KR100493987B1 - Advanced zero sequence harmonic filter - Google Patents

Abstract

The present invention relates to an image harmonic filter that reduces the image harmonic current, and in particular, effectively attenuates the image harmonic current of the system generated in a three-phase four-wire power conversion system, as well as the fundamental due to the phase unbalance flowing through the neutral line. A filter using an image splitting reactor capable of reducing wave current, wherein the image split harmonic filter for reducing image harmonic currents generated when driving a single-phase nonlinear load in a three-phase four-wire power system includes: A three-leg iron core with low impedance and high impedance for the three-phase AC power source connected in series between the 4-wire AC power supply and the single-phase load that generates the image harmonic currents. Image breaker reactor with the three-phase coil wound around the middle leg with the same number of turns It characterized by further comprising an image minutes harmonic filter, such as zag transformer-third harmonic LC filter tuning or jig which is connected in parallel between the actors and the load.

Description

Improved Image Harmonic Filter {Advanced Zero Sequence Harmonic Filter}

The present invention relates to an improved image harmonic filter using an image separation reactor capable of effectively blocking image harmonic currents generated when using a single-phase nonlinear load in a three-phase four-wire power system. By using a split-block reactor, there is an improvement of up to 160% over the reduction rate of the image harmonic current of the existing image harmonic filter.

The recent rapid increase in the use of electronic products has increased the generation of image harmonic currents in power lines, and these image harmonic currents are larger than phase currents. It also causes serious problems such as transformer overheating, generator output loss, power factor decrease, power loss increase, induced disturbance, and neutral ground potential increase.

In order to solve this problem, conventional harmonic currents have been reduced by using a third harmonic LC tuning filter or by using a zigzag transformer for reducing harmonics of the image.

However, the third harmonic LC tuning filter has a resonance problem with the system, and the zigzag transformer has a low effect of reducing harmonic currents when the impedance of the system is smaller than that of the zig-zag transformer.

In order to solve this problem, a technique of reducing image harmonics by connecting a low-impedance jig-zag transformer between a load and a neutral line of a power system has been disclosed (USP 5576942), and FIG. 1. As shown in Fig. 1, a harmonic filter (Domestic Patent Registration No. 10-0364513) in a power line is disclosed.

However, the US prior art (US Patent No. 5576942) has a single phase line reactor connected to a neutral line in series, thereby causing the reactor element to be overheated by the image harmonics, thereby causing the neutral wire to be disconnected.

In addition, the domestic prior art (Domestic Patent Registration No. 10-0364513) connects a line reactor in series between a power supply and a load to increase the impedance of the system to facilitate the inflow of image harmonic currents into the zigzag transformer, but the line reactor Because of the large current capacity, the price is high, and if the impedance of the line reactor is increased to increase the reduction rate of harmonic current in the image, the impedance of the line reactor as well as the impedance of the normal and reverse phases increases, resulting in the heat generation of the line reactor. Severe voltage drop occurs in the system and power loss caused by the line reactor

As shown in FIG. 2, the image cut-off reactor of the present invention is a reactor in which three-phase coils are wound around the middle leg of the core having three legs with the same number of windings, and have its own reactance (Z _S ) and mutual reactance (Z _M ). As a result, the impedance Z ₀ with respect to image harmonics increases, and decreases with respect to normal phase Z _P and reverse phase harmonics Z _N.

If the line reactors have the same impedance for video, normal and reverse phase, the video cut-off reactor will increase the video impedance to twice its circulating reactance plus its own reactance, and the normal and reverse phase impedances will react on their own. The circulating reactance is subtracted from and reduced.

Equation 1 is an impedance calculation equation of the cut-off reactor for the image, normal and reverse phases.

Z ₀ = Z _S + 2Z _M

Z _P = Z _S -Z _M (Equation 1)

Z _N = Z _S -Z _M

According to the present invention, an image interruption reactor having a high impedance with respect to the image harmonics of the system and a small impedance with respect to the normal and reverse phases is connected in series between the system and the load. When the harmonic LC tuning filter is connected in parallel to reduce the third harmonic current, the image blocking reactor prevents resonance with the system and smoothly introduces the third harmonic current into the filter.

Alternatively, the video splitting reactor is connected in series between the three-phase four-wire power system and the load, and a jig-zag transformer is connected in parallel between the video splitting reactor and the load to reduce the video split current. The third-order harmonic current flows smoothly by the blocking reactor, and the normal and reverse phase impedance is minimized, minimizing voltage drop that may occur when the line reactor is installed in series between the three-phase four-wire power system and the load. In addition, the calorific value and self-loss are also reduced.

When the line reactor is installed, the voltage drop rate is 5 ~ 6%. When the video split reactor is installed, the voltage drop rate is about 0 ~ 1%.

An improved image harmonic filter according to a feature of the present invention for achieving the above object,

Image harmonic current generated in the system driving single-phase nonlinear load 13 by connecting each of A, B, C phase and N phase 42 with a power applied through a three-phase four-wire transformer 12. In the device for reducing,

As shown in FIG. 3, a power supply system using a three-phase four-wire transformer 12 having a three-phase four-wire transformer 12 having a three-phase coil wound in the middle leg of the core having three legs wound with the same number of turns. Connect in series between the single-phase nonlinear load 13 driven by power supplied from the transformer, and the third order in parallel between the above-described image disconnect reactor 22 and the single-phase nonlinear load 13 connected in series. The harmonic current LC tuning filter 32 is connected, and the neutral point 43 of the single-phase capacitor connected to Y in the third harmonic current LC tuning filter and the neutral wire 42 of the three-phase four-wire power system are connected in parallel. A method of reducing the image harmonic current flowing into the

