KR101210736B1 - Circuit breaker - Google Patents

Abstract

The present invention provides a circuit breaker to selectively switch the protection function of the breaker with a simple button operation so that it can be operated as a wiring breaker or an earth leakage breaker as necessary. The main circuit contactor 2, the opening / closing mechanism part 3, the operation handle 4, the overcurrent separation device 5, the video current transformer 6, the earth leakage detection circuit 7 and the trip coil unit 8 are mounted on the main body case. In the circuit breaker with overcurrent protection and ground fault protection which have one structure, it is ON by the pushbutton 16 to the wiring path of the power supply line 9 which feeds from the main circuit 1 to the earth leakage detection circuit 7, It is made to insert and connect the mode changeover switch unit 11 which operates OFF, and selects and sets the ground fault protection function to "valid" and "invalid".

Description

Circuit breaker {CIRCUIT BREAKER}

The present invention relates to a circuit breaker having an overcurrent protection function and a ground fault protection function applied to a low voltage distribution system.

As is well known, circuit breakers applied to low voltage distribution systems include circuit breakers (MCCB) with overcurrent protection and earth leakage breakers (ELCB) with overcurrent protection and ground fault protection. There is).

The circuit breaker described above has a configuration in which the main circuit contact, the opening / closing mechanism part, the operation handle and the overcurrent separating device are mounted on the main body case (molded resin case) of the circuit breaker. On the other hand, the earth leakage circuit breaker detects the occurrence of a ground fault from the secondary output level of the video current transformer and the video current transformer which detects an unbalanced current of the main circuit, in addition to the overcurrent protection function components such as a circuit breaker. A circuit is provided with a trip coil unit for receiving an output signal from an earth leakage detection circuit (an electronic circuit including an IC) and an earth leakage detection circuit and tripping the opening / closing mechanism of the circuit breaker. Moreover, as a control power supply of a ground fault detection circuit, a cylindrical shape rectifies the voltage between phases of a main circuit, and supplies electric power to a ground fault detection circuit.

In addition, the general-purpose products of the circuit breaker and the earth leakage breaker currently produced in Korea are made of the main body case of the same external size in order to increase the user's feeling, and the common protective function parts are attached to this body case. The mounted configuration is mainstream.

On the other hand, as for the products of wiring breakers and earth leakage breakers, the insulation strength between phases of the main circuit is prescribed by the standard, and the test is carried out by externally testing voltage ( High voltage) is applied to measure the insulation strength of the product. In this case, in the ground fault circuit breaker, a ground fault detection circuit composed of an electronic circuit is connected to the control power supply circuit branch-connected to the main circuit, and therefore, in order to protect the ground fault detection circuit from the above test voltages, It is necessary to isolate the detection circuit from the main circuit. Therefore, an additional voltage test switch (mega test switch) connected to the opening / closing mechanism of the earth leakage breaker is additionally provided, and the power supply circuit connected to the earth leakage detection circuit is disconnected by turning off the switch at the time of performing the withstand voltage test. At the same time, an earth leakage circuit breaker is also known which mechanically forcibly trips the opening / closing mechanism of the circuit breaker in conjunction with the switch operation to open the main circuit contacts and to hold the circuit breaker in this open state. , Patent Document 1).

[Prior Art Literature]

[Patent Document]

Patent Document 1: Japanese Patent Application Laid-Open No. 2007-317361

By the way, with respect to the circuit breaker used by a low voltage | voltage distribution apparatus, it is common for a user to select either a circuit breaker or an earth leakage circuit breaker according to the situation, such as an on-site power distribution facility and the kind of load used. However, at the start of the operation of a new on-site power distribution facility, the user first adopts an earth leakage breaker to check the presence or absence of a leakage current (ground fault current) occurring in the power distribution circuit and the magnitude of the leakage current. Many users do not like to stop the operation of a load (for example, a motor) due to a tripping by a current, and to replace the wiring with a circuit breaker. In addition, when changing the load used by a power distribution installation, the circuit breaker used previously may be changed into the earth leakage breaker according to the kind of load.

