KR20180099451A - Module-type ups system having hot swap function of switch by using on-off control of inverter output - Google Patents

Abstract

A module-type UPS system is disclosed. Particularly, the module-type UPS system switches a switch part by using a plurality of electromagnetic contactors in the case of a failure of the switch part and can replace or repair the switch part without interrupting power supply to a load. The module-type UPS system includes a power part; a second electromagnetic contactor; a switch part; a third electromagnetic contactor; a first electromagnetic contactor; a relay; and a coil excitation power source.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a modular USB system having a hot swap function of a switch unit utilizing ON / OFF control of an inverter output,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flux system, and more particularly, to a flux system capable of replacing a switch without interrupting power supply to a load.

A UPS system is interposed in the middle of a supply of a commercial power source to a load of a device (for example, a computer, an application device, etc.) Is a power supply device used for preventing a malfunction or a stoppage of the power supply. In other words, it absorbs all of the above in commercial power supply and supplies stable AC output voltage, current and frequency to the load.

[Prior Art Literature]

[Patent Literature]

Korean Registered Utility Model No. 20-0355163 Registered on June 24, 2004 (Name: UPS for SICS)

An object of the present invention is to provide a flux system capable of replacing or repairing a switch unit without interrupting power supply to a load when a switch unit of a flux system fails.

According to an aspect of the present invention, there is provided a power system including a power unit for outputting a system input, which is an AC power input to a flux system, to an inverter output, which is an AC power of a constant voltage and a constant frequency, And the system input connected through the power line and the inverter output line in series and input through the inverter output line and the first bypass line bypassing the power line, A first electromagnetic contactor provided on the first bypass line and shorted when the inverter output is turned on and opened when the inverter output is turned off; And the inverter is short-circuited when the inverter output is turned on, A third electromagnetic contactor mounted on the system output line and shorted when the inverter output is on and open when the inverter output is off; And a relay which is disposed on a second bypass line for bypassing the switch unit and outputting to the system output, and is opened when the inverter output is turned on and is short-circuited when the inverter output is off.

Wherein the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor and the coil excitation power source inside the relay are connected on the inverter output line R-N, and when the inverter output is turned on in the inverter output line, Wherein the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor and the coil inside the relay are energized such that the first electromagnetic contactor, the second electromagnetic contactor and the third electromagnetic contactor are short- Wherein when the inverter output is turned off, the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor, and coils within the relay are energized, and the first electromagnetic contactor, the second electromagnetic contactor, The third electromagnetic contactor is opened, and the relay is short-circuited.

The power unit includes a rectifier that converts the system input, which is an AC power source, into DC power and outputs the DC power, and an inverter that converts the DC power into AC power and outputs the DC power to the inverter output.

The power unit may further include a battery that is charged by the DC power source and applies the charged DC power to the inverter when the supply of the system input is stopped.

According to another aspect of the present invention, there is provided a system for controlling an inverter, comprising: an inverter for converting an AC power input to an input power source into an AC power having a constant voltage and a constant frequency, A second electromagnetic contactor connected in series with the power unit through an inverter output line to which the inverter output is transmitted, and a second electromagnetic contactor connected to the second electromagnetic contactor through an inverter output line to which the inverter output is transmitted, A switch unit connected to the first bypass line through which the system input bypasses the power unit to selectively transmit either the inverter output or the system input; A third electromagnetic contactor selectively transmitting to the system output; A first electromagnetic contact disposed on a bypass line and connected in parallel with the power unit and connected in series with the switch unit; and a second electromagnetic contactor connected to the switch unit, wherein the system input bypasses the power unit and the switch unit, And a relay disposed on the second bypass line and connected in parallel with the power section and the switch section. Here, the first electromagnetic contactor, the second electromagnetic contactor, and the third electromagnetic contactor are opened when the inverter output is off, and the relay is short-circuited when the inverter output is off.

In particular, the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor, and the coil excitation power source inside the relay are connected on the inverter output line R-N to which the inverter output is transmitted .

Here, when the inverter output of the inverter output line is turned on, if the coils of the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor and the relay are energized, the first electromagnetic contactor, And the third electromagnetic contactor are short-circuited, and the relay is opened.

And when the inverter output is off, the coils of the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor, and the relay are energized, and the first electromagnetic contactor, the second electromagnetic contactor, The contactor is opened, and the relay is short-circuited.

