KR200349337Y1 - Dedicated voltage control device - Google Patents

Abstract

In Korea, the frequency used in the power system is 60Hz. This is called the commercial frequency. Controlling the voltage at the commercial frequency means controlling the magnitude and frequency of the voltage. In general, voltage control at the commercial frequency is difficult because the high voltage and high energy power control the commercial frequency voltage is not technically easy. Nevertheless, constant high-quality constant voltage that is constant in frequency and unstable in size is required not only in the field of precision electrical equipment, especially in the field of using motors, but also in the recent precision information and communication business. In addition, if the voltage fluctuation rate is severe, the life of the electric device is shortened and the brightness of the lamp is shaken, which causes inconvenience in daily life.

Due to the development of industry and the increase of industrial volume, various semiconductor power conversion facilities such as advanced control devices, power electronic devices, etc. have increased in recent years, and in recent years, there are many harmonic sources due to the increase in the use of OA devices such as computers, copiers and printers. The harmonics generated by these load installations are cable and transformer overheating, generator output loss, power factor reduction, power loss increase, and ELB. MCCB malfunction, communication line induced obstacles, neutral earth potential rise, etc. are adversely affected.

Harmonics, which were previously thought to occur only in industrial sites, are now occurring in all living spaces where modern people live, including various buildings, stadiums, apartments, residential lighting, and airports.

Inverter method used in the existing voltage control basically converts AC voltage to DC voltage and then regenerates AC, causing harmonics and high frequencies to occur, generating third harmonic current, and the nature of the load It is not suitable for voltage control of common load commercial frequency commonly used in a manner suitable for inductive loads.

The present invention devised a voltage drop exclusive voltage control device and method to solve the problems raised above and to enable control without affecting the voltage quality.

Description

Voltage control device dedicated to voltage drop {omitted}

With the development of power semiconductor devices, that is, power electronic devices, the most common device of voltage control has become an inverter-based system (Fig. 2). Inverter voltage control technology is to rectify AC voltage into DC voltage, and then make AC again by switching the power electronic device. The operating principle of the voltage controller in this manner is to rectify the power supply (4 in Fig. 2) and make a DC waveform, and then go through a filter 23 to make a high-quality DC power supply, and then the power device (Fig. 2). Qp1, Qp2, Qn1, and Qn2) are controlled by the gate controller 26 to drive the inverter 24 to generate alternating current, and the filter 25 is again used to make the alternating voltage signal again to make a cleaner AC voltage. After rough supply to the load (3 in Figure 2).

Advantages of the voltage control method of the inverter method of FIG. 2 are largely as follows.

First, even frequency can be controlled. The first advantage is mainly used as a concept for motor control.

Second, the voltage control range is wide. That is, it is an advantage that the voltage step-up and step-down are possible at the same time.

Instead of having the advantages of the inverter type control that uses the power electronic device to control the voltage has the following disadvantages.

First, the controller is complicated and the device (Qp1, Qp2, Qn1, Qn2 in FIG. 2) becomes expensive. In particular, in the case of a large capacity of several tens of kVA or more, the price of reactors (L1 and L2 in FIG. 2) and capacitors (C1 and C2 in FIG. 2) used to smooth the price of the device may be several hundred thousand won.

Second, control is difficult. Accurate control is necessary to maintain the correct voltage and frequency. This gate controller 26 is usually controlled by a microprocessor.

Third, the voltage control by the inverter controller (FIG. 2) basically uses a switching action of the power electronic device (Qp1, QP2, Qn1, Qn2 in FIG. 2), and a lot of high frequencies and harmonics are generated during the switch operation. The generation of such harmonics causes an induction effect on a communication facility.

