KR100650608B1 - Large capacity automatic power control system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic voltage regulation system (AVR system) for maintaining and supplying a stable voltage against voltage fluctuations. In particular, the present invention relates to stable voltage control of a large-capacity AC power supply and a power-saving device for large-capacity power.

In general, AVR has no problem in small capacity power (150Kw or less). However, in large capacity AVR systems, power control means and control circuits for stable voltage control are complicated, and expensive high-capacity power conversion transformers, semiconductor switching elements, and accessory circuits are involved. As a result, there have been disadvantages in that it is difficult to commercialize or is weak in economy and stability.

The present invention is to implement a large-capacity AVR system using a small capacity power control device, in particular to configure a power control device of the mutual induction reactor (Reactor) method at the output stage, the output of the AVR by using a small capacity AVR at the input terminal It is to provide a large-capacity power control device with an AVR function that can supply stable and constant large-capacity power to the load side by controlling only the primary-side small-capacity power of the mutual induction reactor method according to the signal.

AVR, AVR system, automatic voltage regulation, mutual induction reactor, power saving

Description

Large capacity automatic power control system

Figure 1a to 1c is a typical conventional power conversion device and reactor illustrative view, Figure 1a is a lottery transformer, Figure 1b is a single winding transformer, Figure 1c is a reactor

2 is a circuit diagram showing an embodiment of a known mutual induction reactor.

3 is a functional equivalent circuit diagram of a known mutual induction reactor.

Figure 4 is a block diagram showing the configuration of the present invention large capacity automatic voltage regulation (AVR) system.

Figure 5 is a circuit diagram showing the configuration of the present invention large capacity automatic voltage regulation (AVR) system.

6 is a view showing an embodiment of a mutual induction reactor in the present invention.

7 is a view showing an embodiment configured in three phases in the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic voltage regulation system (AVR system) for maintaining and supplying a stable voltage against voltage fluctuations. In particular, the present invention relates to stable voltage control of a large-capacity AC power supply and a power-saving device for large-capacity power.

In general, AC voltage regulators have a Slydax. The slidax can adjust the output voltage, but it is not suitable for power supplies or loads that require a stable AC voltage because there is no regulation for output stabilization.

Therefore, to solve this problem, a special power stabilizer such as an automatic voltage regulator (AVR) is used.

The AVR is a device that automatically maintains the output voltage at a constant value. There are two types of AVRs that are used independently of the AC generator, the DC generator, the constant voltage rectifier, and the like.

In the case of a generator, the magnetic field current is controlled by detecting a change in the terminal voltage caused by a change in load, speed, etc., and in the case of other devices, the input voltage is controlled by detecting a change in the terminal voltage caused by a change in power supply voltage or load.

In general, the AVR for controlling the small capacity power (150Kw or less) is technically and commercially available. However, in the large capacity AVR system, the power control means and the control circuit for the stable voltage control are complicated and expensive large capacity power conversion transformer or semiconductor switching element and With the accompanying circuits, decisions were made that were not commercially viable or were weak in economics and stability.

The present invention is to implement a large-capacity AVR system using a small-capacity power control device, in particular the power of the induction reactor method disclosed in the patent application No. 21274 1994 filed by the inventor of the present application at the output stage It is equipped with the AVR function that makes it possible to supply the stable and constant large capacity power to the load side by configuring the control device and controlling only the primary small capacity power of the mutual induction reactor type according to the output signal of the AVR by using the small capacity AVR at the input terminal. It is to provide a large capacity power control device.

The large-capacity automatic voltage power control device according to the present invention includes a mutual induction reactor type power supply that converts a voltage on an input side to a load, a voltage sensing sensor detecting an input voltage, and a detection result of a voltage sensing sensor. It includes a small capacity automatic voltage regulator (AVR) for switching the control of the primary side of the mutual induction reactor power supply so that a constant voltage of

The mutual induction reactor type power supply device is a mutual induction reactor for returning the first and second mutual induction currents generated in a coil in which the secondary side current coil and the primary side voltage coil are wound around each other in a closed magnetic core to the load side. And an automatic power regulator (AVR), which controls the switching with a voltage regulating tap of several stages that designates the primary winding voltage of the mutual induction reactor type power supply, thereby supplying the load side supply voltage through the secondary current coil. Characterized in that the configuration to adjust.