The power unit includes a rectifier that converts the system input, which is an AC power source, into DC power and outputs the DC power, and an inverter that converts the DC power into AC power and outputs the DC power to the inverter output.

The power unit may further include a battery that is charged by the DC power source and applies the charged DC power to the inverter when the supply of the system input is stopped.

In a USB system according to an embodiment of the present invention, when a switch unit malfunctions, the switch unit can be switched using a plurality of electromagnetic contactors, and the switch unit can be replaced or repaired without disconnecting the power supply to the load.

FIG. 1 is a block diagram illustrating a data transmission system according to an embodiment of the present invention. Referring to FIG.
FIG. 2 is a block diagram for explaining a detailed configuration of a power unit in a USB system according to an embodiment of the present invention.
3 is a block diagram for explaining a detailed configuration of a switch unit in a flux-fired system according to an embodiment of the present invention.
4 is a diagram for explaining the bypass operation of the transmission system 10 according to the embodiment of the present invention.

Prior to the detailed description of the present invention, the terms or words used in the present specification and claims should not be construed as limited to ordinary or preliminary meaning, and the inventor may designate his own invention in the best way It should be construed in accordance with the technical idea of the present invention based on the principle that it can be appropriately defined as a concept of a term to describe it. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the elements in the accompanying drawings are exaggerated, omitted, or schematically shown, and the size of each element does not entirely reflect the actual size.

First, the configuration of a UPS system according to an embodiment of the present invention will be described. FIG. 1 is a block diagram illustrating a data transmission system according to an embodiment of the present invention. Referring to FIG. FIG. 2 is a block diagram for explaining a detailed configuration of a power unit in a USB system according to an embodiment of the present invention. And FIG. 3 is a block diagram for explaining a detailed configuration of a switch unit in a USB system according to an embodiment of the present invention.

1, a UPS system according to an embodiment of the present invention includes a control unit 100, a power unit 200, a switch unit 300, a first magnetic contactor MC1 (Magnetic Contactor 1: 410) A second electromagnetic contactor MC2 420, a third electromagnetic contactor MC3 430, and a relay 500 (RL).

In the embodiment of the present invention, the power supplied to the USB system 10 is referred to as a system input (SI), and the power supplied to the load through the USB system is referred to as a system output (SO). The output of the power unit 200 will be referred to as an inverter output IO.

As shown, the power unit 200, the second electromagnetic contactor 420, the switch unit 300, and the third electromagnetic contactor 430, in order from the system input SI and the system output SO, Lt; / RTI > The first electromagnetic contactor 410 is connected in parallel to the power section 200 and the second electromagnetic contactor 420. In addition, the relay 500 is connected in parallel with the power section 200, the second electromagnetic contactor 420, the switch section 300 and the third electromagnetic contactor 430.

As described above, there are three paths in which the system input (SI) is output to the system output (SO) as connected. According to the basic path, when the system input SI is applied to the power unit 200, the power unit 200 outputs the applied system SI to the inverter output IO, and the inverter output IO is the second The electromagnetic contactor 420, the switch unit 300, and the third electromagnetic contactor 430 in this order to the system output SO. In summary, the system input SI is output to the system output SO through the power unit 200, the second electromagnetic contactor 420, the switch unit 300, and the third electromagnetic contactor 430 in sequence.

In addition to the basic path described above, there are two paths, i.e., bypass lines BL1 and BL2. The first bypass line BL1 is a path for bypassing the power unit 200 and the second bypass line BL2 is a path for bypassing the power unit 200 and the switch unit 300. [ The system input SI is output to the system output SO via the first electromagnetic contactor 410, the switch portion 300 and the third electromagnetic contactor 430 at the first bypass line BL1. In addition, the system input SI is output from the second bypass line BL2 to the system output SO via the relay 500. [

Each of the components of the UPS system will now be described. First, the power unit 200 will be described. The power unit 200 receives the system input power, which is an AC power, and outputs AC power having a predetermined frequency and a predetermined voltage. To this end, the power unit 200 includes a rectifier 210 and an inverter 220 as shown in FIG. 2, and further includes a battery B. The rectifier 210 and the inverter 220 are connected in series and the battery B is connected in parallel between the rectifier 210 and the inverter 220.

