KR20220069680A - Earth-Leakage Circuit Breaker - Google Patents

Abstract

Disclosed is an earth leakage breaker. According to an embodiment of the present invention, the earth leakage breaker comprises a detachably coupled connector and an armature support unit to which the connector is coupled. The connector is slid and coupled to the armature support unit. In addition, a PCB assembly includes a connector accommodating unit into which the connector is slid and inserted or extracted. Accordingly, coupling and detachment between the connector and the armature support unit can be easily and reliably performed.

Description

Earth-Leakage Circuit Breaker

The present invention relates to an earth leakage breaker, and more particularly, to an earth leakage breaker having a structure in which a power line connection is simple.

An earth leakage breaker is a device used to prevent electric shock, fire, and various safety accidents due to overcurrent. Earth leakage breaker is generally installed in the distribution board.

The earth leakage breaker senses the leakage current. When the detected leakage voltage or current is higher than the reference value, the earth leakage breaker sends a trip signal to the coil to trip the circuit breaker.

The earth leakage breaker of the traditional structure includes a trip device, a PCB module, a connector and a screw member. The PCB module receives power for operation from an external power source. This may be achieved by a power line that is energably connected to the outside.

The power line is connected to the connector. Also, the connector is connected to the trip device. That is, the current for operating the PCB module is transmitted to the PCB module through the power line, the connector, and the trip device.

However, in the conventional structure of the earth leakage breaker, the connector and the trip device are fastened through a separate member such as a screw member. That is, in the conventional structure of the earth leakage breaker, after the connector and the trip device are arranged side by side, the member is through-coupled and fastened.

In this fastening method, it is difficult to guarantee the accuracy and speed of fastening. That is, since the process of arranging the connector and the trip device side by side and the process of passing the member through the connector and the trip device must all be accompanied, the process becomes complicated and complicated.

In addition, the process is generally performed manually by an operator. In this case, when the connector and the trip device are incompletely fastened due to an operator's erroneous operation and inexperience, there is a risk that the operation reliability of the earth leakage breaker may be deteriorated.

Korean Patent Publication No. 10-2018-0105973 discloses an earth leakage circuit breaker. Specifically, the present invention discloses an earth leakage breaker for wiring having a structure capable of tripping the earth leakage breaker while simultaneously shutting off the power of the electronic device.

However, the earth leakage breaker having this structure still requires a separate fastening member as a means for connecting the connector and the trip device. That is, the prior literature does not suggest a method for easily and reliably connecting the connector and the trip device.

Korean Patent Publication No. 10-2009-0045787 discloses an earth leakage circuit breaker. Specifically, the present invention discloses an earth leakage circuit breaker having a structure that is easy to assemble and reduce costs by minimizing the number of components of the electronic circuit breaker.

However, the earth leakage breaker having this structure also requires a separate fastening member as a means for connecting the connector and the trip device. That is, the prior document only discloses a structure for coupling the base and the indicator lever by inserting the rotation shaft into the ring of the base, but does not suggest a method for easily and reliably connecting the connector and the trip device.

Korean Patent Publication No. 10-2018-0105973 (2018.10.01.) Korean Patent Publication No. 10-2009-0045787 (2009.05.08.)

An object of the present invention is to provide an earth leakage circuit breaker having a structure that can solve the above problems.

First, an object of the present invention is to provide an earth leakage breaker having a structure that can easily form an energized state with an external control power source.

Another object of the present invention is to provide an earth leakage breaker having a structure capable of stably maintaining an energized state with an external control power source.

Another object of the present invention is to provide an earth leakage breaker having a structure that does not require a separate fastening member to form and maintain an energized state with an external control power source.

Another object of the present invention is to provide an earth leakage breaker having a structure capable of easily releasing an energized state with an external control power source.

In addition, an object of the present invention is to provide an earth leakage circuit breaker having a structure that enables operation convenience and cost reduction.

In order to achieve the above object, the present invention is provided rotatably armature (armature); an armature support for rotatably supporting the armature; and a connector detachably coupled to the armature support and energably connected to an external control power source, wherein the connectors are disposed to face each other, and a gap therebetween is in one direction toward the armature support. It provides an earth leakage circuit breaker including a plurality of coupling portions that are formed to be changed.

In addition, the plurality of coupling portions of the earth leakage breaker may include: a first portion extending obliquely in a direction facing each other; and a second portion that is continuous with the first portion and extends obliquely in opposite directions.

In addition, a distance between the plurality of coupling portions of the earth leakage breaker may be minimized in a portion in which the first portion and the second portion are continuous.

In addition, the connector of the earth leakage breaker, the first base extending along the one direction, the end of which is continuous with any one of the coupling part of the plurality of coupling parts; and a second base extending along the one direction, the end of which is continuous with the other coupling part among the plurality of coupling parts, and is spaced apart from the first base and disposed to face the first base. .

In addition, the connector of the earth leakage breaker may include a connection portion continuous with the first base and the second base, respectively.

In addition, the plurality of coupling parts of the earth leakage breaker may include: a first coupling part continuous with the end of the first base; and a second coupling part continuous with the end of the second base.

In addition, the first coupling part and the second coupling part of the earth leakage breaker may include: a first part extending obliquely toward each other; and a second portion that is continuous with the first portion and extends obliquely to be opposite to each other.

In addition, the armature support part of the earth leakage breaker may include a connector coupling part inserted and coupled between the plurality of coupling parts.

In addition, the connector coupling portion of the earth leakage breaker, a first inclined portion located on one side facing the connector and extending to be inclined to increase the thickness along the one direction; a second inclined portion continuous with the first inclined portion and extending to be inclined in a direction opposite to the first inclined portion so that a thickness thereof is reduced along the one direction; and a third inclined part that is continuous with the second inclined part and inclinedly extending in the same direction as the first inclined part so that the thickness thereof is increased along the one direction.

In addition, when the connector of the earth leakage breaker is coupled to the connector coupling part, a plurality of the coupling parts may be positioned between the second inclined part and the third inclined part.

In addition, the connector of the earth leakage breaker, the first base extending along the one direction, the end of which is continuous with any one of the coupling part of the plurality of coupling parts; and a second base extending along the one direction, the end of which is continuous with the other coupling part among the plurality of coupling parts, and is spaced apart from the first base and disposed to face the first base, The second base may include a pressing unit extending in a direction opposite to the first base and provided in a plate shape.

In addition, the present invention, the armature (armature) provided rotatably; an armature support for rotatably supporting the armature; and a connector detachably coupled to the armature support and energably connected to an external control power source, wherein the connector includes a plurality of curved portions disposed to face each other and rounded to be convex toward each other. And, the armature support portion provides an earth leakage breaker including a connector coupling portion inserted and coupled between the plurality of curved portions.

In addition, the connector of the earth leakage breaker, the connector extends along one direction toward the armature support, the end of the first base is continuous with any one of the curved portion of the plurality of curved portions; and a second base extending along the one direction and having an end continuous with the other curved portion among the plurality of curved portions.

In addition, the connector coupling portion of the earth leakage breaker is located on one side facing the connector, the connector is a first inclined portion extending in a direction toward the armature support to increase the thickness thereof; a second inclined portion continuous with the first inclined portion and extending to be inclined in a direction opposite to the first inclined portion so that a thickness thereof is reduced along the one direction; a third inclined portion continuous with the second inclined portion and extending to be inclined in the same direction as the first inclined portion so that the thickness thereof is increased along the one direction; and an accommodation space that is a space formed by being partially surrounded by the second inclined portion and the third inclined portion, wherein the plurality of curved portions may be retractably accommodated in the accommodation space.

In addition, the minimum value of the thickness of the connector coupling portion of the earth leakage breaker may be greater than the minimum value of the vertical distance between the plurality of curved portions.

According to an embodiment of the present invention, the following effects can be achieved.

First, the earth leakage breaker is provided with a connector. The connector is electrically connected to an external control power supply. The connector is inserted and coupled to a connector receiving portion provided in the PCB housing. Both sides in the extending direction of the connector accommodating part are formed open, so that the connector enters the connector accommodating part through one of the open both sides, and may be exposed through the other side.

An armature support is provided adjacent to the PCB housing. The armature support includes a connector coupling part inserted into the space between the coupling part or the curved part provided at the exposed end of the connector.

Accordingly, when the connector penetrates the connector receiving portion and slides toward the armature support portion, the connector and the armature support portion are coupled to each other to conduct electricity. Accordingly, the energized state of the external control power supply and the earth leakage breaker can be easily formed.

Further, the distance between the engaging portions or the curved portions of the connector is variable along its longitudinal direction or its moving direction. That is, the distance between the coupling portion or the curved portion is decreased along the longitudinal direction and then increased again. Accordingly, the distance between the engaging portions or the curved portions has a minimum value inside the longitudinal direction thereof.

The connector coupling portion also has a variable thickness along its longitudinal direction or the moving direction of the connector. That is, the thickness of the cross section of the connector engaging portion increases, decreases, and increases along the longitudinal direction thereof. Accordingly, the portion having the minimum thickness of the cross section of the connector engaging portion is surrounded by the portion having a greater thickness than the portion.

When the connector is coupled to the connector engaging portion, a portion having the smallest distance between the engaging portion or the curved portion is brought into contact with a portion having the smallest cross-section of the connector engaging portion. Accordingly, the portion of the engaging portion or the curved portion having the smallest distance therebetween is surrounded by the portion having a greater thickness among the portions of the connector engaging portion.

Accordingly, as long as no external force is applied, the coupling state of the connector and the connector coupling portion may be stably maintained.

In addition, as described above, by changing the structure of the connector and the connector coupling part, the connector and the connector coupling part can be easily coupled. In addition, as long as no external force is applied, the coupling state of the connector and the connector coupling portion may be stably maintained.

