KR100507999B1 - Chopper type voltage compensator with energy storage means - Google Patents

Abstract

The present invention relates to a chopper type voltage compensator having an energy storage function.

A series input transformer 200 connected in series between the AC power supply VS and the load P; A chopper circuit 100 having an input terminal connected to the AC power supply VS and an output terminal connected to the series input transformer 200 through a first switch SS1; A charger 300 connected to the AC power supply and having a rectifier therein; An inverter 500 connected to the charger 300 in parallel with the condenser 400 and connected to the series input transformer 200 through a second switch SS2; In response to the voltage signal of the AC power supply VS, when the normal voltage is applied, the first and second switches SS1 and SS2 are turned on to turn on the transformer 200, the chopper circuit 100, and the inverter 500. The charger 300 is charged while forming a load current bypass path to be connected, and when the low voltage is generated at a ratio less than a predetermined value, the first switch SS1 is turned on and the second switch SS2 is turned off. The voltage compensation by the chopper circuit 100 is performed, and when the low voltage is generated at a ratio equal to or greater than a predetermined value, the first switch SS1 is turned off and the second switch SS2 is turned on so that the charger 300 and the inverter 500 are turned on. And a controller 600 for controlling voltage compensation by

The low voltage can be compensated with a simple structure even when a low voltage of a predetermined ratio or more is generated, so that the low voltage can be compensated more stably than the conventional chopper method.

Description

Chopper type voltage compensator with energy storage function {CHOPPER TYPE VOLTAGE COMPENSATOR WITH ENERGY STORAGE MEANS}

The present invention relates to a chopper type voltage compensator having an energy storage function. More particularly, the present invention relates to a chopper type voltage compensator for compensating for an undervoltage when an instantaneous low voltage is generated due to an accident of a power system. The present invention relates to a chopper type voltage compensator capable of appropriately responding to a low voltage occurrence.

The occurrence of instantaneous low voltages due to accidents in the power system is particularly damaging to plants with integrated production lines.

In order to minimize such damage, a chopper type voltage compensator that receives additional power from an input power source and compensates the undervoltage using a chopper method when a low voltage occurs is widely used.

1 is a block diagram illustrating a conventional chopper type voltage compensator.

The series input transformer 200 is connected in series with the power supply VS, and an output voltage of the chopper circuit 100 is used as an input of the transformer 200.

The chopper circuit 100 is a power conversion circuit capable of converting an arbitrary size of an AC input power and supplying it to a load, and the output frequency has the same characteristics as the input frequency.

In the illustrated chopper circuit 100, the switches S1 to S4 are sequentially connected in series and branched to the transformer 200 between the switches S2 and S3, and the switches S1 and S2 and the switches S3 and S4 are connected in opposite directions. Each switch has a configuration in which diodes D1 to D4 are connected in parallel in opposite directions.

Operation For example, when the power supply VS is positive, the switches S1 and S4 are alternately turned on and off, while at the same time D2 and D3 are used to form an electrical path. If the power supply (VS) is negative, the switches S2 and S3 are alternately turned on and off to supply the chopping voltage in such a way that the diodes D1 and D4 naturally form an electrical path.

When the low voltage is generated, the chopper circuit 100 generates an insufficient voltage by using an input commercial power supply VS and adds it in series to the load P side by using a series input transformer 200.

For example, if the normal voltage of the power supply VS supplied to the load P side is 100V, but only 90V is actually input, the controller 600 detects this and generates a low voltage (10V) at the time of low voltage generation. By calculating the chopping control to compensate for this.

Through this process, a normal voltage is applied to the load P.

However, such a conventional chopper type voltage compensator has a limit in that it cannot sufficiently compensate the load when a low voltage of 40% or more of the rated voltage is generated.

As a result of examining the actual low voltage generation type, a lot of low voltages of 40% or more are generated, and thus, there is a problem in that the low voltage compensation cannot be completed by the conventional method.

