small hydroelectric generator is often connected to the distribution line 2. As a result, a vibration phenomenon was observed in which the voltage regulators 1A and 1B periodically repeat unnecessary tap switching.

As shown in an example in FIG. 8, the voltage oscillation due to the periodic tap switching includes a tap (hereinafter referred to as an A tap) in which each of the voltage adjusting devices 1A and 1B performs a lowering operation in a short time, This is a phenomenon in which tap switching is frequently repeated at intervals of about several tens of seconds between taps that perform a lifting operation (hereinafter referred to as B taps). As a result of investigating the cause of the phenomenon of periodically repeating the tap switching, a plurality of voltage regulators 1A, 1B and the distributed power supply 10 installed on the distribution line 2 are individually voltage-controlled, so that the voltage oscillates. I think that.

If such periodic tap switching is continuously performed for a short time between two taps or three taps, the system voltage is unnecessarily changed, which is not desirable. Furthermore, if the voltage regulator 1 repeats tap switching frequently within a short period of time, there is a problem that the tap changer 9 generates heat or wears down to shorten its life.
JP-A-8-23633

The present invention improves the above-mentioned problem, and controls the tap switching operation to prevent fluctuations in the system voltage when a voltage oscillation that repeats the raising and lowering taps multiple times at almost the same cycle occurs within a predetermined time. In addition, the present invention provides a voltage regulator that prevents the tap changer from being worn.

The voltage regulator according to claim 1 of the present invention is a voltage regulator that regulates the system voltage by switching the tap when a voltage change exceeding the dead band width of the secondary voltage is detected. A vibration detection determination unit that determines that vibration is detected when an operation that repeats the tap multiple times at substantially the same cycle is detected, and is connected to the vibration detection determination unit, and is fixed to the through tap or the current tap when it is determined to be vibration. A tap selection unit that outputs a tap fixing signal to a tap selector and a timer unit that returns to a steady tap switching state after a predetermined time has elapsed since the tap selection unit was activated.

According to a second aspect of the present invention, there is provided a voltage adjusting device for adjusting a system voltage by switching a tap when a voltage change exceeding a dead band width of a secondary voltage is detected. A vibration detection determination unit that determines that vibration is detected when an operation that repeats the tap multiple times at substantially the same cycle is detected, and a delay signal that is connected to the vibration detection determination unit and slows down the tap switching response speed when it is determined as vibration. Is output to the tap changer, and a timer unit for returning to the steady tap switching state after a lapse of a predetermined time after the response speed delay unit operates.

According to a third aspect of the present invention, when a voltage change exceeding the dead band width of the secondary voltage is detected, the voltage adjustment device adjusts the primary voltage of the system voltage by tap switching and outputs the voltage to the secondary side. In the apparatus, when detecting an operation in which the raising tap and the lowering tap are repeated a plurality of times at substantially the same cycle within a predetermined time, a vibration detection determination unit that determines vibration is connected to the vibration detection determination unit, and is determined as vibration. When the dead band width expanding unit that outputs an expanded signal that expands the tap switching dead band width to the voltage comparison unit and the dead band width expanding unit is activated, a secondary voltage exceeding the expanded dead band width is detected and the tap switching is performed. A timer that returns to the steady tap switching state after a predetermined time has elapsed since the automatic return unit that returns to the steady tap switching state when the signal is detected or the dead band width expanding unit operates. And it is characterized in that comprising a.

According to a fourth aspect of the present invention, in the voltage regulator according to the first, second, or third aspect, the vibration detection determination unit includes a switching count unit that counts the number of tap switching between the raising tap and the lowering tap, It is connected to the switching upper limit setting unit that sets the upper limit, and when the number of tap switching within the predetermined time reaches the set upper limit, it is determined that the rising tap and the lowering tap are vibrations that are repeated several times at substantially the same period, and the fixed signal Alternatively, a delay signal or a dead band expansion signal is output.

According to the voltage adjustment device of the first aspect of the present invention, when it is determined that the vibration is detected by the vibration detection determination unit, the tap is fixed to the through tap or the current tap, and the voltage is not adjusted without switching the tap for a certain time. By doing so, a plurality of voltage regulators and distributed power supplies can independently control the voltage, thereby preventing the occurrence of voltage oscillations that interfere with each other.

According to the voltage regulator of claim 2, when the vibration detection determination unit determines that the vibration is generated, the tap switching signal output to the tap changer is delayed so that the raising tap and the lowering tap can be set within a short time. It is possible to prevent the occurrence of voltage oscillation that is repeated a plurality of times at substantially the same cycle.

