KR101564736B1 - Source transfer switching apparatus - Google Patents

Abstract

The present invention discloses a power switching device. The present invention detects whether a main power source is a power failure, an abnormal state, or a current abnormality, and when the main power source is judged to be a power failure, an abnormality, or a current abnormality, By turning off the relay, an arc is generated at the relay contact and the contact can be prevented from being welded. Further, the driving units for driving the relay units connecting the main power source and the auxiliary power source of the present invention to the load may apply the driving voltage higher than the rated voltage of the relay to turn on the relay unit more quickly than when the rated voltage is applied. Can be turned on. The drive units for driving the relay units connecting the main power source and the auxiliary power source of the present invention to the load apply a voltage lower than the rated voltage of the relay unit to the sustain voltage for holding the relay unit in the ON state, It is possible to reduce the off time compared with the voltage application.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

More particularly, the present invention relates to a power switching apparatus, and more particularly, to a power switching apparatus that receives two different AC power sources and outputs a predetermined main power, and when an abnormality is detected in the main power or a power failure occurs, ≪ / RTI >

With the rapid development of computer technology and information and communication technology, modern society has become a network-based society based on Internet and digital information communication network, and this trend is expected to continue to develop and expand. In order to do this, it is essential to construct a computer network and an information communication infrastructure, so that a large number of base stations are installed and operated all over the world.

In the base stations, various communication devices such as a switching device, a router, a fiber terminal device, and a cable modem are installed in various layers. Almost all devices operate a power supply redundancy system for the uninterrupted and stable operation of these devices. That is, when a power failure or an abnormality occurs in a certain device, the standby device is instantly activated so that the communication service is not interrupted. Moreover, redundancy of the power supply must be configured for stable operation of the communication service.

Power supply redundancy consists of main power and auxiliary power. In order to use redundant power effectively, you can use power supply duplication switch called Source Transfer Switch (STS). 1 is a configuration diagram of a general AC power supply STS.

1, stable and rapid switching operation characteristics between power supplies are required for the stable operation of the communication devices.

The transfer switch has the function of supplying the used power, the generating power and the spare power to the load side through the switching operation and has been developed and used in various forms. Such transfer switches generally include Automatic Transfer Switch (ATS), Closed Transition Transfer Switch (CTTS), Static Transfer Switch (STS), and Source Transfer Circuit (STS).

ATS is installed between utility power and emergency power in general power system and it has a mechanical switching operation and there is a circulation phenomenon of about 50 to 100 [ms] on the load side during the switching operation. It is not desirable to apply the ATS system to the UPS output side because there is a malfunction phenomenon during the switching.

CTTS is a concept similar to general ATS, but operates as a closed type during switching, so there is no malfunction on the load side. Both the main power supply and the emergency power supply must be in operation. The operation mechanism supplies power to the load side through parallel operation (line input / after the lower stage) for 100 [ms] at the moment when both the voltage and frequency phase become less than the reference error in the live state. Such a CTTS system does not have a circuit phenomenon at the time of switching, but the power source must be in a live state to enable a disconnection disconnection body. Therefore, it is not a suitable system for UPS redundancy.

STS (Static Transfer Switch) is not mechanical contact structure, but it can be switched to the load side by fast switching operation by using power semiconductor device such as thyristor or triac. Generally, it is produced in 3 phase large capacity. The phases must be matched between the two power sources, so that disconnection can be possible. The transfer time is generally about 4 [ms], and the transfer speed is about 300 [ms] in the asynchronous state. This switch is installed between the UPS output and the UPS output distribution board. It is large in size and high in price because it has three phases.

STS (Source Transfer Switch) using Relay uses forcible transfer, and it is also possible to perform non-transference of load side by high-speed transfer operation. Generally, it is applied to small single phase small capacity. The transfer time is about 10 [ms]. These STSs can be installed between the UPS output distribution board and the load, and are compact and inexpensive to operate with an economical system.

