KR200354200Y1 - Apparatus for automatic power factor modulation of power reducing type - Google Patents

Abstract

The present invention relates to a power-saving automatic power factor adjustment device. More specifically, by adding an automatic power factor adjustment device to a power saver, it always maintains a 95% power factor to prevent power loss, eliminate reactive power, and flow only active power. Relates to a device.

Energy-saving automatic power factor adjustment apparatus of the present invention includes a current transformer for converting the current from the input power; A power factor detector for detecting a power factor by the output signal of the current transformer; A plurality of automatic regulators including a switching unit, a series reactor unit, a discharge coil unit, and a condenser unit for automatically correcting the power factor detected by the power factor detector; And a power saver including a plurality of magnetic contactors provided at an end portion of the voltage induction winding part connected to the input power source.

Therefore, the power saving type automatic power factor adjustment device of the present invention has the greatest advantages of the automatic power factor adjustment device, which is effective in reducing the active power and improving the harmonics and noise, but has not seen the effect of power saving by only the power saving factor and power factor improvement part that lacked the power factor improvement. Combination can provide maximum power saving and power improvement effect. By combining automatic power factor adjustment device inside the power saver box, there is no need to install capacitors externally, so you can see the spatial effect. This saves the time and cost of having to do two operations for the capacitor installation.

Description

Apparatus for automatic power factor modulation of power reducing type

The present invention relates to a power-saving automatic power factor adjustment device. More specifically, by adding an automatic power factor adjustment device to a power saver, it always maintains a 95% power factor to prevent power loss, eliminate reactive power, and flow only active power. Relates to a device.

Electric power is an extremely versatile and convenient energy source. However, the production and transmission of electrical energy is expensive, and when the demand for electricity increases, the cost also increases. For this reason, there have always been attempts to increase power transmission and utilization efficiency or, conversely, to reduce losses in the transmission and use of electrical energy. AC power is characterized by the phase relationship between current and voltage. If the inductive load is large, the current is delayed rather than the voltage. If the inductive load is large, the current is ahead of the voltage. In-phase relationships arise from resistive loads or from the balance of induced and capacitive loads. From the in-phase current, a 'real' resistive power is generated, and from an abnormal current, 'apparent' reactive power is generated by the influence of inductive or capacitive reactance of the power circuit. Commonly used to measure the phase relationship between current and voltage is a power factor, which corresponds to the cosine of the phase angle between voltage and current. The power factor is maximized at unit values when the phase relationship is resistive, less than 1 as positive when inductive, and less than 1 as negative when capacitive. Power lines tend to have more inductive loads, such as motors and transformers, rather than capacitive loads. Utilities often charge industrial workers a surcharge when the load produces a power factor below a certain value. To avoid this, users connect power factor correction capacitors to the power line to induce the load to maintain the power factor at an economic value. In household power plants, most of the electrical energy is consumed in refrigerators, ventilators, air conditioners, lighting fixtures and sometimes heating appliances.

Relatively small amounts of energy are used in telecommunications, computers, and entertainment. Power meters used for home and small-scale industries do not distinguish between real and apparent power. Thus, in reality, customers are charged for both real and apparent power even though they have not consumed apparent power. There is a power factor correction system used for large industries, but no economic device for power factor correction for home or small industries. In general, industrial power factor correction systems relate to the equipment to be compensated for and the devices operating with the equipment. In the past, installing power factor correction devices for each inductive load as much as possible was considered impractical and uneconomical for homeowners.

The prior art Korean Patent No.0138481 relates to a three-phase automatic transformer having a balancing function to improve the efficiency of the electrical devices connected to the automatic transformer because it can eliminate the imbalance between the three phase voltages and currents.

Korean Patent Laid-Open Publication No. 10-2004-0007652 relates to an automatic power factor correction system for measuring a phase angle of generated power, calculating a capacitor, and connecting a power line to compensate a measured reactive power value.