However, conventionally, circuit breakers used in low voltage distribution systems are two types of circuit breakers and circuit breakers, and one circuit breaker product that allows users to selectively cover overcurrent protection and ground fault protection functions. There is nothing currently. In addition, in Patent Document 1 described above, a mega test switch is inserted into a power supply circuit that feeds a ground fault detection circuit. Since the mega test switch is connected to the opening / closing mechanism of the circuit breaker, the ground fault protection function is invalid. Therefore, it cannot be used as a circuit breaker for wiring.

Therefore, an object of the present invention is to provide a novel circuit breaker in which the protection function of the breaker is selectively switched in a simple operation so that the user can use it as a circuit breaker or as an earth leakage breaker as necessary.

In order to achieve the above object, according to the present invention, an overcurrent protection function and a ground fault are provided in a circuit breaker main body case in which a main circuit contact, an opening / closing mechanism, an overcurrent separation device, and a current leakage separation device including an image current transformer and an earth leakage detection circuit are mounted. In a circuit breaker with a protection function,

Equipped with a mode changeover switch unit that turns on and off the contacts inserted by power supply circuits feeding from the main circuits to the ground fault detection circuits and sets and sets the ground fault protection function to 'valid' or 'invalid' (Claim 1). Specifically, the changeover switch is configured in the following manner.

(1) In the circuit breaker of the above configuration, a mode changeover switch is built in the circuit breaker main body case and connected to a power supply circuit between a main circuit and a ground fault detection circuit, and an actuator connected to an operation end of the switch main body. It consists of a pushbutton type switch operation part for operating a switch ON and OFF, and attaches it to the cover of a circuit breaker main body case with the operation end of the pushbutton of the switch operation part facing outside (claim 2).

(2) The switch main body according to the above (1), wherein the switch main body is arranged on the bottom side of the switch case with a pair of insulated switch cases partitioned between the poles and a pair of contacting members separated from each other. A fixed electrode, an entangled movable contact disposed to face the fixed electrode, and an assembly of an operating rod pulled out upward of the switch case by collectively supporting the movable contact of each pole. The main body is placed in an empty space between the video current transformer mounted in the circuit breaker main body case and the side wall of the circuit breaker main body case (claim 3).

(3) The actuator according to (1), wherein the actuator is a rocking lever in combination with the biasing spring, and one lever arm extending on both sides of the pivot shaft portion is connected to the operation rod of the switch body, and the other. The lever arm on the side is placed opposite the tip of the pushbutton (claim 4).

(4) The switch operating portion according to the above (1), wherein the switch operating portion is composed of a push / twist lock type push button, and an assembly of cylindrical guides surrounding the push button and the return spring and mounted on a cover of the breaker body case. Further, a longitudinal slit in which the protrusion formed on the front end side of the push button is inserted into the circumferential surface of the cylindrical guide to guide the push button in the on / off direction, and the lower side of the slit. It extends from the end to the circumferential direction to form the engaging end engaging with the protrusion and locking the pushbutton to the locked position (claim 5).

According to the above configuration, the ground fault protection function of the circuit breaker can be selected and set to "effective" or "invalid" mode only by switching the pushbutton of the mode switching switch unit equipped with the circuit breaker. This temporarily switches the circuit breaker's ground fault protection function to 'valid' to confirm whether or not leakage current flows through the power distribution circuit of the on-site power distribution equipment on the user side, and then the ground fault protection function is 'invalid'. Switch to and use it as a circuit breaker for wiring. Alternatively, the circuit breaker used as the circuit breaker by setting the ground fault protection function to 'invalid' can be operated as an earth leakage breaker by returning the ground fault protection function to 'effective'.

1 is a circuit diagram of a circuit breaker according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing the assembly structure of the circuit breaker corresponding to FIG. 1. FIG.
Fig. 3 is a configuration diagram of the mode switching switch unit in Fig. 1, (a) is an exploded perspective view of the entire unit, and (b) is a perspective view seen from the lower surface side of the cylindrical guide.
Fig. 4 is an internal structural diagram of the switch main body in Fig. 3, wherein (a) and (b) show the states of switch ON and OFF, respectively.
Fig. 5 is an operation explanatory diagram of the mode changeover switch shown in Fig. 3, in which (a) and (b) show a push-up and a press-fit state, respectively.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on the Example shown to FIGS. 1-5.