As shown in FIG. 4, a power supply system using a three-phase four-wire transformer 12 having a three-phase four-wire transformer 12 having a three-phase four-wire transformer 12 wound around a three-leg coil with the same number of windings in a middle leg of an iron core having three legs. Three-phase jig connected in series between the single-phase nonlinear load 13 driven by power supplied from the transformer, and connected in parallel between the series-connected cut-off transformer 22 and the single-phase nonlinear load 13 connected in series. A method of reducing image harmonic currents flowing into the system by connecting the neutral wire 43 of the zig-zag transformer 31 and the neutral wire 43 of the system in parallel;

As shown in FIG. 5, a power supply system using a three-phase four-wire transformer 12 having a three-phase four-wire transformer 12 having a three-phase four-wire transformer 12 wound around a three-leg coil with the same number of windings in a middle leg of an iron core having three legs. Single-phase connected in series between the single-phase nonlinear load 13 driven by power supplied from the transformer, and connected in parallel between the above-described series-connected cut-off transformer 22 and the single-phase nonlinear load 13 in parallel. Condenser 33, the three-phase jig-zag transformer 31 connected in series with the single-phase condenser 33, the neutral line 43 of the jig-zag transformer and the neutral line 42 of the system in parallel There is a method to reduce the image harmonic current flowing into the system by being connected.

As described above, the present invention uses the reactor element that has been installed in the system to enhance the reduction efficiency of the image harmonic current by using an image blocking reactor in which the impedance of the normal phase and the reverse phase is low and only the image impedance is increased. In addition to improving the reduction rate, the reduction rate of the phase unbalance current flowing through the neutral wire due to the phase unbalance is also superior to the existing line reactor, and is effective in reducing the current flowing through the neutral wire.

Table 1 shows the results of the simulations performed in detail for the effect of the invention.

6 7 8 9 10 Example of installation Without filter Line L + LC Filter Image Blocker L + LC Filter Line L + Z-Z Tr Image Blocking L + Z-Z Tr N phase current [A] 158.46 49.47 18.38 26.37 13.48

 6 is a current waveform flowing through a neutral wire of a three-phase four-wire system without a harmonic filter.

7 shows a current flowing in a neutral line of a three-phase four-wire system when a line reactor is connected in series to a three-phase four-wire system and a third harmonic current LC tuning filter is installed in parallel between the line reactor and the single-phase nonlinear load. Waveform.

8 is a diagram of a three-phase four-wire system in which an image separation reactor is connected in series to a three-phase four-wire system, and a third harmonic current LC tuning filter is installed in parallel between the image separation reactor and a single-phase nonlinear load. It is a current waveform flowing through the neutral line.

FIG. 9 is a current waveform flowing in a neutral line of a three-phase four-wire system when a line reactor is connected in series to a three-phase four-wire system and a zig-zag transformer is installed in parallel between the line reactor and the single acid nonlinear load.

FIG. 10 is a current waveform flowing through a neutral wire of a three-phase four-wire system when a video separation reactor is connected to the three-phase four-wire system in series and a zig-zag transformer is installed in parallel.

1 is a diagram illustrating a conventional image harmonic reduction device.

2 is a view showing an image separation reactor according to the present invention.

3 is a diagram illustrating the connection of an image separation blocking reactor and an image harmonic filter combining an LC filter according to an embodiment of the present invention.

4 is an exemplary diagram of wiring of an image harmonic filter in which an image blocking reactor and a zig-zag transformer are combined according to an exemplary embodiment of the present invention.

FIG. 5 is a diagram illustrating a connection of an image separation reactor according to an embodiment of the present invention, and an image harmonic filter whose impedance is further lowered by using a resonance between a capacitor and a zig-zag transformer.

6 is an image harmonic current waveform flowing through a neutral line by a single-phase nonlinear load when an image harmonic filter is not used.

7 is an image harmonic current waveform flowing through a neutral line when an image harmonic filter using a line reactor and an LC filter is used.

8 is an image harmonic current waveform flowing through a neutral line when an image harmonic filter using an image separation reactor and an LC filter is used.

9 is an image harmonic current waveform flowing through a neutral line when an image harmonic filter using a line reactor and a zig-zag transformer is used.

10 is an image harmonic current waveform flowing through a neutral line when an image harmonic filter using an image separation reactor and a zig-zag transformer is used.

Claims (3)

 In the improved image harmonic filter, Power supply system having three-phase four-wire connection to supply power to load, The three-phase coil is wound around the middle leg with the same number of windings among the three legs connected in series between each of the three phases of the power supply and each of the three phases of the load. Increase the impedance of the image components, which are multiples of (3n, n = 0, 1, 2, ...) such as 3, 6, 9, to prevent the inflow of image harmonic currents into the system. Using an image blocking reactor that smoothly flows into the system by lowering the impedance for the normal current that is a multiple of (3n + 1) and the reverse phase current that is a multiple of (3n + 2) such as 2, 5, and 8 An improved image harmonic filter, characterized in that. delete  In the improved image harmonic filter, Power supply system having three-phase four-wire connection to supply power to load, The three-phase coil is wound around the middle leg with the same number of windings among the three legs connected in series between each of the three phases of the power supply and each of the three phases of the load. Increase the impedance of the image components, which are multiples of (3n, n = 0, 1, 2, ...) such as 3, 6, 9, to prevent the inflow of image harmonic currents into the system. An image interruption reactor that smoothly flows into the system by lowering the impedance for the normal current which is a multiple of the same (3n + 1) and the reverse phase current that is a multiple of (3n + 2) such as 2, 5, and 8; An improved image harmonic filter comprising a zig-zag transformer connected in parallel to each phase line and the neutral line between the image separation reactor and the load.