KR100461471B1 - Power distributor of respective cut-out type - Google Patents

Abstract

The present invention relates to a power distribution device formed by a combination of an earth leakage circuit breaker and a circuit breaker for distributing current input from a power source, and to distribute the current input to the power supply side and the power input side to each load. A load side can be formed, and a circuit in the energized state can be opened and closed by manual or electric operation, and the circuit breaker for automatically cutting off the current in the case of overload and disconnection and the load side of the circuit breaker are connected in parallel as many as the number of distribution loads. It is a power distribution device for individual break type wiring including a circuit breaker and a circuit breaker that automatically cuts off power when a short circuit occurs.

Therefore, even if a short circuit occurs in any one of a plurality of loads, there is an effect that the power supply of only a load having a short circuit can be cut off without affecting other loads.

Description

Power distribution device for individual cut-off wiring {POWER DISTRIBUTOR OF RESPECTIVE CUT-OUT TYPE}

The present invention relates to a power distribution device formed by a combination of an earth leakage circuit breaker and a circuit breaker for distributing current input from a power source, and to distribute the current input to the power supply side and the power input side to each load. A load side can be formed, and a circuit in the energized state can be opened and closed by manual or electric operation, and the circuit breaker for automatically cutting off the current in the case of overload and disconnection and the load side of the circuit breaker are connected in parallel as many as the number of distribution loads. It is a power distribution device for individual break type wiring including a circuit breaker and a circuit breaker that automatically cuts off power when a short circuit occurs.

In the conventional wiring distribution apparatus, an earth leakage circuit breaker is installed at an input side for receiving current from the outside, and current is supplied from the earth leakage circuit breaker to supply current to the load through each circuit breaker.

In the wiring distribution apparatus as described above, when a short circuit occurs in any one of a plurality of loads, the power is cut off even in a load in which the remaining short circuit does not occur due to the interruption of the power in the ground fault circuit breaker on the input side receiving current from the outside. At the same time, there was a problem in that it was not easy to find a shorted load because all power of the loads were cut off in determining the shorted load.

Further, in installing the wiring distribution apparatus, unnecessary wiring is required because the input side of the earth leakage breaker and the load side connected to the input portion of the wiring breaker are located in a straight line.

1 is a configuration diagram of a conventional wiring distribution apparatus.

As shown in FIG. 1, a conventional wiring distribution apparatus receives an electric current from the outside and supplies a current to a circuit breaker (NFB) and at the same time, a circuit breaker (ELB) and a circuit breaker to cut off power when a short circuit occurs in a load. It consists of a wiring breaker that receives current from the system and supplies current to each load and at the same time turns the power on or off.

The earth leakage breaker has a power supply side at an upper end of the earth leakage breaker and a load side at a lower side thereof.

That is, since the input side and the output side of the ground fault circuit breaker are located opposite to each other, unnecessary wiring is necessary because the load side of the ground fault circuit breaker and the input side of the upper circuit breaker must be connected when connecting the ground fault circuit breaker and the distribution circuit breaker. There is a problem in that it is not easy to work when the wiring distribution device configured as shown in Figure 1, when a short circuit occurs in any one of the load connected to the load of the circuit breaker, the entire circuit due to the power cut off in one circuit breaker There was a problem that the power is cut off.

Accordingly, the individual electrical leakage interrupting wiring distribution apparatus of the present invention forms a load side for distributing the current inputted from the power supply and the current inputted to the power supply to each load, and converts the electric current in the energized state by manual or electric operation. It can be opened and closed, and it is composed of a circuit breaker that automatically cuts off current in the state of overload and disconnection, and an earth leakage breaker that is connected to the load side of the circuit breaker in parallel as many times as the number of distribution loads and distributes power and automatically cuts off the power in case of short circuit. Even if a short circuit occurs in any one of the plurality of loads, the power supply of only the faulted load can be cut off without affecting the other loads, and at the same time, the input side and the output side of the circuit breaker are located on the same side to manufacture the wiring distribution device. Remove unnecessary wiring during the An object of the present invention is to provide a wiring distribution apparatus with high mechanical reliability.

1 is a configuration diagram of a conventional wiring distribution device

2 is a conceptual diagram of a power distribution device for an individual ground fault interruption wiring according to the present invention.