Therefore, the source transfer switch (STS) using the relays does not require tricky operating conditions when two or more UPSs have to synchronously operate when the UPS output is redundant. In the event of a UPS failure, there is an advantage that the failure of the UPS to the other UPS can be prevented and the route of the UPS can be configured in a dual configuration, thereby reducing the obstacle and the failure rate. An example of a switching apparatus using such a relay is shown in Fig.

2 is a view schematically showing a redundant power switching apparatus using a conventional relay. 2, the conventional redundant power switching apparatus 10 includes an input section 11, a CPU 13, a control section 15, a relay 17, and an output section 19 .

 The redundant power switching apparatus 10 receives two AC power sources having different phases and uses one good power source as a main power source and the other power source as a standby power source In the event of a power failure or abnormality in one power supply, the power supply is switched quickly so that good power is always supplied to the output side even if a power failure or abnormality occurs in one power supply.

The main and sub power sources are input to the input unit 11 and the CPU 13 controls the entire system and grasps the state of the input power source. The relay 17 has a current capacity of 25 A, and the control unit 15 controls the relays 17, and the output unit 19 outputs the AC power output from the relay 17. [

When two power sources (main / sub) having different phases are input to the input unit 11 of the redundant power switching apparatus 10, the CPU 13 detects the abnormality of the corresponding power source through each power line. If there is no abnormality, the CPU 13 controls the connection of the relay 17 to output the main power to the output unit 19 through the basic contact.

When the output is normally connected, the CPU 13 continuously monitors the voltage and the input waveform of the main power source, and provides a relay switching signal to the control unit 15 when a power failure or abnormality occurs. At this time, the control unit 15 outputs the voltage for driving the relay 17 to the relay 17, the relay 17 disconnects the main power input side contact, moves the contact point to the sub power supply input side, 19 to protect the equipment connected to the output unit 19.

However, in the process of switching the power source, a problem arises that the power is not supplied for a period of time (about 10 ms) until the contact is disconnected from the main power source and the contact is connected to the sub power source.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power switching device which shortens the switching time of a power switching device using a conventional relay and minimizes the time during which power supply is interrupted.

According to an aspect of the present invention, there is provided a power switching apparatus including: a first voltage sensing unit for sensing and outputting a voltage of an AC power input from a main power source; A first relay unit for interrupting a connection between the main power source and the load; A second relay unit for interrupting a connection between the auxiliary power source and the load; A first driving unit for turning on or off the first relay unit according to a first control signal; A second driving unit for turning on or off the second relay unit according to a second control signal; A current sensing unit for sensing and outputting a current flowing in the load; And an abnormality or a power failure of the main power connected to the load by using at least one of a voltage value input from the first voltage sensing unit and a current value input from the current sensing unit, The first relay unit outputs the first control signal such that the first relay unit is turned off at a time point when the potential of the main power source becomes zero (zero potential point), and after the zero potential point, And a control unit for outputting the second control signal to be turned on.

Further, in the power switching apparatus, the time (off time) required for the first relay section to be turned off after the first control signal instructing the control section to turn off the first relay section 2 relay unit is turned on after the first relay unit is turned on and the control unit determines that an abnormality has occurred in the main power source, Outputs the first control signal for instructing to turn off the first relay unit after first outputting the second control signal for instructing to turn on the second relay unit and outputs the first control signal for turning off the first relay unit, The relay unit can be controlled to be turned on.

The second driving unit may apply a driving voltage greater than the rated voltage of the second relay unit to the second relay unit to reduce the on time than when the rated voltage of the second relay unit is applied.

The first driving unit applies a holding voltage lower than a rated voltage of the first relay unit while the first relay unit is maintained in the on state, and reduces the off time more than when the rated voltage of the first relay unit is applied. .