Accordingly, an energized state between the connector and the connector coupling portion can be easily formed and maintained without a separate member.

In addition, the connector is provided with a pressing part. The pressing part is formed to extend in a direction different from the moving direction of the connector, and is exposed to the outside. In one embodiment, the pressing unit is provided in a plate shape, so that the operator can move the connector by pressing each side of the pressing unit.

Accordingly, the operator can easily couple the connector to the connector engaging portion by pressing the pressing portion in the direction toward the connector engaging portion. In addition, the operator can easily separate the connector from the connector engaging portion by pressing the pressing portion in a direction opposite to the connector engaging portion.

In addition, by the above-described configuration, the operator can couple or separate the connector and the connector coupling portion by pressing the pressing portion. When the connector is sufficiently moved, the pressing portion and the connector receiving portion come into contact with each other, so that the connector is no longer moved toward the connector engaging portion.

The coupling, separation, and movement restriction may be achieved by the connector and the connector coupling unit itself without the addition of a separate member. Therefore, work convenience is improved, and the number of required parts is reduced, so that cost can be reduced.

1 is a perspective view illustrating an earth leakage circuit breaker according to an embodiment of the present invention.
Fig. 2 is an open perspective view showing the internal configuration of the earth leakage breaker of Fig. 1;
3 is a perspective view illustrating a PCB assembly, an armature support and a connector provided in the earth leakage breaker of FIG. 1 .
4 is a plan view illustrating a PCB assembly, an armature support and a connector provided in the earth leakage breaker of FIG. 1 .
5 is a front view illustrating a PCB assembly, an armature support and a connector provided in the earth leakage breaker of FIG. 1 .
6 is a side view illustrating a PCB assembly, an armature support and a connector provided in the earth leakage breaker of FIG. 1 .
7 is a perspective view illustrating a PCB assembly provided in the earth leakage breaker of FIG. 1 .
Fig. 8 is a front view showing the PCB assembly of Fig. 7;
9 is a plan view illustrating the PCB assembly of FIG. 7 ;
10 is a perspective view illustrating a state in which an armature support and a connector provided in the earth leakage breaker of FIG. 1 are coupled.
11 is a side view illustrating a state in which the armature support and the connector of FIG. 10 are coupled.
12 is a plan view illustrating a state in which the armature support and the connector of FIG. 10 are coupled.
13 is a front view illustrating a state in which the armature support and the connector of FIG. 10 are coupled.
14 is a perspective view illustrating the armature support of FIG. 10 .
Fig. 15 is a side view showing the armature support of Fig. 14;
Fig. 16 is a plan view showing the armature support of Fig. 14;
Fig. 17 is a front view showing the armature support of Fig. 14;
18 is a cross-sectional view AA' and BB' sectional view (b) illustrating the armature support of FIG. 14 .
19 is a perspective view illustrating a connector provided in the earth leakage breaker of FIG. 1 .
Fig. 20 is a side view showing the connector of Fig. 19;
FIG. 21 is a side view illustrating another embodiment of the connector of FIG. 19 .
22 is a perspective view illustrating a process in which a connector and an armature support are coupled according to an embodiment of the present invention.
23 is a side view illustrating a process in which the connector and the armature support are coupled according to an embodiment of the present invention.
24 is a perspective view illustrating a process in which a PCB assembly, an armature support, and a connector provided in an earth leakage breaker according to an embodiment of the present invention are coupled.
25 is a side view illustrating a process in which a PCB assembly, an armature support, and a connector provided in an earth leakage breaker according to an embodiment of the present invention are coupled.
26 is a perspective view illustrating a state in which a PCB assembly, an armature support, and a connector provided in an earth leakage breaker according to an embodiment of the present invention are coupled.

Hereinafter, an earth leakage breaker 10 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, in order to clarify the characteristics of the present invention, descriptions of some components may be omitted.

1. Definition of terms

The term “energized” used in the following description refers to a state in which two or more different members can receive current or electrical signals from each other. In an embodiment, the energized state may be formed in a wired manner by a conducting wire member or the like, or may be formed in a wireless manner by Wi-Fi or Bluetooth.

Each component described below is described on the assumption that it is provided in the earth leakage breaker 10, but it will be understood that it can be applied to a circuit breaker, a circuit breaker, etc. as long as the characteristics of the present invention are maintained.

The terms “top”, “bottom”, “left”, “right”, “front side” and “rear side” used in the following description will be understood with reference to the coordinate system shown in FIGS. 1 and 26 .

2. Description of the configuration of the earth leakage breaker 10 according to the embodiment of the present invention

1 to 6 , an earth leakage breaker 10 according to an embodiment of the present invention is shown.

The earth leakage breaker 10 according to an embodiment of the present invention is connected to an external power source and a load to be energized, respectively. In addition, the earth leakage breaker 10 may allow or cut off current between an external power source and a load through a trip operation.

Since the operation of the earth leakage breaker 10 is a well-known technique, a detailed description thereof will be omitted.

In the illustrated embodiment, the earth leakage breaker 10 includes a housing 100 and a trip assembly 200 .

In addition, referring further to FIGS. 7 to 21 , the earth leakage breaker 10 according to the illustrated embodiment further includes a PCB assembly 300 , an armature support 400 , and a connector 500 .

Hereinafter, the earth leakage breaker 10 according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings, but the PCB assembly 300 , the armature support part 400 and the connector 500 will be described as separate clauses.

(1) Description of the housing 100

The housing 100 forms the outer shape of the earth leakage breaker 10 . The housing 100 has a space formed therein to accommodate each configuration of the earth leakage breaker 10 . In the illustrated embodiment, the trip assembly 200 , the PCB assembly 300 , the armature support 400 and the connector 500 are accommodated in the housing 100 .

The housing 100 may be formed of an insulating material. This is to prevent arbitrary energization with an external power source or load.

The housing 100 may be formed of a material having heat resistance and predetermined rigidity. This is to prevent damage due to an arc generated as a trip operation is performed.

In the illustrated embodiment, the housing 100 includes an upper cover 110 , a lower cover 120 , a space 130 , and a terminal unit 140 .

The upper cover 110 forms one side of the housing 100, an upper side in the illustrated embodiment.

A space is formed inside the upper cover 110 . The space communicates with a space formed inside the lower cover 120 . Accordingly, the space 130 may be defined as a space surrounded by the upper cover 110 and the lower cover 120 .

Each component of the earth leakage breaker 10 may be accommodated in the space of the upper cover 110 . In an embodiment, the trip assembly 200 , the PCB assembly 300 , the armature support part 400 , the connector 500 , and the like may be accommodated in the space of the upper cover 110 .

The upper cover 110 is coupled to the lower cover 120 .

The lower cover 120 forms the other side of the housing 100, the lower side in the illustrated embodiment.

A space is formed inside the lower cover 120 . As described above, the space may be defined as the space 130 in communication with the space formed inside the upper cover 110 .

Each component of the earth leakage breaker 10 may be accommodated in the space of the lower cover 120 as well. In an embodiment, the trip assembly 200 , the PCB assembly 300 , the armature support part 400 , the connector 500 , and the like may be accommodated in the space of the lower cover 120 .

The space 130 is defined as a space surrounded by the upper cover 110 and the lower cover 120 .

Various components of the earth leakage breaker 10 are mounted in the space 130 . In one embodiment, the space 130 may accommodate the trip assembly 200 , the PCB assembly 300 , the armature support 400 , and the connector 500 .

The space 130 communicates with the outside. In the illustrated embodiment, the front side, the rear side, and the upper side of the space portion 130 communicate with the outside. A plurality of terminal units 140 may be disposed on the front side and the rear side of the space unit 130 . The plurality of terminal units 140 may be electrically connected to an external power source and a load, respectively.

A lever member (not shown) for manual manipulation by the user after the trip operation is performed may be exposed on the upper side of the space 130 . In the above embodiment, the lever member (not shown) may be exposed to the outside by passing through a through hole (not shown) formed in the upper cover 110 .

The terminal unit 140 connects each component of the earth leakage breaker 10 to an external power source and a load so as to conduct electricity. The terminal unit 140 is partially exposed to the outside of the upper cover 110 and the lower cover 120 . The terminal unit 140 may be electrically connected to an external power source and a load through a separate conducting wire member (not shown) or the like.

A plurality of terminal units 140 may be provided. In the embodiment shown in FIG. 1 , three terminal units 140 are provided on the front side of the earth leakage breaker 10 . The three terminal units 140 are physically and electrically spaced apart from each other in the left and right directions.

This is due to the fact that the current flowing through the earth leakage breaker 10 according to the embodiment of the present invention is a three-phase alternating current. That is, the number and arrangement of the terminal units 140 may be changed according to the number of currents passed through the earth leakage breaker 10 .

Although not shown, the terminal unit 140 may also be disposed on the rear side of the earth leakage breaker 10 . In this case, the terminal unit 140 disposed on the front side may be electrically connected to any one of external power sources and loads, and the terminal unit 140 disposed at the rear side may be electrically connected to the other one of external power sources and loads.

(2) Description of the trip assembly 200

The trip assembly 200 performs a trip operation as an overcurrent or an abnormal current flows through the earth leakage breaker 10 . As the trip assembly 200 is operated, the earth leakage breaker 10 may connect or cut off an external power source and a load to be energized.

The trip assembly 200 is accommodated in the space 130 . The trip assembly 200 is movably coupled to the upper cover 110 and the lower cover 120 . In one embodiment, the trip assembly 200 may be rotatably coupled.

In the illustrated embodiment, the trip assembly 200 includes a bimetal 210 , a distance adjusting member 220 and an armature 230 .

The bimetal 210 is curved by heat generated when an overcurrent or an abnormal current is passed through the earth leakage breaker 10 . When the bimetal 210 is curved, the crossbar (not shown) is rotated by being pressed or struck. Accordingly, a trip mechanism (not shown) may be activated to perform a trip operation.