First, Fig. 1 is a circuit diagram of a circuit breaker according to the present invention, in which 1 is a main circuit corresponding to each phase of R, S, T, 2 is a main circuit contact, and 3 is a main circuit contact 2. The open / close mechanism part 4 is an operation handle, and 5 is an overcurrent separating device which detects the overload current and the short circuit current of the main circuit 1 and trips the open / close mechanism part 3. In addition, the earth leakage separator for detecting the ground current of the distribution path and tripping the opening / closing mechanism part 3 includes an image current transformer for detecting the unbalanced current using the main circuit 1 of each of R, S, and T as primary conductors. 6), an earth leakage detection circuit (electronic circuit including an IC) 7 for detecting the occurrence of a ground fault from the secondary output level of the video current transformer 6, and an open / close mechanism unit for receiving an output signal from the earth leakage detection circuit 7; It consists of the trip coil unit 8 which trips (3).

Here, the ground fault detection circuit 7 supplies power between the phases of the main circuit through the power supply line 9 and the rectifier circuit 10 branched to the main circuit 1 of each phase as its control power supply. The mode changeover switch unit 11 according to the present invention is connected to the power supply circuit. In addition, the detailed structure of the mode changeover switch unit 11 is mentioned later. In the illustrated example, the phase voltages of the R, S, and T phases of the main circuit are supplied by direct current conversion, but the voltage between the phases of the R-T phases is supplied to the ground fault detection circuit 7 in some cases.

Next, FIG. 2 shows the assembly structure of the entire circuit breaker in which the above mode switching switch unit 11 is mounted. In FIG. 2, reference numeral 12 denotes a circuit breaker main body case of a circuit breaker which is divided into a case 12a, a cover 12b, and a top cover 12c. Here, the circuit breaker main body case 12 includes an opening / closing mechanism part 3, an operation handle 4, an overcurrent separating device 5, an image current transformer 6, a ground fault detection circuit 7, and a trip coil unit 8. ), Tripping the opening / closing mechanism part 3 by receiving the mechanical output signals of the main circuit conductor 13, the arc extinguish chamber 14, and the trip coil unit 8 corresponding to each of the phases R, S, and T. Each functional part of the trip crossbar 15 to operate is laid out and mounted as shown.

In addition, the above-described modes are provided in the space in the case surrounded by the annular core of the image current transformer 6, the side wall of the case 12a, and the U-shaped main circuit conductor (R phase) 13 inserted into the annular core of the image current transformer. The assembly of the changeover switch unit 11 is provided with a storage arrangement. In addition, the cover 12b is assembled with a push button 16 for turning on and off the switch main body of the unit opposite to the mode switching switch unit 11, and then the push button 16 is mounted on the top cover 12c. The operation window hole 12c-1 corresponding to the opening is opened.

Next, the detailed structures of the mode changeover switch unit 11 and the pushbutton 16 will be described with reference to FIG. This mode changeover switch unit 11 consists of the switch main body 17, the actuator 18 linked to the operation end of the switch main body 17, and the assembly of the unit case 19. As shown in FIG.

Here, as shown in FIG. 4, the switch main body 17 is a box-shaped switch case (mold resin case) 17a in which the space | interval of each pole inside is divided by the partition, and a pair of left-right contact spaced apart from each other. The pair of fixed electrodes 17b of each pole assembled on the lower side of the switch case 17a, the entangled movable contact 17c facing the fixed electrode 17b, and each pole. The movable contact holder 17c is collectively supported, and the operation end is made up of a movable contact holder 17d as an operating rod with the operation end drawn upward from the switch case 17a, and a hook-shaped handle portion (at the tip of the contact holder 17d) 17d-1) is formed.

In the above configuration, when the handle portion 17d-1 is press-fitted in the direction of the arrow A in Fig. 4A, the movable contact 17c contacts the fixed electrode 17b so that the switch is turned ON. Further, when the contact holder 17d is pulled up in the direction of the arrow B in Fig. 4B, the movable contact 17c opens from the fixed electrode 17b and the switch is turned OFF.

And this switch main body 17 is attached to the switch support end part 19a formed in the interruption position of the unit case 19, as shown in FIG. Reference numeral 20 denotes six lead wires drawn out from the switch case 17a by wiring to the fixed electrode 17b of the switch main body 17.

