JPH0799727A - Distribution system harmonic suppressor - Google Patents

Abstract

PURPOSE:To suppress the harmonic of a distribution system by a method wherein the harmonic voltage of the distribution system is detected through a pole transformer and a voltage which cancels the harmonic voltage is applied from an active filter. CONSTITUTION:Harmonic suppressors are distributed in a distribution system. Each harmonic suppressor is composed of the pole transformer 8 of the distribution system, a matching transformer 5 and an active filter(AF) 6 which are connected to the low voltage side of the pole transformer 8 and an LC filter 7 which is connected to them in series. That is, the voltage VT of the low voltage side of the pole transformer 8 is detected by the AF6 and its commercial frequency voltage component and other higher degree frequency components are converted into a DC component and an AC component respectively by a converter 6a. Further, the AC component is extracted through a high-pass filter 6b and the harmonic component is detected by an arithmetic unit 6c. The harmonic voltage component is multiplied by a gain K1 in a multiplier 6d and the resultant voltage V1 is supplied to the matching transformer 5 form the AF6. Therefore, a harmonic voltage is absorbed by the resultant harmonic voltage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a harmonic suppressor for suppressing harmonics of a distribution line generated from a load in a distribution system.

[0002]

2. Description of the Related Art Conventionally, as a method for suppressing harmonics generated from a load of a power distribution system, as shown in FIG. 9, for example, a passive filter (LC) is provided to a specific harmonic source 1 whose harmonic order is known in advance. A general method is to install and suppress the filter 2.

However, in such a suppression method,
Since the order of the harmonics to be suppressed is fixed in the passive filter 2, even if the harmonics of the specified order can be suppressed,
There is a problem that harmonics of other orders cannot be suppressed. Further, since the passive filter 2 is directly connected to the distribution voltage system of 6 kV class, it is a large-capacity, large-sized and expensive device itself in consideration of overload prevention and tuning deviation due to unexpected harmonics. Therefore, even if it can be installed in a high-voltage customer, it is difficult to mount it on the pole of the distribution system.

Therefore, recently, as shown in FIG. 10, a current injection type active filter 3 capable of suppressing multi-order harmonics has been used. The principle is to detect the harmonic current I _e, the suppression current I _A to cancel the harmonic current I _e is injected from the active filter 3, a current I _e + I _A flowing to the power distribution system, the harmonic This is a method of reducing the distribution current.

By the way, when such a current injection type active filter 3 is installed in a power distribution system to suppress harmonics, as shown in FIG. 11, an unspecified number of harmonic sources 1 of the load and the active filter 3 are provided. In general, a case in which a capacitive load 4 such as a power factor improving capacitor or an underground cable is present between the two. In this case, the active filter 3
The harmonic current I _e1 is detected and a negative suppression current I _A is injected to cancel it.

However, when the capacitive load 4 exists on the load side, the suppression current I _A is divided into the suppression current I _A1 flowing in the power system and the suppression current I _A2 flowing in the capacitive load 4. Therefore, the active filter 3 has the current I _e1 + I
_{Although A2} is detected, since the current I _A2 is negative and flows in the opposite direction, a harmonic current is superimposed as shown in FIG. As a result, the active filter 3 detects the superimposed harmonic current and injects a larger suppression current I _A in an attempt to cancel it, which may eventually result in unstable operation.

[0007] The current injection type fluctuating filter 3 is directly connected to the power distribution system, and P
Since the operation is performed by the WM control, in this case, harmonics of the carrier frequency component flow out from the active filter 3 to the power distribution system, and it is feared that noise may be generated in an adjacent communication line due to the inductive action of the harmonics. .

[0008]

As described above, in the conventional method of suppressing harmonics in a power distribution system, if a capacitive load is present on the load side, the harmonics cannot be suppressed, and the harmonics cannot be applied to communication lines. There is a problem in that the device itself needs a large capacity, a large size, and a high price because it causes noise that affects the device and it is necessary to insulate the device because it is directly connected to 6 kV.

It is an object of the present invention to suppress an unspecified number of higher harmonics without any trouble even if a capacitive load is present on the load side, and to prevent the generation of noise affecting communication lines and the like. Moreover, it is an object of the present invention to provide a highly reliable harmonic suppression device that can be compactly installed and can be easily installed on a pole or the like of a distribution system.