The bimetal 210 may be formed of a plurality of metal materials having different coefficients of thermal expansion. Accordingly, when heat is applied to the bimetal 210 , the bimetal 210 may be curved in a direction in which a metal having a relatively small coefficient of thermal expansion is disposed.

The bimetal 210 is provided with a distance adjusting member 220 . As the bimetal 210 is curved, the distance adjusting member 220 contacts and presses the crossbar (not shown) or strikes the crossbar (not shown).

The distance adjusting member 220 extends in a direction toward a crossbar (not shown) and a direction opposite thereto, and in the front-rear direction in the illustrated embodiment.

The distance adjusting member 220 is coupled to the bimetal 210 . In the illustrated embodiment, the distance adjusting member 220 is disposed adjacent to the upper end of the bimetal 210, the through-coupled to the bimetal 210.

The distance adjusting member 220 is fixedly coupled to the bimetal 210 . At this time, before the distance adjusting member 220 is fixed to the bimetal 210 , the distance adjusting member 220 may be moved in a direction toward a crossbar (not shown) or in a direction opposite thereto.

Accordingly, the distance between the distance adjusting member 220 and the crossbar (not shown) is adjusted, so that the distance at which the bimetal 210 must be curved in order to perform the trip operation may be adjusted.

The armature 230 is rotated to independently perform a trip operation with the bimetal 210 .

Specifically, it takes a predetermined time for the bimetal 210 to be curved by applying heat. Accordingly, when only the bimetal 210 is provided, it is difficult for the earth leakage breaker 10 to immediately perform a blocking operation when an overcurrent or an abnormal current is applied.

Accordingly, the armature 230 is attracted toward the bimetal 210 by a magnetic field formed when an overcurrent or an abnormal current is passed through the terminal unit 140 .

Meanwhile, the armature 230 is connected to a cross bar (not shown) through a trip bar (not shown). Accordingly, when the armature 230 moves toward the bimetal 210 , the trip bar (not shown) and the cross bar (not shown) are also rotated to perform a trip operation.

That is, when an overcurrent or an abnormal current is applied to the earth leakage breaker 10 , the armature 230 may be preemptively operated before the bimetal 210 is operated to perform a trip operation.

The armature 230 is rotatably supported by the armature support 400 . Specifically, the protrusions respectively provided on both sides of the width direction of the armature 230 in the left and right directions in the illustrated embodiment are rotatably inserted into the armature insertion part 420 of the armature support part 400 .

3. Description of the PCB assembly 300 according to an embodiment of the present invention

The earth leakage circuit breaker 10 according to an embodiment of the present invention includes a PCB assembly 300 . The PCB assembly 300 includes a PCB module 310 that is electrically connected to an external control power source.

In addition, the connector 500 is inserted into or withdrawn from the PCB assembly 300 . The connector 500 coupled to the PCB assembly 300 is supported by the PCB assembly 300 , so that the coupling between the armature support part 400 and the connector 500 may be stably maintained.

At this time, the connector 500 is slidably moved in its longitudinal direction to be coupled to or drawn out from the PCB assembly 300 . Accordingly, coupling and disconnection of the connector 500 can be easily performed.

Hereinafter, the PCB assembly 300 according to an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 9 .

The PCB assembly 300 is accommodated in the space 130 . When the production of the earth leakage breaker 10 is completed, the PCB assembly 300 may be surrounded by the upper cover 110 and the lower cover 120 so as not to be exposed to the outside.

The PCB assembly 300 is positioned adjacent the armature support 400 . In the illustrated embodiment, the PCB assembly 300 is located on the front side of the armature support 400 .

The PCB assembly 300 is electrically connected to an external control power source. The connection may be formed by a terminal unit 340 to be described later.

In the illustrated embodiment, the PCB assembly 300 includes a PCB housing 301 , a PCB module 310 , a PCB receiving unit 320 , a communication unit 330 , a terminal unit 340 , and a connector receiving unit 350 . do.

The PCB housing 301 forms the outer shape of the PCB assembly 300 . The PCB housing 301 mounts or supports various components provided in the PCB assembly 300 .

Specifically, a PCB receiving part 320 is formed inside the PCB housing 301 . The PCB module 310 is accommodated in the PCB accommodating part 320 .

In addition, the communication part 330 is formed through the inside of the PCB housing 301 . The terminal unit 140 passes through the communication unit 330 .

A terminal part 340 is provided on one side of the PCB housing 301 , on the right side in the illustrated embodiment. A member for applying a control power and a control signal to the PCB module 310 may be energably coupled to the terminal unit 340 .

The connector receiving part 350 is provided on the other side of the PCB housing 301, in the illustrated embodiment, on the upper side. The connector 500 slides into or out of the connector receiving part 350 .

The PCB housing 301 may be formed of an insulating material. This is to prevent random energization with external power and load.

The PCB housing 301 may have any shape capable of supporting or accommodating each of the above-described components. In the illustrated embodiment, the PCB housing 301 is provided in a polygonal plate shape having a length in the left-right direction longer than a length in the up-down direction and a thickness in the front-rear direction.

The PCB module 310 is operated according to an external control power supply and a control signal. The PCB module 310 is electrically connected to the control power supply and an external power supply to which a control signal is applied.

The PCB module 310 is accommodated in the PCB housing 301 . Specifically, the PCB module 310 is accommodated in the PCB accommodating part 320 formed inside the PCB housing 301 .

The PCB module 310 is energized with an external power source. To this end, the PCB module 310 is electrically connected to the terminal unit 340 .

A plurality of PCB modules 310 may be provided. The plurality of PCB modules 310 may be physically and electrically spaced apart from each other and accommodated in the PCB housing 301 . In the illustrated embodiment, two PCB modules 310 are provided and are respectively accommodated in the two PCB receiving units 320 .

The PCB accommodating part 320 is a space accommodating the PCB module 310 . The PCB accommodating part 320 may be defined as a space formed inside the PCB housing 301 . In the illustrated embodiment, the PCB accommodating part 320 is surrounded by the PCB housing 301 in all directions except for the front side.

A plurality of PCB receiving units 320 may be provided. The plurality of PCB receiving units 320 may be physically spaced apart from each other. In the illustrated embodiment, two PCB accommodating units 320 are provided, respectively, located on the left and right sides of the PCB housing 301 . As described above, the PCB module 310 may be accommodated in each PCB receiving unit 320 .

The communication unit 330 is a passage through which the terminal unit 140 passes. The communication part 330 is formed through the inside of the PCB housing 301, in its thickness direction, and in the front-rear direction in the illustrated embodiment.

The terminal unit 140 may pass through the communication unit 330 to be electrically connected to the trip assembly 200 or other components provided in the earth leakage breaker 10 .

The communication part 330 is formed inside the PCB housing 301 . In the illustrated embodiment, the communication part 330 is positioned between two PCB receiving parts 320 respectively formed on the left and right sides of the PCB housing 301 . In an embodiment, the communication part 330 may be located in a central portion of the PCB housing 301 in the left-right direction.

In the illustrated embodiment, the communication part 330 is formed to have a circular cross section. The shape of the communication part 330 may be any shape through which the terminal part 140 can pass.

The terminal unit 340 is connected to an external power supply for supplying control power and a control signal to the PCB module 310 to be energized. The connection may be formed by coupling a connector member (not shown) connected to the external power source to be energized with the terminal unit 340 .

The terminal unit 340 may be provided in any form capable of being electrically connected to the external power source. In the illustrated embodiment, the terminal unit 340 is provided in the form of a connector including a plurality of pins.

The terminal unit 340 is electrically connected to the PCB module 310 . Specifically, the terminal unit 340 may be electrically connected to the PCB module 310 accommodated in the PCB receiving unit 320 through a conductive wire member (not shown).

The terminal part 340 is located in the PCB housing 301 . Specifically, the terminal unit 340 is located on one side of the PCB housing 301 , on the right side in the illustrated embodiment.

The terminal unit 340 may be located adjacent to the PCB receiving unit 320 . In the illustrated embodiment, the terminal unit 340 is located above the PCB receiving unit 320 located on the right side.

The connector receiving part 350 is a part where the connector 500 is coupled to or separated from the PCB housing 301 . The connector 500 may be slid into the connector accommodating part 350 to be inserted or withdrawn.

The connector 500 inserted into the connector accommodating part 350 has a coupling part 540 located at one end in its longitudinal direction, and a rear side end in the illustrated embodiment, the connector coupling part 450 of the armature support part 400 . can be combined with

That is, the one end of the connector 500 inserted into the connector accommodating part 350 is exposed toward the outside of the connector accommodating part 350 , in the illustrated embodiment, to the rear side.

The connector receiving part 350 is located in the PCB housing 301 . In the illustrated embodiment, the connector receiving part 350 is located on one side of each side of the PCB housing 301 on which the terminal part 340 is located, that is, on the upper side.

The connector accommodating part 350 may be formed with several sides open. In the illustrated embodiment, the connector accommodating part 350 is open on its front side and rear side. It will be understood that the above direction is a direction in which the connector 500 is inserted into or withdrawn from the connector accommodating part 350 .

In addition, in the illustrated embodiment, the upper side of the connector receiving portion 350 is also opened.

A plurality of connector receiving units 350 may be provided. The plurality of connector accommodating parts 350 may be positioned to be spaced apart from each other in the direction in which the PCB housing 301 extends, and in the left-right direction in the illustrated embodiment.

In the illustrated embodiment, three connector accommodating parts 350 are provided, and are positioned to be spaced apart from each other in the left and right directions.

The number and arrangement of the connector accommodating parts 350 may be changed according to the number and positions of the trip assembly 200 and the armature support part 400 .

In the illustrated embodiment, the connector receiving portion 350 includes a first wall 351 , a second wall 352 , a protrusion 353 , a connector insertion space 354 , and an inclined portion 355 .