In addition, the engaging convex portion 19c is formed on the outer surface of the unit case 19, and as shown in FIG. 2, the mode switching switch unit 11 is mounted on the main body case 12 of the circuit breaker. The engaging convex portion 19c is inserted into the engaging groove 12a-1 notched at the upper end edge of the side wall of the case 12a so as to be positioned and supported in position.

In addition, the actuator 18 uses a rocking lever in which the lever arms 18b and 18c extend on both the left and right sides of the shaft 18a as a swinging point, and uses a spring (a spring) on the shaft 18a. 18d) (torsion coil spring) is combined, and the shaft part 18a is axially supported by the bearing part 19b provided in the top part of the unit case 19, and it assembles so that it can oscillate. Further, at the distal end of the lever arm 18b extending from the shaft portion 18a to the right side, an engaging arm portion 18e hanging on the handle portion 17d-1 drawn upward from the switch body 17 is formed. It is. The lever arm 18c extending from the shaft portion 18a to the left side is to be opposed to the tip of the pushbutton 16 disposed on the case cover 12b as described later. Further, the biasing spring 18d assembled to the actuator 18 applies the lever arm 18b clockwise in the free state of the actuator to press-drive the switch body 17 to the ON position.

On the other hand, the push button 16 is a push / twist lock type button, which is a cylindrical cylindrical guide integrally formed on the cover 12b of the main body case 12 in combination with a return spring 21 (compression coil spring). 22), the tip end of the pushbutton 16 is opposed to the lever arm 18c of the actuator 18 in this depression position.

In addition, the head of the pushbutton 16 is inscribed with a groove into which a driver (tool) is inserted, and the engaging projection 16a formed at the tip of the shaft portion extending downward from the head is attached to the tip of the cylindrical guide 22. It is joined and prevented from falling out. In addition, a guide projection 16b is formed on the head circumferential surface of the pushbutton 16, and a longitudinal guide slit 22a is formed on the circumferential surface of the cylindrical guide 22 corresponding to the projection 16b. And a coupling end 22b extending in the circumferential direction from the end of the slit 22a (see FIG. 3 (b)). With this structure, the pushbutton 16 is guided in the pressing direction, and the pushbutton 16 is held at the pressing position by the push / twist operation.

Next, with reference to Figs. 5 (a) and 5 (b), the operation and function of the mode changeover switch unit 11 and the push button 16 will be described. That is, in the initial state of the circuit breaker shipped from the manufacturer, the pushbutton 16 is pushed upward of the cylindrical guide 22 by the spring force of the return spring 21 as shown in FIG. In this state, the actuator 18 of the mode changeover switch unit 11 receives the spring force of the biasing spring 18d (see FIG. 3), and swings clockwise to move the movable contact holder 17d of the switch body 17 ( 4) is pressed and supported in the state of contact ON. Thereby, the main circuit 1 and the earth leakage detection circuit 7 shown in FIG. 1 are connected via the power supply line 9, and the phase voltage of the main circuit 1 is connected to the rectifier circuit 10. FIG. It is converted into a DC voltage and fed to the ground fault detecting circuit 7. Thus, in this state, the circuit breaker has a ground fault protection function and functions as an earth leakage breaker.

On the other hand, when the push button 16 is pushed in the direction of the arrow A of FIG. 5 (b) using a tool such as a driver from the outside and twisted, the tip of the push button 16 is the mode changeover switch unit 11. Press the actuator 18 to drive the lever arm 18c in a counterclockwise direction, and the pushbutton 16 itself is a coupling formed by the projections 16b of the head formed on the cylindrical guide 22. It engages with the end part 22b, and is latched and supported by a press force of the return spring 21 in the press-fitting position. In addition, the actuator 18 is also pressed by the pushbutton 16 to be held in this position.

Thereby, as shown in FIG.4 (b), the switch main body 17 pulls up the contact holder 17d to the arrow B direction, a contact is turned off, and the circuit of the power supply line 9 in FIG. To isolate. As a result, the ground fault detecting circuit 7 is disconnected from the main circuit 1 and the function as the ground fault breaker is released, and the circuit breaker functions as a circuit breaker with the ground fault protection function 'disabled'.