According to another aspect of the present invention, there is provided a power switching apparatus including: a first voltage sensing unit for sensing and outputting a voltage of an AC power input from a main power source; A first relay unit for interrupting a connection between the main power source and the load; A second relay unit for interrupting a connection between the auxiliary power source and the load; A first driving unit for turning on or off the first relay unit according to a first control signal; A second driving unit for turning on or off the second relay unit according to a second control signal; A current sensing unit for sensing and outputting a current flowing in the load; And an abnormality or a power failure of the main power connected to the load by using at least one of a voltage value input from the first voltage sensing unit and a current value input from the current sensing unit, And a control unit for outputting the first control signal to turn off the first relay unit and output the second control signal to turn on the second relay unit when it is determined that a power failure has occurred, The first relay unit applies a driving voltage greater than the rated voltage of the second relay unit to the second relay unit to reduce the on time than the rated voltage of the second relay unit, While maintaining the state of the first relay unit, a holding voltage lower than the rated voltage of the first relay unit is applied to apply the rated voltage of the first relay unit Kill off time can be reduced than usual.

The control unit of the power switching devices simultaneously outputs the first control signal indicating the OFF state of the first relay unit and the second control signal indicating the ON state of the second relay unit at the time of power failure of the main power source can do.

The first driving unit and the second driving unit of the power switching devices may include a capacitor connected between the first terminal of the coil included in the first relay unit and the second relay unit and the ground, A diode connected between a source of a driving voltage for providing a voltage, a source of a holding voltage for providing a holding voltage, and a second terminal of a coil included in the first relay part and the second relay part, And a switching element that is turned on or off according to a control signal input from the control unit to allow the driving voltage or the current based on the holding voltage to flow to the first relay unit and the second relay unit.

The control unit of the power switching devices compares the reference voltage and the voltage of the main power source at predetermined time intervals to determine whether the voltage provided to the load by the main voltage is an overvoltage or a low voltage, Can be determined.

Further, the power switching devices may further include a second voltage sensing unit for sensing and outputting a voltage of the AC power input from the auxiliary power supply, wherein the controller determines that an abnormality of the main power is generated, The control unit outputs the first control signal to turn off the first relay unit and outputs the second control signal to turn on the second relay unit to turn on the second relay unit, .

The present invention detects whether a main power source is a power failure, an abnormal state, or a current abnormality, and when the main power source is judged to be a power failure, an abnormality, or a current abnormality, By turning off the relay, an arc is generated at the relay contact and the contact can be prevented from being welded.

Further, the driving units for driving the relay units connecting the main power source and the auxiliary power source of the present invention to the load may apply the driving voltage higher than the rated voltage of the relay to turn on the relay unit more quickly than when the rated voltage is applied. Can be turned on.

The drive units for driving the relay units connecting the main power source and the auxiliary power source of the present invention to the load apply a voltage lower than the rated voltage of the relay unit to the sustain voltage for holding the relay unit in the ON state, It is possible to reduce the off time compared with the voltage application.

1 is a configuration diagram of a general AC power supply STS.
2 is a view schematically showing a redundant power switching apparatus using a conventional relay.
3 is a diagram showing a configuration of a power switching apparatus according to a preferred embodiment of the present invention.
Fig. 4 is a diagram showing the configuration of the driving unit shown in Fig. 3. Fig.
5 is a timing chart showing timing of generation of a control signal at the time of occurrence of a main power abnormality.
6 is a timing chart showing the generation timing of the control signal during the power failure.

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

3 is a diagram showing a configuration of a power switching apparatus according to a preferred embodiment of the present invention.

Referring to FIG. 3, a power switching apparatus according to a preferred embodiment of the present invention includes a first relay unit 130, a second relay unit 230, a first voltage sensing unit 110 A second voltage sensing unit 210, a first driving unit 140, a second driving unit 240, a current sensing unit 400, and a controller 300.

The first relay unit 130 is disposed between the main power supply 110 and the load 500 for supplying AC power and is turned on or off according to the control of the first driving unit 140, (110) and the load (500).

The first voltage sensing unit 110 senses the voltage of the AC power input from the main power supply 110 and outputs the sensed voltage to the controller 300.

The first driving unit 140 turns on or off the first relay unit 130 according to the first control signal input from the control unit 300 and outputs the main power 110 and the load 500 And electrically connects and disconnects them.

The second relay unit 230 is disposed between the auxiliary power supply 210 for supplying AC power and the load 500 and is turned on or off according to the control of the second driving unit 240, (110) and the load (500).