The first wall 351 is a portion where the connector receiving part 350 is continuous with the PCB housing 301 . The first wall 351 is formed to extend from the one side surface of the PCB housing 301 , the upper side surface in the illustrated embodiment.

The first wall 351 may extend at a predetermined angle with the one side surface of the PCB housing 301 . In an embodiment, the predetermined angle may be a right angle.

A plurality of first walls 351 may be provided. The plurality of first walls 351 may be spaced apart from each other and disposed to face each other. In the illustrated embodiment, two first walls 351 are provided, and are positioned to be spaced apart from each other in the left-right direction.

Accordingly, in the above embodiment, the first wall 351 forms both side walls of the connector receptacle 350 , in the illustrated embodiment, a left wall and a right wall.

The first wall 351 supports the connector 500 coupled to the connector receiving part 350 from one side. In an embodiment in which a plurality of first walls 351 are provided, the plurality of first walls 351 support both sides of the connector 500 .

In the illustrated embodiment, the first wall 351 may support the left and right sides of the connector 500 .

The first wall 351 extends in the direction in which the connector 500 is inserted or withdrawn, in the illustrated embodiment, in the front-rear direction. In an embodiment, the first wall 351 may extend by a length in the front-rear direction of the PCB housing 301 . The extended length of the first wall 351 may be extended enough to support the connector 500 inserted into the connector receiving part 350 .

A step portion 351a may be provided on at least one of the plurality of first walls 351 . In the illustrated embodiment, a step portion 351a is provided on the first wall 351 located on the left side.

The step portion 351a may physically separate the first wall 351 from the upper surface of the PCB housing 301 . In the above embodiment, the stepped portion 351a may be formed as a space positioned between the first wall 351 and the upper surface of the PCB housing 301 .

The first wall 351 is continuous with the second wall 352 .

The second wall 352 is continuous with the plurality of first walls 351 , respectively. In other words, the second wall 352 extends between the plurality of first walls 351 .

The second wall 352 is continuous with the first wall 351 at one end in the direction in which the first wall 351 extends, in the illustrated embodiment the rear end.

In addition, as described above, the plurality of first walls 351 are spaced apart from each other so that the front side and the rear side of the connector accommodating part 350 communicate with the outside.

Accordingly, the second wall 352 is continuous with the other side of the first wall 351 opposite to the PCB housing 301 , and the upper side in the illustrated embodiment.

That is, the front side of the connector accommodating part 350 is between the plurality of first walls 351 , and the rear side of the connector accommodating part 350 is between the plurality of first walls 351 and the second wall 352 , with the outside and the outside. A space to communicate is formed.

The second wall 352 supports the other side of the connector 500 accommodated in the connector receiving part 350 . In the illustrated embodiment, the second wall 352 supports the upper side of the rear of the connector 500 .

At this time, it will be understood that the rear lower side of the connector 500 accommodated in the connector receiving part 350 is supported by the upper surface of the PCB housing 301 .

In addition, the second wall 352 limits the direction in which the connector 500 is moved toward the connector coupling portion 450 , the rearward direction in the illustrated embodiment. That is, when the coupling part 540 or the curved part 550 of the connector 500 is coupled to the connector coupling part 450 , the second wall 352 may come into contact with the pressing part 521 .

Accordingly, the connector 500 is no longer moved to the rear side. Accordingly, excessive insertion of the connector 500 can be prevented.

The second wall 352 may have a continuous inclined portion 355 extending obliquely toward the connector insertion space 354 .

The protrusion 353 supports a conducting wire member (not shown) coupled to the connector 500 .

That is, as will be described later, the connector 500 includes a wire coupling groove 512 to which a conducting wire member (not shown) is coupled. In this case, the conducting wire member (not shown) may pass through the space formed between the plurality of protrusions 353 to be coupled to the connector 500 .

Accordingly, the coupling state between the conducting wire member (not shown) and the connector 500 may be stably maintained.

The protrusion 353 is provided on the first wall 351 . As described above, a plurality of first walls 351 are provided to face each other.

Accordingly, a plurality of protrusions 353 may also be provided, so that the plurality of first walls 351 may be respectively disposed on each surface facing each other, and may be formed to protrude toward the other surface.

In the illustrated embodiment, the protrusion 353 is located biased toward the front side of the first wall 351 . This is due to the wire coupling groove 512 of the connector 500 inserted into the connector receiving portion 350 is located biased toward the front side.

That is, the position of the protrusion 353 may be determined according to the position of the wire coupling groove 512 of the connector 500 .

In the illustrated embodiment, the protrusion 353 includes a first protrusion 353a and a second protrusion 353b.

The first protrusion 353a and the second protrusion 353b may be disposed to be spaced apart from each other. Accordingly, a predetermined space is formed between the first protrusion 353a and the second protrusion 353b. The conducting wire member (not shown) may pass through the predetermined space.

The shape and arrangement method of the first protrusion 353a and the second protrusion 353b may be changed according to the shape of the conducting wire member (not shown) inserted into the predetermined space.

The connector insertion space 354 is a space into which the connector 500 is retractably inserted. The connector insertion space 354 extends in the direction in which the first wall 351 extends, in the illustrated embodiment, in the front-rear direction.

The connector insertion space 354 is partially surrounded by the first wall 351 and the second wall 352 . In the illustrated embodiment, left and right sides of the connector insertion space 354 are surrounded by a plurality of first walls 351 facing each other. In addition, the rear upper side of the connector insertion space 354 is partially surrounded by the second wall 352 .

That is, portions of the front side, the rear side, and the upper side of the connector insertion space 354 communicate with the outside.

The connector 500 may be inserted into the connector insertion space 354 through the front side of the connector insertion space 354 . In addition, the connector 500 may be coupled to the armature support 400 through the rear side of the connector insertion space 354 .

In an embodiment, the connector 500 may be slidably inserted or withdrawn into the connector insertion space 354 .

Meanwhile, the connector 500 inserted into the connector insertion space 354 may be supported by the respective walls 351 and 352 surrounding the connector insertion space 354 .

The inclined portion 355 guides the movement of the connector 500 when the connector 500 partially inserted into the connector insertion space 354 is further moved toward the armature support portion 400 .

A slope 355 is formed in the second wall 352 . Specifically, the inclined portion 355 is formed to extend toward the connector insertion space 354 from one side of the second wall 352 facing the connector insertion space 354, and the front side in the illustrated embodiment.

The inclined portion 355 may be divided into a plurality of parts. In the illustrated embodiment, the inclined portion 355 is located on the upper side, is continuous with the first portion and the first portion extending obliquely toward the connector insertion space 354, toward the connector insertion space 354 and a second portion extending obliquely with respect to the first portion.

Accordingly, when the connector 500 is moved to the rear side in the direction toward the armature support part 400 , in the illustrated embodiment, the coupling part 540 or the curved part 550 of the connector 500 is on the inclined part 355 . Accordingly, the second wall 352 does not protrude upward.

Although not shown, the second portion may extend in a direction opposite to that of the first portion. That is, in the illustrated embodiment, the second portion may be inclined toward the lower side of the rear.

In the above embodiment, the coupling portion 540 or the curved portion 550 of the connector 500 may be guided more effectively by the inclined portion 355 .

A detailed description of a process in which the connector 500 is coupled to the PCB assembly 300 will be described later.

4. Description of the armature support 400 according to an embodiment of the present invention

10 to 13 , the earth leakage breaker 10 according to an embodiment of the present invention includes an armature support unit 400 . The armature support part 400 is connected to the connector 500 to be detachably connected, and receives control power applied through the connector 500 .

At this time, the armature support 400 may be coupled to or separated from the connector 500 according to the movement of the connector 500 . That is, the armature support 400 and the connector 500 may be coupled or separated without a separate fastening member.

In addition, the armature support 400 may not be arbitrarily separated from the coupled connector 500 when no external force is applied due to its structural characteristics.

Hereinafter, the armature support 400 according to an embodiment of the present invention will be described in detail with reference to FIGS. 14 to 18 .

The armature support 400 rotatably supports the armature 230 . Specifically, the protrusions provided on both sides of the armature 230 are rotatably inserted into the insertion groove 421 of the armature support part 400 .

Accordingly, when an overcurrent or an abnormal current is passed through the earth leakage breaker 10 to generate a magnetic field in the bimetal 210 , the armature 230 is rotated to perform a trip operation.

At this time, the armature support 400 is not moved regardless of the rotation of the armature 230 . Accordingly, the coupling state between the armature support part 400 and the connector 500 may be stably maintained.

The armature support 400 is coupled to the connector 500 to be energized. A current transmitted from an external power source to the connector 500 may be transmitted to the trip assembly 200 through the armature support 400 .

The armature support 400 is detachably coupled to the connector 500 . The coupling is achieved when the coupling portion 540 or the curved portion 550 of the connector 500 is coupled to or spaced apart from the connector coupling portion 450 . A detailed description thereof will be provided later.

The armature support 400 may be formed of a conductive material. This is to allow the current transmitted through the connector 500 to flow smoothly.

A plurality of armature support units 400 may be provided. The plurality of armature supports 400 may be physically and electrically spaced apart from each other. In the illustrated embodiment, three armature support parts 400 are provided, and are positioned to be spaced apart from each other in the left and right directions.

The number and arrangement method of the armature support unit 400 may be changed according to the number and arrangement method of the trip assembly 200 .

In the illustrated embodiment, the armature support part 400 includes a body part 410 , an armature insertion part 420 , a bimetal receiving part 430 , an arm 440 , and a connector coupling part 450 .

The body part 410 forms the skeleton of the armature support part 400 . Other components of the armature support 400 may be connected to the body 410 .

