KR100443137B1 - Circuit breaker - Google Patents

Abstract

The present invention relates to a circuit breaker, wherein a circuit breaker of a distribution panel-conventional type has a problem of having a two-pole configuration with a width of a conventional one pole. Formed by a case 13 having an I-shaped cross section and covers 14 and 15 provided on both sides thereof, the plate surface of which is formed on both sides of the case along a case partition wall in a flat component of an overcurrent trip element and an overcurrent trip element. Configure to stack. Accordingly, the width dimension is reduced and the insulation of the left and right poles is secured by the case partition wall, and the two-pole opening and closing parts and the overcurrent trip element of the two elements can be accommodated within the conventional one-pole convention size.

Description

Circuit breaker

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention mainly relates to a circuit breaker of an agreement type for use in a light distribution panel, and more particularly, to a circuit breaker and an earth leakage circuit breaker having a function of two poles within a length of an agreement width.

28 to 30, a conventional circuit breaker of this type will be described.

In Fig. 28, the wiring breaker 1 includes an opening and closing part of one pole and an overcurrent trip element of one element in a main body 2 of an insulator (mold resin) having a width of 25 mm, which is defined as an agreed length. The opening and closing handle 3 protrudes on the front surface, and the power supply side terminal 4 and the load side terminal 5 are arrange | positioned at the both ends, respectively.

Many of these circuit breakers 1 are arranged inside the distribution panel 6 as shown in FIG. 29 to branch off the trunk lines 8 from the main circuit breakers 7. In the distribution panel 6, a single-phase line circuit is generally employed, and a 100V circuit and a 200V circuit are often mixed. In that case, the voltage line 9a of the wiring 9 (FIG. 30) of the 100V circuit is connected to the wiring breaker 1, and the neutral wire 9b is connected to the block terminal 10 arranged separately. The 200V circuit is connected to each of the two circuit breakers 1 in which the voltage lines on both sides are arranged in parallel. At that time, the two opening / closing handles 3 are integrally coupled as one structural member and can be opened and closed at the same time.

In addition, the same type of circuit breaker is based on the width dimension of 25mm per pole, which is defined as the agreed length, and is mainly composed of the width dimension of 50mm at the two poles, but it is different from the circuit breaker for 100V circuit.

In the distribution panel 6 using the circuit breaker 1, since the circuit breaker 1 is a single-pole product, the block terminal 10 is used for the wiring of the neutral wire 9b of a 100V circuit, and as a result, the distribution board 6 is used. The wiring breakers 1 and the wirings 9 connected to the block terminals 10 arranged to be spaced apart from each other while requiring an array space of the block terminals 10 are connected to each other by a voltage line 9a and a neutral line 9b. There is a problem that the length of the wire is different, which is cumbersome for the processing and connection of the wiring. Moreover, as for the 200V circuit, when two wiring breakers 1 were used in parallel, there was a problem that the required width dimension at that portion was 50 mm, which is twice that of the wiring breaker 1. In addition, the external dimensions of wiring breakers and earth leakage breakers were different.

Therefore, the object of the present invention is to enable wiring of a single wiring circuit breaker having an agreed type for any of the 100V circuit and the 200V circuit of the single-phase line circuit, and also reduce the distribution panel by commonizing the external dimensions of the circuit breaker and the earth leakage breaker. At the same time, the work of wiring and the connection work are reduced.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, in this invention, the circuit breaker for wiring of 100V of the width | variety of 25mm in width is made into a 2-pole switching part and the overcurrent trip device of 1 element, and as a circuit breaker for 200V circuits, it is a 2-pole switching part and 2 elements. In this case, a study is carried out to secure the necessary insulation distance and current carrying capacity by using a two-pole switch or overcurrent trip device in the same width dimension. In addition, the earth leakage breaker is provided with an earth leakage trip element in the circuit breaker for the purpose of commonizing the external dimensions of the circuit breaker and the earth leakage breaker.

