KR101134854B1 - Apparatus for compensating and supplying voltage - Google Patents

Abstract

An apparatus for compensating and supplying an input voltage is disclosed. The present invention provides a compensation voltage generator and a voltage supply unit that sums and outputs a voltage to generate a compensation voltage only when the input power is unstable and the commercial AC voltage is out of a predetermined range, and does not generate a compensation voltage when within a predetermined range. In this case, the efficiency is increased, and the size of the compensation voltage generator is reduced by designing the voltage to be compensated for.

Description

Voltage Compensation Supply {APPARATUS FOR COMPENSATING AND SUPPLYING VOLTAGE}

The present invention relates to a voltage compensation supply device for supplying a constant voltage to a load, such as an inverter, regardless of voltage instability of a commercial AC power source that is an input power source.

In the prior art, there are two types of apparatus for compensating input voltage. One converts a commercial AC voltage into a DC voltage using a bridge diode, installs a DC-DC converter at the rear end of the DC link capacitor, and compensates the DC link voltage by using the DC-DC converter. It is a form. The other type has a full-bridge converter between a commercial AC power supply and a DC link capacitor to perform bidirectional voltage compensation.

However, in the voltage compensation supply device according to the prior art, in the former case, since the capacity of the DC-DC conversion unit corresponds to 100% of the load, there is a problem that the efficiency is low, its capacity and size are large, and in the latter case There is a problem that the price increases by using a full-bridge converter in converting a commercial AC voltage to a DC voltage.

An object of the present invention is to provide a voltage compensation supply device that generates a compensation voltage and supplies a load driving voltage only when a commercial AC voltage is out of a predetermined range due to an unstable input power supply.

Another object of the present invention is to provide a voltage compensation supply device for compensating a positive voltage when a commercial AC voltage is lower than a predetermined lower limit, and compensating a negative voltage when higher than a predetermined upper limit.

The voltage compensation supply apparatus according to the present invention for achieving the above objects, the voltage conversion unit for converting a commercial AC voltage to a first DC voltage and outputs, and if the commercial AC voltage is out of a predetermined range, the commercial AC voltage And a compensation voltage generator for converting and outputting the second DC voltage, and a voltage supply unit for adding the first DC voltage and the second DC voltage to the load.

In the voltage compensation supply device according to the present invention, the voltage converting unit includes a first AC-DC conversion unit for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the first AC-DC conversion unit. And a first smoothing unit that smoothes to a first DC voltage and outputs the same to the voltage supply unit.

In the voltage compensation supply device according to the present invention, the compensation voltage generating unit includes a second AC-DC conversion unit for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the second AC-DC conversion unit. And a DC-DC converter unit for converting the DC voltage smoothed from the second smoothing unit to the second DC voltage and outputting the smoothed second voltage to the voltage supply unit.

According to an aspect of the present invention, there is provided a voltage compensation supply device comprising: a voltage converter configured to convert a commercial AC voltage into a first DC voltage and output the first AC voltage; a voltage detection unit to detect the commercial AC voltage; and a switching signal. A compensation voltage generator for converting the commercial AC voltage into a second DC voltage and outputting the converted DC voltage; a voltage supply unit configured to add the first DC voltage and the second DC voltage to a load; And a control unit generating the switching signal based on the voltage and outputting the switching signal to the compensation voltage generator.

In addition, the voltage compensation supply apparatus according to the present invention further comprises an insulation unit for insulating the voltage converter and the compensation voltage generator.

In the voltage compensation supply device according to the present invention, the voltage converting unit includes a first AC-DC conversion unit for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the first AC-DC conversion unit. And a first smoothing unit that smoothes to a first DC voltage and outputs the same to the voltage supply unit.

In the voltage compensation supply device according to the present invention, the compensation voltage generating unit includes a second AC-DC conversion unit for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the second AC-DC conversion unit. And a DC-DC conversion unit for converting the DC voltage smoothed from the second smoothing unit to the second DC voltage in accordance with the switching signal and outputting the voltage to the voltage supply unit. The DC-DC converter is a step-down converter having a switching element that is opened and closed in accordance with the switching signal.