In the illustrated embodiment, the body portion 410 is provided in a rectangular plate shape having a vertical extension length longer than a left-right extension length and a thickness in the front-rear direction. The shape of the body part 410 may be any shape that can be combined with other components of the armature support part 400 to support them.

The body portion 410 partially surrounds the bimetal receiving portion 430 . In the illustrated embodiment, the body portion 410 surrounds the front side of the bimetal receiving portion 430 .

A coupling hole 411 is formed inside the body 410 . A coupling member (not shown) for coupling the body 410 to the trip assembly 200 or other components of the earth leakage breaker 10 may be coupled to the coupling hole 411 .

The coupling hole 411 is formed through the thickness direction of the body portion 410 in the front-rear direction in the illustrated embodiment. In addition, in the illustrated embodiment, the coupling hole 411 is located biased to the lower side of the body portion (410). It will be understood that the position is opposite to the position of the armature insert 420 .

A plurality of coupling holes 411 may be formed. The plurality of coupling holes 411 may be disposed to be spaced apart from each other. In the illustrated embodiment, two coupling holes 411 are provided, and are positioned to be spaced apart from each other in the width direction of the body portion 410 and in the left and right directions in the illustrated embodiment.

The number and positions of the coupling holes 411 may be changed according to a coupling method between the armature support part 400 and the trip assembly 200 .

The body portion 410 is continuous with the armature insertion portion 420 . In the illustrated embodiment, the upper left and right ends of the body portion 410 are continuous with the armature insertion portion (420). In the above embodiment, the body portion 410 and the armature insertion portion 420 may be continuous while forming a predetermined angle. In the illustrated embodiment, the predetermined angle may be a right angle.

The armature insertion part 420 is a portion to which the armature 230 is rotatably coupled. The armature 230 may be rotated independently of the armature insert 420 .

The armature insertion part 420 is continuous with the body part 410 . In one embodiment, the armature insertion part 420 may extend in a direction opposite to the body part 410 while forming a predetermined angle with the body part 410, in the illustrated embodiment, to the rear side.

In the illustrated embodiment, the armature insertion portion 420 extends rearwardly perpendicular to the body portion 410 .

The armature insertion part 420 partially surrounds the bimetal receiving part 430 . Specifically, the armature insertion unit 420 may surround the left or right side of the bimetal receiving unit 430 . As will be described later, a plurality of armature insertion units 420 may be provided to surround both the left and right sides of the bimetal receiving unit 430 , respectively.

A plurality of armature insertion units 420 may be provided. The plurality of armature insertion units 420 may be disposed to face each other with the bimetal receiving unit 430 interposed therebetween. In the illustrated embodiment, two armature insertion portions 420 are provided, and are continuous with the left and right sides of the body portion 410 with the bimetal receiving portion 430 interposed therebetween.

In the above embodiment, it will be understood that the armature 230 is rotatably supported in a plurality of positions, ie, left and right, respectively.

In the illustrated embodiment, the armature insertion portion 420 includes an insertion groove 421 .

The insertion groove 421 is a space into which the projection provided in the armature 230 is inserted. The protrusion of the armature 230 may be rotatably inserted into the insertion groove 421 . Accordingly, the armature insertion unit 420 may rotatably support the armature 230 .

The insertion groove 421 may be formed to have a predetermined depth. That is, in the illustrated embodiment, the insertion groove 421 has an upper side open, and is formed to be depressed by a predetermined depth toward the lower side. Accordingly, the protrusion of the inserted armature 230 is not arbitrarily separated from the insertion groove 421 .

A plurality of insertion grooves 421 may be formed. The plurality of insertion grooves 421 may be provided in each of the plurality of armature insertion units 420 . In the illustrated embodiment, two insertion grooves 421 are provided, respectively, formed in the two armature insertion portions 420 .

The bimetal accommodating part 430 is a space in which the bimetal 210 is accommodated to be deformable.

The bimetal receiving portion 430 is partially surrounded by the body portion 410 and the armature insertion portion 420 . In the illustrated embodiment, the front side of the bimetal receiving portion 430 is surrounded by the body portion (410). In addition, left and right sides of the bimetal receiving portion 430 are partially surrounded by the armature insertion portion 420 .

In addition, the armature 230 and a permanent magnet (not shown) may be accommodated in the bimetal receiving part 430 . That is, each component that performs a process preceding the trip operation may be accommodated in the bimetal accommodating unit 430 .

The arm 440 is provided to adjust the position of the connector coupling part 450 to which the connector 500 is coupled.

The arm 440 is continuous with the armature insert 420 . The arm 440 is formed to extend upward from the upper edge of the armature insertion part 420 in the direction opposite to the body part 410, in the illustrated embodiment. In one embodiment, arm 440 may extend parallel to armature insert 420 .

The arm 440 is continuous with the connector coupling part 450 . Specifically, one side opposite to the armature insertion part 420 among the ends of the arm 440 in the extending direction, in the illustrated embodiment, the upper end is continuous with the connector coupling part 450 .

The arm 440 and the connector coupling part 450 may form a predetermined angle. In an embodiment, the predetermined angle may be a right angle.

A plurality of arms 440 may be provided. The plurality of arms 440 may be spaced apart from each other and disposed to face each other. In the illustrated embodiment, two arms 440 are provided, respectively, continuous with the left and right armature insertion parts 420 .

At this time, the bimetal receiving part 430 is positioned between the two arms 440 . That is, in other words, the two arms 440 are disposed to face each other with the bimetal receiving part 430 interposed therebetween.

Arm 440 extends by a predetermined length. The extended length of the arm 440 is preferably extended to a position where the connector coupling part 450 can be coupled to the coupling part 540 or the curved part 550 of the connector 500 .

The connector coupling part 450 is a part to which the connector 500 is detachably coupled. Specifically, the coupling part 540 or the curved part 550 of the connector 500 is detachably coupled to the connector coupling part 450 .

The connector coupling part 450 is electrically connected to the connector 500 . That is, the connector coupling part 450 may be electrically connected to the connector 500 coupled thereto. Accordingly, the connector 500 and the armature support 400 are connected to be energized.

The connector coupling part 450 is continuous with the female 440 . Specifically, the connector coupling part 450 is one side opposite to the armature insertion part 420 among the ends in the extending direction (ie, the vertical direction) of the arm 440 , and is continuous with the upper end in the illustrated embodiment.

The connector coupling part 450 may extend to form a predetermined angle with the arm 440 . In an embodiment, the predetermined angle may be a right angle.

A plurality of connector coupling parts 450 may be provided. The plurality of connector coupling portions 450 may be continuous with the plurality of arms 440 , respectively, and may extend toward each other.

In the illustrated embodiment, two connector coupling parts 450 are provided, respectively, continuous with the two arms 440 . In addition, the two connector coupling portions 450 extend in a direction toward each other.

That is, in other words, the plurality of connector coupling portions 450 extend inwardly in a direction toward the bimetal receiving portion 430 .

In the illustrated embodiment, the connector coupling part 450 includes a first inclined part 451 , a second inclined part 452 , a third inclined part 453 , a first horizontal part 454 , and a second horizontal part ( 455 , a tapered portion 456 , and an accommodation space 457 .

The first inclined portion 451 forms a portion of the connector coupling portion 450 , a front side portion in the illustrated embodiment. The first inclined portion 451 is a portion where the connector 500 coupled to the connector coupling portion 450 first faces.

The first inclined portion 451 extends obliquely in the insertion and withdrawal directions of the connector 500, and in the front-rear direction in the illustrated embodiment.

Specifically, in the illustrated embodiment, the upper portion of the first inclined portion 451 extends obliquely upward toward the rear side. In addition, a lower portion of the first inclined portion 451 inclined downward toward the rear side.

Accordingly, it will be understood that the height of the cross-section of the first inclined portion 451 (ie, the length in the vertical direction) is formed to be longer on the rear side than on the front side.

Due to its shape, the first inclined portion 451 may be easily inserted into the gap g formed between the coupling portion 540 or the curved portion 550 of the connector 500 .

The first inclined portion 451 is continuous with the second inclined portion 452 .

The second inclined portion 452 is continuous with the first inclined portion 451 . Specifically, the second inclined portion 452 is continuous with the first inclined portion 451 through the first horizontal portion 454 .

The second inclined portion 452 is a portion where the connector 500 passing through the first inclined portion 451 and the first horizontal portion 454 faces each other.

The second inclined portion 452 extends obliquely in the insertion and withdrawal directions of the connector 500, and in the front-rear direction in the illustrated embodiment. In this case, the second inclined portion 452 extends in a direction opposite to the extending direction of the first inclined portion 451 .

Specifically, in the illustrated embodiment, the upper portion of the second inclined portion 452 extends obliquely downward toward the rear side. In this case, the lower side of the second inclined portion 452 horizontally extends toward the rear side. Alternatively, the lower portion of the second inclined portion 452 may extend obliquely upward toward the rear side.

Accordingly, it will be understood that the height (ie, the length in the vertical direction) of the cross section of the second inclined portion 452 is shorter on the rear side than on the front side.

The second inclined portion 452 is continuous with the third inclined portion 453 .

The third inclined portion 453 is continuous with the second inclined portion 452 . Specifically, the third inclined portion 453 is continuous with the second inclined portion 452 through the second horizontal portion 455 .

The third inclined portion 453 is a portion at which the connector coupling portion 450 and the connector 500 are coupled to each other.

The third inclined portion 453 extends obliquely in the insertion and withdrawal directions of the connector 500, and in the front-rear direction in the illustrated embodiment. In this case, the third inclined portion 453 extends in the same direction as that of the first inclined portion 451 . Similarly, the third inclined portion 453 extends in a direction opposite to the extending direction of the second inclined portion 452 .

Specifically, in the illustrated embodiment, the upper portion of the third inclined portion 453 extends obliquely upward toward the rear side. In addition, a lower portion of the third inclined portion 453 horizontally extends toward the rear side. Alternatively, the lower portion of the third inclined portion 453 may extend inclined downward toward the rear side.