The circuit breaker for a 100V circuit of the present invention has a main body of an insulator composed of a case having an I-shaped cross section having a partition in the center, and a cover of two poles arranged on both sides of the case, and a pair of left and right legs. An opening / closing handle positioned on the partition wall with the leg portion rotatably connected to the case, and a plate surface disposed on both sides thereof along the case partition wall, and one end of which is rotatably connected to the leg portion of the opening / closing handle and movable contact to the other end. The flat left and right bipolar movable contactors, a bipolar bimetal, a flat body, and a leg of a U-shaped cross section formed by bending the bilateral sides thereof. A fixed iron core surrounding the bimetal in the width direction thereof, the bimetal is rotatably supported at one end in parallel with the bimetal An overcurrent trip element, the pole portion of which is provided with a flat armature opposite the fixed iron core and a return spring for biasing the armature to the opposite side to the fixed iron core, the plate surface of the amateur being disposed on one side of the partition wall along the case partition wall; A plate surface is disposed between the partition wall and the overcurrent trip element along the case partition wall so as to be rotatably supported by the case at one end, and having a claw projecting laterally at the other end. A left and right two-pole opening / closing spring comprising a latched flat latch, a tension spring disposed between the case partition and the left and right two pole movable contacts respectively and positioned between the movable contact and the latch, and the overcurrent trip element. The bimetal or amateur can be easily inserted to The left and right sides of the case partition wall which are fixed to the armature or bimetal and are provided with an adjustment screw facing the bimetal or armature and a fixed contact point facing the movable contact through a gap are formed at the same time as the terminals are integrally formed. A fixed pole of the two poles and the left and right two pole terminals respectively disposed on opposite sides of the case partition wall, and one end of the bimetal of the overcurrent trip element and the movable contact of the one side of the case partition wall and the other end of the bimetal; The lead wire which connects between the said terminal, and the lead wire which connects between the said movable contactor and the said terminal in the other side of the said case partition wall are provided.

This circuit breaker arranges the left and right components on both sides of the case center partition wall of I-shaped cross section, and ensures the insulation between anodes. The bimetals and amateurs of the movable contactor, the latch, and the overcurrent trip element are formed in a flat plate shape, and they are stacked along the case partition wall to reduce the width dimension. The opening and closing springs of the left and right two poles are respectively disposed between the case partition wall and the movable contacts of the left and right two poles, and are simultaneously accommodated in the space required between the movable contactor and the case partition wall for attachment of the movable contact. The movable contacts of the left and right two poles are simultaneously opened and closed by a common opening and closing handle. The tripping characteristic of the overcurrent trip element can be adjusted by turning the adjusting screw to switch between the head and the bimetal or amateur.

The circuit breaker for a 200-V circuit of the present invention also has a main body of an insulator composed of a case of an I-shaped cross section having a partition wall in the center, and a cover of two left and right poles respectively fitted on both sides of the case, and a pair of left and right legs. An opening and closing handle positioned on the partition wall and rotatably connected to the case, and a plate surface is disposed on both sides thereof along the case partition wall, and one end is rotatably connected to the leg portion of the opening and closing handle to attach a movable contact to the other end. And a c-shaped cross section consisting of flat left and right two-pole movable contactors, a flat bimetal, a flat body, and legs formed by bending on both sides thereof. A fixed iron core enclosing the bimetal in the width direction thereof, supported in such a way as to be rotatable at one end in parallel with the bimetal, and at the other end thereof. Is a flat armature opposed to the fixed iron core and a return spring biasing the armature to the opposite side to the fixed iron core, the first over-current trip disposed on one side of the partition wall along the case partition wall. A c-shaped cross section consisting of an element, a bimetal of a flat type, a flat body and a leg formed by bending on both sides thereof, and having a fixed iron core surrounding the bimetal in its width direction on both legs, parallel to the bimetal It consists of a flat armature which is rotatably supported at one end and the other end of which the opposing portion opposes the fixed iron core and a return spring which biases the armature toward the fixed iron core, and the plate surface of the base of the fixed iron core is formed along the case partition wall. The second overcurrent trip element disposed on the other side of the case A transmission member that penetrates through a wall between the amateurs of the first and second overcurrent trip elements and transfers the suction action of the amateurs of the second overcurrent trip elements to the amateurs of the first overcurrent trip elements; And a plate surface is disposed between the partition wall and the overcurrent trip element along the case partition wall so as to be rotatably supported by the case at one end and protrude laterally from the other end. The first and second opening and closing springs of the left and right poles, each of which is disposed between the flat latch latched by the unit, the case partition wall, and the left and right two pole movable contacts, and is stretched between the movable contactor and the latch. And a second overcurrent trip element respectively penetrating the bimetal or amateur to allow room to penetrate therethrough. Twist the armature or bimetal and attach the first and second adjustment screws facing the bimetal or armature and the fixed contact point facing the movable contact through a gap, and the terminals are integrally formed so that one end of the partition wall One end of the bimetal of the first over-current trip element and the movable member at fixed contacts of two left and right two poles respectively disposed at both sides, the left and right two pole terminals respectively disposed at opposite ends of the case partition wall, and the case partition wall. A lead wire connected between the contactor and between the other end of the bimetal and the terminal, respectively, between the one end of the bimetal of the second overcurrent trip element and the movable contactor and the other end of the bimetal on the other side of the case partition wall. The lead wire which connects between the said terminals is provided, respectively.