The voltage compensation supply device according to the present invention increases efficiency by generating a compensation voltage only when the commercial AC voltage is out of a predetermined range because the input power source is unstable and does not generate a compensation voltage when within a predetermined range.

The present invention is advantageous in that the size is small by designing a separate compensation voltage generator to compensate for the voltage to be compensated, and the loss is small and the efficiency is increased by generating only the voltage to be compensated instead of the total output voltage.

1 is a block diagram schematically showing a voltage compensation supply device according to an embodiment of the present invention;
2 is a block diagram schematically showing a voltage compensation supply device according to another embodiment of the present invention;
3 and 4 are block diagrams and circuit diagrams showing the detailed configuration of FIGS. 1 and 2;
5 shows an example of a circuit for compensating and supplying a positive voltage in the voltage compensation supply device of FIGS. 1 and 2;
6 is a diagram illustrating an example of a circuit for compensating and supplying a negative voltage in the voltage compensation supply device of FIGS. 1 and 2.

Hereinafter, a voltage compensation supply device according to the present invention will be described in detail with reference to the accompanying drawings.

1, the voltage compensation supply apparatus according to an embodiment of the present invention, the voltage conversion unit 200 for converting the commercial AC voltage of the commercial AC power supply 100 to a first DC voltage and outputs, the commercial When the AC voltage is out of a predetermined range, the compensation voltage generator 300 converts the commercial AC voltage into a second DC voltage and outputs the sum of the first DC voltage and the second DC voltage to supply the load. It is configured to include a voltage supply unit (400).

Referring to FIG. 3, the voltage converter 200 may include a first AC-DC conversion unit 210 for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the first AC-DC conversion unit. It comprises a first smoothing unit 220 to smooth to the first DC voltage and output to the voltage supply.

The first AC-DC converter 210 is composed of a combination of diode rectifiers and converts an AC voltage of an input power source into a DC voltage. At this time, the DC voltage is actually a pulse flow. The first smoothing unit 220 includes a DC link capacitor or a simple circuit including the same, and smoothes the DC voltage in the form of the pulse current output from the first AC-DC conversion unit 210 to convert the first DC voltage. Output to the voltage supply unit 400.

Referring to FIG. 3, the compensation voltage generator 300 may include a second AC-DC conversion unit 310 for converting the commercial AC voltage into a DC voltage, and a DC output from the second AC-DC conversion unit. A second smoothing unit 320 for smoothing the voltage, and a DC-DC conversion unit 330 for converting the DC voltage smoothed from the second smoothing unit into the second DC voltage and outputting the second DC voltage to the voltage supply unit 400. It is configured to include.

The second AC-DC converter 310 is composed of a combination of diode rectifiers and converts an AC voltage of an input power source into a DC voltage. At this time, the DC voltage is actually a pulse flow. The second smoothing unit 320 is composed of a DC link capacitor or a simple circuit including the same, and smoothes the DC voltage in the form of the pulse current output from the second AC-DC conversion unit 310 to convert the DC-DC conversion. Output to the unit 330.

The DC-DC converter 330 converts the DC voltage smoothed through the second smoothing unit 320 into a second DC voltage having a predetermined size and supplies the voltage to the voltage supply unit 400. Output

Referring to FIG. 4, the DC-DC conversion unit 330, and the DC-DC conversion unit 330 includes a step-down converter having a switching element S5 that is opened and closed according to the switching signal. Converter).

The voltage compensation supply apparatus according to the present invention may further include an insulation unit 700 that insulates the voltage converter 200 from the compensation voltage generator 300. The insulation unit 700 electrically insulates the ground from the ground of the voltage converter 200 and the compensation voltage generator 300 by using a high frequency transformer or the like.

Referring to FIG. 4, the voltage supply unit 400 includes a full-bridge converter having a plurality of switching elements S1 to S4. The voltage supply unit 400 adds a first DC voltage output from the voltage converter 200 and a second DC voltage output from the compensation voltage generator 300 to output the load to a load such as an inverter. do. Referring to FIG. 4, when the input voltage is smaller than a predetermined predetermined range, the switching elements S1 and S4 are turned on, and the switching elements S2 and S3 are turned off to enable voltage compensation in a positive direction. On the other hand, when the input voltage is greater than a predetermined range, the switching elements S1 and S4 are turned off, and when S2 and S3 are turned on, voltage compensation is possible in the negative direction.