Accordingly, it will be understood that the height of the cross section of the third inclined portion 453 (ie, the length in the vertical direction) is formed to be longer on the rear side than on the front side.

As a result, the coupling portion 540 or the curved portion 550 of the connector 500 that has entered the second inclined portion 452 is the first inclined portion 451 , the second inclined portion 452 and the third inclined portion ( 453) can be stably accommodated in the enclosed space.

In this case, the height of the thickest part of the cross-sections of the first inclined portion 451 and the third inclined portion 453 may be greater than or equal to the interval g formed between the coupling portion 540 or the curved portion 550 . Accordingly, the connector 500 that has entered the second inclined portion 452 is not arbitrarily separated.

In addition, the height of the thinnest portion of the cross section of the second inclined portion 452 may also be greater than or equal to the interval g formed between the coupling portion 540 or the curved portion 550 . Accordingly, the contact state between the connector 500 and the connector coupling part 450 that have entered the second inclined part 452 may be maintained.

The first horizontal portion 454 connects the first inclined portion 451 and the second inclined portion 452 . The first horizontal portion 454 extends between the first inclined portion 451 and the second inclined portion 452 .

The first horizontal portion 454 may extend at a predetermined angle with an upper portion of the first inclined portion 451 and an upper portion of the second inclined portion 452 . In the illustrated embodiment, the first horizontal portion 454 may extend at an obtuse angle with an upper portion of the first inclined portion 451 and an upper portion of the second inclined portion 452 , respectively. In the above embodiment, the first horizontal portion 454 may horizontally extend toward the rear.

The second horizontal part 455 connects the second inclined part 452 and the third inclined part 453 . The second horizontal portion 455 extends between the second inclined portion 452 and the third inclined portion 453 .

The second horizontal portion 455 may extend at a predetermined angle with an upper portion of the second inclined portion 452 and an upper portion of the third inclined portion 453 . In the illustrated embodiment, the second horizontal portion 455 may extend to form an obtuse angle with an upper portion of the second inclined portion 452 and an upper portion of the third inclined portion 453 , respectively. In the above embodiment, the second horizontal portion 455 may extend horizontally rearward to be parallel to the first horizontal portion 454 .

At this time, the second horizontal portion 455 is maintained in contact with the coupling portion 540 or the curved portion 550 of the connector 500 is inserted. Accordingly, it will be understood that the height of the second horizontal portion 455 will be higher than the height of the first horizontal portion 454 .

The tapered portion 456 is a portion in which an end of the connector coupling portion 450 is chamfered. As the tapered part 456 is formed, the weight of the connector coupling part 450 and the armature support part 400 may be reduced.

In addition, the tapered part 456 is formed at one end of the connector coupling part 450 , so that the operator can easily identify the direction of the armature support part 400 .

In the illustrated embodiment, the tapered portion 456 is located on the rear side of the connector engaging portion 450 . In addition, the tapered portion 456 is formed to be inclined in an outward direction from the rear end of the connector engaging portion 450 , that is, in a direction opposite to the facing connector engaging portion 450 .

The accommodation space 457 is a space in which the connector 500 coupled to the connector coupling part 450 is accommodated. Specifically, the coupling portion 540 or the curved portion 550 of the connector 500 is accommodated in the accommodation space 457 .

The accommodation space 457 is partially surrounded by the first to third inclined portions 451 , 452 , and 453 and the first and second horizontal portions 454 and 455 . Specifically, in the illustrated embodiment, the lower side of the accommodation space 457 is surrounded by the first to third inclined portions 451 , 452 , 453 and the first and second horizontal portions 454 and 455 .

As described above, the first to third inclined portions 451 , 452 , and 453 and the first and second horizontal portions 454 and 455 may be formed to have different heights. Accordingly, it will be understood that the lower boundary of the accommodating space 457 may have different heights along the direction in which the connector 500 is inserted, and the front-rear direction in the illustrated embodiment.

The coupling portion 540 or the curved portion 550 accommodated in the accommodation space 457 is not arbitrarily separated without an external force due to the shape of the first to third inclined portions 451 , 452 , and 453 . A detailed description thereof will be provided later.

5. Description of the connector 500 according to the embodiment of the present invention

Referring again to FIGS. 10 to 13 , the earth leakage breaker 10 according to the embodiment of the present invention includes a connector 500 . The connector 500 is detachably coupled to the armature support 400 . Accordingly, control power applied to the connector 500 from the outside may be transmitted to the armature support unit 400 .

At this time, the connector 500 and the armature support 400 may be coupled or separated according to the movement of the connector 500 . That is, the armature support 400 and the connector 500 may be coupled or separated without a separate fastening member.

In addition, the connectors 500 coupled to the armature support 400 may not be arbitrarily separated from each other unless an external force is applied due to their structural characteristics.

Hereinafter, the armature support 400 according to an embodiment of the present invention will be described in detail with reference to FIGS. 19 to 21 .

The connector 500 is electrically connected to an external control power source. The connection may be achieved by a conducting wire member (not shown) or the like. In an embodiment, the conductive wire member (not shown) connected to the connector 500 may be accommodated in a space formed between the plurality of step portions 351a provided in the PCB assembly 300 .

The connector 500 is detachably coupled to the armature support 400 . In addition, the connector 500 is electrically connected to the armature support 400 .

In one embodiment, the connector 500 may be coupled to the armature support 400 by sliding in the direction toward the armature support 400 , in the illustrated embodiment, to the rear side. When the connector 500 is coupled to the armature support 400 , the connector 500 and the armature support 400 may be energized.

In the above embodiment, the connector 500 may be separated from the armature support 400 by sliding in a direction opposite to the armature support 400 and moving forward in the illustrated embodiment. When the connector 500 is spaced apart from the armature support 400 , the energization of the connector 500 and the armature support 400 may be released.

The connector 500 is retractably coupled to the PCB assembly 300 . Specifically, the connector 500 is inserted or drawn out into the connector insertion space 354 of the connector accommodating part 350 provided in the PCB assembly 300 .

As described above, the front side and the rear side of the connector insertion space 354 are respectively opened to communicate with the outside. Accordingly, the connector 500 may enter the connector insertion space 354 through the front side of the connector insertion space 354 . In addition, the connector 500 may be exposed to the outside through the rear side of the connector insertion space 354 to be coupled to the connector coupling portion 450 .

That is, the connector 500 is coupled through the connector accommodating part 350 .

A plurality of connectors 500 may be provided. The plurality of connectors 500 may be disposed to be spaced apart from each other. In the illustrated embodiment, three connectors 500 are provided, and are positioned to be spaced apart from each other in the left and right directions.

The number and arrangement method of the connectors 500 may be changed according to the number and arrangement method of the trip assembly 200 or the armature support unit 400 .

The connector 500 may be formed of a conductive material. This is to allow the control current transmitted from the external control power supply to smoothly flow to the armature support unit 400 .

The connector 500 may be formed of a material having a predetermined elasticity. In the process in which the coupling portion 540 or the curved portion 550 of the connector 500 is coupled to the connector coupling portion 450 , the shape is deformed to store the restoring force.

By the restoring force stored in the connector 500 , the coupling state between the connector 500 and the connector coupling part 450 may be stably maintained.

In the illustrated embodiment, the connector 500 includes a first base 510 , a second base 520 , a connection part 530 , a coupling part 540 , and a curved part 550 .

The first base 510 forms a part of the outer shape of the connector 500 . In the illustrated embodiment, the first base 510 forms the lower side of the connector 500 .

The first base 510 extends in a direction in which the connector 500 is coupled to the connector coupling part 450 and in a direction opposite thereto. In the illustrated embodiment, the first base 510 extends in the front-rear direction.

The first base 510 is disposed to face the second base 520 . The first base 510 and the second base 520 are spaced apart by a predetermined distance, and are connected by a connection part 530 . In other words, a predetermined space is formed between the first base 510 and the second base 520 .

In the illustrated embodiment, the first base 510 is provided in the form of a plate having a length in the front-rear direction is longer than an extension length in the left-right direction and a thickness in the vertical direction. It will be understood that the direction in which the first base 510 extends longer is the same as the direction in which the connector 500 moves.

The first base 510 is continuous with the coupling portion 540 or the curved portion 550 . Specifically, the first coupling portion 541 or the first curved portion 551 is continuous at one end in the direction in which the first base 510 extends, and at the rear end in the illustrated embodiment.

In the illustrated embodiment, the first base 510 includes a wire coupling portion 511 and a wire coupling groove 512 .

The wire coupling unit 511 is a portion to which a conducting wire member (not shown) for energably connecting the external control power source and the connector 500 is coupled.

The wire coupling part 511 is located at any one end of each end in the direction in which the first base 510 extends. In the illustrated embodiment, the wire coupling portion 511 is located on the front side of the first base (510).

The wire coupling part 511 is formed to extend from the first base 510 toward the second base 520 . In the illustrated embodiment, the wire coupling portion 511 extends upward.

The wire coupling part 511 may be provided in a plate shape. That is, in the illustrated embodiment, the wire coupling portion 511 extends in the front-rear direction and the vertical direction, and is formed to have a thickness in the left-right direction. The shape of the wire coupling part 511 may be any shape to which a conducting wire member (not shown) can be coupled.

A plurality of wire coupling units 511 may be provided. The plurality of wire coupling portions 511 may be disposed to be spaced apart from each other. In the illustrated embodiment, two wire coupling units 511 are provided to face each other with an upper space of the first base 510 interposed therebetween.

The wire coupling groove 512 is a space into which the conducting wire member (not shown) is inserted. The wire member (not shown) inserted into the wire coupling groove 512 is supported on the inner circumferential surface of the wire coupling part 511 surrounding the wire coupling groove 512 . Accordingly, an energized state between the conducting wire member (not shown) and the connector 500 may be stably maintained.