This wiring breaker adds a second overcurrent trip element, and one latch for tripping the circuit breaker in the event of an overcurrent detection is provided in common to the two overcurrent trip elements, and the latch is applied to the armature of the first overcurrent trip element. have. In order to transfer the operation of the second overcurrent trip element to the first overcurrent trip element, a transmission member is inserted between the two amateurs. For this reason, the tripping mechanism (latch) can be combined with the left and right poles, and the required widthwise space can be reduced. The bimetal curvature of the second overcurrent trip element is transmitted to the armature via the second adjusting screw and also to the armature of the first overcurrent trip element via the transmission member. In addition, the suction operation of the armature of the second overcurrent trip element is transmitted to the armature of the first overcurrent trip element through the transmission member regardless of the bimetal.

In addition, the circuit breaker of the present invention connects the left and right two-pole conductors or the first and second overcurrent trip elements and the terminals, respectively, which are connected between the overcurrent trip element and the movable contact terminal on both sides of the case partition wall, respectively. An image current transformer comprising a left and right two-pole conductor as a primary conductor, an earth leakage detection circuit that amplifies the secondary output of the image current transformer, and a trip coil unit driven by the output of the earth leakage detection circuit and resisting a return spring to suck the plunger. And a tripping lever comprising a trip lever for moving the armature of the overcurrent trip element or the armature of the first overcurrent trip element to the fixed iron core side in conjunction with the suction operation of the plunger.

The earth leakage breaker is provided so as to slide freely along the case partition wall, and the head is biased by a spring in a direction protruding from the case, and the earth leakage display piece is always caught by a trip lever and the display is held inside the case. In connection with the reset operation of the latch after the earth leakage trip, it is preferable to provide an earth leakage display mechanism comprising a display latch for moving the earth leakage display piece against the spring and rejoining the trip lever.

In the circuit breaker in which the opening / closing spring is disposed between the case partition wall and the movable contactor, the latch receiving the tension of the opening / closing spring between the movable contactor tends to fall toward the half case partition wall. Therefore, the protrusions extending toward the case partition wall are integrally formed on both legs of the fixed iron core of the overcurrent trip element or the first overcurrent trip element, and pressing the latch toward the case partition wall reliably prevents the latch from falling as described above. can do.

Similarly, there is a possibility that the movable contact, which receives the tension of the opening / closing spring, falls between the latches on the case partition wall side and the end of the movable contact side contacts the case partition wall. Therefore, it is advisable to penetrate through the opening opened in the case partition wall between the end portions of the movable contact portions of the movable contactors on both sides of the case partition wall so as to penetrate the connecting pieces fitted at both ends of the movable contact member. By inserting the connecting piece, the connecting contact is prevented from interfering with the left and right movable contacts, so that the movable contact does not come into contact with the case partition wall.

In the movable contact, it is preferable to provide a concave portion for accommodating a lead wire portion (a boundary between the bonded portion and the non-bonded portion) joined to the movable contact at the end of the connecting piece. The lead wire joined to the movable contact by solder or welding is likely to be loosened or disconnected due to stress concentration at the boundary part by repeating the bending by the opening and closing operation of the movable contact. Therefore, by storing the boundary portion at the recessed portion of the connecting piece, the bend of the lead wire is far from the boundary portion, so that the phenomenon of loosening or disconnection at this portion is reduced.

On the other hand, the bimetal of the overcurrent trip element is heated and bent by the overcurrent flowing through itself, and this bending operation is transmitted to the latching amateur through the adjusting screw, but at that time, when the head of the adjusting screw directly contacts the bimetal or the amateur, the bimetal is bypassed. The converter will lose some of the heat needed to bend the bimetal. It is therefore advisable to insert insulation between the head of the adjusting screw between the opposing bimetal or amateur. As a result, generation of the bypass path through the adjustment screw can be prevented.

In the circuit breaker, if the head of the adjusting screw is positioned on the cover side, and the adjusting hole facing the head is provided in the cover, the adjusting screw can be rotated through the adjusting hole with the cover attached, and the tripping characteristic is improved after assembly is completed. If it is necessary to readjust, there is no need to remove the cover.