Fourth, it is difficult to recover a complete sinusoid. In order to recover the PWM converted signal 71 to the output sinusoidal waveform 81 desired by the user, the output sinusoidal waveform 81 should be generated with the PWM converted signal 71. The filter 25 is used to generate the output sinusoidal waveform 81. At this time, the larger the capacitance of the capacitor and the reactor, which are the components of the filter 25, the closer to the sinusoidal wave. However, since the output waveform varies greatly depending on the capacitors and reactors used, it is ideal to install capacitors and reactors with large capacities, ideally, to install capacitors and reactors suitable for all loads (3). However, when a resistive load requiring a large capacity is installed, the output current 81 appears as a stepped waveform 82. Step waveform 82 is the instantaneous rate of change Appears very large. Therefore, the formula for the voltage in the reactor, Instantaneously a high surge voltage is introduced. Therefore, in the case of a large capacity resistive load, degradation is promoted by voltage surge in the inverter (Fig. 2).

Fifth, the change of the output waveform 81 is very large according to the load 3. The load 3 connected to the rear end of the inverter (FIG. 2) has a different capacity, resistance component, and reactor component depending on the type of the load 3. Therefore, no matter what load (3) is connected to a constant sinusoidal voltage to supply the load, but can be called an ideal inverter (Fig. 2).

In the conventional inverter (FIG. 2), when the load 3 is a reactor component, the sine wave output was possible even if the reactor and the capacitor, which are elements used in the filter 25, are not large in size. Therefore, the existing inverter (FIG. 2) was mainly used as a motor drive type.

On the other hand, when the load 3 is a resistive component, it is difficult to restore the complete sine wave voltage waveform normally only by the reactor and the condenser in the filter 25, and a step phenomenon 82 occurs in the waveform. In order to solve this problem, the size of the reactor and the condenser of the filter 25 is increased so that the step phenomenon 82 gradually decreases but is not completely solved.

Sixth, the higher the capacity, the more expensive. Currently, the inverter (Fig. 2) method has been used as much as it is widely used in electric equipment using a small motor. However, high-capacity power equipment is very expensive and difficult to control. However, even though it is expensive, it is being used in some necessary places, but it is not widely used for large-capacity voltage control, and especially for voltage control in power system, it is currently almost impossible to use due to price, harmonic and high frequency problems.

Seventh, energy transfer is unilateral. This property is the most comparable to the present invention. In the conventional inverter method (FIG. 2), it is common to rectify the constant voltage in half-wave using the diode 22 or the unidirectional semiconductor at the input terminal. At this time, the diode 22 and the unidirectional semiconductor used are one-sided in the sense of current, and the current flows in one direction and prevents the current in the opposite direction. Therefore, the conventional inverter (FIG. 2) receives only the power supply 4 supplied by the electric company and has only the property of consuming power in the inverter (FIG. 2) and the load (3).

However, in the case of a motor or general electric equipment, back electromotive force is generally generated when the power is cut off. In addition, even in normal operation, a small amount of energy is generated in the load 3 at all times. At this time, the energy can be reduced to the power supply (4) supplied by the electricity provider and this energy is called regenerative energy.

The conventional inverter (FIG. 2) uses a diode 22 or a unidirectional semiconductor without using the above-mentioned regenerative energy concept, so that energy flows between the power supply 4 and the load 3 supplied by the utility company. When the regenerative energy is generated at the load, the energy cannot be reduced to the power supply 4 supplied by the electric company, but must be consumed as heat or other energy at the inverter (Fig. 2) or at the load.

Eighth, the third harmonic current is mainly used from the power supply 4 supplied by the electric utility when the inverter (Fig. 2) is driven with the low capacity load connected. The power generated by the power plant is not supplied directly to the user, but is finally supplied to the user through the switchboard through several substations. In order for the power system from the power plant to the switchboard to operate smoothly, it is necessary to use a stable current of 60 Hz even under load.

However, when the load (3) connected to the inverter (Fig. 2) is a low capacity when the existing inverter (Fig. 2) is driven, the power supply 4 current supplied by the electric utility becomes three harmonic currents instead of sine waves. Unlike other harmonics, in the case of three harmonics, there is no 120 'phase difference at the neutral point where three phases are combined, so when three phases are combined, the other harmonics cancel and disappear, while the three harmonics are amplified and not amplified and affect the system.

The present invention solves the problem of the conventional inverter method, and enables the constant voltage supply to the load 3 even when the voltage supplied by the power source 4 fluctuates, and also improves the power factor with an additional effect. The purpose of the present invention is to improve the quality of power supplied to 3), to protect the device from overvoltage and overcurrent as well as to reduce power.