The present invention is characterized in that it is possible to implement a large-capacity AVR system using a small-capacity AVR by controlling only the excitation current of the mutual induction reactor using a small-capacity AVR.

Such a known mutual induction reactor provides a power factor improving device and a method for improving power factor by active feedback current according to power consumption of the load side of the reactor, and converts power (E × I) of a transformer, which is a general power converter. Is a power saving device applying the principle that the primary side and the secondary side are 1: 1, and when the power of the current coil side decreases by a certain amount, it is fed back to the voltage coil side to reduce the current coil side and the amount returned to the voltage coil. The power saving effect of the input power source is reduced, and thus the power consumption of the power conversion transformer required for voltage drop can be greatly reduced.

In order to explain the principle of the mutual induction reactor as described above, a transformer-type power conversion device to obtain a power saving effect by dropping a constant voltage on the load side will be described as follows.

In the same power supply circuit in FIG. 1, when the input voltage of V ₁ is 220V and the output voltage of V ₂ is about 20V less than the input voltage, the conventional transformer construction method is performed in the lottery transformer 1 of FIG. In the case of Equation 1 below.

n1: 1 primary coil

V1: input voltage

f: power supply frequency (HZ)

Bm: Magnetic flux density of iron core

S: Cross section of iron core

The voltage relationship between input and output is n ₁ / n ₂ = V ₁ / V ₂ , so the ratio of input and output voltages is equal to the ratio of windings.

Therefore, n ₂ must wind a winding proportional to 200V and determine the copper thickness of the specification sufficient for the load-side current.

If the load-side current is 1A, a transformer of 200V × 1A = 200VA capacity is required.

As another method, there is a single winding transformer (2) as shown in (b), but a single winding requires a 200VA transformer capable of supplying 1A to 200V.

That is, in order to satisfy the voltage and current on the load side, the transformer capacity must be equal to or greater than the maximum capacity on the load side.

In another third method, a reactor 3 or a resistor is connected in series with a load-side circuit to drop the output voltage V _{2 by a} voltage applied to both ends thereof.

However, since the load circuit current (1A) and the voltage between both ends of the reactor (3) should be 20V, power consumption occurs according to 20V × 1A = 20VA-class reactor (3) and P = I ² R (Z). Not only do they get worse, but for various reasons, such reactors and series resistors are rarely used for voltage drop in AC circuits.

Therefore, the voltage drop in the mutual induction reactor is composed of a primary side voltage coil connected in parallel to the power supply and a secondary side current coil connected in series to the power supply as shown in FIG. It is a mutually induced reactor method.

In addition, the secondary coil (n ₂ ) and the current coil voltage (V _x ) is determined by the value of V ₁ -V ₂ .

That is, although the winding was proportional to the secondary coil (n ₂ ) of the conventional lottery transformer, the design method of the mutual induction reactor used in the present invention is the current coil voltage (V) which is the difference between the input voltage (V ₁ ) and the output voltage (V ₂ ). _x ) determines the number of turns and capacity of the secondary coil (n ₂ ).

Therefore, the capacity of the transformer 9 is determined by the voltage across the secondary side current coil (V _x ) and the load side current (IL).

For example, if the output voltage of 200V dropping 20V at the input power of 220V is required and the current is 1A, the transformer capacity of 200VA is required in the past, but the induction reactor used in the present invention is 20VA, which is sufficient for 1/10 capacity. will be.

By using the mutual induction reactor used in the present invention, it is possible to give a reduced pressure and a boosted voltage, thereby providing an automatic voltage adjustment function.

First, for decompression, as shown in FIG. 2, the starting point (.) Of the secondary coil (n ₂ ) is connected to the winding starting point (.) Of the primary coil (n ₁ ) of the transformer (9) and the winding end (7). (8) to the load side 10 in series with the primary coil, and the other input line of the load is connected to the end of the voltage coil (5) sense again.

In the case of boosting, if the winding start point and the end point of the secondary coil (n ₂ ) are connected to each other in the reverse phase in the load side connection, the output voltage becomes V ₂ = V ₁ + V _x to boost the input voltage.