The second voltage sensing unit 210 senses the voltage of the AC power input from the auxiliary power supply 210 and outputs the sensed voltage to the controller 300.

The second driving unit 240 turns on or off the second relay unit 230 according to the second control signal input from the control unit 300 to turn on the auxiliary power supply 210 and the load 500 And electrically connects and disconnects them.

The current sensing unit 400 senses a current flowing in the load 500 and outputs the sensed current to the controller 300.

The control unit 300 receives the voltage value from the first voltage sensing unit 110 while the main power source 110 supplies power to the load 500 and receives the voltage value from the current sensing unit 400 through the load 500 The current value of the current flowing through the resistor is inputted.

The control unit 300 compares the voltage value input from the first voltage sensing unit 110 inputted at each predetermined time with a reference voltage value and determines whether the voltage value provided to the current load 500 is a reference voltage value It is determined whether or not an abnormality has occurred in the main power supply 110 by checking whether an overvoltage or a low voltage is provided to the load 500 side.

In addition, the controller 300 compares the current flowing in the load 500 with the reference current to determine whether an overcurrent flows, and determines whether an abnormality has occurred in the main power supply 110. [

The control unit 300 determines the time point when the potential of the main power source 110 becomes 0 (zero potential time point) when it is determined that an abnormality has occurred in the main power source 110 due to an abnormal condition of overvoltage, undervoltage, And outputs the first control signal to the first driving unit 140 so that the first relay unit 130 is turned off at the zero potential time point so that the second relay unit 230 is turned on after the zero potential point 2 control signal to the second driver 240. [ When the first relay unit 130 is turned off at the time when the potential of the main power source 110 becomes zero, it is possible to prevent the arc from being generated due to the voltage difference and to prevent the deterioration of the first relay unit 130, Can be prevented.

At this time, the control unit 300 switches the main power source 110 to the auxiliary power source 210 only when the main power source 110 is abnormal and the auxiliary power source 210 operates normally. The control unit 300 checks the voltage of the power source output from the auxiliary voltage source 210 from the second voltage sensing unit 220 in the same manner as the method of determining the abnormality of the main power source 110, The voltage of the power source output from the auxiliary voltage source 210 from the second voltage sensing unit 220 may be checked when it is determined that an abnormality has occurred in the main power source 110. That is, So as to determine whether or not the auxiliary power source 210 is abnormal.

The first relay unit 130 is turned off while the second relay unit 230 is turned on and supplied to the load 500 while the off time of the first relay unit 130 is set to the zero potential time point The time during which the power source is switched from the main power source 110 to the auxiliary power source 210, that is, the time during which the power source is not supplied to the load 500 side, is minimized.

For this, the first driving unit 140 and the second driving unit 240 are configured as shown in FIG. 4 (b).

Fig. 4 is a diagram showing the configurations of the first and second driving units shown in Fig. 3;

A conventional relay unit and its driving unit will be described with reference to FIG. 4A. In the related art, a main power source 110 (or an auxiliary power source 210) is connected to a terminal of a relay unit, To the load 500 side. Further, by applying a rated driving voltage (for example, 12 VDC) to one end of the coil included in the relay unit, connecting the other end of the coil to the switching device, and turning on / off the switching device in accordance with the control signal of the control unit 300, And the power supply is controlled from the main power supply 110 (auxiliary power supply 210) to the load 500 side. In this case, the switching element is generally implemented as a bipolar transistor, but is not limited thereto.

4A, the voltage applied to the coil of the relay unit is the same as the voltage applied to the coil while the relay unit is turned on, while the relay unit is turned on.

4 (b), when the first and second relay units 130 and 230 are turned on, the driving voltage V1 supplied from the first and second driving units 140 and 240 is rated The time required for the first and second relay units 130 and 230 to turn on is shorter than when the rated voltage is applied to the first and second relay units 130 and 230. [

Further, after the first and second relay units 130 and 230 are turned on, the sustain voltage V2 applied when the on state is maintained is lower than the rated voltage of the first and second relay units 130 and 230 So that the time required for turning off the first and second relay units 130 and 230 is shorter than that in the related art, thereby enabling quick switching.