Figure 3 is a block diagram of the circuit breaker of the power distribution device for an individual earth leakage interrupting wiring according to the present invention

4 is a block diagram of a power distribution device for an individual ground fault interruption wiring according to the present invention;

5 is an embodiment of a power distribution device for an individual ground fault interruption wiring according to the present invention;

6 is an embodiment in which a wiring breaker and an earth leakage breaker are connected by using a busbar.

7 is a configuration diagram of a ground fault circuit breaker used in a power distribution device for a ground fault interrupting wiring according to the present invention;

FIG. 8 is a detailed circuit diagram of the interior of the earth leakage breaker of FIG. 7.

*** Explanation of symbols for main parts of drawing ***

10: power supply side 15: load side

20: drive part 30: trip part

40: trip coil 50: overvoltage control unit

60: outer frame NFB: circuit breaker

ELB: Earth Leakage Circuit Breaker

In order to achieve the above object, the present invention forms a load side for distributing the electric current input from the external power source and the current input to the power source to each load, manual or electrical operation of the electric path of the energized state It can be opened and closed by a circuit breaker that automatically cuts off the current in case of overload and disconnection, and the circuit breaker which is connected to the load side of the circuit breaker in parallel as many times as the number of distribution loads and distributes the power. It is composed.

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

2 is a conceptual diagram of a power distribution device for an individual grounding interruption wiring according to the present invention.

As shown in FIG. 2, the basic concept of the individual circuit breaker-distribution wiring distribution apparatus according to the present invention receives a current from the outside through a wiring breaker (NFB), and supplies each load when the input current is supplied to the load. To supply current through the earth leakage breaker (ELB).

When a short circuit occurs in any one of a plurality of conventional loads through the above-described individual circuit for circuit breaker interruption, it is possible to prevent the power of the entire load from being cut off and to cut off the power of only the load having the short circuit. .

3 is a block diagram of a circuit breaker of a power distribution device for an individual grounding interruption wiring according to the present invention.

As shown in Figure 3, the individual circuit breaker according to the present invention according to claim 1, wherein the wiring breaker (NFB) is the outer frame 60 and the external for the insulation of the internal circuit and the form of the circuit breaker Located inside the mold 60, and connected to the power supply side 10 and the power supply side 10 receives the current from the power supply and the power supply side 10 to turn on or off the power input and the movable part 20 An overvoltage controller connected to the trip unit 30 for tripping at an overcurrent or overvoltage and the trip coil 40 connected to the trip unit 30 to drive the trip unit using an overcurrent and the overcurrent controller to determine an overvoltage And a load side 15 connected to the overvoltage control unit 50 for powering the circuit breaker.

The outer frame 60 for the shape of the circuit breaker and the insulation of the internal circuit is manufactured to fix the internal parts using a thermosetting resin so as to maintain the shape of the circuit breaker, and the shape is not deformed even under constant heat. Do not

In addition, it is preferable to be manufactured in a form that can increase the reliability of the insulation by using a high voltage and a high current.

The outer frame 60 of the circuit breaker and the shape of the material is generally used in the same industry, and is not limited to any particular shape and material.

The driving unit 20 is for physically turning on or off the power, and releases the connection state with the terminal of the power supply side 10 that receives current from an external power source to turn off the power when overcurrent or overvoltage occurs.

The trip unit 30 drives the driving unit 20 by using a physical feature in which the shape of the bimetal is deformed into a single shape by heat generated when an overcurrent flows using the bimetal. The bimetal has a structure in which the shape of the spring due to the heat generated only when the overcurrent flows is deformed by the spring-shaped coil into a single shape by the heat, so that the trip part connected to the trip coil is pushed up, and when the current flows in the bimetal, It is a principle that the bimetal receives the heat and bends the heat to operate the trip driving unit to block the heat.

The trip coil 40 is connected to the trip part 30 to drive the bimetal of the trip part 30 using the over current when an over current flows. When a short circuit condition occurs, a large current of 1500 A or more is generated, so the bimetal has a time to receive heat, and thus the bimetal melts and cuts before the bimetal pushes the trip driving part, so the trip coil 40 is instantaneously tripped. When a large current is generated, electromagnetic force is generated in the coil and the trip driving part is pushed and blocked by the electromagnetic force, which blocks the instantaneous high speed within 0.1 seconds before receiving heat from the bimetal.

