KR100524114B1 - distributing board - Google Patents

Abstract

The present invention relates to a distribution panel, comprising: a base panel, a main circuit breaker, a plurality of auxiliary circuit breakers and an earth leakage circuit breaker installed on the base panel, a plurality of busbar bars having one end fixedly supported on the base panel; A distribution panel comprising a plurality of magnetic bus bars connected to the bus bar and at least one end of which is electrically connected to the interruption, the first relay being connected to the R, S and T phase power lines of the main circuit breaker; Connected to the R phase, the S phase, the T phase of the first relay, and the N phase of the main circuit breaker, and a power saving unit for improving load side energy consumption, and an R phase, S phase, and T phase currents input from the power saving unit. A second relay for energizing the bus bar and an input terminal thereof are commonly connected to an input terminal of the first relay and an auxiliary power line, so that the R, S, and T phase currents input from the main circuit breaker are input. By further including a third relay for energizing the bus booth bar to minimize the power loss due to harmonics by increasing the power factor of the power supplied to the load side, while detecting an accident such as an overload, short circuit occurring in the power line, It prevents the spread and detects the incomplete connection of the current circuit connected to the relay, thereby shutting off the power supply.

Description

Distribution board

The present invention relates to a distribution board, and more specifically, to increase the power factor of the power supplied from the power plant to the load side to minimize the power loss due to harmonics, while detecting various power accidents such as overload, short circuit occurring in the power line The present invention relates to a distribution panel which prevents an accident from spreading upon occurrence and cuts off power by detecting an incomplete connection of a current circuit connected to a relay.

In general, the distribution panel is provided with a main circuit breaker, a plurality of auxiliary circuit breakers and an earth leakage circuit breaker, and each circuit breaker is electrically connected to a plurality of busbars to supply and cut power to the load side through a power transmission wiring from a power plant. As is well known, large buildings, such as buildings, have at least floor-mounted distribution panels made of steel in the walls to supply power to the various equipment in the office.

However, various power accidents such as overload and short circuit often occur in transmission and distribution power lines that generate electricity at a power plant and supply power to a load for use by end customers. As a result, there was a problem in that the distribution board as well as the load-side equipment is broken or damaged. In addition, the power distribution panel is lowered due to the phase change of the power supply current supplied to the load side, the current of the harmonic component is increased, the reactive power increases to increase the power loss, and the stable power supply is not easily achieved. There was a problem. In addition, in the related art, a power accident such as a short circuit occurs due to carelessness during construction of a distribution board or due to incomplete connection between a breaker and a power line in use.

The present invention is to solve the above problems, an object of the present invention to provide a distribution panel that can reduce power factor control and harmonics.

Furthermore, an object of the present invention is to provide a distribution panel that can prevent the failure, damage, etc. of the device due to the power accident such as overload, short circuit, etc. generated in the power line.

According to an aspect of the distribution panel according to the present invention for achieving the above object, the base panel 10, the main circuit breaker 11 and the plurality of auxiliary circuit breakers 12 are installed on the base panel 10 and A circuit breaker 13, a plurality of busbar bars 15 having one end fixedly supported on the base panel 10, and a busbar bar 15 connected thereto, and at least one end of the circuit breaker 12. In the distribution panel comprising a plurality of charity bus bar (16) electrically connected to the 13, the first relay connected to the R, S, T phase power lines of the main circuit breaker (11), R-phase, S-phase, T-phase of the relay and the N-phase of the main circuit breaker 11, the power-saving unit to improve the load side energy consumption, and the R, S-phase, T-phase currents input from the power-saving unit And a second relay for energizing the bus bus bar 15 and an input terminal of the second bus It is commonly connected to the power line, and the R-phase, S-phase, T-phase current inputted from the main line circuit breaker (11) as claim further comprising a third relay to the power application to the bus bar bus bar (15).

According to this aspect, the distribution panel according to the present invention can compensate the phase and power factor of the power current through the power saving unit, reduce the harmonics, increase the effective power, and stably supply power to the load side and power to the load side.

Distribution board according to an additional aspect of the present invention is a current transformer (CT1 ~ CT3) and the current transformer (CT1 ~ CT3) for detecting the R phase, S phase, T phase and N phase current input to the main circuit breaker (11) First to fourth rectifiers each including a transformer PT1 to PT4 for depressurizing the AC power input from the power supply, a bridge circuit for converting the AC power output from the transformers PT1 to PT4 to a DC power source, and the first to And a control unit for opening and closing the first, second, and third relays according to an input signal from the fourth rectifying unit.