[0010]

In order to achieve the above-mentioned object, in order to suppress the harmonics generated from the load of the distribution system, in the invention described in [Claim 1], it is distributedly installed in the distribution system. It consists of a pole transformer on the distribution line, a matching transformer connected to the low voltage side, an active filter, and a passive filter (LC filter) connected in series with these, and the active filter converts the harmonic voltage generated on the load side. By detecting the voltage through a pole transformer and applying a voltage for canceling the harmonic voltage to the matching transformer, LC
The filter is configured to absorb the harmonic voltage.

According to the invention described in [Claim 2], the transformers are dispersedly installed in the distribution system, and the pole transformer of the distribution line, the matching transformer and the active filter connected to the low-voltage side thereof, and these are connected in series. The active fill, which consists of the LC filter, uses the voltage on the low voltage side of the pole transformer as the control power source via the automatic voltage regulator, detects the harmonic voltage generated on the load side via the pole transformer, and The LC filter is configured to absorb the harmonic voltage by applying a voltage for canceling the harmonic voltage to the matching transformer.

In the invention described in [Claim 3], the transformers are installed in the distribution system in a distributed manner, and the pole transformer of the distribution line, the matching transformer and the active filter connected to the low-voltage side thereof, and these are connected in series. The active filter detects the harmonic voltage and harmonic current on the low voltage side of the pole transformer in order to cancel the harmonic voltage of the distribution line on the high side of the pole transformer. To find the voltage drop due to the pole transformer by the product of the current and the impedance of the pole transformer, and to correct the added voltage drop by adding it to the detected harmonic voltage to cancel the corrected harmonic voltage. By applying this voltage to the matching transformer, the pole transformer and the LC filter absorb the harmonic voltage.

[0013]

Therefore, the harmonic suppressing device according to the first aspect of the present invention detects the harmonic voltage of the distribution system through the pole transformer and applies a voltage for canceling it to the active filter. As a result, the combined impedance including the matching transformer and the LC filter is set to a resistance close to 0 [Ω] with respect to the voltage to be suppressed, the harmonic voltage is absorbed, and the harmonic of the distribution system is suppressed. it can.

Further, in this case, since the active filter operates as a voltage source, it is not affected by the capacitive load on the load side. And PWM of active filter
The high frequency of the carrier frequency component generated by the control switching becomes difficult to flow out to the power distribution system due to the inductive impedance of the matching transformer and pole transformer that have high resistance to the high frequency.

On the other hand, in the harmonic suppressing device according to the second aspect of the present invention, the harmonic voltage can be absorbed to suppress the harmonics of the distribution system, and the low voltage side of the pole transformer. Since this voltage is used as the control power supply for the active filter via the automatic voltage regulator, a power supply facility such as a battery is not required, and a compact design can be achieved.

Further, in the harmonic suppression method for a harmonic suppression device according to [claim 3] of the present invention, in order to cancel out the harmonic voltage of the distribution line on the high voltage side of the pole transformer, the pole transformer The voltage drop due to the impedance is corrected to the detected harmonic voltage, and the voltage for canceling the corrected harmonic voltage is applied from the active filter to the matching transformer, so that the impedance of the pole transformer and the LC filter is reduced. Is a resistance close to 0 [Ω] with respect to the voltage of the distribution line on the high voltage side of the pole transformer, and the harmonic voltage of the high voltage distribution line can be absorbed to suppress the harmonics.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a circuit diagram showing a configuration example of the harmonic wave suppression device according to the first embodiment, and the same elements as those in FIGS. 9 and 10 to 11 are designated by the same reference numerals and the description thereof will be omitted.

That is, as shown in FIG. 1, the harmonic suppression device of this embodiment is distributed and installed in the distribution system (only one device is shown in the figure), and the pole transformer 8 of the distribution system is shown. , And matching transformer 5 connected to the low voltage side
And an active filter 6 and a passive filter (LC filter) 7 connected in series to them, the active filter 6 detects a harmonic voltage generated on the load side through a pole transformer 8, and detects this harmonic wave. By applying a voltage for canceling the voltage to the matching transformer 5, the LC filter 7 absorbs the harmonic voltage.

FIG. 2 is a block diagram showing a control configuration example of the active filter 6. That is, the active filter 6 includes a conversion device 6a, a high-pass filter 6b, a calculation device 6c, and a multiplier 6d, as shown in the figure.

Here, the conversion device 6a inputs the voltage V _T on the low voltage side of the pole transformer 8 and converts the commercial frequency voltage component into a DC component and the other higher order frequency components into an AC component. . The high-pass filter 6b receives the output from the conversion device 6a and extracts the alternating current component.