The overvoltage control circuit 50 controls the overvoltage to not be applied to the load side when the input current voltage is applied above a predetermined voltage, and cuts off the power when an overvoltage of 270V or more flows. The overcurrent trip is caused by bimetal and the short circuit current (instantaneous high current) is tripped by the trip coil 40, but the trip due to overvoltage is operated by a structure in which the overvoltage trips by the overvoltage controller 50. The principle of this is that if overvoltage (270V) is applied, the voltage is dropped to 270V by the voltage drop method in the electronic circuit. The trip coil is operated to shut off.

The overvoltage control circuit 50 generally uses a circuit used for the overvoltage control circuit, and is not necessarily limited to any particular circuit configuration, and the limit voltage for shutting off the power supply is not limited to the detailed description of the present invention. .

The load side 15 is located on the same side as the power supply side of the circuit breaker.

That is, the load side of the wiring breaker connected to the inputs of the multiple earth leakage breakers is installed on the top of the wiring breaker, which is the same position as the input of the earth leakage breaker, so that it is easy to work and reduces unnecessary wiring, thereby increasing the mechanical reliability of the wiring distribution device. There is a number.

4 is a block diagram of a power distribution device for an individual grounding interruption wiring according to the present invention.

As shown in FIG. 4, the individual ground fault interrupting wiring distribution apparatus according to the present invention is connected to a circuit breaker (NFB) for receiving current from an external power source and a circuit breaker for supplying current to a load connected to the circuit breaker (ELB). It consists of.

The circuit breaker NFB and the earth leakage breaker ELB are placed on the same line, and the load side of the circuit breaker and the input portion of the earth leakage breaker are located in one direction to facilitate work and maintenance, and at the load side of the circuit breaker. Since the wiring connected to the input of the earth leakage breaker can be reduced, the mechanical reliability of the wiring distribution device is high.

5 is an embodiment of a power distribution device for an individual earth leakage break wiring according to the present invention.

As shown in FIG. 5, an embodiment of supplying current to four loads of a power distribution device for individual ground-circuit breaking wiring according to the present invention.

For example, in the case where the electric current supplying load is electric light 1, electric light 2, electric light 3, washing machine and refrigerator, the electric current supplying load is 5, and the earth leakage breaker ELB required for this is required.

That is, a current input from an external power source is supplied to an earth leakage breaker connected in parallel to the wiring breaker through a circuit breaker, and current is supplied to each load through the earth leakage breaker.

If a short circuit occurs in the electric light 1, the earth leakage breaker corresponding to the electric light 1 operates to turn off the power, and the other electric light 2 lights are not affected by the electric leakage of the light 1.

In this way, the total load can be prevented from turning off the power, and at the same time, it is easy to find the load in which the short circuit occurs.

FIG. 6 is a diagram illustrating an example of connecting a circuit breaker and an earth leakage breaker using a busbar. FIG.

As shown in Figure 6, in connecting the circuit breaker (NFB) and the earth leakage breaker (ELB) for the circuit of the individual circuit breaker for wiring according to the present invention, it can be connected by wire as shown in FIG. More preferably, a circuit breaker using a busbar made of a form that can connect the load terminal of the circuit breaker (NFB) and the input terminal of the ground fault circuit breaker (ELB) at regular intervals using a metal material having excellent conductivity. Current is supplied from the circuit breaker to the circuit breaker.

7 and 8 are embodiments using a ground fault circuit breaker with a ground fault indicator lamp in the ground fault breaker of the individual ground fault interrupting wiring distribution apparatus according to the present invention.

7 is a configuration diagram of an earth leakage breaker (ELB) used in a power distribution device for an individual earth leakage blocking wire according to the present invention.

As shown in FIG. 7, an earth leakage breaker (ELB) used in a power distribution device for an individual earth leakage blocking wire according to the present invention includes a power supply unit 160 that receives power and a load unit 140 that is a terminal connected to a load side. And a lamp unit 150 adjacent to the load unit 140 and indicating a display in the case of a short circuit, and a blocking unit for disconnecting the connection between the power supply unit 160 and the load according to a detection result of the leakage current detector 77. 130 and a test unit 120 capable of testing the presence or absence of an earth leakage breaker ELB on an adjacent surface of the blocking unit 130 is illustrated.

