KR20100012555A - Compensation device for interruption of electric power and lowering input voltage - Google Patents

Abstract

PURPOSE: A compensation device for interruption of an electric power and a lowering input voltage is provided to by-pass power by using a first by-pass unit without additional by-pass circuit. CONSTITUTION: A rectifier(310) rectifies an AC voltage to a direct current voltage. A energy storage(320) stores the direct current voltage of the rectifier. A first by-pass part(330) transfers the electrical energy of the energy storage in response to switch control signals to the load(360). A first by-pass unit bypasses the current corresponding to the AC voltage of a transformer(340). The transformer transfers the voltage corresponding to the stored energy to the load. Transformer bypasses the voltage corresponding to the AC voltage through the first by-pass unit. A second bypass module(350) makes AC power source a short circuit in response to the switch control signals. A second bypass module switches in order to make a closed circuit of a transformer and a load. The load absorbs the electrical energy of the AC voltage or the energy storage.

Description

Compensation device for interruption of electric power and lowering input voltage}

The present invention relates to a compensation device capable of compensating for a power failure or an instantaneous low voltage state, and more particularly, to a compensation device capable of compensating for an instantaneous low voltage state as well as a power failure.

Figure 1 shows a conventional instantaneous low voltage compensation device.

Referring to FIG. 1, the instantaneous low voltage compensator 100 charges a voltage corresponding to an AC power when a normal voltage is applied from the AC power source 110, and then charges a voltage when a relatively low power is applied. To the load 1600. That is, when a voltage having a normal voltage level is applied from the AC power source 110, to the AC voltage converted through the first inverter 120 converting AC into DC. The compensator 140 is charged with a corresponding DC voltage. When a voltage lower than the normal voltage level is applied from the AC power source 110, the second inverter converts the DC voltage charged in the compensator 140 into an AC voltage. The AC voltage converted through the 130 is transmitted to the load 160 through the transformer 150.

The instantaneous low voltage compensation device 100 is supplied with power only through one wire of the converter 150 without the two inverters 120 and 130 operating at the normal voltage, and the inverter operates only at the low voltage to supply the insufficient voltage. The efficiency is relatively high because it is

However, since the instantaneous low voltage compensation device 100 is a concept of adding an insufficient voltage to the load 160 in series, when power is not supplied during a power failure, the first inverter 120 and the second inverter 130 may operate. There is a disadvantage.

2 shows a conventional uninterruptible power supply.

Referring to FIG. 2, the uninterruptible power supply 200 turns on the first switch Sw1 and the second switch Sw2 when the power source is normally operating. At this time, the input AC power In is output to the load (not shown) on one side (Out), and the charger 230 is charged via the inverter 210 which converts AC into DC on the other side. Let's do it. The third switch Sw3 has no problem even when turned on, but is generally turned off.

The uninterruptible power supply 200 turns on the third switch Sw3 when a power failure occurs. At this time, the voltage level of the AC power input In is not normal or has a ground voltage level. The voltage charged in the charger 230 is output to a load (not shown) via the third switch Sw3 ( Out).

Since the uninterruptible power supply 200 does not operate when the voltage level of the alternating current In is lowered, the uninterruptible power supply 200 becomes a valid circuit only during a power failure.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a power failure and low voltage compensation device capable of compensating not only when an input voltage is lower than a normal voltage level but also when a supply power is cut off.

The power failure and low voltage compensation device according to the present invention for achieving the technical problem includes a rectifier, an energy storage unit, a first bypass unit, a transformer, a second bypass unit and a load. The rectifier rectifies the input AC voltage into a DC voltage. The energy storage unit stores the DC voltage output from the rectifier. In response to a plurality of switch control signals, the first bypass unit transfers electrical energy stored in the energy storage unit to a load or bypasses a current corresponding to an AC voltage applied through a transformer. The transformer generates a voltage corresponding to energy stored in the energy storage unit applied through the first bypass unit and transmits the voltage to the load, or transfers an input AC voltage to the load and generates a voltage corresponding thereto. Bypass through the first bypass unit. In response to at least one switch control signal, the second bypass unit short-circuits the AC power supplying the AC voltage, and switches the transformer and the load so that the transformer and the load become a closed circuit. The load absorbs an input AC voltage or electrical energy supplied from the energy storage unit.

The present invention has the advantage that it can compensate for the case when the input power supply is cut off as well as when the input voltage is lower than the normal voltage level.

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

3 illustrates a power failure and low voltage compensation device according to the present invention.