Further, the arithmetic unit 6c inputs the output from the high-pass filter 6d and detects the harmonic component thereof. Furthermore, the multiplier 6d is the arithmetic unit 6c.
The output from is input, the gain of K ₁ is multiplied, and the voltage V ₁ is output.

Next, the operation of the harmonic wave suppressing device of the present embodiment having the above-mentioned structure will be described. In FIG.
The voltage V _T on the low voltage side of the pole transformer 8 is detected by the active filter 6, and the commercial frequency voltage is converted into a DC component and the other high-order frequency components are converted into an AC component by the converter 6a in FIG. Further, the AC component is extracted via the high-pass filter 6b, and the harmonic component is detected by the arithmetic unit 6c. Then, a multiplier 6 is added to the detected harmonic voltage component.
The gain of K ₁ is multiplied by d, and the voltage V ₁ is output from the active filter 6 to the matching transformer 5.

FIG. 3 is a diagram showing the single-phase equivalent circuit of FIG. In FIG. 3, the active filters 6 distributed in the distribution system detect the harmonic voltage component V _T1 of the distribution voltage V _T and apply V ₁ = −K ₁ V _T1 that is K ₁ times higher. Here, when the impedance of the LC filter 7 is Z ₁ , the equivalent impedance of V ₁ to the harmonic and LC filter 7 is Z ₁ / (1 + K ₁ ).

Therefore, by setting the gain K ₁ of the multiplier 6d to infinity or a large value in the active filter 6, the equivalent impedance Z ₁ / (1 + K ₁ ) becomes almost 0 [Ω]. Therefore, the impedance becomes about 0 [Ω] with respect to the above harmonic voltage, so that the harmonic voltage is absorbed.

Therefore, even if there is a capacitive load 4 such as a power factor improving capacitor or an underground cable between the active filter 6 and the harmonic generation source 1, a conventional current is injected. Since it is not a system but a system that detects voltage and absorbs only harmonic voltage, it is not affected by the type of load.

As a result, even if the capacitive load 4 exists on the load side, it is possible to suppress the harmonics generated by an unspecified number of harmonic sources 1 without being affected by the capacitive load 4, and thus the power distribution. It is possible to eliminate the harmonic interference of the system and further reduce the distribution voltage to a proper total voltage distortion rate or less.

Further, in the prior art, since the active filter is directly connected to the distribution line, the harmonics of the carrier frequency component generated by the PWM control method flow out from the active filter to the distribution line, and the induction action due to this harmonic causes There is a risk that it may become a source of noise on the communication line or telephone line installed in parallel with the distribution line. However, in this point, in the method of the present embodiment, the inductive impedance of the matching transformer 5 and the pole transformer 8 has a high resistance to a high frequency, and the high frequency does not flow out to the distribution system, so that noise such as a communication line is generated. There is no fear of becoming a source.

Further, the capacitance required for the LC filter 7 is
It is the product of the fundamental wave voltage and the harmonic current, but since the impedance to the harmonic wave is lowered by the operation of the active filter 6, it is not necessary to increase the fundamental wave capacity.
Moreover, since it is used on the low voltage side of the pole transformer 8, it is easier to secure insulation than when it is installed on the high voltage side of the pole transformer 8. Therefore, a compact design is possible, and it can be easily installed on a pillar or the like.

Next, another embodiment of the present invention will be described. FIG. 4 is a circuit diagram showing a configuration example of a harmonic wave suppression device according to a second embodiment of the present invention, the same elements as those in FIG. Will be described only.

In the distribution system, as shown in FIG.
A large number of unspecified harmonic sources 11, 12, ..., such as home electric appliances, are dispersed and distort the voltage of the distribution system. Therefore, matching transformers 51, 52, ..., Active filters 61, 6 distributed and installed in the power distribution system with respect to the unspecified large number of harmonics.
2, the harmonic voltages V ₁ , V ₂ , ... Of the distribution voltage to which the matching transformers 51, 52 are connected are applied.

Specifically, the impedances of the matching transformers 51, 52, ..., Active filters 61, 62, ..., LC filters 71, 72 ,. By absorbing only the wave voltage, the voltage distortion of the power distribution system can be suppressed.

FIG. 5 is a circuit diagram showing a structural example of a harmonic wave suppression device according to a third embodiment of the present invention. The same elements as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. Now, only different parts will be described.