1 is a representative view of the present invention

2 is a structure for explaining an inverter which is one type of voltage control

3 is an explanatory diagram of the operation of IGBT during the chipping of the present invention

4 shows the conversion waveform of the input voltage by Q1 CHOPPING

During voltage control to supply a constant voltage to the load, the IGBT switch Q1 is operated for a half period of the amount of the supply voltage supplied by the utility company. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider.

5 is a waveform of conversion of input voltage by Q2 CHOPPING

During voltage control to supply a constant voltage to the load, the IGBT switch Q2 is operated for a half period of the negative supply voltage supplied by the utility company. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider.

6 is a waveform converted by Q1, Q2 CHOPPING

7 is a PWM conversion by the conventional inverter method

8 is a voltage waveform generated when restoring a PWM conversion signal in an existing inverter

9 is an output voltage waveform according to the present method

10 is a three-phase four-wire circuit configuration according to the present invention

11 is a three-phase three-wire circuit configuration according to the present invention

[Description of the code for the main parts of the drawing]

1. 2. Terminal of load stage

It is the purpose of the constant voltage to constantly control the voltage applied between these two terminals. In addition, it is constant voltage control to make the voltage between these two terminals constant and to stabilize the frequency.

3. Load

It is generally a load from an electrical point of view. All electrical appliances and appliances used for home or industrial purposes are loads. The load is divided into resistive loads such as electric lights (phase load) and inductive loads such as motors (ground load), discharge lamps, or capacitors and capacitive loads (true loads). Here, in-phase load means that the phase of voltage and current match, ground load means that it is 90 degrees late when the current is based on the phase of the voltage, and true load means 90 degrees when the current is referenced to the voltage. .

4. Power source supplied by electricity provider

Means the power supplied by the electricity provider. It means to supply infinite energy electrically, and that the internal impedance is '0' is called the ideal power source.

5. IGBT switch Q2

In order to supply constant voltage to the load, the IGBT switch Q2 is operated in the negative half period of the commercial frequency power supply voltage supplied by the utility company during voltage control. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider. Therefore, existing devices do not need a rectifier circuit and a smoothing circuit that only have a magnitude of 0 and 1 when converting a power supply voltage supplied by an electric utility to a PWM method.

The IGBT switch used in the present invention consists of one IGBT (G2), a reverse diode, and a snub circuit in the IGBT module.

6. IGBT switch Q1

In order to supply constant voltage to the load, the IGBT switch Q1 is operated in the half cycle of the commercial frequency power supply voltage supplied by the utility company during voltage control. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider. Therefore, when existing devices convert the power supply voltage supplied by electricity providers to PWM method, they do not need rectification circuit and smoothing circuit, unlike when they have only 0 and 1 magnitude.

The IGBT switch used in the present invention consists of one IGBT (G1), a reverse diode, and a snub circuit in the IGBT module.

7. IGBT switch Q4

In order to supply the constant voltage to the load, the power supply voltage supplied by the utility company receives the signal from the gate control circuit, and is sent out from the gate control circuit to prevent the discontinuity of the load current generated when the IGBT switch Q2 CHOPPING the power supply voltage. In response to the signal, the IGBT switch Q4 operates to free wheeling action, which prevents the discontinuity of the load current.

The IGBT switch used in the present invention is composed of one IGBT (G4), a reverse diode, and a snub circuit in the IGBT module.

8. Load stage filter

Filter the CHOPPING signal made by the operation of IGBT switch Q1, Q2, Q3, Q4 to the sine wave voltage and use the reactor and condenser to prevent the harmonic generated by CHOPPING action from being supplied to the load.

When restoring an existing PWM signal to a sinusoidal wave, a large amount of L and C must be used, but a full sinusoidal wave cannot be restored even if a large amount of L and C is used. When making the chopped signal to sine wave voltage, since IGBT switch Q1 and Q2 of the present invention have the power supply voltage, it can generate sine wave waveform without mixing harmonics on the load side with only L and C of small capacity.