Referring to FIG. 3, the power failure and low voltage compensation device 300 may include a rectifier 310, an energy storage unit 320, a first bypass unit 330, a transformer 340, and a second bypass unit 350. And a load 360 and a control unit 370.

The rectifier 310 converts an AC voltage Vs into a DC voltage to charge energy in the energy storage 320. The energy storage unit 320 may be implemented as a condenser bank or a battery bank. It is advantageous to use a battery bank for long time compensation in case of power failure, and to use a capacitor bank for frequent low voltage compensation. The term bank is used here because it includes one capacitor or one or more batteries. In an actual design, more than one may be possible.

The first bypass unit 330 transmits electrical energy stored in the energy storage unit 320 to the load 360 or is applied through a transformer 340 in response to the plurality of switch control signals S1 to S4. Bypassing the current corresponding to the AC voltage (Vs), four diodes (S1 ~ S4) and four diodes (D1 ~ D4) connected in parallel to each of the four switches (S1 ~ S4) is provided for this purpose. .

The first switch Sw1 switches one terminal o of the energy storage unit 320 and the first terminal 1 of one side of the transformer 340 in response to the first switch control signal S1. The second switch Sw2 switches one terminal p of the energy storage unit 320 and the second terminal 1 ′ of one side of the transformer 340 in response to the second switch control signal S2. The third switch Sw3 switches the other terminal o 'of the energy storage unit 320 and the first terminal 1 of one side of the transformer 340 in response to the third switch control signal S3. . The fourth switch Sw4 switches the other terminal o 'of the energy storage unit 320 and the second terminal 1' of one side of the transformer 340 in response to the fourth switch control signal S4. do.

The P-type terminal of the first diode D1 is connected to the first terminal 1 of one side of the transformer 340, and the N-type terminal is connected to one terminal o of the energy storage unit 320. The P-type terminal of the second diode D2 is connected to the second terminal 1 ′ of one side of the transformer 340, and the N-type terminal is connected to one terminal o of the energy storage unit 320. In the third diode D3, an N-type terminal is connected to the first terminal 1 of one side of the transformer 340, and a P-type terminal is connected to the other terminal o ′ of the energy storage unit 320. The fourth diode D4 has an N-type terminal connected to the second terminal 1 'of one side of the transformer 340, and a P-type terminal connected to the other terminal o' of the energy storage unit 320. .

The transformer 340 generates a voltage corresponding to the energy stored in the energy storage unit 320 applied through the first bypass unit 330 and transmits the voltage to the load 360, or receives an input AC voltage Vs. At the same time as to transfer to the load 360 generates a voltage corresponding to the bypass via the first bypass unit 330. The transformer 340 has a first side connected to the first bypass unit 330, a second side connected to the first bypass unit 350, and a load 360, and a voltage corresponding to a current applied to the first side. The voltage corresponding to the current applied to the second side is induced to the first side.

In response to the at least one switch control signal S5, the second bypass unit 350 short-circuits both terminals of the AC power supplying the AC voltage Vs, and the transformer 340 and the load 360 are closed. Switch to if possible. The second bicing unit 350 operates in response to the fifth switch control signal S5, and one terminal is connected to one terminal of the AC power source and the first terminal 2 on the other side of the transformer 340. The other terminal may be implemented as a switch connected to one terminal of the load.

The load 360 absorbs the input AC voltage Vs or the electric energy supplied from the energy storage 320, and the other terminal is connected to the second terminal 2 ′ on the other side of the transformer 340. do. The controller 370 generates a plurality of switch control signals S1 to S5 applied to the first bypass unit 330 and the second bypass unit 350 in response to the AC voltage Vs.

When the input AC voltage Vs indicates a normal voltage level, the third switch Sw3 and the fourth switch Sw4 are turned on. In this case, currents induced from one side 2-2 ′ to the other side 1-1 ′ of the transformer 340 through which the input AC voltage Vs flows are bypassed.

The input AC voltage Vs has a voltage level relatively lower than the normal voltage level, or when the power failure occurs, the first switch Sw1, the fourth switching Sw4, and the fifth switch Sw5 are turned on. At this time, the energy stored in the energy storage unit 320 through the transformer 340 is transmitted to the load 360 via the first bypass unit 330 and the transformer 340. At the same time, the second bypass unit 350 allows the transformer 340 and the load 360 to form a closed circuit.