According to this aspect, when the overload, short circuit, or incomplete connection between the auxiliary circuit breaker 12 and the ground circuit breaker 13 occurring in each power line is detected, the first, second, and third relays 17 according to the aspect of the present invention. , 18, 19) to prevent breakdown and breakage of the distribution panel and load-side devices due to power accidents such as overload and short circuit occurring in the power line.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

In the present embodiment, the overcurrent refers to an abnormal current that is not a normal current, that is, a current in which the current flows excessively instantaneously when the normal current increases due to a power accident and when the power line is shorted. When the power is shorted by the load or when the power line is dropped to the ground, instantaneous current flows excessively.

1 is an external perspective view of a distribution panel according to an embodiment of the present invention.

As shown, the distribution panel according to the present invention includes a plurality of main panel circuit breakers 11 and the main circuit breaker 11 installed on the base panel 10 and the power input from the main circuit breaker 11 to the load side. Auxiliary circuit breaker (12), earth leakage breaker (13), support plate (14), busbar booth (15), charity busbar (16), first, second, and third relay (17, 18, 19) And a power saving unit 20.

In the present embodiment, the distribution panel supports the main circuit breaker 11 to the support plate 14 to be installed in the space above the bus booth bar 15 and the charity busbar 16, thereby further providing an installation space for the distribution board. Although compactly configured, the distribution panel according to the present invention is not limited thereto. In addition, in the distribution system of the distribution panel, a three-phase four-wire system for distributing three-phase current to four lines of power is preferable, but a three-phase three-wire system and a single-phase three-wire system are also possible.

When the main circuit breaker 11 and the auxiliary circuit breaker 12 do not have a fault in the power line, when the overcurrent / ground current flows due to a fault such as short-circuit as well as the opening and closing of a normal current, that is, a current higher than the rated power Flows to cut off electricity.

The circuit breaker 13 cuts off power supply when electricity flows to a place other than a wiring, that is, when a ground fault occurs.

The bus bar 15 may have a rectangular cross section or a circular cross section, and may be divided into R phase, S phase, T phase, and N phase power lines. The bus bar 15 may be manufactured in various ways according to the rated power of the main circuit breaker 11.

The charity bus bar 16 is connected to the bus bar 15 through a fitting part (not shown), and at least one end thereof is electrically connected to the breakers 12 and 13.

The first, second, and third relays 17, 18, and 19 open and close electrical circuits, and may operate by receiving signals such as current, voltage, temperature, and light. In the present embodiment, the first, second, and third relays 17, 18, and 19 may be implemented by known electromagnetic relays.

The power saving unit 20 is connected to the R-phase, S-phase, T-phase and N-phase power lines of the main circuit breaker 11 of the first relay 17 to compensate for the phase and power factor of the power current supplied to the load side. While controlling, while reducing the harmonics to increase the effective power, the power consumption of the load side to be efficient, and to provide a stable supply of power to the load side.

The power saving unit 20 is a device for properly connecting a current transformer, a transformer, a capacitor, a coil, and the like, which is a Korean Utility Model No. 20-0278351 filed before the filing date and registered using "no-load loss blocking magnetic field. Electric saver ".

2 is a block diagram of a distribution panel according to a preferred embodiment of the present invention.

As shown in FIG. 2, the first relay 17 is connected to the R-phase, S-phase, and T-phase power lines of the main circuit breaker 11, and the second relay 18 is connected to the power saving unit 20. R-phase, S-phase, and T-phase power lines are connected, and the third relay 19 has its input terminal connected in common with the input terminal of the first relay 17 to the auxiliary power line, so that the R of the main circuit breaker 11 is connected. It is connected to the phase, S and T phase power lines. The third relay 19 serves to bypass the power supplied from the main circuit breaker 11 to the load side when the power saving unit 20 fails.

In general, group power demand sources such as factories and apartment complexes are equipped with water substation facilities for obtaining electric power by converting extra high voltages of 6,600V and 22,900V to 380V or 220V. In addition, the water substation is essentially equipped with a safety device for monitoring the state of the current flowing in the power line.

Preferably, the distribution panel according to the present invention can efficiently perform work such as inspection and troubleshooting by integrally mounting a safety device that is conventionally installed and used separately in the distribution panel. The schematic configuration of the safety device applied to the present invention is a current transformer CT1 to CT3 for detecting the R, S, T, and N phase currents input to the main circuit breaker 11, as shown in FIG. And a first to fourth transformers including transformers PT1 to PT4 for reducing the AC power input from the current transformers CT1 to CT3 and bridge circuits for converting AC power output from the transformers PT1 to PT4 to DC power. The rectifier, the controller 30, the current display unit 32, the fault display unit 34, the relay driver 36, and the communication unit 40 are included.