The present invention is to solve the above problems, as a chopper type voltage compensator that compensates for the undervoltage in the event of an instantaneous low voltage due to an accident of the power system, in particular with an energy storage function properly when a large low voltage occurs It is an object of the present invention to provide a chopper-type voltage compensator with an energy storage function that allows it to cope with it.

The present invention for achieving the above object, the series input transformer 200 is installed in series between the AC power supply (VS) and the load (P); A chopper circuit 100 having an input terminal connected to the AC power supply VS and an output terminal connected to the series input transformer 200 through a first switch SS1; A charger 300 connected to the AC power supply and having a rectifier therein; An inverter 500 connected to the charger 300 in parallel with the condenser 400 and connected to the series input transformer 200 through a second switch SS2; In response to the voltage signal of the AC power supply VS, when the normal voltage is applied, the first and second switches SS1 and SS2 are turned on to turn on the transformer 200, the chopper circuit 100, and the inverter 500. The charger 300 is charged while forming a load current bypass path to be connected, and when the low voltage is generated at a ratio less than a predetermined value, the first switch SS1 is turned on and the second switch SS2 is turned off. The voltage compensation by the chopper circuit 100 is performed, and when the low voltage is generated at a ratio equal to or greater than a predetermined value, the first switch SS1 is turned off and the second switch SS2 is turned on so that the charger 300 and the inverter 500 are turned on. It is configured to include; a controller 600 for controlling to perform voltage compensation by.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of a chopper type voltage compensator according to an embodiment of the present invention, and FIG. 3 is a control flowchart of a chopper type voltage compensator according to an embodiment of the present invention.

A series input transformer 200 is connected in series between the AC power supply VS and the load P.

An output terminal of the chopper circuit 100 having an input terminal connected to the AC power supply VS is connected to the series input transformer 200 through a first switch SS1.

The charger 300 having a rectifier therein is connected to the AC power supply VS.

The input terminal of the inverter 500 is connected to the charger 300 in parallel with the capacitor 400 functioning as a condenser bank, and the output terminal of the inverter 500 is connected to the series input transformer through a second switch SS2. Connected to 200.

The controller 600 receives a voltage signal of the AC power supply VS and performs switching control of the entire circuit including the first and second switches SS1 and SS2 according to the voltage state.

The controller 600 may turn on both the first and second switches SS1 and SS2 when the normal voltage is applied to connect the load current by connecting the transformer 200, the chopper circuit 100, and the inverter 500. The charger 300 is charged while forming a pass path.

On the other hand, the controller 600 turns on the first switch SS1 and turns off the second switch SS2 when the low voltage occurs at a ratio less than a predetermined value (for example, less than 40%). Control to perform voltage compensation by 100).

On the other hand, the controller 600 turns off the first switch SS1 and turns on the second switch SS2 when the low voltage is generated at a ratio equal to or greater than a predetermined value (for example, 40% or more). And the voltage compensation by the inverter 500 are controlled.

In summary, a transfer switch, a charger, and a capacitor bank are installed in a conventional chopper type low voltage compensator. For example, a voltage compensation is performed using a conventional chopper method for a low voltage of less than 40%, and a charger is provided for a low voltage of 40% or more. By using the energy stored in the capacitor bank via the compensation as an inverter mode.

An operating state of such a chopper type voltage compensator will be described with reference to FIG. 2.

First, when a steady voltage is applied, the input side of the series input transformer 200 is shorted so that the commercial voltage VS is supplied to the load P as it is. To this end, the first and second switches SS1 and SS2 and the switches S3 and S4 in the chopper circuit 100 and the switches S7 and S8 in the inverter 500 are turned on.

4A and 4B are current flow state diagrams at steady voltages of a chopper type voltage compensator according to an embodiment of the present invention, and show current flow states according to changes in the AC power supply VS.

In more detail, when the normal voltage is applied, if the primary side (inverter side) of the series input transformer 200 is open, a voltage drop on the secondary side occurs. Therefore, in order to prevent this, the primary side (inverter side) of the series input transformer 200 is shorted to form a load current bypass path.