According to the voltage regulator of the third aspect, when the vibration detection determination unit determines that the vibration is present, the tap switching dead band of the voltage comparison unit is increased from the normal state, thereby reducing the tap switching frequency. Voltage oscillation can be prevented.

According to the voltage regulator of the fourth aspect, the number of tap switching signals is counted, and when the count reaches the upper limit number, the vibration detection determination unit determines that the vibration has occurred, and the tap is fixed and the tap is switched. Can be stopped, or a delay signal can be output to slow down the tap switching response speed, or a dead band width expansion signal can be output to expand the tap switching dead band width to prevent voltage oscillation.

We realized a voltage regulator that controls the tap switching operation to prevent fluctuations in the system voltage when voltage oscillations occur.

Hereinafter, an embodiment of the present invention according to claim 1 will be described in detail with reference to FIG. In the voltage regulator 1, the transformer 3 is provided between the primary side 2A and the secondary side 2B of the distribution line 2, and the vibration detection determination unit 12 is provided in the voltage detection unit 4 that detects the voltage of the secondary side 2B. It is connected. A vibration count unit 13 and a vibration period measurement unit 14 are connected to the vibration detection determination unit 12 so as to detect voltage vibration. A timer unit 8 is connected to the vibration detection determination unit 12 so as to set a unit time for measurement. Further, the vibration detection determination unit 12 is connected to the tap selection unit 7 and outputs a tap fixing signal.

Further, the vibration detection determination unit 12 is connected to the voltage comparison unit 6, and a reference voltage unit 5 is connected to the detection unit 12 to compare the detection voltage with the reference voltage. The voltage comparison unit 6 is connected to a tap selection unit 7, and a timer unit 8 is connected to the tap selection unit 7 so as to set a tap switching time. Further, the tap selection unit 7 is connected to a tap changer 9 and outputs a tap change signal.

In the voltage regulator 1 having the above-described configuration, the voltage gradually changes due to a load change or the like in a steady operation state, and the voltage of the secondary side 2B is detected by the voltage detector 4 in order to adjust the voltage. The voltage is compared with the reference voltage of the reference voltage unit 5 by the voltage comparison unit 6 to determine whether the voltage is raised or lowered, the tap to be switched is selected by the tap selection unit 7, and the timer unit 8 saves time. The switching signal is output to the tap changer 9 of the transformer 3 to switch the taps to adjust the voltage.

At this time, the vibration counting unit 13 counts the number of one cycle in which the voltage is increased and decreased by the raising tap and the lowering tap from the detected voltage, and the vibration period measuring unit 14 measures the period, The measurement data is output to the vibration detection determination unit 12. The vibration detection determination unit 12 determines how many times the measurement data vibrates during the measurement unit time set by the timer unit 8, for example, 3 minutes, that is, the number of vibrations in which the raising tap and the lowering tap are alternately switched. Measure and compare this with a preset number of vibrations, eg 3 times.

For example, as shown in FIG. 2, within a predetermined measurement unit time, the B-th tap that becomes the raising tap and the A-tap that becomes the lowering tap are alternately switched six times, and the seventh switching is performed after the third cycle. When this is done, it is compared with the set number of cycles 3, and if this is reached, it is determined that there is voltage oscillation. When it is determined that the voltage vibration is detected, the vibration detection determination unit 12 outputs a tap fixing signal for fixing to the tap switch 9 or the current tap through the tap selection unit 7. In the case of fixing to the current tap, as shown in FIG. 2, it is fixed to the B tap as it is, and the tap switching is stopped for a time set by the timer unit 8, for example, from several minutes to several tens of minutes, regardless of voltage fluctuation. To do.

Further, when it is determined as voltage oscillation and the tap changer 9 is fixed to the through tap, it is fixed to the tap for which voltage adjustment is not performed for the time set by the timer unit 8. When the tap fixing time set by the timer unit 8 has elapsed, the normal voltage adjustment is restored. Accordingly, the voltage regulators 1A and 1B and the distributed power supply 10 individually control the voltage independently and interfere with each other. As a result, vibration is generated, so that the voltage adjustment is stopped by fixing the tap for a certain time. Thus, the occurrence of voltage oscillation can be prevented. The vibration detection determination unit 12 clears the past switching vibration determination data to zero and confirms a new vibration at the time when tap switching other than the A tap and the B tap is confirmed.