Referring to FIG. 4 (b), the structure of the first and second driving units 140 and 240 according to the preferred embodiment of the present invention will be described. The first and second relay units 130 and 230 include A capacitor 41 is connected between the first terminal of the coil and the ground, and a resistor 42 is connected between the first terminal and the driving voltage source. A diode is connected between the first terminal and the holding voltage source.

A switching element 44 is connected to a second terminal of the coil included in the first relay unit 130 and the second relay unit 230 to be turned on and off according to a control signal input from the controller 300.

Referring to the operation of the first and second driving units 140 and 240 shown in FIG. 4B, when the switching element 44 is off, the driving voltage source is connected to the first relay unit 130 and the second relay unit 140, (V1) higher than the rated voltage of the capacitor (230), and the capacitor (41) is charged by the driving voltage.

Thereafter, when the switching element 44 is turned on by the control signal, the driving voltage V1 charged in the capacitor 41 instantaneously flows through the first relay part 130 and the second relay part 230, So that the first relay unit 130 and the second relay unit 230 are turned on more quickly when the rated voltage is applied.

 Thereafter, a voltage lowered by the diode forward voltage is applied to the first terminal of the coil included in the first relay unit 130 and the second relay unit 230 from the holding voltage V2 supplied from the holding voltage source , The on state of the first relay unit 130 and the second relay unit 230 is maintained by this voltage.

Unlike the prior art shown in FIG. 4A, the first and second driving units 140 and 240 of the present invention may include a first relay unit 130 and a second relay unit 230, which are included in the first relay unit 130 and the second relay unit 230, And does not include a reflux diode that connects the first terminal and the second terminal of the coil. This is to allow the energy stored in the coil to be discharged more quickly when the switching device 44 is turned off, and the surge voltage Is absorbed by the capacitor 41, thereby enabling a quicker relay-off.

As described above, in the preferred embodiment of the present invention, in order to quickly turn on the relay, the driving power supply V1 supplied from the driving voltage source is set to be higher than the rated voltage. The time required for the first and second relay units 130 and 230 to turn on is significantly decreased as the voltage is increased until the rated voltage of the first relay unit 130 and the second relay unit 230 is approximately doubled, It was confirmed that the time taken for further warming did not show any meaningful decrease. Accordingly, the first driving unit 140 and the second driving unit 240 according to the preferred embodiment of the present invention supply a driving voltage corresponding to about twice the rated voltage. In the example shown in Fig. 4, the present invention supplied 24 VDC as the driving voltage V1 to turn on the relay having the rated voltage of 12 VDC.

Further, as described above, the present invention provides the coil with a voltage lower than the rated voltage as the holding voltage V2, thereby reducing the electromagnetic force generated in the coil than when providing the rated voltage, In the example shown in Fig. 4, a holding voltage of 9VDC, which is lower than the rated voltage of 12V DC, is applied to the relay.

In the above-described example, the present invention shortens the time (10 ms) required for turning on the first and second relay units 130 and 230 to about 5 ms when the rated voltage is applied and the first and second relay units 130 and 230 ) From the on-state to the off-state has also been shortened to within 2 ms in the conventional 5 ms.

The control unit 300 controls the first relay unit 130 and the second relay unit 230 to be turned on by the first driving unit 140 and the second driving unit 240, A time period until a relay signal is applied and a time period until each relay section is turned on and a time period until each relay section is turned off by applying a control signal so that each relay section is turned off, In order to minimize the time until the second relay unit 230 connecting the auxiliary power source 210 and the load 500 is turned on after the first relay unit 130 is turned off, The second control unit 240 outputs the second control signal so that the second relay unit 230 is first turned on and then the first relay unit 130 is turned off at the zero potential of the main power source 110, 1 driver 140 to output a first control signal.

5 is a timing chart showing the generation timing of the control signal when the main power supply 110 is abnormal.

5, when it is determined that an abnormality has occurred in the main power source 110 at time t1, the controller 300 determines that the voltage of the power source supplied from the main power source 110 is 0 (Zero potential time point t4) is calculated.