Further, in the circuit breaker, it is preferable to place a pressing latch facing the side of the latch through a small gap in the vicinity of the toenail, and press the cover with the cover while simultaneously inserting the pressing latch into the case partition wall. The tripping characteristic of the overcurrent trip element is directly affected by the amount of clamping on the claw of the latch on the armature. Therefore, if the claws of the latch are shaken, the tripping characteristic becomes unstable and there is a risk of miss tripping due to vibration during opening and closing. Therefore, by providing a pressing latch for pressing the vicinity of the toenail of the latch with as few gaps as possible, it is possible to prevent the shaking and to stabilize the trip characteristic and to prevent the mis-strip.

However, conventional conventional circuit breakers do not incorporate an alarm switch (a switch for outputting an alarm signal during a trip operation) due to limitations in dimensions. Thus, the present invention enables the built-in alarm switch by arranging the micro switch along the central partition of the case of the I-shaped cross section. That is, an alarm switch made of a micro switch is provided along the case partition wall so as to interlock with the latch, and the alarm switch is fitted into the protrusion formed in the case partition wall to be inserted into the case partition wall and the cover to be fixed.

The following describes an embodiment of the present invention based on FIGS. In addition, the same code | symbol is used for the part corresponding to a conventional example. In FIG. 1, the wiring breaker 1 accommodates a two-pole opening part and one element or two elements of an overcurrent trip element in a main body 2 having a width of 25 mm defined in an agreed type. Here, referring to FIG. 6, the right side is referred to as a first storage space and the left side is referred to as a second storage space with the partition wall 13a interposed therebetween. The first movable contact 17 is stored in the first storage space, and the second movable contact 24 is stored in the second storage space. Moreover, the opening / closing handle 3 protrudes on the front surface of the main body 2, and the power supply side terminals 4 and 11 (first terminal) and the load side terminals 5 and 12 (second terminal) are arranged at both ends. It is making up. This wiring breaker 1 is arranged in a large number inside the distribution board 6 shown in Figs. 2 and 3 to branch off the trunk lines 8 of the main circuit breaker 7. (Opening and closing part) One element (overcurrent trip element) is used, so that the conventional block terminal for the neutral electrode is unnecessary. In addition, two-pole, two-element devices are used in a 200V circuit, so there is no need to make two parallel circuits.

4 to 13 show a circuit breaker constituted by a two-pole single element product.

The circuit breaker is composed of an opening / closing part and an overcurrent trip element in the main body 2 of an insulator made of a mold resin shown in FIG. 1, but the main body 2 is left and right on the case 13 and both sides thereof. It is composed of two pole covers 14 and 15, and each of the storage parts is attached to the case 13, and then pushed on the covers 14 and 15, so that the case 13 and the covers 14 and 15 penetrate from side to side. Tighten with screws not shown.

4 and 5 show an on state, and at the left pole side shown in FIG. 4, the current is connected to the fixed contact 4a, the fixed contact 16, and the movable contact which are integrated therewith at the power supply side terminal 4; (17), the movable contactor 18 bonded thereto, the flexible conductor 19 having one end joined thereto, the bimetal 21 of the overcurrent trip element 20 having the other end joined therewith, and the flexible conductor bonded to one end thereof ( 22) and the other end flows to the joined terminal 5 on the load side. On the other hand, there is no overcurrent trip element on the right side of FIG. 5, and the current is connected to the fixed contact 11a, the fixed contact 23, the movable contact 24, the movable contact 25, and the flexible conductor 26 at the power supply terminal 11. And flows to the load-side terminal 12.

The case 13 is composed of an I-shaped cross section having a partition 13a at the center as shown in FIG. 6, and each terminal 4, 5, 11, 12, which is bent in an L shape, is formed on both sides thereof. It is attached to the groove of the same shape formed. On the left side of the case 13, a flat latch 27 of a resin molded product is disposed along the partition wall 13a with its plate surface being rotatably supported by the case 13 via a pin 28 at the left end of FIG. . A claw 27a protruding laterally is integrally formed at the right end of FIG. 4 of the latch 27, and the claw 27a is engaged with the armature of the overcurrent trip element 20 described later.

The movable contacts 18 and 25 of the two poles of the left pole are formed in the same shape with different left and right sides of the flat conductor and bent to the inside (case 13 side) of the lower end of the figure as shown in FIG. And the movable contacts 17 and 24 are bonded to 25a. The movable contacts 18 and 25 are plated on both sides of the partition 13a along the partition 13a and rotatably connected to the opening and closing handle 3 at an arc-shaped portion formed at the upper end of FIG.