The power unit 200 outputs the system input SI to the inverter output IO in a steady state instead of the power failure or outputs the power of the battery B to the inverter output IO in the case of a power failure. The system input SI is an AC power source. In a normal state, the rectifier 210 converts AC power, which is a system input SI, into DC power and outputs the DC power. The converted DC power is applied to the inverter 220 at the same time as the storage battery B is charged. Then, the inverter 220 converts the DC power to the AC power, and then outputs it to the inverter output IO. The DC power of the battery B is discharged and applied to the inverter 220. The inverter 220 converts the DC power of the battery B into an alternating current And outputs it to the inverter output (IO). As shown in FIG. 4, a plurality of power units 200 may be connected in parallel. Each power unit 200 may be fabricated in a module form and be replaceable as needed.

3, the switch unit 300 selects any one of the system input SI and the inverter output IO input through the first bypass line BL1 and outputs the same as the switch output WO. That is, the switch unit 300 outputs the system input SI input through the first bypass line BL1 to the switch output WO or controls the inverter output IO to the switch Can be output as an output (WO).

The transmission system 10 according to the embodiment of the present invention can operate in four modes, and the four modes include an inverter mode, a battery mode, a first bypass mode, and a second bypass mode.

The inverter mode is a normal operation and operates when a system input (SI), which is an AC power source, is applied to the flux system 10 in a non-power-off state. At this time, the first to third electromagnetic contactors 410, 420 and 430 are in an ON state and the relay 500 is in an OFF state. In the inverter mode, when the system input SI is applied to the power unit 200, the inverter output IO of a constant frequency and a constant voltage is output through the rectifier 210 and the inverter 220 under the control of the controller 100 do. In accordance with the control of the control unit 100, the switch unit 300 selects the inverter output IO as an input so that the inverter output IO is output as the switch output WO, And is output to the system output SO and applied to the load.

The battery mode is a mode that switches when a power failure occurs in the inverter mode. In the battery mode as well as the inverter mode, the first to third electromagnetic contactors 410, 420, and 430 are ON and the relay 500 is OFF. In the inverter mode operation, when a power failure occurs in the commercial input power source, the mode is switched to the battery mode, and the battery B performs power supply via the DC line between the rectifier 210 and the inverter 220. That is, when a power failure occurs, the battery B supplies power (DC power) to the inverter 220, the power of the battery B is output to the inverter output IO, And output to the system output (SO).

The first bypass mode is a mode that operates when a failure occurs in the power unit 200 due to, for example, an overcurrent. The first to third electromagnetic contactors 410, 420 and 430 are ON and the relay 500 is OFF even in the first bypass mode as in the inverter mode and the battery mode. When the failure occurs in the power unit 200 in the inverter mode, the switch unit 300, which has selected the inverter output IO under the control of the control unit 100, selects the first bypass line BL1. Accordingly, the system input (SI) becomes the system output (SO) via the switch unit (300). Therefore, even if a failure occurs in the power unit 200 through the first bypass mode, the system input SI, which is a commercial power source, is directly applied to the load through the system output SO. In this way, the switch unit 300 can switch over from the inverter mode to the first bypass mode under the control of the control unit 100. Since the switch unit 300 selects the first bypass line BL1 in the first bypass mode and the current does not flow in the power unit 200, the operator of the data system 10 has a low risk of electric shock It is safe to replace or repair the power unit 200 than in the inverter mode. When the failure of the power unit 200 is eliminated in the first bypass mode, the switch unit 300, which has selected the first bypass line BL1 under the control of the controller 100, ). Thus, the transmission system 10 is switched from the first bypass mode to the inverter mode.

The second bypass mode is a mode that operates when a failure occurs in the switch unit 300, for example. In the second bypass mode, unlike the inverter mode, the battery mode and the first bypass mode, the first to third electromagnetic contactors 410, 420 and 430 are switched from the on state to the off state, 500 are switched from the OFF state to the ON state. As the first to third electromagnetic contactors 410, 420 and 430 are switched from the ON state to the OFF state, no power is applied to the power section 200 and the switch section 300, Since the relay is on, the system input SI is output to the system output SO through the second bypass line BL2. In this way, in the second bypass mode, the system input SI, which is a commercial power source, is output to the system output SO through the second bypass line BL and applied to the load. In this second bypass mode, since the switch unit 300 is not powered, the operator of the USB system 10 can repair or replace the switch unit 300 without the risk of electric shock.