Since the first and second switches SS1 and SS2 are turned on at the same time, the bypass path is formed simultaneously with the chopper side path A2 or B2 and the inverter side path A1 or B1, depending on the phase of the commercial voltage VS. Paths of the type shown in 4a and 4b are alternately formed.

Through this process, the load current bypass path on the inverter 500 side can be secured during normal power supply.

The charger 300 always charges a certain amount of energy in the capacitor bank at this normal voltage.

On the other hand, when the operation of the circuit when the low voltage occurs, it can be divided into two operation modes according to the state of the compensator.

First, when the amount of low voltage generated is less than 40%, voltage compensation is performed by the existing chopper method.

To this end, the first switch SS1 remains on and the second switch SS2 remains off.

In this state, the switches S1 to S4 in the chopper circuit 100 are controlled to be switched, and a shortage voltage is generated using the chopper method from the input AC voltage to compensate for the voltage through the series input transformer 200.

At this time, the switches S5 to S8 in the inverter 500 maintain the off state.

On the load P side, a value obtained by adding an undervoltage to an input voltage is applied to the final load, thereby applying a normal voltage.

Next, when the amount of low voltage generation is 40% or more, voltage compensation is performed in the inverter mode. For this purpose, the controller 600 turns off the first switch SS1 and turns on the second switch SS2.

In addition, while using the DC energy stored in the capacitor bank, the switches S5 to S8 in the inverter 500 are switched to the PWM inverter mode. At this time, the switches S1 to S4 in the chopper circuit 100 maintain the off state.

As a result, only the insufficient voltage is generated in the inverter 500 and added to the load P using the series input transformer 200, which is similar to the case of the chopper mode.

Then, the sum of the input voltage and the undervoltage is applied to the normal voltage to the final load.

The present invention described above may be embodied in other various forms without departing from the spirit or main features thereof. Therefore, the above embodiments are merely examples in all respects and should not be interpreted limitedly.

The present invention as described above can compensate the low voltage with a simple structure even when a low voltage is generated at a predetermined ratio or more (for example, 40% or more), and thus compensates the low voltage more stably than the conventional chopper method.

In addition, when the normal voltage is maintained, a plurality of inverter-side load current bypass paths of the series input transformer can be maintained, thereby significantly improving the reliability of the compensator.

1 is a block diagram illustrating a conventional chopper type voltage compensator,

2 is a block diagram of a chopper type voltage compensator according to an embodiment of the present invention;

3 is a control flowchart of a chopper type voltage compensator according to an embodiment of the present invention;

4A and 4B are diagrams illustrating current flow at steady voltages of a chopper type voltage compensator according to an exemplary embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

VS: AC Power P: Load

SS1: first switch SS2: second switch

100: chopper circuit 200: series input transformer

300: charger 400: condenser

500: inverter 600: controller

Claims (1)

A series input transformer 200 connected in series between the AC power supply VS and the load P; A chopper circuit 100 having an input terminal connected to the AC power supply VS and an output terminal connected to the series input transformer 200 through a first switch SS1; A charger 300 connected to the AC power supply and having a rectifier therein; An inverter 500 connected to the charger 300 in parallel with the condenser 400 and connected to the series input transformer 200 through a second switch SS2; In response to the voltage signal of the AC power supply VS, when the normal voltage is applied, the first and second switches SS1 and SS2 are turned on to turn on the transformer 200, the chopper circuit 100, and the inverter 500. The charger 300 is charged while forming a load current bypass path to be connected, and when the low voltage is generated at a ratio less than a predetermined value, the first switch SS1 is turned on and the second switch SS2 is turned off. The voltage compensation by the chopper circuit 100 is performed, and when the low voltage is generated at a ratio equal to or greater than a predetermined value, the first switch SS1 is turned off and the second switch SS2 is turned on so that the charger 300 and the inverter 500 are turned on. A chopper type voltage compensator having an energy storage function, comprising: a controller 600 for controlling voltage compensation by the controller.