Looking at the configuration of such a mutual induction reactor, the primary coil (n1) of Figure 2 is a voltage working coil (V Coil) connected in parallel with the input voltage (V1) and the secondary coil (n2) and the input voltage (V1) A current-operating coil (I Coil) connected in series between the load 10 side is configured to perform mutual electromagnetic induction with a ferromagnetic iron core material.

3 shows a functional equivalent circuit of the mutual induction reactor 4.

Accordingly, the secondary side current coil 6 induces and generates reverse phase voltage Vref with respect to the primary side voltage coil 5 by the electromagnetic induction of the primary side voltage coil 5 connected in parallel with the power supply Vs. The secondary coil 6 connected in series to the load 10 as a current acting coil (I Coil) induces an electromagnetic induction action on the primary voltage coil (5) by the load current amount to give a power feedback effect. .

This power feedback effect results from power factor improvement, or current phase compensation.

In the present invention, to implement a large-capacity AVR system using such a mutual induction reactor as described in detail with reference to the embodiment shown in the accompanying drawings as follows.

4 and 5 is a view showing a large capacity automatic voltage regulation system of the present invention.

According to the monitoring result of the large-capacity power supply device 100 that converts the voltage on the input side to the load, the voltage sensor 110 for detecting the input side voltage, and the voltage sensor 110, the load 130 may be decompressed or boosted. It is configured to include a small capacity automatic voltage regulator (AVR) (120) for switching the input of the large-capacity power supply 100 so that a predetermined constant voltage can be supplied to),

The large-capacity power supply device 100 induces mutual induction of the first and second mutual induction currents generated in a transformer in which the current coils 102 and the voltage coils 101 are wound to each other to the load 130 side. The reactor type power saving device, and the small capacity automatic voltage regulating device 120 controls switching with each tap T1 to T4 for adjusting the voltage of the primary voltage coil 101 of the large capacity power supply 100. To adjust the voltage supplied to the load side 130 step by step.

In addition, both ends of the voltage coil 101 of the large-capacity power supply device 100 are connected by the polarity switching switch 103.

The polarity switching switch 103 is switched by the output signal (S2) of the small capacity automatic voltage regulator 120 so that the polarity of the voltage coil 101 is switched.

In this way, the voltage is reduced or boosted with respect to the input voltage state, and the voltage adjusting taps T1 to T4 of the voltage coil 101 are controlled to supply a constant voltage to the load side.

The apparatus further includes a voltage detecting sensor 140 as a means for detecting an overcurrent and an abnormal current that may be generated in the secondary winding current coil 102 of the large-capacity power supply 100. The adjusting device 120 is configured to control the bypass switch 104 to directly supply the input side voltage to the load (S1) without passing through the large-capacity power supply device 100 from the detection result of the voltage detecting sensor 140 thereof. Has

In addition, the small automatic voltage regulator 120 controls the switch 105 for switching any one of the taps (T1 ~ T4) of the voltage coil of the large-capacity power supply 100 to the appropriate voltage tap in accordance with the input side supply voltage ( S3) has a configuration and means.

Prevents the effect on the load 130 when an abnormal current occurs in the large-capacity power supply 100 and prevents the effect on the load 130 when an abnormal current occurs in the large-capacity power supply 100 and a large capacity power supply In order to minimize the damage of the device 100, the bypass terminal B and the switching switch 104 are configured to allow the input supply voltage to be directly transmitted to the load 130.

In addition, the switching device is configured to allow the user to arbitrarily switch to the bypass terminal (B), so that the small automatic voltage regulator 120 may be configured to include a manual control device to be switched to the bypass terminal (B). do.

In the present exemplary embodiment, the voltage detection sensor 140 is configured to detect abnormal voltages (overvoltages and abnormal voltages) of the power supply device 100, and the bypass terminal B of the automatic voltage regulating device 120 is formed from the detection result thereof. ) To be switched on.

Referring to the operation of the large-capacity automatic voltage regulation system as described above is as follows.

The voltage sensor 110 monitors the supply voltage of the input side, and transmits the monitoring result to the small automatic voltage regulator 120.

The small automatic voltage regulator 120 recognizes an input supply voltage value and switches the bypass switch 104, the polarity switching switch 103, and the switch 105 configured in the large-capacity power supply device 100 according to the value. Outputs control signals S1, S2, S3 for control.