The opening / closing handle 3 of the resin molded article has a pair of left and right pairs of legs 3b on both sides of the base 3 of the handle 3a which protrudes outward of the main body 2, as is apparent from FIG. The opening / closing handle 3 is located on the partition 13a at the leg portion 3b and is rotatably connected to the case 13 via a pin 29. In addition, instead of the pin 29, the projection shaft may be integrally formed inside the covers 14 and 15 (FIG. 7), and the projection shaft may be inserted into the opening / closing handle 3 from both sides to support the opening / closing handle 3. In this case, however, a problem arises in that the opening / closing handle 3 cannot be supported until the covers 14 and 15 are mounted.

The movable contact 18 is also located outside the latch 27.

At the distal end of the leg portion 3b, a concave indentation corresponding to the arc shape of the movable contactors 18 and 25 is formed, and the movable contactors 18 and 25 infiltrate the concave inlet so that the arc shape slides freely and latches. It is connected to the opening / closing handle 3 so as to be rotatable as described above, while being held by the opening / closing spring 30 of the left and right poles, each of which is made up of a tension spring spanning between 27 and 27. Here, the spring contact pieces 18b and 25b are folded and formed in the movable contactors 18 and 25, and the spring latch projections 27b (FIG. 6) are formed in the latch 27 to protrude on both the left and right sides. The spring 30 is hung on both ends thereof in the stretched state. Further, an elongated hole 31 is formed in an arc shape in a portion where the spring engaging projection 27b on the right side side (the left side in FIG. 6) passes through the partition wall 13a.

In FIG. 6, the movable contacts 18 and 25 in which the opening / closing springs 30 are fastened to the spring engaging pieces 18b and 25b are shown at the arrow points in FIG. There is a tendency to fall inwards under the rotational force in the direction, and in some cases, the bent portions 18a and 25a come into contact with the partition 13a to cause abrasion powder or the opening / closing operation is inhibited. Therefore, as shown in FIG. 8, the connecting piece 32 which regulates the space | interval of each other is inserted between the edge parts of the movable contacts 18 and 25. As shown in FIG. The connecting piece 32 of the resin molded article is divided into two sides, as shown in the figure, and one shaft portion 32a penetrates through the triangular window hole 33 drilled through the case partition wall 13a and the other hole portion 32b. ) And integrated as shown in FIG. In addition, since the left and right sides of the connecting piece 32 are pressed inward by the rotational force, they are not separated from each other even without providing a drop preventing means. The connecting piece 32 prevents the planes at both ends from contacting the inner surfaces of the movable contacts 18 and 25 and passes over them, and at the same time, each of the two projections 32c is cut out of the upper and lower portions of the spring engaging pieces 18b and 25b. It is positioned by fitting it.

In Fig. 8, the concave portions 32d are provided at both ends of the connecting piece 32, and the concave portions 32d are joined to each other by soldering to the inner surfaces of the movable contacts 18 and 25. The boundary of 26), that is, the boundary between the joint where the solder is soaked and the non-bonded portion, is stored inside. The boundary portions of the flexible conductors 19 and 26 are likely to be disconnected or loosened by the stress center when the flexible conductors 19 and 26 are repeatedly bent in accordance with the opening and closing movements of the movable contacts 18 and 25. In this case, by storing the boundary portion in the concave portion 32d, the warpage may be separated from the boundary division of the contest of the flexible conductors 19 and 26, thereby preventing the phenomenon such as disconnection or loosening.

4, 7, and the overcurrent trip element 20 is a bimetal 21 in a single shape, a fixed iron core 35 coupled with a rivet 34, and a pin 36 freely at one end. A flat armature 37 which is supported to rotate and whose opposite end portion 37a is opposed to the fixed iron core 35 and is biased to the side opposite to the fixed iron core 35 (counterclockwise in FIG. 7 with pin 36 as the point). It is made of the return spring 38 which consists of twisted spring. The fixed iron core 35 has a c-shaped cross section consisting of a flat substrate 35a having bent ends at two positions and a leg portion 35b which is bent on both sides of the lower end thereof, and has bimetals 21 at both legs 35b. ) In the width direction. A pair of left and right arms are bent at the upper end of the substrate 35a and the armature 37 of the fixed iron core 35, and the pins 36 supporting the armature 37 pass through the arms and pass through the pins 36 The return spring 38 (FIG. 7) attached to the end) is hung on the upper end of the arm 37 at the other end of the arm of the fixed iron core 35.