In addition, the capacitor of the filter improves the power factor together with the capacitor of the condenser unit, thereby bringing a large amount of active power toward the load from the power supply voltage supplied by the utility company, thereby providing substantial electrical insulation effect.

9. Condenser

It is used to remove harmonics generated during CHOPPING by using capacitor connected to both ends of input terminal.

In addition, the power factor is improved along with the condenser included in the load stage filter to bring a lot of active power into the load from the power supply voltage supplied by the utility company, thereby providing substantial electrical insulation effect.

10. Gate control circuit

It is a device for controlling the operation of the IGBT switch Q1, Q2, Q3, Q4 as shown in Figure 3 to control the IGBT operation during the CHOPPING of the present invention.

11.IGBT switch Q3

The IGBT switch Q3 receives a signal from the gate control circuit to prevent the discontinuity of the load current generated when the IGBT switches Q1 and Q2 are CHOPPING the power voltage. In this case, the free wheeling action, which prevents the Q4 from operating and discontinuous load current, occurs.

The IGBT switch used in the present invention consists of one IGBT (G3), a reverse diode, and a snub circuit in the IGBT module.

22. Rectifier

It is a part that converts AC power to DC power and consists of four diodes, rectifier elements. Another representation of the rectifier is called a converter. The circuit here is a full-wave rectifier circuit. Converting AC power to DC power is called rectification.

23 Smoothing Filter

The voltage waveform rectified by the rectifier 22 is a waveform having an AC component instead of a complete DC. Such a waveform is referred to as 'having a pulsating component' and becomes a voltage waveform closer to direct current by the reactor (L1 in FIG. 2) and the condenser (C1 in FIG. 2).

24 inverter

The inverter unit makes a voltage having a desired frequency and a desired magnitude again by using the DC voltage passed through the smoothing filter. A new AC power supply is made by switching power electronic devices.

25 smoothing circuit

AC voltage created by using power electronics contains many harmonics and high frequencies, so applying these harmonics and high frequencies to the load causes problems such as noise and communication failure. Therefore, a filter is used to limit these harmonics and high frequencies.

26 gate control circuit

The switch function of the power electronic device used in the inverter of the 24 corresponds to the part for controlling the voltage and frequency. Usually controlled by a microprocessor. In addition, by using an isolated power supply as a control power supply to ensure the operation of each power electronic device. However, it is expensive to manufacture such an isolated power supply.

31. Waveform of the power supplied by the utility

The power supplied by the utility has a frequency of 60 Hz. However, since the value changes minutely, it is always necessary to observe the waveform of the power supply.

32. T _zero: the time from the zero crossing time until the next zero crossing time

In order to make accurate CHOPPING, you need to know exactly the start time and end time of Q1 and Q2. In addition, IGBT switches Q1 and Q2 should be controlled to operate the IGBT switches Q3 and Q4 so as to perform free wheeling during CHOPPING. Therefore, if you know the exact zero crossing time, you can set the element you want to control above.

33. T _ch : Time to chipping

In order to supply constant voltage to the load, CHOPPING starts when IGBT switch Q1 and Q2 CHOPPING the power supply voltage to the power supply voltage supplied by the electric service provider by receiving the signal sent from the gate control circuit. And ends. IGBT switches Q1 and Q2 need to know the exact zero crossing time in order to set the time when the CHOPPING begins. If CHOPPING starts immediately at zero crossing time, Q4 is operated when Q1 operates when the time setting is not done correctly because the 'on', 'off' time and zero crossing time of Q3 and Q4 are not matched by minute frequency fluctuation. When Q2 is in operation, Q3 is in operation. In this case, an over-current flows into the arm-short phenomenon in which Q1-Q4-Q3-Q2 is connected to the circuit, causing equipment failure.

To solve this problem, not all IGBT switches are operated at zero crossing time, but the IGBT switch operates with a time difference by the chopping-free interval. In this case, it is not chopping the whole waveform, but by excluding the section where energy does not flow much from chopping, it is not a problem to generate a complete sine wave when the waveform is generated in the load, and normal IGBT switch operation is possible.