The bypass switch 104 is switched by the control signal S1 to be switched to either the constant voltage terminal R or the bypass terminal B, and the polarity switching switch 103 is controlled by the control signal S2. The switching operation is performed to reduce or increase the pressure, and the switch 105 is operated by the control signal S3 to switch each tap T1 to T4 of the voltage coil 101 so that precise voltage adjustment can be made. .

Therefore, the input side supply voltage with voltage variation is supplied to the load 130 side through the secondary side current coil 102 of the large-capacity power supply device 100 configured as a mutual induction reactor, but this output is supplied by the small automatic voltage regulator 120. The stable power is supplied according to the voltage control effect of the controlled voltage coil 101.

On the other hand, Figure 7 shows an embodiment of the present invention consisting of three phases.

The power supply device 100 is connected in parallel to each of the three phases R, S, and T, and the neutral wire N and the small automatic voltage regulator (AVR) 120 are configured in each phase, and a direct terminal switch ( MC1) is configured.

Here, the switch MC2 may be configured as a relay switch interlocked with the direct terminal switch MC1 or a switch for arbitrarily determining whether the automatic voltage regulator 120 operates.

In the embodiment of the present invention of Figure 7, the voltage sensing sensor for monitoring the input side or output side voltage is not shown.

The output side sensor may be configured as a switch operated or manually operated by the user, and configured to be interlocked with the switch MC2.

As described above, the present invention is to control only the primary voltage coil excitation winding current of the large-capacity power supply device constituted by the mutual induction reactor, so that a large-capacity automatic voltage power control device can be implemented using a small-capacity AVR.

In addition, by using the system of the present invention using a mutual induction reactor type power supply device, it is possible to provide a large capacity automatic voltage power control device capable of stabilizing voltages as well as boosting voltage, rather than a simple decompression power control device. The capacity can be reduced to about one-tenth, allowing economic and practical devices to be implemented, as well as providing automatic voltage control with power savings and power factor improvement.

Claims (6)

Mutual induction reactor type large-capacity power supply that converts the input voltage and supplies it to the load, a voltage sensor for detecting the input voltage, and a voltage constant at the load by reducing or boosting the input voltage according to the detection result of the voltage sensor. It is configured to include a small capacity automatic voltage regulator (AVR) for switching the input to control the primary side of the large-capacity power supply to be supplied, The large-capacity power supply device is a mutual induction reactor type power supply device in which a secondary current coil and a primary voltage coil are fed back and forth mutually induced currents generated in a coil in which a closed magnetic core is wound around each other to the load side. The small-capacity automatic voltage regulator (AVR) controls the secondary current coil by controlling switching and switching of polarity (step-up or pressure-reduction) with voltage regulating taps of several stages that designate the primary-side winding voltage of the large-capacity power supply. Configured to adjust the load side supply voltage through Means for detecting over-current and abnormal current that may occur in the secondary winding current coil of the large-capacity power supply device, and Bypass switching path for supplying the input side voltage directly to the load without going through the large-capacity power supply device And a bypass switch, wherein the small automatic voltage regulating device controls the bypass switch from the detection result of the voltage sensing means to supply the input side voltage directly to the load without going through the large-capacity power supply. Large capacity automatic voltage power control device. delete The secondary winding current coil of claim 1, further comprising a switch means such that the input side voltage can be directly connected to the load without going through a large-capacity power supply device when an overcurrent or an abnormal current occurs in the secondary winding current coil, and the switch means is arbitrarily switched by a user. A large capacity automatic voltage power control device comprising a means for enabling operation control. According to claim 1 or 3, when the input voltage supply is three-phase, the large-capacity power supply is connected in parallel to each of the three phases (R, S, T), the neutral wire (N) and the small automatic voltage in each phase A high-capacity automatic voltage power control device comprising a regulator connected to each other, and a bypass switch means configured at an input voltage side. 5. The large capacity automatic voltage power control device according to claim 4, wherein switch means for determining whether the small automatic voltage regulating device is operated (ON / OFF) is configured for each small automatic voltage regulating device.  6. The apparatus of claim 5, wherein the switch means for determining whether the small automatic voltage regulating device is operated is on / off in association with the bypass switch means.

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