The voltage supply unit 400 may be simply configured as a combination of diodes, as shown in FIGS. 5 and 6.

5 and 6, the voltage supply unit 400 is a combination of diodes configured to operate when the commercial AC voltage is out of the predetermined range. Referring to FIG. 5, the voltage supply unit 400 includes diodes D401 and D402 and adds the first DC voltage and the second DC voltage to the load, and performs voltage compensation in a positive direction. Referring to FIG. 6, the voltage supply unit 400 includes diodes D403 and D404 to perform voltage compensation in a negative direction.

2, a voltage compensation supply device according to another embodiment of the present invention includes a voltage converter 200 for converting a commercial AC voltage into a first DC voltage and outputting the voltage, for detecting the commercial AC voltage. A unit 500, a compensation voltage generation unit 300 for converting the commercial AC voltage into a second DC voltage based on a switching signal, and outputting the sum of the first DC voltage and the second DC voltage to the load; And a control unit 600 for generating the switching signal based on the voltage detected by the voltage detection unit and outputting the switching signal to the compensation voltage generator.

In addition, the voltage compensation supply apparatus according to the present invention further comprises an insulation unit 700 for insulating between the voltage converter and the compensation voltage generator. The insulation unit 700 is electrically insulated by changing the ground of the voltage converter 200 and the compensation voltage generator 300, and the voltage supply unit 400 supplies the first DC voltage and the second DC voltage. Add up. As the insulation unit 700, for example, a high frequency transformer or the like can be used.

Referring to FIG. 3, the voltage converter 200 may include a first AC-DC conversion unit 210 for converting the commercial AC voltage into a DC voltage, and a DC voltage output from the first AC-DC conversion unit. It comprises a first smoothing unit 220 to smooth to the first DC voltage and output to the voltage supply.

The first AC-DC converter 210 is composed of a combination of diode rectifiers and converts an AC voltage of an input power source into a DC voltage. At this time, the DC voltage is actually a pulse flow. The first smoothing unit 220 includes a DC link capacitor or a simple circuit including the same, and smoothes the DC voltage in the form of the pulse current output from the first AC-DC conversion unit 210 to convert the first DC voltage. Output to the voltage supply unit 400.

The voltage detection unit 500 detects a commercial AC voltage of the input power and transmits a detection signal to the control unit 600. The control unit 600 compares whether the detected commercial AC voltage is within a predetermined range and determines whether to compensate the voltage output to the load. In addition, the control unit 600 determines the magnitude of the voltage to be compensated according to the detected magnitude of the commercial AC voltage. Here, the predetermined range may be determined differently according to the use environment and the installation environment. For example, the predetermined range may be set to Vpeak, Vrms, or the like. The voltage detection unit 500 may be installed directly in the commercial power supply 100 or may be installed in the voltage converter 200.

Referring to FIG. 3, the compensation voltage generator 300 may include a second AC-DC conversion unit 310 for converting the commercial AC voltage into a DC voltage, and a DC output from the second AC-DC conversion unit. A second smoothing unit 320 for smoothing a voltage, and a DC-DC conversion unit 330 for converting a DC voltage smoothed from the second smoothing unit into the second DC voltage according to the switching signal and outputting the second DC voltage to the voltage supply unit. It is configured to include).

The second AC-DC converter 310 is composed of a combination of diode rectifiers and converts an AC voltage of an input power source into a DC voltage. At this time, the DC voltage is actually a pulse flow. The second smoothing unit 320 is composed of a DC link capacitor or a simple circuit including the same, and smoothes the DC voltage in the form of the pulse current output from the second AC-DC conversion unit 310 to convert the DC-DC conversion. Output to the unit 330.

The DC-DC converter 330 has a predetermined magnitude of a DC voltage smoothed through the second smoothing unit 320 according to the switching signal output from the control unit 600. The signal is converted into a second DC voltage and output to the voltage supply unit 400. Here, the switching signal is a pulse width modulation (PWM) signal determined based on the magnitude of the compensation voltage. That is, the control unit 600 controls the magnitude of the compensation voltage by adjusting the duty ratio of the switching signal.