Hereinafter, the bypass operation of the USB system 10 according to the embodiment of the present invention will be described in more detail. 4 is a diagram for explaining the bypass operation of the transmission system 10 according to the embodiment of the present invention.

Referring to FIG. 4, the power unit 200 receives a system input SI and outputs an inverter output through an inverter output line. The power unit 200, the second electromagnetic contactor 420, the switch unit 300, and the third electromagnetic contactor 430 are serially connected in series. That is, the second electromagnetic contactor 420 and the switch unit 300 are connected in series with the power unit 200 through the output side of the power unit 200, that is, the inverter output line. And the first electromagnetic contactor 410 is connected in parallel with the power section 200 and the second electromagnetic contactor 420 on the first bypass line BL1. The relay 500 is also connected in parallel with the power section 200, the second electromagnetic contactor 420, the switch section 300 and the third electromagnetic contactor 430 on the second bypass line BL2.

The first electromagnetic contactor 410 is provided on the first bypass line BL1 to selectively cut off the first bypass line BL1 and is short-circuited when the inverter output IO is turned on, And is opened when the inverter output IO is off. The second electromagnetic contactor 420 is interposed in the inverter output line IL between the power unit 200 and the switch unit 300 to selectively block the inverter output line IL and the inverter output IO And is opened when the inverter output IO is turned off. The third electromagnetic contactor 430 is connected in series with the switch unit 300 on the system output line SL to selectively cut off the system output line SL. The third electromagnetic contactor 430 is short-circuited when the inverter output IO is turned on and is opened when the inverter output IO is turned off. The relay 500 is disposed on the second bypass line BL2 for allowing the system input SI to bypass the power unit 200 and the switch unit 300 and output to the system output SO, And to supply power to the load. The relay 500 is opened when the inverter output is ON, and is short-circuited when the inverter output is OFF.

Basically, when the power unit 200 outputs the system input to the inverter output, the switch unit 300 outputs the inverter output IO input through the inverter output line IL and the inverter output Selects one of the system inputs SI input via one bypass line, and outputs the selected one to the system output SO via the system output line SL.

Particularly, according to the embodiment of the present invention, the first electromagnetic contactor 410, the second electromagnetic contactor 420 and the third electromagnetic contactor 430 operate in an ON state when the inner coil is energized, 500 operate in the OFF state when the inner coil is energized. As shown, the inner coil excitation power supply CC for driving the first electromagnetic contactor 410, the second electromagnetic contactor 420, the third electromagnetic contactor 430 and the relay 500 all have inverter output lines R Phase. Accordingly, when power is not applied to the inverter output line, that is, when the inverter output is turned off, the first electromagnetic contactor 410, the second electromagnetic contactor 420, the third electromagnetic contactor 430, 500 are all also turned off. Accordingly, when the inverter output line is turned off, the first electromagnetic contactor 410, the second electromagnetic contactor 420 and the third electromagnetic contactor 430 are switched to the OFF state, (ON) state.

The operation of the second bypass mode will now be described in more detail. The first electromagnetic contactor 410, the second electromagnetic contactor 420, and the third electromagnetic contactor 430, which are applied on the inverter output line R-phase N, since the voltage of the inverter output line is ON in the inverter operation state, And the coil of the relay 500 are excited. Accordingly, the first electromagnetic contactor 410, the second electromagnetic contactor 420 and the third electromagnetic contactor 430 are in an on state, that is, short-circuited, and the relay 500 is in an off state, . Specifically, when the operation of the inverter is turned off through the control unit 100, the inverter unit is first switched from the inverter mode to the first bypass mode within the switch unit 300, and after a predetermined time (e.g., 3 to 4 seconds) The voltage of the line is turned off. As such, when the inverter output line is turned off, the first electromagnetic contactor 410, the second electromagnetic contactor 420, the third electromagnetic contactor 430, and the third electromagnetic contactor 430 applied on the R phase- The coils of the relay 500 are turned off and the first to third electromagnetic contactors 410, 420 and 430 are switched to the OFF state and the relay 500 is turned ON, that is, short-circuited. Thereby, the transmission system 10 is switched to the second bypass mode. In this second bypass mode, the system input SI, which is a commercial power, is output to the system output SO through the second bypass line BL and applied to the load. Since no power is applied to the switch unit 300, the operator of the flux system 10 can repair or replace the switch unit 300 without the risk of electric shock.