34. T _fw : free wheeling operation time in G3, G4

In order to prevent the discontinuity of the load current generated when IGBT switches Q1 and Q2 CHOPPING the power supply voltage, the power supply voltage supplied by the electric utility company receives the signal sent from the gate control circuit to supply the constant voltage to the load. The IGBT switches Q3 and Q4 operate by receiving the signal sent out from the controller so that the free wheeling action occurs so that the load current does not become discontinuous. At this time, G1 and G2 start time and end time longer than T _ch starting time, so that free wheeling operation occurs exactly.

35. Graph describing operation status of IGBT switch Q1

The IGBT switch Q1 receives a signal from the gate control circuit to supply a constant voltage to the load and chops the power supply voltage supplied by the utility company. When Q2 is chopping, the IGBT switch Q1 remains in operation to connect with the power supply voltage.

36. Graph of operation status of IGBT switch Q3

IGBT switch Q3 must not be operated to prevent arm-short during negative half cycle that IGBT switch Q1 is CHOPPING by free wheeling operation and IGBT switch Q2 is chopping.

37. Graph of operation status of IGBT switch Q2

The IGBT switch Q2 receives a signal from the gate control circuit to supply a constant voltage to the load and chops the power supply voltage supplied by the utility company, and is in operation to connect with the power supply voltage when Q1 chops.

38. Graph of operation status of IGBT switch Q4

IGBT switch Q4 must not operate to prevent arm-short in positive half cycle that IGBT switch Q2 is CHOPPING, and IGBT switch Q4 operates by free wheeling action and IGST switch S1 chopping.

41.Input Voltage Conversion Waveform by Q1 Chopping

In order to supply the constant voltage to the load, the IGBT switch Q1 is operated in half the period of the commercial frequency power supply from the power supply voltage supplied by the utility when receiving the signal transmitted from the gate control circuit. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider.

51.Transformation waveform of input voltage by Q2 CHOPPING

In order to supply constant voltage to the load, the IGBT switch Q2 is operated in the half cycle of the commercial frequency power supply voltage supplied from the utility when receiving the signal transmitted from the gate control circuit. At this time, the CHOPPING signal has the characteristic that it is CHOPPING at high frequency while maintaining the magnitude and phase of the power voltage waveform supplied by the electricity provider.

61. Convert waveform by Q1, Q2 CHOPPING

71. PWM conversion by conventional inverter method

81 Voltage waveform when restoring PWM conversion signal in the existing inverter

In order to restore the PWM conversion signal to the desired output sinusoidal waveform, a new waveform must be generated by the PWM signal. A filter is used to generate a new waveform. The larger the capacitor and reactor capacity of the filter, the closer it is to a sinusoid. However, since the output waveform varies greatly depending on the capacitors and reactors used, it is ideal to install capacitors and reactors with large capacity ideally.

82. Output current waveform not fully restored

If a resistive load that requires a large capacity is installed, the output current will appear as a step waveform. The staircase waveform is the rate of instant change Appears very large. Therefore, the formula for the voltage in the reactor, Instantaneously a high surge voltage is introduced. Therefore, in the case of a large capacity resistive load, deterioration is promoted by voltage surge in the inverter.

In order to solve the problems of the conventional inverter method (FIG. 2), the present invention allows voltage control in a manner different from that of the conventional inverter method (FIG. 2) in order to always supply power of a desired quality. At this time, the conditions under which the present invention is used are limited, and the conditions are as follows.

First, use only for reduced pressure.

Second, do not vary the frequency.

Third, operate constant voltage within rated range.

When the voltage control method is used as a power saving concept for the voltage drop, even if all three conditions mentioned above are applied, there is no problem for the purpose of power saving.