As shown in FIG. 5, the harmonic suppression device of this embodiment is distributedly installed in the distribution system (only one device is shown in the figure), and the pole transformer 8 of the distribution line and its transformer are installed. It consists of a matching transformer 5 connected to the low voltage side, an active filter 6, an LC filter 7 and an automatic voltage regulator 9 connected in series to these, and the distribution voltage V _T of the pole transformer 8 on the low voltage side is an automatic voltage regulator. 9 to be used as a power source for controlling the active filter 6,
Detects the harmonic voltage generated on the load side through the pole transformer 8 and applies the harmonic voltage for canceling the harmonic voltage to the matching transformer 5 to absorb the harmonic voltage in the LC filter 7. It is configured to do.

That is, by controlling the operation of the active filter 6 as in the first embodiment of the present invention and applying a voltage for canceling the harmonic voltage of the distribution line to the matching transformer 5, the harmonics of the distribution line are reduced. On the other hand, by making the impedances of the matching transformer 5, the active filter 6, and the LC filter 7 close to 0 [Ω] and absorbing only the harmonic voltage,
Voltage distortion can be suppressed. Further, since the active filter 6 receives the control power source from the low voltage side of the pole transformer, the active filter 6 main body does not require a power source facility such as a battery and can continuously operate.

Next, a fourth embodiment of the present invention will be described. FIG. 6 is a circuit diagram showing a configuration example of a harmonic wave suppression device according to a fourth embodiment of the present invention. The same elements as those in FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. Will be described only.

As shown in FIG. 6, the harmonic suppression device of the embodiment of FIG. 4 is distributed and arranged in the distribution system (only one device is shown in the figure), and the pole transformer 8 of the distribution line is also shown. , And a matching transformer 5 connected to the low-voltage side thereof, an active filter 6, a transformer 10, and an LC filter 7 connected in series to these, and the active filter 6
Detects the harmonic voltage via the pole transformer 8 and the harmonic current on the low voltage side of the pole transformer 8 via the transformer 10, and detects the high voltage side distribution line of the pole transformer 8. In order to cancel the harmonic voltage of the above, a voltage corrected by the voltage drop due to the impedance of the pole transformer 8 is applied to the matching transformer 5.

FIG. 7 is a block diagram showing a control configuration example of the active filter 6. That is, the active filter 6 includes the conversion devices 6a and 10 as shown in FIG.
a, the high-pass filters 6b and 10b, and the arithmetic unit 6
c and 10c, multipliers 6d and 10d, and adder 10e
And consists of.

The converters 6a and 10a convert the voltage V _T on the low voltage side of the pole transformer 8 and the harmonic current I _T flowing from the high voltage side of the pole transformer 8 to the low voltage side on the pole transformer. The commercial frequency current component is converted into a direct current component, and the other higher order frequency components are converted into an alternating current component.

Further, the high pass filters 6b and 10b
Is to input the outputs from the converters 6a and 10a, respectively, and extract the alternating current component. Further, the arithmetic units 6c and 10c are provided with high-pass filters 6b and 10b.
The output from each is input, and the harmonic component is detected.

Furthermore, the multiplier 6d is the arithmetic unit 6c.
It outputs the voltage by inputting the output from, multiplying by the K ₁ gain. On the other hand, the multiplier 10d is the arithmetic unit 10c.
Input the output from the pole transformer impedance Z _PT
Is multiplied by and the voltage is output.

The adder 10e receives the outputs from the arithmetic units 6d and 10d and outputs a voltage V ₂ which is the sum of the outputs. Next, the operation of the harmonic wave suppression device of the present embodiment configured as described above will be described with reference to FIGS. 6 to 7.

In FIG. 6, on the one hand, the harmonic voltage V _T on the low voltage side of the pole transformer 8 is detected by the active filter 6 via the pole transformer 8, and the converter 6a converts the commercial frequency voltage into a DC component. In addition, other high-order frequency components are converted into alternating current components. The AC component is extracted via the high-pass filter 6b, and the harmonic component is detected by the arithmetic unit 6c. Further, a multiplier 6 is added to the detected harmonic voltage component.
The voltage multiplied by the gain of K ₁ by d is output.
On the other hand, the harmonic current I _T flowing through the low voltage side of the pole transformer 8 is detected by the active filter 6 via the pole transformer 8, and the converter 10a converts the commercial frequency current into a direct current component and other high-order components. The frequency component is converted into an alternating current component. In addition, the AC component is extracted through the high-pass filter 10b,
The harmonic component is detected and the phase is adjusted by 10c. Further, a multiplier 10d is added to the detected harmonic current component.
Thus, the value obtained by multiplying the impedance Z _PT of the pole transformer 8 is the correction value V _PT for the voltage drop due to the impedance of the pole transformer 8. Then, the output of the above harmonic voltage component is added by the adder 10e to the correction value V _PT for the voltage drop due to the impedance of the pole transformer 8, and the multiplier 6d adds K ₁ to this harmonic voltage component. The voltage V ₂ multiplied by the gain is output from the active filter 6 to the matching transformer 5.