Referring to the disclosed patent with reference to FIG. 1, the automatic power factor correction apparatus of a power plant that induces a variable value of reactive power includes the electrical factors of the power generated from the load of the power plant that can display the reactive power value generated by the load. Measure the power factor by connecting the capacitors to the power line to compensate for the reactive power value indicated by the electrical factor.In particular, the automatic power factor corrector measures the phase angle of the generated power, calculates the capacitor, and connects it to the power line to measure the measured reactive power value. To compensate.

However, the conventional three-phase automatic transformer as described above removes the imbalance between voltage and current of each phase, and the automatic power factor correction system has the effect of improving the power factor, but blocks harmonics and noise that satisfy both effects simultaneously. There is a problem in that the maximum power saving and power improvement effects, such as improving the power factor, are not seen significantly.

Accordingly, the present invention is to solve all the disadvantages and problems of the prior art as described above, by adding an automatic power factor adjustment device to the power saver to always maintain 95% power factor to prevent power loss, exclude reactive power and only active power It is an object of the present invention to provide a power-saving automatic power factor adjustment device that flows, automatically opens and closes a capacitor, and automatically opens and closes a transformer, reducing iron loss and copper loss of a transformer, extending the life of a used device, and eliminating a failure rate.

1 is a block diagram showing the main elements of a conventional automatic power factor correction system.

2 is a circuit diagram of a power saver according to the present invention.

3 is an operation of the reactive power control method according to the present invention.

Figure 4 is a circuit diagram of a power saving automatic power factor adjustment apparatus according to the present invention.

5 is a one-phase and three-phase connection diagram of the power factor detector according to the present invention.

<Description of the symbols for the main parts of the drawings>

100. Current transformer 110. Power factor detector

120. Switching section 130. Series reactor section

140. Discharge coil unit 150. Condenser unit

160. Automatic regulator 170. Circuit breaker

180. Power Saver 190. Automatic Transfer Switch (A.T.S)

The object of the present invention is a current transformer for converting current from an input power source; A power factor detector for detecting a power factor by the output signal of the current transformer; A plurality of automatic regulators including a switching unit, a series reactor unit, a discharge coil unit, and a condenser unit for automatically correcting the power factor detected by the power factor detector; And a power saving device including a plurality of magnetic contactors provided at an end portion of the voltage induction winding part connected to the input power source.

Details of the above object and technical configuration of the present invention and the effects thereof according to the present invention will be more clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 2 is a circuit diagram of a power saver according to the present invention.

The power saver includes a power line 10 having inputs R, S, and T and outputs u, v, w, a voltage induction winding 20 that is determined to maintain power, and an end of the voltage induction winding. It consists of two magnetic contactors 30 and 40 connected to the part. The number of turns of each phase in the power line 10 is 1: 2: 1, and when the power is used, the current on the power supply side of the front end is balanced due to mutual cancellation of magnetic flux even if the load side is somewhat unbalanced. Done. At this time, the form of electromotive force generated by mutual cancellation of interlinked magnetic fluxes has the characteristic of filtering noise and harmonics unlike the general voltage induction control device, resulting in power consumption improvement and power factor improvement effect. Will also be brought.

The winding ratio of each phase in the voltage induction winding unit 20 is 1: 1: 1: 1, and the unbalance of the phase voltages of each phase is balanced in the course of repeating the forward and reverse windings. This is because the crossroads are used in common so that mutual linkages between phases can be mutually cancelled.

The voltage of each phase is different from the primary and secondary voltages according to the voltage characteristics of the power used, the power properties (harmonic generation, the failure caused by the equipment used). In this case, a magnetic contactor having a small voltage deviation may be selected from among a plurality of magnetic contactors having different voltage variations of each phase to select a voltage of each phase having a small deviation in the primary or secondary.

3 is an operation of the reactive power control method according to the present invention.

In FIG. 3, the horizontal axis represents the active power, and the vertical axis represents the reactive power. For convenience, it is assumed that LF representing a load variation is a straight line. Initially, when the load of apparent power corresponding to OL increases and crosses the input line such as Oa, bank C ₁ of the capacitor is injected. Therefore, the power becomes Oa 'and the length of aa' corresponds to the capacity of 1 bank of the capacitor. When the load increases again, it changes along the line a'b parallel to LF, and when it comes to point b, the capacitor bank C ₂ is injected and moves to the point b '.