In FIG. 7, the armature 37 is biased on the opposite side to the fixed iron core 35 by the return spring 38 as described above, but a hook (not shown) is attached to the leg portion 35b of the fixed iron core 35. In combination, it is maintained in a posture parallel to the bimetal 21. In the contact portion 37a of the armature 37, a step 37b is formed on the surface opposite to the fixed iron core 35 by extrusion molding by pressing. In addition, a screw hole 37c (FIG. 9) in which a screw is cut is provided in a burring-processed hole in the tip portion of the amateur 37, and a hole 21a drilled in the bimetal 21 is provided in the screw hole 37c. The head 39a of the adjustment screw 39, which is gently inserted and twisted, faces the bimetal 21 through the gap G (FIG. 7).

In the overcurrent trip element 20 having the above-described configuration, the plate surface of the armature 37 is disposed on the same side as the latch 27 along the case partition wall 13a, and as shown in FIG. 4, at the arm of the fixed iron core 35. Attaching pieces 35c, 35d, and 35e integrally protruding from both ends of the protruding pin 36 and up, down, left, and right sides of the fixed iron core 35 are elastically pressed into the recesses of the case partition 13a and positioned to cover the cover. (14) is pressed and fixed. And the claw 27a of the latch 27 is couple | bonded with the step part 37b of the armature 37 at all times. When the electric current shown by the arrow in FIG. 9 flows through the bimetal 21, the bimetal 21 curves in the left direction of FIG. 7 with the joule row, and approaches the head 39a of the adjustment screw 39. FIG. .

At this time, when the bimetal 21 directly contacts the head 39a, the current path of the bimetal 21-adjusting screw 39-amateur 37-pin 36-fixed core 35-bimetal 21 Is formed so that the current flowing through the bimetal 21 is reduced, and a part of the heat amount necessary for the bending of the bimetal 21 is lost, so that the trip characteristic is affected. Therefore, here, the insulating washer (first insulating material) 40 made of the fluororesin shown in FIG. 9 is mounted under the adjusting screw 39 to insulate the bimetal 21 from the adjusting screw 39. Doing.

When the current flowing through the bimetal 21 becomes an overload state, the curved bimetal 21 pulls the amateur 37 toward the fixed iron core 35 through the adjustment screw 39. As a result, the latch 27 by the armature 37 is released after the passage of time according to the current. In addition, when a large current such as a short-circuit current flows through the bimetal 21, the armature 37 is instantly sucked into the fixed iron core 35 by the c-shaped magnetic path of the fixed iron core 35 and the magnetic flux passing through the armature, thereby latching 27. ), The jam by the amateur 37 is released.

When the latch 27 is released by the armature 37, the wiring breaker trips as described later, but the time (trip characteristic) until the trip after the overcurrent flows is applied to the stepped portion 37b of the armature 37. The amount varies depending on the amount of the claws 27a of the latch 27. On the other hand, the latch 27 supported by the pin 28 at the end opposite to the toenail 27a tends to swing in the horizontal direction due to rattling or temperature creep at the end of the toenail 27a side. Therefore, in order to obtain stable trip characteristics, it is preferable to press the end of the latch 27 formed on the toenail 27a to suppress the shaking in the horizontal direction. Therefore, in the vicinity of the toenail 27a shown in FIG. 10, the pressing latch 45 is provided on the side surface of the latch 27 via a slight gap. The pressurized latch 45 is a resin molded article having a shape shown in FIG. 11 and inserted into a cutout in the cutout 13b formed integrally with the case 13 in the direction of the arrow, and the end portion thereof shown in FIG. The latch 27 is prevented from swaying laterally overlapped with the tip of 27.

The time until the latch 27 is released by the bending of the bimetal 21 is adjusted by turning the adjusting screw 39 to change the gap G. FIG. In order to make this adjustment possible with the cover 14 covered, the cover 14 shown in FIG. 7 rotates the head 39a of the adjustment screw 39 to trip after the circuit breaker 1 is assembled. Can be adjusted. The cover plate 43 shown in FIG. 13 is attached to the adjustment hole 41 through the hook 43a after adjustment. In order to reliably prevent the cover plate 43 from falling off, it is preferable to attach the adhesive sheet 44 such as a main body name plate to the cover 14 from above.