Subsequently, to provide the auxiliary power source 210 to the load 500 side, the time t2 at which the second driving unit 240 outputs the second control signal to turn on the second relay unit 230 is calculated , And outputs a second control signal instructing the second driving unit 240 to turn on the second relay unit 230 at the time point t2. The ON time of the second relay unit 230 of the present invention is about 5 ms so that the voltage of the main power source 110 becomes zero so that immediately after the first relay unit 130 is turned off, The control unit 300 counts the reverse time at the time t4 when the voltage of the main power source 110 becomes 0 and turns on the second relay 230 at a time t2 which is slightly later than about 5 ms, And outputs a second control signal to the second driver 240 to instruct the second driver 230 to turn on the second control signal. The second driving unit 240 receives the second control signal and operates the second relay unit 230 by supplying a voltage higher than the rated voltage (24 VDC in the example) to the coil of the second relay unit 230.

The controller 300 then calculates the time required for the first relay unit 130 to be turned off from the time when the voltage of the main power source 110 becomes zero and the first relay unit 130 And outputs the first control signal to the first driving unit 140 at that time point. In the above example, since the time taken for the first relay unit 130 to turn off is within 2 ms, the control unit 300 outputs the first control signal to the first driver unit 2 ms 2 ms before the potential of the main power source 110 becomes zero. (140). Then, the first driving unit 140 cuts off the on-state holding voltage supplied to the first relay unit 130, and the first relay unit 130 starts to be turned off.

The first relay unit 130 is turned off when the voltage of the main power source 110 becomes zero and the second relay unit 230 is turned on immediately after the first relay unit 130 is turned off, The power source supplied to the power source 500 is switched from the main power source 110 to the auxiliary power source 210.

The operation of the power switching apparatus of the present invention has been described in the case where an abnormal state such as overvoltage, undervoltage, and overcurrent occurs in the main power supply 110 so far.

6 is a timing chart showing the generation timing of the control signal during the power failure.

Referring to FIG. 6, when a power failure occurs in the main power source 110 at a time t1 and power supply from the main power source 110 is interrupted, the control unit 300 controls the first relay unit 130 to turn off the first relay unit 130 A second control signal for instructing the second relay unit 230 to turn on to supply power to the load 500 from the auxiliary power supply 210 while outputting a first control signal to the first driving unit 140, To the second driver 240.

Then, the first driving unit 140 turns off the first relay unit 130 first (refer to t2), and the second driving unit 240 turns on the second relay unit 230 to turn on the power from the auxiliary power source 210 And supplied to the load 500 side (see t3).

In this example, since the time from the receipt of the control signal to the second driving unit 240 until the second relay unit 230 is on is about 5 ms, The power is supplied from the auxiliary power source 210 to the load 500 side.

Although the main power supply 110 has been described as an example of switching the power supplied to the load 500 by the auxiliary power supply 210, the auxiliary power supply 210 may supply the load It will be understood by those skilled in the art that the same applies to the case where the power source is switched.

The present invention has been described with reference to the preferred embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and all differences within the scope of equivalents thereof should be construed as being included in the present invention.

110 main power supply 120 first voltage sensing unit
130 first relay part 140 first driving part
210 auxiliary power source 220 second voltage sensing unit
230 second relay part 140 second driving part
300 controller 400 current sensing unit
500 load

Claims (9)