When the capacitor bank is set in such a manner that the capacitor banks are sequentially introduced when the load increases and the power factor is 0.95 at the maximum load, the capacitor bank capacity is set to coincide with the power factor 0.95 line in FIG. On the other hand, when the load decreases, when the capacitor 1 bank is opened at the point e that intersects the cutoff value when changing along the f′d ′ line, the vector of the load power becomes Oe and goes through e′ff ′ gg ′ as the load decreases. It depends on the capacitor capacity only. Therefore, the setting width can be minimized as necessary to allow extremely fine control.

4 is a circuit diagram of a power saving automatic power factor adjustment apparatus according to the present invention.

Power lines K and L are power lines of the current transformer 100 of the power factor detector 110, and R and N lines are power lines of the power factor detector 110. The switching unit 120 used a magnetic switch to switch ON / OFF the signal detected by the power factor detector 110 and the series reactor 130 removes the harmonics and waveforms of the output signal by the switching unit 120. Noise reduction is done to improve. In addition, the discharge coil unit 140 discharges the residual current of the condenser unit 150, and the condenser unit 150 is configured as a condenser that improves the power factor to the load by supplying the reactive reactive power. This will continue to supply power with improved power factor. The automatic regulator 160 includes a switching unit, a series reactor unit, a discharge coil unit, and a condenser unit. The automatic regulator 160 includes a plurality of elements to automatically correct the power factor.

The power saver 180 is protected by the circuit breaker 170 inside the power saver 180, and when operated to the right by the automatic transfer switches (ATS) 190, the power saver mode is activated. The bypass function is then activated. Therefore, the installation position of the power factor detector 110 is installed at the primary side of the power saver 180 so that it can be used at any time when the power factor detector or the power saving system is used.

Measures the voltage at the voltmeter 220 through the voltmeter switchgear 210 and measures the current at the ammeter 240 through the ammeter switchgear 230 and between the voltmeter switchgear 210 and the ammeter switchgear 230 The power is measured through the electricity meter 200.

5 is a one-phase and three-phase connection diagram of the power factor detector according to the present invention, (a) is a three-phase connection diagram, and (b) is a one-phase connection diagram. K-L is the power line of the current transformer of the power factor detector and k-1 is the input signal of the power factor detector.

The present invention has been shown and described with reference to the preferred embodiment as described above, but is not limited to the above-described embodiment without departing from the spirit of the present invention to those of ordinary skill in the art Various changes and modifications will be possible.

Therefore, the power saving type automatic power factor adjustment device of the present invention has the greatest advantages of the automatic power factor adjustment device, which is effective in reducing the active power and improving the harmonics and noise, but has not seen the effect of power saving by only the power saving factor and power factor improvement part that lacked the power factor improvement. Combination can provide maximum power saving and power improvement effect. By combining automatic power factor adjustment device inside the power saver box, there is no need to install capacitors externally, so you can see the spatial effect. This saves the time and cost of having to do two operations for the capacitor installation.

Claims (6)

A current transformer for converting current from an input power source; A power factor detector for detecting a power factor by the output signal of the current transformer; A plurality of automatic regulators including a switching unit, a series reactor unit, a discharge coil unit, and a condenser unit for automatically correcting the power factor detected by the power factor detector; And Power saving device including a plurality of magnetic contactor provided at the end of the voltage induction winding connected to the input power source Power saving automatic power factor adjustment device characterized in that it comprises a. The method of claim 1, The switching unit is a power saving automatic power factor adjustment device, characterized in that the magnetic switch for switching on / off the signal detected by the power factor detector. The method of claim 1, And said series reactor section removes harmonics of the output signal by the switching section and removes noise to improve the waveform. The method of claim 1, The discharge coil unit is a power saving automatic power factor adjustment device, characterized in that for discharging the residual current of the condenser unit. The method of claim 1, The condenser unit is a power saving automatic power factor adjustment device, characterized in that to improve the power factor to the load by supplying the reactive reactive power. The method of claim 1, The magnetic contactor inside the power saver is a power-saving automatic power factor adjustment device, characterized in that for adjusting the voltage deviation of the primary and secondary.