The wire coupling groove 512 is recessed from one side of the wire coupling part 511 . In the illustrated embodiment, the wire coupling groove 512 is recessed in the upper surface of the wire coupling portion 511 is formed. It will be understood that the recessed direction of the wire coupling groove 512 corresponds to the extension direction of the wire coupling part 511 .

The second base 520 forms another part of the outer shape of the connector 500 . In the illustrated embodiment, the second base 520 forms the upper side of the connector 500 .

The second base 520 extends in a direction in which the connector 500 is coupled to the connector coupling part 450 and in a direction opposite thereto. In the illustrated embodiment, the second base 520 extends in the front-rear direction.

The second base 520 is disposed to face the first base 510 . The second base 520 and the first base 510 are spaced apart by a predetermined distance, and are connected by a connection part 530 . In other words, a predetermined space is formed between the second base 520 and the first base 510 .

In the illustrated embodiment, the second base 520 is provided in the form of a plate having a longitudinal extension length in the front-rear direction is longer than an extension length in the left-right direction and having a thickness in the vertical direction. An extension length of the second base 520 in the front-rear direction may be shorter than an extension length of the first base 510 in the front-rear direction.

At this time, since the coupling portion 540 or the curved portion 550 is connected to the rear end of the second base 520 , the rear end of the second base 520 is the same as the rear end of the first base 510 . should be placed in position.

Accordingly, it will be understood that the front side end of the second base 520 will be located on the rear side compared to the front side end of the first base 510 .

In addition, an extension length of the second base 520 in the left-right direction may be the same as an extension length of the first base 510 in the left-right direction. It will be understood that the direction in which the second base 520 extends longer is the same as the direction in which the connector 500 moves.

The second base 520 is continuous with the coupling part 540 or the curved part 550 . Specifically, the second coupling portion 542 or the second curved portion 552 is continuous at one end in the direction in which the second base 520 extends, and at the rear end in the illustrated embodiment.

In the illustrated embodiment, the second base 520 includes a pressing part 521 .

The pressing portion 521 is a portion pressed to move the connector 500 in a direction toward and opposite to the connector coupling portion 450 . The operator may slide the connector 500 by pressing the pressing part 521 to the rear side or the front side.

The pressing part 521 is located at one side in the direction in which the second base 520 extends, and at the front end in the illustrated embodiment. The pressing part 521 is formed to extend upward in the direction opposite to the first base 510 , in the illustrated embodiment.

It is preferable that the pressing part 521 extends long enough so that the operator can press it with a finger or other tool.

The pressing part 521 may extend to form a predetermined angle with the first base 510 or the second base 520 . In an embodiment, the predetermined angle may be a right angle.

The connection part 530 connects the first base 510 and the second base 520 . Also, the connecting portion 530 forms another part of the connector 500 . In the illustrated embodiment, the connector 530 forms part of the left side of the connector 500 . Alternatively, the connection portion 530 may form part of the right side of the connector 500 .

The connection part 530 is continuous with the first base 510 and the second base 520 , respectively. In other words, the connection part 530 extends between the first base 510 and the second base 520 . In the illustrated embodiment, the lower end of the connection part 530 is coupled to the first base (510). In addition, an upper end of the connection part 530 is coupled to the second base 520 .

The connector 530 may extend in a direction in which the connector 500 is coupled to or separated from the connector coupling part 450 . In the illustrated embodiment, the connection part 530 is formed to extend in the front-rear direction. It will be understood that the direction is the same as the direction in which the first base 510 and the second base 520 extend.

In the illustrated embodiment, the connecting portion 530 is provided in a plate shape having a length in the front-rear direction is longer than a length in the vertical direction, and having a thickness in the left-right direction. The shape of the connection part 530 may be any shape capable of connecting the first base 510 and the second base 520 .

Even if the coupling part 540 or the curved part 550 is pressed by the connection part 530 and the distance g between them is adjusted, the first base 510 and the second base 520 are maintained in a coupled state. can be

The coupling part 540 is a part where the connector 500 is coupled to the connector coupling part 450 . The coupling part 540 is coupled to the first base 510 and the second base 520 , respectively. The coupling part 540 is in contact with or spaced apart from the connector coupling part 450 .

On the other hand, the height of the space formed between the respective bases 510 and 520 and the coupled coupling portion 540 may be defined as the interval g. As the coupling between the connector 500 and the connector coupling part 450 proceeds, the coupling part 540 is pressed outwardly or is released from the pressure by the connector coupling part 450 .

Accordingly, the distance g may be changed while the connector 500 and the connector coupling part 450 are coupled to each other.

The coupling part 540 is continuous with the first base 510 and the second base 520 . Specifically, the coupling portion 540 is continuous with each end in the extending direction of the first base 510 and the second base 520, and the rear end in the illustrated embodiment, respectively.

A plurality of coupling units 540 may be provided. The plurality of coupling portions 540 may be continuous with the first base 510 and the second base 520 , respectively.

In the illustrated embodiment, the coupling part 540 includes a first coupling part 541 continuous with the first base 510 and a second coupling part 542 continuous with the second base 520 .

The first coupling part 541 and the second coupling part 542 are disposed to face each other. The first coupling part 541 and the second coupling part 542 are formed to be spaced apart from each other. The shortest distance between the first coupling part 541 and the second coupling part 542 may be defined as a distance g.

The connector coupling part 450 is coupled to the connector 500 through a space having the height g. In other words, the connector 500 is coupled to the connector coupling part 450 such that the first coupling part 541 and the second coupling part 542 surround the connector coupling part 450 from upper and lower sides.

The first coupling portion 541 and the second coupling portion 542 include first portions 541a and 542a and second portions 541b and 542b, respectively.

The first portions 541a and 542a are portions in which the coupling portion 540 is continuous with each of the bases 510 and 520 . The first portions 541a and 542a are continuous with the rear side ends of the respective bases 510 and 520 .

The first portions 541a and 542a extend obliquely to the rear side in the direction in which the connector 500 is coupled to the connector coupling part 450 , in the illustrated embodiment.

Specifically, the first portion 541a of the first coupling portion 541, which is continuous with the rear end of the first base 510, extends obliquely upward along the rear. In addition, the first portion 542a of the second coupling portion 542 that is continuous with the rear end of the second base 520 is inclined downward along the rear.

In other words, the first portions 541a and 542a extend obliquely toward each other. Accordingly, the vertical distance between the first portions 541a and 542a decreases toward the rear side.

The first portions 541a and 542a are continuous with the second portions 541b and 542b, respectively.

The second portions 541b and 542b extend obliquely to the rear side in the direction in which the connector 500 is coupled to the connector coupling part 450 , in the illustrated embodiment.

Specifically, the second portion 541b continuous with the first portion 541a of the first coupling portion 541 extends obliquely downward along the rear. In addition, a second portion 542b continuous with the first portion 542a of the second coupling portion 542 extends obliquely upward along the rear.

In other words, the second portions 541b and 542b extend obliquely to be opposite to each other. Accordingly, the vertical distance between the second portions 541b and 542b increases toward the rear side.

Accordingly, it will be understood that the vertical distance of the portion where the first portions 541a and 542a and the second portions 541b and 542b are continuous is formed to be the shortest.

The coupling part 540 may be coupled to the connector coupling part 450 by pressing the connector coupling part 450 by the above shape. Therefore, the connector 500 and the connector coupling part 450 can be easily coupled without a separate coupling member, and the coupling state can be stably maintained.

The above-described coupling part 540 may be replaced with a curved part 550 . That is, as shown in FIG. 21 , the curved part 550 may be provided instead of the coupling part 540 .

In the above embodiment, the curved portion 550 is a portion to which the connector 500 is coupled to the connector coupling portion 450 . The curved portion 550 is coupled to the first base 510 and the second base 520 , respectively. The curved part 550 is in contact with or spaced apart from the connector coupling part 450 .

Meanwhile, the height of the space formed between the respective bases 510 and 520 and the combined curved portion 550 may be defined as the interval g. As the coupling between the connector 500 and the connector coupling part 450 proceeds, the curved part 550 is pressed outwardly or is released from the pressure by the connector coupling part 450 .

Accordingly, the distance g may be changed while the connector 500 and the connector coupling part 450 are coupled to each other.

The curved portion 550 is continuous with the first base 510 and the second base 520 . Specifically, the curved portion 550 is continuous with each end in the extending direction of the first base 510 and the second base 520 , and the rear end in the illustrated embodiment, respectively.

A plurality of curved portions 550 may be provided. The plurality of curved portions 550 may be continuous with the first base 510 and the second base 520 , respectively.

In the illustrated embodiment, the curved portion 550 includes a first curved portion 551 continuous with the first base 510 and a second curved portion 552 continuous with the second base 520 .

The first curved portion 551 and the second curved portion 552 are disposed to face each other. The first curved portion 551 and the second curved portion 552 are formed to be spaced apart from each other. The shortest distance between the first curved portion 551 and the second curved portion 552 may be defined as an interval g.

The connector coupling part 450 is coupled to the connector 500 through a space having the height g. In other words, the connector 500 is coupled to the connector coupling part 450 such that the first curved part 551 and the second curved part 552 surround the connector coupling part 450 from upper and lower sides.

The first curved portion 551 and the second curved portion 552 extend convexly and roundly toward each other.

That is, the first curved portion 551 continuous with the first base 510 is convexly rounded upward and extends toward the second curved portion 552 . In addition, the second curved portion 552 that is continuous with the second base 520 is rounded and extended downwardly toward the first curved portion 551 .

Accordingly, the vertical distance between the first curved portion 551 and the second curved portion 552 may be formed differently in the front-rear direction.

That is, the vertical distance between the first curved portion 551 and the second curved portion 552 is decreased and then increased toward the rear.