IGBT switches Q1 (6) and Q2 (5) are placed at the input terminals of the current, so that the power supply voltage (4) supplied by the utility company receives the signal from the gate control circuit (10) and receives the IGBT switch in half the period of the commercial frequency power supply. Q1 (6) operates and the IGBT switch Q2 (5) operates in the negative half cycle. The IGBT switches Q1 (6) and Q2 (5) receive a signal transmitted from the gate control circuit 10 and 'on-off' the voltage input by the switching action to convert the voltage signal. At this time, in the conventional inverter (FIG. 2), the signal input through the rectifier circuit 22 and the smoothing circuit 23 is digitized to convert the PWM, whereas in the present design, the sine wave power source is supplied to the IGBT switch Q1 (6), Q2 (5) By 'on-off'. In Q1 (6), the positive signal is CHOPPING, and in Q2 (5), the negative signal is CHOPPING.

In order to prevent the discontinuity of the load current generated when the IGBT switches Q1 (6) and Q2 (5) change the power supply voltage (4) by receiving the signal transmitted from the gate control circuit (10), the gate control circuit (10) The IGBT switches Q3 (11) and Q4 (7) operate in response to the signal transmitted from the N / A, thus freewheeling. The time for free wheeling of the IGBT switch Q3 (11) is from the time of starting the IGBT switch Q1 (6) to the end of the CHOPPING. IGBT switch Q4 (7) also operates free wheeling time from the time when IGBT switch Q2 (5) starts to the end and ends with a little extra time.

In the half cycle of IGBT switch Q1 (6) CHOPPING, IGBT switch Q3 (11) is operated by free wheeling action and IGBT switch Q2 (5) is connected between power supply voltage (4) and load (3) supplied by utility company. It works for connection. However, Q4 (7) does not work at this time. Similarly, in a positive half cycle in which IGBT switch Q2 (5) is CHOPPING, IGBT switch Q4 (7) operates by freewheeling action, and IGBT switch Q1 (6) is supplied with power supply voltage (4) and load (3) supplied by the utility company. It works for connection with. But Q3 (11) does not work at this time.

At this time, IGBT switches Q1 (6) and Q2 (5) need to find out the correct zero crossing time (32) to set the time when CHOPPING starts. If CHOPPING starts immediately at zero crossing time (32), if the 'on', 'off' time and zero crossing time of Q3 (11) and Q4 (7) are not matched by minute frequency fluctuation, When Q1 (6) operates, Q4 (7) operates, or Q2 (5) operates when Q2 (5) operates. In this case, an over-current flows into the arm-short phenomenon in which Q1-Q4-Q3-Q2 is connected to the circuit, causing equipment failure.

To solve this problem, not all IGBT switches are operated at zero crossing time (32), but IGBT switches are operated with a time difference by the chopping-free interval. In this case, the chopping of the entire waveform is not performed, but by excluding the section in which energy does not flow much from the chopping, it is not a problem to generate a complete sinusoidal waveform when the waveform is generated in the load 3, and normal IGBT switch operation is possible.

The capacitor connected to both ends of the input stage eliminates harmonics generated when the power supply voltage supplied by the utility provider is switched by the IGBT switches Q1 (6), Q2 (5), Q3 (11) and Q4 (7).

On the load side, the CHOPPING power supply voltage 61 is a sinusoidal voltage desired by the user and acts as a filter 8 by using a reactor and a condenser to prevent the harmonics generated by the CHOPPING action from being supplied to the load.

At this time, the generated sinusoidal voltage generates the supply voltage (4), which is a direct switching action, from the load to the desired sinusoidal voltage again and supplies it to the load while maintaining the power supply voltage (4) supplied by the electric utility as it is. This PWM conversion can be generated more efficiently than generating the sinusoidal waveform 81 with the digital signals 71 of 0 and 1 by the PWM conversion. Therefore, the filter 8 including the capacitor and the reactor having a smaller capacity than the capacitor and the reactor used in the conventional inverter (Fig. 2) can also supply a complete sine wave (Fig. 9).

The effect of the present invention is as follows.