The DC-DC converter 330 is a step-down converter having a switching element S5 that is opened and closed according to the switching signal. The step-down converter is a buck converter, a switching element such as a MOSFET, a diode connected in parallel with the switching element, an LC circuit for removing high frequency components when opening and closing the switching element, and storing energy, and connected in parallel to the current path A diode D301 is formed. When the switching device S5 is turned on by outputting the switching signal from the control unit 600, the second DC voltage is output to the voltage supply unit 400 during the turn-on time. In this case, the switching signal generates a high frequency when the switching element is turned on, and the high frequency signal is removed through a low pass filter (LPF) composed of L and C connected to a rear end, and then a second DC voltage is output. do. When the control unit 600 turns off the switching element S5, the energy stored in the inductor L is discharged. At this time, the current flow path is formed by the diode D301 connected in parallel with the LC circuit. Therefore, the voltage compensation supply device according to the present invention increases efficiency by adjusting the required DC voltage according to the voltage demand for the load by using the DC-DC conversion unit 330, especially when the input voltage is out of a certain range In this case, the loss caused by the semiconductor devices can be reduced.

Referring to FIG. 4, the voltage supply unit 400 includes a full-bridge converter having a plurality of switching elements S1 to S4. The voltage supply unit 400 adds a first DC voltage output from the voltage converter 200 and a second DC voltage output from the compensation voltage generator 300 to output the load to a load such as an inverter. do. Referring to FIG. 4, when the input voltage is smaller than a predetermined predetermined range, the switching elements S1 and S4 are turned on, and the switching elements S2 and S3 are turned off to enable voltage compensation in a positive direction. On the other hand, when the input voltage is greater than a predetermined range, the switching elements S1 and S4 are turned off, and when S2 and S3 are turned on, voltage compensation is possible in the negative direction.

The voltage supply unit 400 may be simply configured as a combination of diodes, as shown in FIGS. 5 and 6.

5 and 6, the voltage supply unit 400 is a combination of diodes configured to operate when the commercial AC voltage is out of the predetermined range. Referring to FIG. 5, the voltage supply unit 400 includes diodes D401 and D402 and adds the first DC voltage and the second DC voltage to the load, and performs voltage compensation in a positive direction. Referring to FIG. 6, the voltage supply unit 400 includes diodes D403 and D404 to perform voltage compensation in a negative direction. Therefore, the circuit can be configured by a combination of diodes rather than full-bridge converters, which are relatively expensive depending on the characteristics of the input power supply of the installation environment, thereby reducing costs while maintaining efficiency.

As described above, the apparatus for compensating and supplying the input voltage according to the present invention includes a compensating voltage generating unit and a voltage supply unit for outputting the sum of the voltages so that the input power is unstable and the commercial AC voltage is outside the predetermined range. The efficiency is increased by generating a compensation voltage and not generating a compensation voltage when it is within a predetermined range.

100: commercial AC power supply 200: voltage converter
300: compensation voltage generator 400: voltage supply
500: voltage detection unit 600: control unit
700: Insulation unit 210: First AC-DC conversion unit
220: first smoothing unit 310: second AC-DC conversion unit
320: second smoothing unit 330: DC-DC conversion unit

Claims (18)