Here, the controller 30 compares the current input current with a set reference value and determines whether an overcurrent flows or a ground overcurrent occurs in each phase power line, and performs a control operation accordingly. The controller 30 may be implemented as a microprocessor in which a ROM, a RAM, and a peripheral device are integrated therein. The program data is stored in the ROM, and the overcurrent / short-circuit upper limit setting values of the R phase, S phase, T phase, and N phase voltages are stored.

The current display unit 32 is a digital display of the current peak value flowing in each phase power line input from the control unit 30, it may be implemented as an LCD.

The fault display unit 34 displays a phase current line signal having a current disturbance input from the controller 30, and emits a light emitting diode to drive the light emitting diodes according to a plurality of light emitting diodes and a driving signal input from the controller 30. It can be implemented as a driving circuit.

The relay driver 36 cuts off power supply to the load when an overcurrent, ground current, or poor contact detection signal is input from the controller 30. Here, the relay driver 36 includes a plurality of relays, and the relays open and close the trip coils mounted on the main circuit breaker 11 and the auxiliary circuit breaker 12 according to a control signal from the controller 30. Control the power to cut off the power supplied to the load side.

The communication unit 40 relays data communication between the control unit 30 and an external terminal, and may be implemented by a known cable modem. Here, the data includes the voltage and current flowing through the power line of each phase.

In a preferred embodiment, the control unit 30 includes an overload, short circuit, or auxiliary circuit breaker 12 generated in each power line through the current transformers CT1 to CT3, the transformers PT1 to PT4, and the first to fourth rectifiers. When an incomplete connection or the like of the earth leakage breaker 13 is detected, the contacts of the first, second, and third relays 17, 18, 19 are controlled. According to this aspect, it is possible to prevent breakdown and breakage of the distribution panel and load-side devices due to power accidents such as overload and short circuit occurring in the power line.

As described above, the distribution panel according to the present invention compensates and controls the phase and power factor of the power current supplied to the load side, reduces harmonics, increases the effective power, and stably supplies power to the load side, while improving power consumption at the load side. This has a useful effect.

 In addition, the distribution panel according to the present invention detects a power accident such as an overload, short circuit, and inadvertent during construction of the distribution panel that supplies power to the load, or a short circuit due to incomplete connection of the breaker and the power line in use. Of course, there is an advantage that can prevent the load-side equipment from failure or damage.

In addition, the distribution panel according to the present invention has the advantage that the remote control through the communication device.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, it should be interpreted by the claims described to include many such variations.

1 is an external perspective view of a distribution panel according to the present invention.

2 is a block diagram of a distribution panel according to a preferred embodiment of the present invention.

<Brief Description of Drawings>

10: Base Panel 11: Main Circuit Breaker

12: auxiliary circuit breaker 13: earth leakage breaker

14: support plate 15: busbar booth

16: Charity booth 17: The first switch

18: 2nd switch 19: 3rd switch

20: power saving

Claims (5)

A base panel 10; A main circuit breaker (11), a plurality of auxiliary circuit breakers (12) and a ground circuit breaker (13) installed on the base panel (10); A plurality of busbar bars 15 having one end fixedly supported on the base panel 10; In the distribution panel comprising a plurality of charity bus bars 16 connected to the bus bar 15, at least one end of which is electrically connected to the breakers 12 and 13, A first relay connected to the R-phase, S-phase, and T-phase power lines of the main circuit breaker 11; A power saving unit connected to the R-phase, S-phase, T-phase, and N-phase power lines of the main circuit breaker 11 of the first relay to improve load side energy consumption; A second relay for energizing the R-phase, S-phase, and T-phase currents input from the power saving unit to the bus bar 15; A third relay whose input terminal is commonly connected to the input terminal of the first relay by an auxiliary power line, and energizes the R, S, and T phase currents input from the main circuit breaker 11 to the bus bar 15; ; The distribution panel further comprising a. The method of claim 1, wherein the distribution panel is: Current transformers CT1 to CT3 for detecting the R-phase, S-phase, T-phase and N-phase currents input to the main circuit breaker 11; Transformers PT1 to PT4 for reducing the AC power input from the current transformers CT1 to CT3; First to fourth rectifiers each including a bridge circuit for converting AC power output from the transformers PT1 to PT4 into DC power; And a control unit which controls opening and closing of the first, second, and third relays according to the input signals from the first to fourth rectifiers. The method of claim 2, wherein the distribution panel is: A current display unit displaying a current flowing through each phase power line input from the control unit; A fault display unit which displays a current faulty phase current line signal input from the controller; The distribution panel further comprising a. The method according to claim 2 or 3, wherein the distribution panel is: And a relay driving unit which cuts off power supply to a load when an overcurrent, ground current, or a poor contact detection signal is input from the control unit. The method according to claim 2 or 3, wherein the distribution panel is: And a communication unit for exchanging various data with the control unit.