In addition, in this state, the main circuit voltage is supplied to the ground fault detecting circuit 7 so that the circuit breaker functions as a ground fault breaker. The push button 16 is twisted in the reverse direction to the above from the outside of the breaker case. As a result, the projection 16b of the pushbutton 16 escapes from the engaging end 22b of the cylindrical guide 22 and engages with the slit 22a for receiving the spring force of the return spring 21. The push button 16 is pushed upward. Accordingly, the lever arm 18c of the actuator 18 that has been pressed by the pushbutton 16 so far swings clockwise by the spring force of the biasing spring 18d, and the lever arm 18b of the switch main body 17 The movable contact holder 17d is press-fitted and returned to the switch ON state. As a result, the ground fault detecting circuit 7 returns to the fed state from the main circuit 1, so that the circuit breaker functions as a ground fault breaker.

As can be seen from the above description, the pushbutton 16 is pushed in and released to be connected to the power supply circuit between the main circuit 1 and the ground fault detection circuit 7 of FIG. 1 in conjunction with this operation. The ground contact protection function of the circuit breaker can be set to 'valid' and 'invalid' by turning on and off the switch contact of the one mode changeover switch unit 11. Thereby, a user can use a circuit breaker equipped with a power distribution installation as an earth leakage breaker or a circuit breaker as needed.

In addition, when performing the withstand voltage test (mega test) of a circuit breaker in the state used as an earth leakage breaker, by operating the above-mentioned mode switch switch unit 11, the circuit breaker of an electronic circuit is detected. It can be isolated from the main circuit of and protected from the test voltage.

(Industrial availability)

According to the present invention, it is possible to provide a novel circuit breaker which can be used as a circuit breaker or an earth leakage breaker if necessary by selectively switching the protection function of the breaker by simple operation.

1: Main circuit 2: Main circuit contact
3: opening and closing mechanism part of the main circuit contact 5: overcurrent separation device
6: video current transformer 7: electric leakage detection circuit
8: trip coil unit 9: power supply line of an earth leakage detection circuit
11: mode changeover switch unit 12: body case of the breaker
16 push button 17 switch body
17b: fixed electrode 17c: movable contact
17d: movable contact holder 18: actuator
19: unit case 21: return spring
22: cylindrical guide

Claims (5)

The circuit breaker main body has overcurrent protection and earth fault protection, which consist of a main circuit contact, an opening / closing mechanism, an overcurrent disconnecting device and an earth leakage disconnecting device including an image current transformer and an earth leakage detecting circuit. For one circuit breaker,
A circuit breaker, comprising a mode changeover switch unit for turning on and off a contact inserted into a power supply circuit supplied from a main circuit to a power supply circuit for supplying a ground fault. The method of claim 1,
The mode changeover switch unit,
A switch body built in the circuit breaker body case and connected to a power supply circuit between a main circuit and the ground fault detection circuit;
It consists of a push-button switch operation unit for turning the switch on and off through an actuator linked to the operation of the switch body,
And a cover of the circuit breaker main body case facing the outside of the push button of the switch operation unit. The method of claim 2,
The switch body,
A switch case made of an insulating material partitioned between the poles, a fixed electrode disposed on the bottom side of the switch case as a pair of contacts separated from each other,
An assembly of entangled movable contacts arranged opposite to the fixed electrode and operation rods which collectively support the movable contacts of each pole and pulls them upwards of the switch case;
A circuit breaker, wherein the switch body is disposed in an empty space between the video current transformer mounted on the circuit breaker main body case and the side wall of the circuit breaker main body case. The method of claim 3,
The actuator is a rocking lever combined with a biasing spring, and one lever arm extending on both sides of its pivot shaft portion is connected to the operation rod of the switch body, and the other lever arm is connected to the pushbutton. Circuit breaker, characterized in that arranged in the distal end of the. The method of claim 2,
The push button type switch operation unit is composed of a push / twist lock type push button, and an assembly of cylindrical guides surrounding the push button and the return spring and mounted on a cover of the breaker body case.
In addition, the circumferential surface of the cylindrical guide is inserted into the projection formed in the push button, the longitudinal slit for guiding the push button in the on / off direction, and extends in the circumferential direction from the lower end of the slit to combine with the projection and pushbutton A circuit breaker, characterized in that a coupling end for locking and holding at a locked position.

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