At this time, the shortest distance of the vertical distance between the first curved portion 551 and the second curved portion 552 may be the same as the vertical distance of the portion in which the first portions 541a and 542a and the second portions 541b and 542b are continuous. have.

The curved part 550 may be coupled to the connector coupling part 450 by pressing the connector coupling part 450 by the above shape. Therefore, the connector 500 and the connector coupling part 450 can be easily coupled without a separate coupling member, and the coupling state can be stably maintained.

6. Description of the process in which the connector 500 is coupled according to an embodiment of the present invention

The earth leakage breaker 10 according to an embodiment of the present invention includes a connector 500 that is energably connected to an external control power source, and an armature support part 400 to which the connector 500 is detachably coupled. The connector 500 and the armature support 400 may be coupled and separated without a separate fastening member.

In addition, the coupled connector 500 and the armature support 400 are not separated arbitrarily without the application of external force due to their structural characteristics and are stably maintained in a coupled state.

Hereinafter, a process in which the connector 500 is coupled according to an embodiment of the present invention will be described in detail with reference to FIGS. 22 to 26 .

First, the connector 500 is inserted and coupled to the connector receiving part 350 of the PCB assembly 300 . At this time, the connector 500 may be horizontally moved toward the connector coupling part 450 , and may be coupled to the connector receiving part 350 by sliding to the rear side in the illustrated embodiment.

As described above, the front side and the rear side of the connector receiving portion 350 are open. The connector 500 enters the connector insertion space 354 through the front side.

As the insertion of the connector 500 proceeds, the rear end of the connector 500 , that is, the coupling portion 540 or the curved portion 550 is exposed to the outside of the connector insertion space 354 through the rear side.

Meanwhile, a portion inserted into the connector insertion space 354 of each portion of the connector 500 is supported by the first wall 351 and the second wall 352 .

At this time, the coupling portion 540 or the curved portion 550 of the connector 500 is guided by the inclined portion 355 formed on the second wall 352 , so that the connector 500 may be moved smoothly.

In addition, the pressing part 521 of the connector 500 is exposed to the outside through an upper space formed between the first walls 351 . As described above, the operator can move the connector 500 by pressing the exposed pressing unit 521 .

As the operator presses the pressing part 521 toward the connector coupling part 450 , the coupling part 540 or the curved part 550 comes into contact with the connector coupling part 450 .

The coupling portion 540 or the curved portion 550 sequentially passes through the first inclined portion 451 , the first horizontal portion 454 , the second inclined portion 452 , and the second horizontal portion 455 , and the receiving space 457 . ) to enter.

At this time, the distance g, which is the shortest distance of the vertical distance of the coupling part 540 or the curved part 550, may be formed to be smaller than the thickness of the second horizontal part 455, which is the thinnest among the connector coupling parts 450. have. In the above embodiment, the coupling portion 540 or the curved portion 550 extending up to the second horizontal portion 455 may be in contact with the connector coupling portion 450 at upper and lower sides.

On the other hand, when the coupling part 540 or the curved part 550 is coupled to the connector coupling part 450 , the pressing part 521 comes into contact with the second wall 352 . Accordingly, the connector 500 is not moved further toward the rear side, that is, the connector coupling portion 450 .

Accordingly, the coupling process between the connector 500 and the armature support 400 is completed.

In addition, the coupled connector 500 and the connector coupling portion 450 are not randomly separated. That is, the second horizontal portion 455 in contact with the coupling portion 540 or the curved portion 550 is a portion having the thinnest thickness among the connector coupling portions 450 .

At this time, due to the contact between the pressing part 521 and the second wall 352 , the connector 500 is not further moved in the direction toward the connector coupling part 450 , that is, to the rear side.

In addition, the coupling portion 540 or the curved portion 550 and the second horizontal portion 455 are in elastic contact. Accordingly, the connector 500 does not move randomly in the direction toward the second inclined portion 452 having a relatively larger thickness, that is, toward the front side.

Although not shown, it will be understood that the connector 500 and the connector coupling part 450 may be separated as the connector 500 is moved by pressing the pressing part 521 to the front side.

Therefore, in the present embodiment, the earth leakage breaker 10 is a coupling between the connector 500 operably connected to an external control power source and the armature support part 400 for transmitting the transmitted control current to the trip assembly 200 . And the energized state can be easily formed without a separate member.

In addition, the coupling and energization of the formed connector 500 and the armature support 400 are not arbitrarily released without the application of an external force. Accordingly, the coupling state between the connector 500 and the armature support 400 may be stably maintained.

Although the above has been described with reference to the preferred embodiment of the present invention, those of ordinary skill in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

10: earth leakage breaker
100: housing
110: upper cover
120: lower cover
130: space part
140: terminal unit
200: trip assembly
210: bimetal
220: distance adjustment member
230: amateur (armature)
300: PCB assembly
301: PCB housing
310: PCB module
320: PCB receiving part
330: communication unit
340: terminal unit
350: connector receiving part
351: first wall
351a: step part
352: second wall
353: protrusion
353a: first projection
353b: second projection
354: connector insertion space
355: inclined part
400: armature support
410: body part
411: coupling hole
420: Amateur Insertion
421: insertion groove
430: bimetal receiving unit
440: arm (arm)
450: connector mating portion
451: first inclined portion
452: second inclined portion
453: third inclined portion
454: first horizontal part
455: second horizontal part
456: tapered part
457: accommodation space
500: connector
510: first base
511: wire coupling unit
512: wire bonding groove
520: second base
521: pressurization unit
530: connection
540: coupling part
541: first coupling part
541a: first part
541b: second part
542: second coupling part
542a: first part
542b: second part
550: curved part
551: first curved portion
552: second curved part

Claims (15)

an armature provided rotatably;
an armature support for rotatably supporting the armature; and
and a connector detachably coupled to the armature support and energably connected to an external control power source,
The connector is
A plurality of coupling portions disposed to face each other, the spacing therebetween including a plurality of coupling portions formed to be changed along one direction toward the armature support,
earth leakage breaker. According to claim 1,
A plurality of the coupling portion,
a first portion extending obliquely in a direction facing each other; and
Contiguous with the first part, each comprising a second part extending obliquely in opposite directions,
earth leakage breaker. 3. The method of claim 2,
The distance between the plurality of coupling portions is the minimum in the portion in which the first portion and the second portion are continuous,
earth leakage breaker. According to claim 1,
The connector is
a first base extending along the one direction and having an end continuous with any one of the plurality of coupling parts; and
A second base extending along the one direction, the end of which is continuous with the other coupling part among the plurality of coupling parts, is spaced apart from the first base and includes a second base disposed to face the first base,
earth leakage breaker. 5. The method of claim 4,
The connector is
Containing a connection portion continuous with the first base and the second base, respectively,
earth leakage breaker. 5. The method of claim 4,
A plurality of the coupling portion,
a first coupling portion continuous with the end of the first base; and
Comprising a second coupling portion continuous with the end of the second base,
earth leakage breaker. 7. The method of claim 6,
The first coupling portion and the second coupling portion,
first portions extending obliquely toward each other; and
Contiguous with the first portion, each comprising a second portion extending obliquely opposite to each other,
earth leakage breaker. According to claim 1,
The armature support part,
Comprising a connector coupling part inserted between the plurality of coupling parts,
earth leakage breaker. 9. The method of claim 8,
The connector coupling part,
a first inclined portion positioned on one side facing the connector and inclinedly extending to increase the thickness along the one direction;
a second inclined portion continuous with the first inclined portion and extending to be inclined in a direction opposite to the first inclined portion so that a thickness thereof is reduced along the one direction; and
Containing a third inclined portion continuous with the second inclined portion and extending obliquely in the same direction as the first inclined portion so that the thickness thereof is increased along the one direction,
earth leakage breaker. 10. The method of claim 9,
When the connector is coupled to the connector coupling portion,
A plurality of the coupling portions are positioned between the second inclined portion and the third inclined portion,
earth leakage breaker. According to claim 1,
The connector is
a first base extending along the one direction and having an end continuous with any one of the plurality of coupling parts; and
and a second base extending along the one direction, the end of which is continuous with the other coupling part among the plurality of coupling parts, and is spaced apart from the first base and disposed to face the first base,
The second base is
Extending in a direction opposite to the first base, including a pressing portion provided in a plate shape,
earth leakage breaker. an armature provided rotatably;
an armature support for rotatably supporting the armature; and
and a connector detachably coupled to the armature support and energably connected to an external control power source,
The connector is
It is disposed to face each other, and includes a plurality of curved portions formed to be rounded to be convex toward each other,
The armature support part,
Comprising a connector coupling part inserted between the plurality of curved parts,
earth leakage breaker. 13. The method of claim 12,
The connector is
a first base from which the connector extends in one direction toward the armature support, the end of which is continuous with any one of the plurality of curved portions; and
and a second base extending along the one direction, the end of which is continuous with the other curved portion of the plurality of curved portions,
earth leakage breaker. 13. The method of claim 12,
The connector coupling part,
a first inclined portion positioned at one side facing the connector and inclinedly extending so that a thickness thereof is increased in a direction in which the connector faces the armature support portion;
a second inclined portion continuous with the first inclined portion and extending to be inclined in a direction opposite to the first inclined portion so that a thickness thereof is reduced along the one direction;
a third inclined portion continuous with the second inclined portion and extending to be inclined in the same direction as the first inclined portion so that the thickness thereof is increased along the one direction; and
and an accommodating space, which is a space formed by being partially surrounded by the second inclined portion and the third inclined portion,
A plurality of the curved portion is accommodated in the receiving space to be withdrawn,
earth leakage breaker. 13. The method of claim 12,
The minimum value of the thickness of the connector coupling portion is greater than the minimum value of the vertical distance between the plurality of curved portions,
earth leakage breaker.

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