That is, in order to suppress the harmonic voltage of the high voltage distribution line on the high voltage side of the pole transformer 8, the harmonic current detected on the low voltage side of the pole transformer 8 is measured in advance. The voltage multiplied by the impedance of the device 8 is used as a correction value, and in addition to the harmonic voltage detected on the low voltage side, the voltage V ₂ is applied from the active filter 6 so as to cancel the harmonic voltage of the high voltage distribution line.

Specifically, the pole transformer 8, the active filter 6, and the LC filter 7 are applied to the harmonics of the high-voltage distribution line.
The voltage distortion of the high-voltage distribution line can be suppressed by bringing the impedance of (1) close to 0 [Ω] and absorbing only the harmonic voltage component.

FIG. 8 is a diagram showing the single-phase equivalent circuit of FIG. Here, the voltages V _T , V _T1 , V ₁ , V ₂ , the current I _T ,
Impedances Z ₁ , Z _F , Z _PT, etc. are vector values. In FIG. 8, the active filters 6 distributed and installed on the pole transformers of the distribution lines of the distribution system are the distribution voltage V _T.
The harmonic voltage components V _T1 to those _1x K, Inpi the pole transformer 8 - applying a voltage plus the voltage drop due to Z _PT dance _{V = -K 1 V T1 + I} T1 · Z PT . Where L
Assuming that the impedance of the C filter 7 is Z _F , the equivalent impedance of V ₂ with respect to the harmonic and the LC filter 7 is (Z _F + Z _PT ) / (1 + K ₁ ).

Therefore, by setting the gain K ₁ of the multiplier 6d to infinity or a large value in the active filter 6, the equivalent impedance (Z _F + Z _PT ) / (1+
K ₁ ) becomes almost 0 [Ω]. Therefore, the impedance is about 0 [Ω] with respect to the harmonic voltage of the high-voltage distribution line, so that the harmonic voltage is absorbed.

As described above, the harmonic suppressor of this embodiment is installed in the distribution system in a distributed manner, and the pole transformer 8 of the distribution system and the matching transformer 5 and the active filter 6 connected to the low voltage side thereof. And a transformer 10 and an LC filter 7 connected in series to the transformer 10, and the active filter 6 converts the harmonic voltage generated on the load side and the harmonic current on the low voltage side of the pole transformer 8 into the pole transformer 8. And a configuration in which the LC filter 7 absorbs the harmonic voltage by applying a voltage to the matching transformer 5 that is detected through the transformer 10 and cancels the harmonic voltage of the high voltage distribution line on the high voltage side of the pole transformer 8. It is what

Therefore, in order to suppress the harmonic voltage on the high voltage side of the pole transformer 8, the harmonic suppression device of the present embodiment eliminates the voltage drop due to the impedance of the pole transformer 8 from the pole transformer. A voltage is applied from the active filter 6 to the matching transformer 5 so as to cancel out the voltage obtained by adding it to the product of the impedance of the device 8 and the harmonic current flowing through the low voltage side and adding it to the detected harmonic voltage. As a result, it is possible to suppress harmonics in the high-voltage distribution line on the high-voltage side of the pole transformer 8, remove harmonic interference in the distribution system, and further reduce the distribution voltage to an appropriate total voltage distortion factor or less. Can be

[0049]

As described above, according to the inventions of claims 1 and 2, the pole transformers of the distribution line, the matching transformers connected to the low voltage side thereof, and the active filter are distributed and installed in the distribution system. , And L connected in series with them
The active filter is composed of a C filter, and the active filter detects a harmonic voltage of the distribution line generated on the load side through a pole transformer and applies a voltage for canceling the harmonic to a matching transformer, thereby the LC filter. Since it is configured to absorb the harmonic voltage, it is possible to suppress an unspecified number of harmonics without any trouble even if a capacitive load exists on the load side.
Further, it is possible to provide a highly reliable harmonic suppression device that is free from the possibility of generating noise that affects communication lines and the like, and that is compact and can be easily installed on a pole of a power distribution system or the like.