FIG. 3 shows another embodiment of the present invention according to claim 2. This voltage adjustment device 1 is further provided with a response speed delay unit 16 between the voltage detection unit 4 and the voltage comparison unit 6 in FIG. 1, and the vibration detection determination unit 12 and the tap selection unit 7 are not connected. Only the difference. The response speed delay unit 16 has a structure that delays the transmission speed of the signal output to the tap changer 9 by adjusting the electric quantity of the signal with the capacitor capacity, for example.

When the vibration detection determination unit 12 determines that the voltage oscillation is in the above configuration, the voltage adjustment device sends a delay signal that delays the detection voltage to be sent to the voltage comparison unit 6 to the voltage comparison unit 6, and the voltage comparison unit 6 performs this delay. The detected voltage is compared with the reference voltage of the reference voltage unit 5 to determine whether the voltage is increased or decreased, the tap to be switched is selected by the tap selection unit 7, and a switching signal is sent to the tap switch 9 of the transformer 3. The output is delayed and the tap is switched to adjust the voltage. In this way, by delaying the determination time in the voltage comparison unit 6 and delaying the switching time in the tap changer 9, voltage oscillation in which the raising tap and the lowering tap are repeated a plurality of times in substantially the same cycle within a short time. Can be prevented. The response speed delay unit 16 is canceled when the time set by the timer unit 8 has elapsed, and returns to normal voltage adjustment.

In the above embodiment, the response speed delay unit 16 is provided between the vibration detection determination unit 12 and the voltage comparison unit 6. However, the voltage comparison unit 6 and the tap selection unit 7 or the tap selection unit 7 and the tap are provided. The structure provided between the switch 9 may be sufficient.

FIG. 4 shows another embodiment of the present invention according to claim 3. This voltage adjustment device 1 is provided with a dead zone widening unit 17 between the vibration detection determination unit 12 and the voltage comparison unit 6 of FIG. 1, and an automatic return unit 18 is connected to the voltage comparison unit 6 to detect vibration detection. The only difference is that the section 12 and the tap selection section 7 are not connected.

Normally, in the dead zone range (between the upper and lower thresholds), for example, if the reference voltage is 6600 V, the tap switching signal is not output even if the voltage fluctuates in the upper and lower ranges of about 80 V, that is, 160 V. The dead zone width expanding portion 17 expands the dead zone range to a range of about 150 V in the vertical direction, that is, 300 V, for example. The automatic return unit 18 is for returning to a steady tap switching state in which the dead band range of the voltage comparison unit 6 is about 80 V up and down when a secondary voltage exceeding the expanded dead band width is detected and tap switching is determined. is there.

In the voltage adjusting device having the above configuration, when the vibration detection determining unit 12 determines that the voltage vibration, the dead band width expanding unit 17 is activated, for example, the dead band width of 80 V above and below the reference voltage is expanded to about 150 V above and below, The range in which the voltage comparison unit 6 determines whether to increase or decrease the voltage is expanded as compared with the reference voltage. Therefore, the tap is not switched in the range where the detection voltage is 6450 to 6750V. As a result, it is possible to reduce the frequency of tap switching and prevent voltage oscillation in which the raising and lowering taps are repeated a plurality of times within a short time with a slight voltage fluctuation.

When a voltage exceeding the expanded dead zone width and the range of about 150 V up and down is detected, it is canceled by the automatic return unit 18 and returned to the normal up and down dead zone width of 80 V. The automatic return unit 18 may be provided in the tap changer 9 so that the dead band width of the voltage comparison unit 6 is restored when a tap change signal is detected.

In the above-described embodiment, the configuration has been described in which the automatic return unit 18 releases and returns to the normal dead band width. A configuration in which a timer unit 8 for returning to the steady tap switching state is provided may be used.

FIG. 5 shows another embodiment of the present invention according to claim 4. When it is determined that the detected voltage is voltage vibration, the vibration detection determination unit 12 of the voltage adjustment device 1 outputs a tap fixing signal that is fixed to the tap selection unit 7 or the current tap. Further, a switching count unit 20 for counting the number of tap switching between the raising tap and the lowering tap is provided, and this is connected to the tap selection unit 7. The switching count unit 20 is connected to the vibration detection determination unit 12 via a switching upper limit setting unit 21. Except for the point that the vibration counting unit 13 and the vibration period measuring unit 14 are not provided, other configurations are the same as those in FIG.

In the voltage regulator having the above-described configuration, the switching count unit 20 counts the number of tap switching signals from the tap selection unit 7, and the count number is within the switching upper limit setting unit 21 within a predetermined time set by the timer unit 8. For example, when the set number reaches seven times, the vibration detection determination unit 12 determines that the voltage vibration. When the voltage vibration is determined, the vibration detection determination unit 12 outputs a tap fixing signal to the tap selection unit 7 to be fixed to the tap or the current tap. When fixing to the tap at the current position, the tap is fixed as it is, and the tap switching is stopped for the time set by the timer unit 8 regardless of the presence or absence of voltage fluctuation. Thereafter, when the tap fixing time set by the timer unit 8 has elapsed, the normal voltage adjustment is resumed.