A voltage converter converting the commercial AC voltage into a first DC voltage and outputting the first AC voltage;
A compensation voltage generator configured to convert the commercial AC voltage into a second DC voltage and output the second AC voltage when the commercial AC voltage is out of a predetermined range; And
And a voltage supply unit configured to supply the load by adding the first DC voltage and the second DC voltage.
And the voltage supply unit is a full-bridge converter. The method of claim 1, wherein the voltage converter,
A first AC-DC conversion unit converting the commercial AC voltage into a DC voltage; And
And a first smoothing unit that smoothes the DC voltage output from the first AC-DC conversion unit to the first DC voltage and outputs the voltage to the voltage supply unit. The method of claim 2, wherein the compensation voltage generator,
A second AC-DC conversion unit converting the commercial AC voltage into a DC voltage;
A second smoothing unit that smoothes the DC voltage output from the second AC-DC conversion unit; And
And a DC-DC conversion unit converting the DC voltage smoothed from the second smoothing unit into the second DC voltage and outputting the converted voltage to the voltage supply unit. delete A voltage converter converting the commercial AC voltage into a first DC voltage and outputting the first AC voltage;
A compensation voltage generator configured to convert the commercial AC voltage into a second DC voltage and output the second AC voltage when the commercial AC voltage is out of a predetermined range; And
And a voltage supply unit configured to supply the load by adding the first DC voltage and the second DC voltage.
The voltage supply unit,
And a combination of diodes configured to operate when the commercial AC voltage is out of the predetermined range. A voltage converter converting the commercial AC voltage into a first DC voltage and outputting the first AC voltage;
A voltage detection unit detecting the commercial AC voltage;
A compensation voltage generator for converting the commercial AC voltage into a second DC voltage based on a switching signal and outputting the second DC voltage;
A voltage supply unit configured to add the first DC voltage and the second DC voltage to a load; And
And a control unit generating the switching signal and outputting the switching signal to the compensation voltage generator based on whether the voltage detected from the voltage detection unit is within a predetermined range.
The voltage supply unit,
Voltage compensation supply, characterized in that the full-bridge converter. The method of claim 6,
And an insulation unit insulated between the voltage converter and the compensation voltage generator. The method of claim 6 or 7, wherein the voltage converter,
A first AC-DC conversion unit converting the commercial AC voltage into a DC voltage; And
And a first smoothing unit that smoothes the DC voltage output from the first AC-DC conversion unit to the first DC voltage and outputs the voltage to the voltage supply unit. The method of claim 8, wherein the compensation voltage generator,
A second AC-DC conversion unit converting the commercial AC voltage into a DC voltage;
A second smoothing unit that smoothes the DC voltage output from the second AC-DC conversion unit; And
And a DC-DC conversion unit converting the DC voltage smoothed from the second smoothing unit into the second DC voltage according to the switching signal and outputting the converted DC voltage to the voltage supply unit. The method of claim 9, wherein the DC-DC conversion unit,
And a step-down converter having a switching element opened and closed according to the switching signal. delete A voltage converter converting the commercial AC voltage into a first DC voltage and outputting the first AC voltage;
A voltage detection unit detecting the commercial AC voltage;
A compensation voltage generator for converting the commercial AC voltage into a second DC voltage based on a switching signal and outputting the second DC voltage;
A voltage supply unit configured to add the first DC voltage and the second DC voltage to a load; And
And a control unit generating the switching signal and outputting the switching signal to the compensation voltage generator based on whether the voltage detected from the voltage detection unit is within a predetermined range.
The voltage supply unit,
And a combination of diodes configured to operate when the commercial AC voltage is out of the predetermined range. The method of claim 12,
And an insulation unit insulated between the voltage converter and the compensation voltage generator. The method of claim 12 or 13, wherein the voltage converter,
A first AC-DC conversion unit converting the commercial AC voltage into a DC voltage; And
And a first smoothing unit that smoothes the DC voltage output from the first AC-DC conversion unit to the first DC voltage and outputs the voltage to the voltage supply unit. The method of claim 14, wherein the compensation voltage generator,
A second AC-DC conversion unit converting the commercial AC voltage into a DC voltage;
A second smoothing unit that smoothes the DC voltage output from the second AC-DC conversion unit; And
And a DC-DC conversion unit converting the DC voltage smoothed from the second smoothing unit into the second DC voltage according to the switching signal and outputting the converted DC voltage to the voltage supply unit. The method of claim 15, wherein the DC-DC conversion unit,
And a step-down converter having a switching element opened and closed according to the switching signal. The method of claim 5, wherein the voltage converter,
A first AC-DC conversion unit converting the commercial AC voltage into a DC voltage; And
And a first smoothing unit that smoothes the DC voltage output from the first AC-DC conversion unit to the first DC voltage and outputs the voltage to the voltage supply unit. The method of claim 17, wherein the compensation voltage generator,
A second AC-DC conversion unit converting the commercial AC voltage into a DC voltage;
A second smoothing unit that smoothes the DC voltage output from the second AC-DC conversion unit; And
And a DC-DC conversion unit converting the DC voltage smoothed from the second smoothing unit into the second DC voltage and outputting the converted voltage to the voltage supply unit.

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