First, there is no rectifying circuit and smoothing circuit. In order to convert the PWM in the existing inverter circuit (FIG. 2), the power supply voltage supplied by the electric service provider must be changed to the DC voltage while passing through the rectifying circuit 22 and the smoothing circuit 23. At this time, when the power supply voltage 4 to be used becomes large, the capacity of the components used in the rectifying circuit 22 and the smoothing circuit 23 should increase. Therefore, the product produced by the conventional inverter method (Fig. 2) is greatly increased in volume and price according to the capacity. However, the signal conversion method of the present invention does not need a rectifying circuit and a smoothing circuit because it converts the signal having the property of the power supply voltage 4 as it is, not the PWM method. For this reason, the present invention is structurally advantageous in price.

Second, the waveform generation is made simply by converting the power supply voltage (4) supplied by the electric service provider as the sinusoidal structure when CHOPPING. Conventional inverter method (FIG. 2) can be generated more efficiently than to generate a sinusoidal voltage to the digital signal 71 of 0 and 1 by PWM conversion.

Third, a small number of modules can be configured. The general IGBT module is composed of the structure of the emitter of the first IGBT switch and the second IGBT switch collector. If two IGBT switches are needed for different purposes, the two IGBT switches are connected to each other. IGBT module must be used. However, in the connection structure of the present invention, one IGBT module can be used as the IGBT switches Q2 (5) and Q3 (11) as the IGBT switches Q1 (6) and Q4 (7), respectively, which serves as a structural advantage.

Fourth, less high frequency generation. When the power supply voltage (4) supplied by the electricity supplier is CHOPPING, the capacitor 9 connected to both ends of the input terminal serves to reduce the high frequency. Also, in order to prevent the high frequency generated by the CHOPPING action from being supplied to the load, the reactor and the condenser are used as the filter 8.

Fifth, a complete sinusoidal wave (FIG. 9) is obtained. Since the chopping signal 61 close to the original sine wave is restored to the original signal, unlike the conventional inverter method (FIG. 2), the sine wave can be implemented with a small capacity and the step waveform phenomenon 82 does not occur.

Sixth. Reverse energy flow is possible. When the IGBT switch Q1 (6) operating for a commercial half-cycle in the commercial frequency power supply 4 and operated by a signal transmitted from the gate control circuit 10, the reverse current may flow depending on the nature of the load. In order to ensure that the IGBT switch Q2 (5) is 'on', the free wheeling action causes the IGBT switch Q3 (11) to be 'on', in contrast to the negative half-cycle of the power supply and in the gate control circuitry. When the IGBT switch Q2 (5) operated by the transmitted signal is CHOPPING as a switching action, the reverse current flows smoothly 'on' the Q1 (6), and the IGBT switch Q4 (7) It operates 'on' so that the regenerative energy that can be generated depending on the nature of the load can be reduced to the power supply side.

The possibility of reverse energy flow means additional energy savings during voltage control. In the conventional inverter method (FIG. 2), since the constant voltage is rectified by half-wave using the diode 22 or the unidirectional semiconductor at the inverter input terminal, only the power supply 4 supplied by the electric service provider flows toward the load in a one-way concept. Therefore, it is impossible to reduce the regenerative energy that may occur depending on the nature of the actual load back to the power source 4. Therefore, when the regenerative energy is generated in the conventional inverter method (Fig. 2), the regenerative energy should be used in the inverter (Fig. 2) and the load (3), so there is no energy saving effect on the regenerative energy, and the inverter (Fig. 2) is consumed. ) And load (3) must be consumed by thermal energy. Heat generated during energy consumption may cause problems in normal operation by raising the load 3 temperature.

Seventh, there is no third harmonic generation. In the voltage control of the present invention, the sinusoidal current is always used in the power supply 4 supplied by the electric service provider regardless of the type of the load 3 and the capacity required by the load. In particular, the existing inverter equipment (FIG. 2) uses a current of 3 harmonics mainly in the power source 4 when a small capacity load is connected, while the present invention uses a constant sinusoidal current in the power source 4 regardless of the load capacity. do.

Eighth, operation is performed in synchronism with the power supply voltage (4). In a power system, each power system device must operate with the same synchronization. In a power system with different motive power sources, the power system may be overwhelmed at the time of connection to equalize the two motives and, in severe cases, may affect the power system safety.