When the replacement or repair of the switch unit 300 is completed, the control unit 100 switches to the inverter mode. As a result, the voltage of the inverter output line is turned on, and the coils of the first to third electromagnetic contactors 410, 420, and 430 and the relay 500 connected to the inverter output line are energized, 3 electromagnetic contactors 410, 420 and 430 are turned on and the relay 500 is turned off so that the system output SO is supplied to the load in the first bypass mode via the switch unit 300 do. Then, when the phase synchronization is performed, the switch unit 300 selects the inverter output line and switches to the inverter mode. As described above, even when the failure occurs in the switch unit 300 or when the switch unit 300 is repaired or replaced, the power supply system according to the embodiment of the present invention can supply power to the load without shutting down the power of the entire power system .

According to the related art, since the switch unit is directly connected to the power line of the system input, the inverter output, and the system output, there is a problem that the power supply of the USB system must be turned off for checking or replacing the switch unit. In view of the above, the present invention provides a shut-off device for primarily disconnecting a live line of each line corresponding to a system input, an inverter output, and a system output in order to replace the switch unit 300, Third magnetic contactors 410, 420 and 430 are introduced. At this time, the relay 500 is introduced on the second bypass line BL2 so that the system input is selectively output to the system output via the second bypass line for substitution to replace the output supply. In addition, the first to third electromagnetic contactors 410, 420, and 430 and the relay 500 are required to operate in a manner that they can operate within a range that does not disturb the operation of the transmission system 10 . To this end, the present invention connects the first to third electromagnetic contactors 410, 420, and 430 and the coil excitation power of the relay 500 to the inverter output to operate according to the inverter output.

In general, if the switch unit is in the live state and needs to be replaced, the system input should be cut off, the power unit should be stopped, and the switch unit should be replaced or repaired. There is a problem that the power supply is interrupted because the switch unit is replaced while the power supply is shut off. According to the embodiment of the present invention, it is possible to safely repair or replace the power unit 200 and the switch unit 300 without turning off the system input and the system output at the time of failure or inspection.

While the present invention has been described with reference to several preferred embodiments, these embodiments are illustrative and not restrictive. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.

100:
200:
300:
410: first electromagnetic contactor
420: second electromagnetic contactor
430: third electromagnetic contactor
500: Relay

Claims (1)

In a modular multipoint system,
A power unit for converting the system input, which is an AC power input to the USB system, into an AC power having a constant voltage and a constant frequency and outputting the AC power to the inverter output;
A second electromagnetic contactor connected in series with the power unit through an inverter output line through which the inverter output is transmitted;
Wherein the system input is connected to a first bypass line through which the system input is bypassed by the power unit and is connected to one of the inverter output and the system input A switch unit for selectively transmitting the signal;
A third electromagnetic contact connected in series with the switch unit for transmitting the output of the switch to the system output;
A first electromagnetic contact disposed on the first bypass line and connected in parallel with the power unit and connected in series with the switch unit;
A relay disposed on a second bypass line for allowing the system input to bypass the power unit and the switch unit and output to the system output, and connected in parallel with the power unit and the switch unit; And
And a coil excitation power source connected to the inverter output line R-phase-N to which the inverter output is transmitted, the coil excitation power source for driving the first electromagnetic contactor, the second electromagnetic contactor, the third electromagnetic contactor and the relay,
Wherein the plurality of power units are connected in parallel to each other, each of the power units includes: a rectifier that converts the system input, which is an AC power source, into a DC power source and outputs the DC power; An inverter for converting the DC power into an AC power and outputting the AC power to the inverter output; And a storage battery interposed between the rectifier and the inverter and charged by a DC power source input from the rectifier, and discharging the charged DC power to the inverter when the supply of the system input is stopped,
The first electromagnetic contactor, the second electromagnetic contactor, and the third electromagnetic contactor are short-circuited and the relay is opened at the same time as the coil excitation power is excited when the inverter output is turned on,
Characterized in that when the inverter output is off, the first electromagnetic contactor, the second electromagnetic contactor and the third electromagnetic contactor are open and the relay is shorted as the coil excitation power is turned off. system.

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