According to the third aspect of the present invention, the pole transformer of the distribution line, the matching transformer, the active filter and the transformer connected to the low voltage side of the transformer are installed in the distribution system in a distributed manner, and these transformers are also installed. It consists of LC filters connected in series, and the active filter detects the harmonic voltage generated on the load side via the pole transformer, and the harmonic current on the low side of the pole transformer via the transformer. In order to cancel the harmonic voltage on the high voltage side of the pole transformer by detecting it, the voltage drop due to the impedance of the pole transformer is corrected to the detected harmonic voltage, and the voltage for canceling the corrected harmonic voltage is added. By applying to a matching transformer, the pole transformer and LC
Since the filter absorbs the harmonic voltage and suppresses the harmonic voltage of the distribution line, even if there is a capacitive load on the load side, it is possible to suppress an unspecified number of harmonics without any trouble, and It is possible to provide a highly reliable harmonic suppression device that is free from the possibility of generating noise that affects communication lines and the like, and that can be made compact and can be easily installed on a pole or the like of a power distribution system.

[Brief description of drawings]

FIG. 1 is a diagram showing a first harmonic suppression device for a distribution system according to the present invention.
Circuit diagram showing an embodiment of

FIG. 2 is a block diagram showing a control configuration example of an active filter in the embodiment.

FIG. 3 is a diagram showing a single-phase equivalent circuit in the case where the harmonic suppression device according to the embodiment is installed in a power distribution system;

FIG. 4 is a circuit diagram showing an example of a state in which the harmonic suppression devices of the same embodiment are dispersedly installed in a power distribution system;

FIG. 5 is a circuit diagram showing a second embodiment of the harmonic suppression device according to the present invention,

FIG. 6 is a circuit diagram showing a third embodiment of the harmonic suppression device according to the present invention,

FIG. 7 is a block diagram showing a control configuration example of an active filter in the embodiment.

FIG. 8 is a diagram showing a single-phase equivalent circuit in the case where the harmonic suppression device according to the embodiment is installed in a power distribution system;

FIG. 9 is a diagram for explaining a concept showing harmonic suppression by a conventional passive filter;

FIG. 10 is a diagram for explaining a concept showing harmonic suppression by a conventional current injection type active filter;

FIG. 11 is a diagram for explaining the principle when the current injection type active filter is applied to a power distribution system;

FIG. 12 is a diagram showing an example of a harmonic current detection waveform model of a current injection type active filter.

[Explanation of symbols]

 1, 11, 12 ……… Harmonic source 2 ………………………… Passive filter 4, 41, 42 ……… Capacitive load 5, 51, 52 ……… Matching transformer 6, 61, 62, 3 … Active filter 7, 71, 72 ……… LC filter 8, 81, 82 ……… Pole transformer 9 ……………………… Automatic voltage regulator 10 …………………… Transformer 6a, 10a ...... Conversion device 6b, 10b ...... High pass filter 6c, 10c ...... Calculation device 6d, 10d ...... Multiplier 10e ...................... Adder

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takashi Ishiguro No. 1 Toshiba-cho, Fuchu-shi, Tokyo Toshiba Corporation Fuchu factory

Claims (3)

[Claims] 1. A pole transformer that is distributedly installed in a distribution system and connected to a distribution line, a matching transformer connected to the low-voltage side thereof, an active filter for suppressing harmonics of the distribution line, and The passive filter is connected in series, the active filter detects the harmonic voltage generated on the load side through the pole transformer, a voltage for canceling the harmonic voltage of the distribution system to the matching transformer. A harmonic suppressor for a power distribution system, wherein the LC filter absorbs a harmonic voltage by applying the voltage. 2. The harmonic suppressor for a power distribution system according to claim 1, wherein the control power source of the active filter is
A harmonic suppression device for a power distribution system, which is obtained from a low voltage side of the pole transformer via an automatic voltage regulator. 3. The harmonic suppression device for a power distribution system according to claim 1, wherein the active filter detects a harmonic voltage generated on the load side via a pole transformer, and at the same time, the pole transformer low voltage. Side harmonic current is detected through the transformer, the voltage drop of the harmonic due to the impedance of pole transformer is corrected, and the voltage for canceling the corrected harmonic voltage is applied to the matching transformer. Therefore, the pole suppressor and the passive filter are configured to absorb the harmonic voltage.