The load (3) connected to most inverters currently being used is operating in synchronization with the power supply voltage (4). In this case, when connected with the device operating in synchronization with the existing power supply voltage (4) can have a fatal effect on both equipment. In the present invention, since the synchronous operation of the load 3 is the same as the power supply voltage 4, safe and efficient power management for the power system is possible.

Ninth, the power factor is improved. The power factor is improved by using a capacitor, which is an element in the condenser unit 9 and the filter 8, at the input terminal used in the present invention, so that the active power component has more active power components than the reactive power components.

Claims (9)

It is connected between the power supply 4 supplied by the electric utility and the load 3 of the consumer who uses the electric power, so that the constant voltage can be supplied to the load 3 even when the voltage supplied by the power supply 4 fluctuates. It is possible to improve the power factor of the furnace to improve the quality of the power supplied to the load (3), and to reduce the power, as well as to protect the device from overvoltage and overcurrent and to extend the life, An IGBT switch Q1 (6) and a switch Q2 (5) for CHOPPING a sine wave sent from the input power source 4; IGBT switches Q3 (11) and Q4 (7) having a free wheeling action, which prevents discontinuity of load current during CHOPPING at the IGBT switches Q1 (6) and Q2 (5); A filter (8) using a reactor and a condenser to make the CHOPPING signal generated by the operation of the IGBT switches Q1, Q2, Q3, and Q4 become a sinusoidal voltage and to prevent the harmonics generated by the chopoping action from being supplied to the load; A condenser unit 9 for removing harmonics generated during chipping; Gate control circuit 10 for controlling the operation of the IGBT switches Q1, Q2, Q3, Q4 Dedicated voltage control device, characterized in that consisting of The IGBT switch Q1 (6) and the switch Q2 (5) according to claim 1, which CHOPPING a sine wave sent from the input power source 4, CHOPPING with the size of input voltage 31 maintained and regenerating according to operation of load 3 by enabling IGBT switch other than IGBT switch used for CHOPPING to enable bi-directional energy flow with input power 4 Energy can be reduced to the input power. Dedicated voltage control device According to claim 1, IGBT switch Q1 (6), Q2 (5) in the freewheeling action IGBT switch Q3, Q4 to prevent the discontinuity of the load current during the CHOPPING, In order to prevent the discontinuity of the load current generated when the IGBT switches Q1 (6) and Q2 (5) change the power supply voltage (4) by receiving the signal transmitted from the gate control circuit (10), the gate control circuit (10) IGBT switches Q3 (11) and Q4 (7) operate by receiving the signal transmitted from the Dedicated voltage control device The filter 8 according to claim 1 Dedicated voltage drop characterized by using a reactor and a condenser to make the chopped signal produced by the operation of the IGBT switches Q1, Q2, Q3, and Q4 become a sine wave voltage and to prevent the harmonics generated by the chopping action from being supplied to the load. Voltage controller The condenser part 9 according to claim 1, It is connected to both ends of the input terminal to remove the harmonics generated during CHOPPING in the gate circuit. Dedicated voltage control device According to claim 1, when the CHOPPING starts immediately at the zero crossing time 32 of the power supply voltage 31, the 'on', 'off' time and zero crossing time of the Q3 (11) and Q4 (7) due to a slight frequency variation If (32) is not correct and this time setting is not made correctly, Q4 (7) operates when Q1 (6) operates, or Q3 (11) operates when Q2 (5) operates and Q1-Q4, or In order to prevent arm-short phenomena in which Q3-Q2 is 'on' at the same time, Not all IGBT switches are operated at zero crossing time (32), but there is Chopping-free interval, so that IGBT switch Q1 (6) and Q2 (5) do not chopping operation and load power voltage to load (3). Passing it through Dedicated voltage control device According to claim 1, the general IGBT module has a structure in which the emitter of the first IGBT switch and the second IGBT switch collector are connected so that if two IGBT switches are required for different purposes, the two switches are connected to each other. Each IGBT module must be used without using all of them, but in the wiring structure of the present invention, one IGBT module can be used as IGBT switches Q2 (5) and Q3 (11) with IGBT switches Q1 (6) and Q4 (7), respectively. That there is Dedicated voltage control device delete delete