In the on state of FIGS. 4 and 5, the movable contacts 18 and 25 are connected to the opening and closing handles 3 by the tension in the opening and closing spring 30 between the latch 27 and the fourth end. It is pressed against the stationary contactors 4a and 11a by receiving rotational force in the clockwise direction of FIG. In this ON state, the opening / closing handle 3 falls to the right side of FIG. 4 with the pin 29 at the point, and the connecting end of the opening and closing handle 3 of the movable contact 18 and 25 is opened and closed. The rotational force acting on the movable contactors 18 and 25 is reversed in the counterclockwise direction when the action line of 30 passes from the right side to the left side in FIG. 4 so that the movable contactors 18 and 25 are fixed contactors 4a and 11a. (Off operation)

On the other hand, although the latch 27 receives the rotational force in the clockwise direction of FIG. 4 with the pin 28 at the opening and closing spring 30, the claws 27a are coupled to the stepped portion 37b of the armature 37. It is hung in the state shown. However, when the latch is released as described above in the on state, the latch 27 rotates in the clockwise direction of FIG. 4 so that the action line of the opening / closing spring 30 moves with the opening / closing handle 3 of the movable contacts 18 and 25. By moving from the left side to the right side of FIG. 4 of the connecting end, the rotational force is reversed, and the movable contactors 18 and 25 open at the fixed contactors 4a and 11a (trip operation). The reset of the wiring breaker 1 after the trip operation operates the opening / closing handle 3 to lift the latch 27 in a counterclockwise direction in FIG. 4 to engage the latch 27 again with the stepped portion 37b. Do it.

The configuration and operation of the two-pole one-element product are described above, but the configuration and operation of the two-pole two-element product will now be described with reference to FIGS. In the two-pole two-element product, a second overcurrent trip element 46 is added to the right pole side (figure 5) of the two-pole one-element product, and the bimetal 47 is connected between the movable contactor 25 and the load side terminal 12. The lead wire conductors 48 and 49 are connected to each other, and the configuration of the terminals is the same as that of the two-pole one-element product.

The second overcurrent trip element 46 has substantially the same configuration as the first overcurrent trip element 20, but the second return spring 50 shown in FIG. The fixing screw 53 is mounted to bias the fixing core 52 side, and the adjusting screw 53 is inserted through the hole 51a of the armature 51 loosely and twisted into the screw hole (not shown) of the bimetal 47. The adjusting hole 54 is drilled in the cover 15 so that the head of the second adjusting screw 53 comes out. In addition, although the step part which hangs the latch 27 is unnecessary for the 2nd armature 51, the 1st armature 37 can also be used as it is in order to reduce the number of components.

In the above-described second overcurrent trip element 46, the base 52a of the fixed iron core is disposed along the case partition wall 13a at the right pole side, and both ends of the pin 55 and the fixing portion 52b of the fixed iron core 52 are provided. Is inserted into the groove of the case partition wall 13a in the same manner as that of the first overcurrent trip element 20, and is then pressed by the cover 15 to be fixed. And as shown in FIG. 15, between the 1st amateur 37 and the 2nd amateur 51, the transmission member 56 which consists of original materials of a resin molded article is inserted and passed.

The transfer member 56 is inserted into the cylindrical guide hole 57 (see FIG. 5) freely penetrating through the case partition wall 13a and is subjected to the force of the second return spring 50. It is pressed by 51 and is in contact with the first amateur 37.

Here, the spring force of the first return spring 38 is stronger than the second return spring 50, and the first armature 37 is the spring of the second return spring 50 through the transmission member 56. Under the force, the spring is held in the shape of FIG. 15 by the spring force of the first return spring 38 and the latch 27 is fastened through the step portion 37b.

When a large current such as a short circuit current flows to the circuit breaker, the amateurs 37 and 51 of the overcurrent trip elements 20 and 46 shown in Figs. 16 and 16 are generally fixed iron cores 35 and 52 at the same time. Is sucked into the first armature 37 through the transfer member 56, the latch 27 is released and the trip is performed. On the other hand, when the first amateur 37 is sucked in advance, the trip is performed irrespective of the cutting member 56. Further, the curvature of the second bimetal 47 is transmitted to the first amateur 37 through the adjusting screw 53, the amateur 51, and the transmission member 56, and the trip is performed.

FIG. 17 is a left side view with the cover of the earth leakage breaker formed by providing an earth leakage trip element in the circuit breaker of the two-pole two element of FIG. 14, and FIG. 18 is the same right side view. 17 and 18, the earth leakage trip element 60 includes conductors 22 and 49 for connecting the overcurrent trip elements 20 and 46 and the load side terminals 5 and 12, respectively. It is driven by an image leakage transformer 61 serving as a conductor, an earth leakage detection circuit 62 that amplifies the secondary output of the image current transformer 61, and an output of the earth leakage detection circuit 62, and resists a return spring (not shown). A trip for moving the armature 37 of the overcurrent trip element 20 to the fixed iron core 35 side in conjunction with the suction operation of the trip coil unit 64 and the plunger 63, which sucks the plunger 63 (FIG. 17). The lever 65 is comprised.