The present invention implements only the advantages of the general instantaneous low voltage compensation device 100 and the uninterruptible power supply 200 in one circuit, and the following effects can be obtained. First, since the power may be bypassed by using the first bypass unit 330 without an additional bypass circuit at the time of normal power supply, the number of elements used may be reduced. At the same time, the effect of efficiency increase can be seen at the same time because it is not always the inverter operation method. In addition, by adding a second bypass unit 350 to compensate the shortcomings that cannot be compensated when the power line is cut off, which is the biggest disadvantage of the instantaneous low voltage compensator 100, the uninterruptible power supply 200 Same function as).

In the above description, the technical idea of the present invention has been described with the accompanying drawings, which illustrate exemplary embodiments of the present invention by way of example and do not limit the present invention. In addition, it is apparent that any person having ordinary knowledge in the technical field to which the present invention belongs may make various modifications and imitations without departing from the scope of the technical idea of the present invention.

Figure 1 shows a conventional instantaneous low voltage compensation device.

2 shows a conventional uninterruptible power supply.

3 illustrates a power failure and low voltage compensation device according to the present invention.

Claims (7)

A rectifying unit 310 rectifying the input AC voltage Vs into a DC voltage; An energy storage unit 320 for storing the DC voltage output from the rectifier 310; In response to the plurality of switch control signals S1 to S4, a current corresponding to the AC voltage Vs applied to the electrical energy stored in the energy storage unit 320 to the load 360 or applied through the transformer 340. The first bypass unit 330 for bypassing the; Generates a voltage corresponding to the energy stored in the energy storage unit 320 applied through the first bypass unit 330 and transfers the voltage to the load 360 or transfers the input AC voltage Vs to the load 360. And a transformer 340 which generates a voltage corresponding to the same and bypasses it through the first bypass unit 330; In response to at least one switch control signal S5, a second bypass unit for shorting an AC power supply for supplying the AC voltage Vs and switching the transformer 340 and the load 360 to be a closed circuit ( 350); And And a load (360) for absorbing the input AC voltage (Vs) or the electrical energy supplied from the energy storage unit (320). The method of claim 1, wherein the energy storage unit 320, An electrostatic and low voltage compensating device comprising at least one capacitor bank and a battery bank. The method of claim 1, wherein the first bypass unit 330, A first switch Sw1 for switching one terminal o of the energy storage unit 320 and a first terminal 1 of one side of the transformer 340 in response to a first switch control signal S1; A second switch Sw2 for switching one terminal p of the energy storage unit 320 and a second terminal 1 'of one side of the transformer 340 in response to a second switch control signal S2. ; A third switch Sw3 for switching the other terminal o 'of the energy storage unit 320 and the first terminal 1 of one side of the transformer 340 in response to a third switch control signal S3. ); A fourth switch for switching the other terminal o 'of the energy storage unit 320 and the second terminal 1' of one side of the transformer 340 in response to a fourth switch control signal S4 ( Sw4); A first diode (D1) connected to a first terminal (1) of one side of the transformer (340) and an N-type terminal to one terminal (o) of the energy storage unit (320); A second diode (D2) connected to a second terminal (1 ') of one side of the transformer (340) and an N-type terminal to one terminal (o) of the energy storage unit (320); A third diode (D3) having an N-type terminal connected to the first terminal (1) of one side of the transformer (340) and a P-type terminal connected to the other terminal (o ') of the energy storage unit (320); And The fourth diode D4 connected to the second terminal 1 'of one side of the transformer 340 and the P type terminal connected to the other terminal o' of the energy storage unit 320. Power failure and low voltage compensation device characterized in that it comprises a. The method of claim 3, When the input AC voltage Vs indicates a normal voltage level, the third switch Sw3 and the fourth switch Sw4 are turned on. The first switch Sw1, the fourth switch Sw4, and the fifth switch Sw5 are turned on when the input AC voltage Vs indicates a voltage level that is relatively lower than the normal voltage level, or during power failure. Power failure and low voltage compensation device, characterized in that. The method of claim 1, The second bypass unit 350 may short-circuit both terminals of the AC power supply Vs in response to the fifth switch control signal S5, and may be provided on the other side of the transformer 340 connected to one terminal. Switching between the first terminal 2 and the load 360, The other terminal of the load 360 is connected to the second terminal (2 ') of the other side of the transformer (340) characterized in that the electrostatic and low voltage compensation device. The method of claim 5, wherein the second bypass unit 350, And a switch element responsive to said fifth switch control signal (S5). The method of claim 1, And a controller 370 for generating a plurality of switch control signals applied to the first bypass unit 330 and the second bypass unit 350 in response to the AC signal Vs. Power failure and low voltage compensation device.

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