A first voltage sensing unit for sensing and outputting a voltage of an AC power input from a main power supply;
A first relay unit for interrupting a connection between the main power source and the load;
A second relay unit for interrupting a connection between the auxiliary power source and the load;
A first driving unit for turning on or off the first relay unit according to a first control signal;
A second driving unit for turning on or off the second relay unit according to a second control signal;
A current sensing unit for sensing and outputting a current flowing in the load; And
Wherein the control unit determines whether the main power source connected to the load is abnormal or not by using at least one of the voltage value input from the first voltage sensing unit and the current value input from the current sensing unit,
And outputs the first control signal so that the first relay part is turned off at a time point when the potential of the main power source becomes 0 (zero potential time point) when it is determined that an abnormality has occurred in the main power source, And a control unit for outputting the second control signal such that the second relay unit is turned on,
The first driving unit and the second driving unit
A capacitor connected between the first terminal of the coil included in the first relay unit and the second relay unit and the ground,
A resistor connected between the first terminal and a drive voltage source for providing a drive voltage higher than the rated voltage,
A diode connected between the first terminal and a holding voltage source providing a holding voltage lower than the rated voltage, and
The second relay unit being connected to a second terminal of the coil included in the first relay unit and the second relay unit and being turned on or off according to a control signal input from the control unit, Or a switching element for causing a current based on the holding voltage to flow. The method according to claim 1,
The control unit instructs the control unit to turn on the second relay unit after the first control unit instructs the control unit to turn off the first relay unit, (On time) after the second control signal is outputted until the second relay unit is turned on,
Wherein the control unit first outputs the second control signal for instructing the second relay unit to turn on when it is determined that an abnormality has occurred in the main power source and then turns off the first relay unit And controls the second relay unit to be turned on after the first relay unit is turned off. 3. The method of claim 2,
Wherein the second driving unit applies the driving voltage larger than the rated voltage of the second relay unit to the second relay unit to reduce the on time than when the rated voltage of the second relay unit is applied. Device. 3. The method of claim 2,
The first driving unit applies a holding voltage lower than the rated voltage of the first relay unit while the first relay unit is kept in the on state to reduce the off time than when the rated voltage of the first relay unit is applied Features a power switching device. A first voltage sensing unit for sensing and outputting a voltage of an AC power input from a main power supply;
A first relay unit for interrupting a connection between the main power source and the load;
A second relay unit for interrupting a connection between the auxiliary power source and the load;
A first driving unit for turning on or off the first relay unit according to a first control signal;
A second driving unit for turning on or off the second relay unit according to a second control signal;
A current sensing unit for sensing and outputting a current flowing in the load; And
Wherein the control unit determines whether an abnormality or a power failure of the main power source currently connected to the load is detected by using at least one of a voltage value input from the first voltage sensing unit and a current value input from the current sensing unit, And a control unit outputting the first control signal to turn off the first relay unit and output the second control signal to turn on the second relay unit when it is determined that a power failure has occurred,
Wherein the second driving unit applies a driving voltage greater than the rated voltage of the second relay unit to the second relay unit to reduce the on time than when the rated voltage of the second relay unit is applied,
Wherein the first driving unit applies a holding voltage lower than a rated voltage of the first relay unit while the first relay unit is kept in an on state to reduce an off time than a rated voltage of the first relay unit,
The first driving unit and the second driving unit
A capacitor connected between the first terminal of the coil included in the first relay unit and the second relay unit and the ground,
A resistor connected between the first terminal and a drive voltage source for providing a drive voltage higher than the rated voltage,
A diode connected between the first terminal and a holding voltage source providing a holding voltage lower than the rated voltage, and
The second relay unit being connected to a second terminal of the coil included in the first relay unit and the second relay unit and being turned on or off according to a control signal input from the control unit, Or a switching element for causing a current based on the holding voltage to flow. 6. The method according to any one of claims 1 to 5,
Wherein the control unit simultaneously outputs the first control signal indicating the turning off of the first relay unit and the second control signal indicating the turning on of the second relay unit at the time of power failure of the main power source Device. delete 6. The method according to any one of claims 1 to 5,
The control unit compares the reference voltage with the voltage of the main power source at every predetermined time and judges whether the main power is abnormal or not by judging whether the voltage supplied to the load is an overvoltage or a low voltage. Power switching device. 6. The method according to any one of claims 1 to 5,
And a second voltage sensing unit for sensing and outputting a voltage of the AC power input from the auxiliary power supply,
When it is determined that an abnormality has occurred in the main power source and the voltage input from the second voltage sensing unit is checked and it is determined that there is no abnormality in the auxiliary power source, the control unit outputs the first control signal, The relay unit is turned off, and the second control unit outputs the second control signal to turn on the second relay unit.

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