Further, when it is determined as voltage oscillation and is fixed to the through tap, it is fixed to the tap for which voltage adjustment is not performed for the time set by the timer unit 8. When the tap fixing time set by the timer unit 8 has elapsed, the normal voltage adjustment is restored. Accordingly, the voltage regulators 1A, 1B and the distributed power supply 10 individually control the voltage independently and interfere with each other. As a result, vibration occurs. Therefore, the voltage adjustment is not performed with the tap fixed for a certain time. The occurrence of voltage oscillation can be prevented.

In the above description, the tap fixing signal is output when the tap switching count reaches the upper limit setting number. However, the delay signal is output to slow down the tap switching response speed. Alternatively, a structure in which the dead zone width expansion signal is output to increase the tap switching dead zone width may be used. Further, the present invention may be configured to output a combination of a tap fixing signal and a delay signal or a dead band expansion signal when it is determined as vibration.

1 is a circuit diagram of a voltage regulator according to an embodiment of the present invention. It is a voltage waveform figure at the time of fixing a tap with the voltage regulator of FIG. FIG. 6 is a circuit diagram of a voltage regulator according to another embodiment of the present invention. It is a circuit diagram of the voltage regulator by another Example from which this invention differs. It is a circuit diagram of the voltage regulator by another Example from which this invention differs. It is a circuit diagram which shows the conventional voltage regulator. It is explanatory drawing which shows a power distribution system. It is a voltage waveform diagram in the state where voltage oscillation has occurred.

Explanation of symbols

1 Voltage regulator
2 Distribution lines
3 transformers
4 Voltage detector
5 Reference voltage section
6 Voltage comparator
7 Tap selection part
8 Timer section
9 Tap changer
10 Distributed power supply
12 Vibration detection determination unit
13 Vibration counter
14 Vibration period measurement unit
16 Response speed delay unit
17 Dead zone widened part
18 Automatic return part
20 switching count section
21 Switching upper limit setting section

Claims (4)

When a voltage change that exceeds the dead band width of the secondary voltage is detected, a voltage regulator that adjusts the system voltage by switching taps detects an operation in which the taps raised and lowered are repeated multiple times at almost the same cycle within a specified time. A tap detection unit that outputs to the tap selector a tap fixing signal that is connected to the vibration detection determination unit and that is fixed to the pass-through tap or the current tap when it is determined to be a vibration. And a timer unit for returning to a steady tap switching state after a lapse of a predetermined time after the tap selection unit is activated. When a voltage change that exceeds the dead band width of the secondary voltage is detected, a voltage regulator that adjusts the system voltage by switching taps detects an operation in which the taps raised and lowered are repeated multiple times at almost the same cycle within a specified time. A vibration detection determination unit that determines vibration, and a response speed delay unit that is connected to the vibration detection determination unit and outputs a delay signal that delays the tap switching response speed to the tap switch when it is determined to be vibration, A voltage regulator comprising: a timer unit that returns to a steady tap switching state after a lapse of a predetermined time after the response speed delay unit is activated. When a voltage change that exceeds the dead band width of the secondary voltage is detected, a voltage adjustment device that adjusts the primary voltage of the system voltage by tap switching and outputs it to the secondary side. When detecting an operation that repeats a plurality of times at substantially the same cycle, a vibration detection determination unit that determines vibration, and an enlarged signal that is connected to the vibration detection determination unit and expands the tap switching dead band when it is determined to be vibration. When the secondary voltage exceeding the expanded dead band width is detected and the tap switching signal is detected after the dead band width expanding unit that outputs to the voltage comparison unit and the dead band width expanding unit are activated, the normal tap switching state is restored. A voltage regulator comprising: a timer unit for returning to a steady tap switching state after a predetermined time has elapsed after the automatic return unit or dead band expanding unit is activated. . The vibration detection determination unit is connected to the switching count unit that counts the tap switching frequency of the raising tap and the lowering tap, and the switching upper limit setting unit that sets the upper limit of the tap switching frequency. 3, wherein a fixed signal, a delay signal, or a dead band widening signal is output by determining that the raising tap and the lowering tap are vibrations that are repeated a plurality of times at substantially the same period. 3. The voltage regulator according to 3.