Wherein the lamp is preferably a light emitting device such as an LED, the location of the lamp is located in the embodiment adjacent to the load portion, but may be conveniently located anywhere on the surface of the earth leakage breaker body. In addition, the LED, which is a light emitting element, is used to notify a user of an accident of a short circuit on the load side, so a buzzer may be used in a closed place.

FIG. 8 is a detailed circuit diagram of the interior of the earth leakage breaker in FIG. 7.

As shown in Fig. 8, at the power supply side terminals 80 and 80 'for supplying power to the earth leakage breaker, the load side terminals 79 and 79' for supplying power to the load side, and the ground current detection means 77, First amplifying means 76 for detecting and amplifying the induced current with a predetermined power supply, and operation means for exciting the current amplified by the first amplifying means 76 in the trip coil 75 to operate the switch. The bimetal 78 is thermally deformed by the resistance of the short circuit current to push the trip mechanism 75, and is connected to the circuit line of the trip coil 75 and the first amplifier 76, A second amplifying unit 73 is also connected, and a ground fault display lamp 74 is connected to the second amplifying unit 73.

Therefore, when a leakage current is generated from the load circuit, it is detected by the leakage current detecting means 77 which is an image current device, and the detected current is amplified by the first amplifier 76 and flows to the trip coil so that the trip coil 75 On the other hand, the amplification current flowing along the circuit line between the trip coil 75 and the first amplifier 76 is amplified in the second amplifier 73, and, as a result, a lamp connected to the second amplifier 73 Turn on 74). Here, the amplifier is also connected to the power supply side.

Although the present invention described above has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended claims. will be.

As described above, the present invention uses a circuit breaker on a power input side that receives current from an external power source, and uses a circuit breaker on a load side to distribute current, so that a short circuit occurs in any one of a plurality of loads. It is possible to prevent the power supply to be cut off, and by installing the circuit breaker on each load individually, there is an effect that can easily check the load that the leakage occurs.

In addition, since the input side of the load side supplying current to the load of the circuit breaker and the earth leakage breaker receiving current from the load side are located in one direction, the operation and maintenance of the wiring distribution device is easy, and from the wiring breaker to the earth leakage breaker. Since the wiring connected can be reduced, the overall volume of the wiring distribution device can be reduced, and the mechanical reliability of the device can be increased by supplying current from the circuit breaker to the earth leakage breaker using the busbar, and the electric leakage with the earth leakage display lamp Due to the use of the circuit breaker in the circuit breaker of the present invention, when the circuit breaker is activated, the buzzer may be raised to display the blocking state of the circuit breaker to the outside.

Claims (12)

In the wiring wiring device that receives the current from the power supply and delivers the input current to each load, A power supply side receiving a current from the power supply; A driving unit connected to the power supply side and blinking a power input; A trip unit connected to the driving unit to trip at an overcurrent and an overvoltage; A trip coil connected to the trip unit to drive the trip unit using an overcurrent; An overvoltage controller connected to the overcurrent controller to trip when a voltage of 270 volts or more is applied; A circuit breaker connected to the overvoltage controller and including a load side for powering the circuit breaker; A power input unit connected in parallel to the load side of the circuit breaker to receive a current; A load unit which supplies a current input to the power input unit; An earth leakage detector for detecting a load side leakage current of the load unit; A first amplifier for amplifying the current detected by the ground fault detection unit with a predetermined power source; The shape of the bimetal is deformed into a single shape by heat generated by the resistance of the short circuit current to the operation means for exciting the current amplified by the first amplifier in the trip coil using the bimetal to operate the switch, and the bimetal of the deformed shape A driving unit operated by pushing the trip unit upward; A second amplifier connected to the circuit line of the trip coil and the first amplifier and also connected to a terminal of a power supply side; A test unit capable of testing whether the driving unit has a short circuit; Lighting by the current output from the second amplifier is a circuit breaker consisting of a ground fault indicator lamp using a lamp and a buzzer that can be identified by the user; An outer frame for insulating an inner circuit of the circuit breaker and a circuit breaker; Distribution device for individual earth leakage interrupting wiring. delete delete delete delete delete delete delete delete delete delete delete