The conductors 22 and 49 are formed by bending a plate conductor bored in a Z shape, one end of which is soldered to the load side terminals 5 and 12, and the other end to the bimetals 21 and 47 shown in FIG. The welded relay conductor 66 is tightened with a screw 67. In addition, the fixed end of the test circuit contact 68 is inserted between the conductor 22 and the relay conductor 66 and tightened at the same time. The test circuit contact 68 is crimped by the test button 69 shown in FIG. In FIG. 24, the test button 69 with the slit 69a formed into the groove is elastically pushed into the guide hole 70a of the button base 70 so as to be prevented from falling out from the bulge of the tip, and move freely up and down. maintain. The button base 70 is mounted by being inserted into the upper edge of the case partition wall 13a through a pair of attachment legs 70b having a hook at the tip.

FIG. 19 shows the overcurrent trip element 20 or the image current transformer 61 in FIG. 17 to illustrate the earth leakage display mechanism. In FIG. 19, the ground fault display mechanism 71 is composed of a ground fault display piece 72 that is long in the up and down direction of the drawing, and a display latch 73 which is rotatably supported by an axis that protrudes integrally from the case partition wall 13a. . The earth leakage display piece 72 is inserted so as to slide freely in the groove on the left side of the case partition wall 13a, and the display portion 72a of the head portion protrudes into the case 13 by a spring 74 made of a compressed coil spring. (Upward in FIG. 19), the pressure is always caught by the trip lever 65, and the display portion 72a is maintained in the illustrated state located inside the case 13. As shown in FIG. On the other hand, the latch 73 is pressed in the counterclockwise direction in the drawing by a spring (not shown), but is always held in the shape shown by being caught by the reset protrusion 27b of the latch 27, and the tip toenail is short-circuited. In the recessed part 72b. The earth leakage display piece 72 and the display latch 73 are adjacent to the cross-sections of the left and right arms formed by bending the upper ends of the fixed iron cores 35 of the overcurrent trip element 20, so that they are the grooves and the support shafts of the case partition wall 13a. Keep it from going out.

21 is an enlarged cross-sectional view of the main portion along the XXI-XXI line of FIG. In FIG. 21, the trip coil 76 is disposed around the fixed iron core 75 and the plunger 63 facing each other at intervals, and a pressurized trip coil unit having a magnetic path is formed by a door-shaped yoke 77. 64 is fixed to the case partition 13a with the screw which is not shown in figure. The trip lever 65 made of a mold resin is supported to freely rotate to a pair of left and right arms 77a formed by bending the yoke 77 through protrusion shafts integrally formed on both left and right sides thereof.

The upper end portion 65a of the drawing of the trip lever 65 is formed in the shape of a hook, and the earth leakage display piece 72 is pushed upward by the spring 74 described above by engaging the earth leakage display piece 72 with the protrusion 72a. ). In addition, the lower end 65b of the trip lever 65 is opposed to the lower end of the armature 37. The plunger 63 is loosely coupled to the trip lever 65 at the left end of the figure and is pressed in the left direction of the figure by a spring not shown.

In FIG. 17, when an unbalance occurs in the current flowing through the primary conductors 22 and 49 of the left and right poles passing through the image transformer 61 due to the occurrence of a short circuit, an output is generated on the secondary side of the image transformer 61. When the level exceeds a predetermined value, a trip signal is output from the ground fault detecting circuit 62, and the trip coil 76 of the trip coil unit 64 is excited. Thus, the tripping lever 65 shown in FIG. 22 is sucked and rotated in the clockwise direction to move the armature 37 to the fixed core 35 side. As a result, the latch 27 is released, and as shown in FIG. 20, the movable contacts 18 and 25 are opened as described above. At the same time, the latch 73, which is released by the latch lever 65, is released and the latch 73, which releases the latch by the latch 27, rotates counterclockwise to disengage from the earth leakage display piece 72 and cause a short circuit. The display piece 72 protrudes upward by the action of the spring 74 and the display portion 72a protrudes from the case 13 to indicate the occurrence of a short circuit trip. In addition, when the trip is caused by the overcurrent, the display latch 73 is separated from the ground fault display piece 72, but the latch by the trip lever 65 is not released, so that the ground fault trip display is not performed.

When the circuit breaker of FIG. 20 which has been tripped is reset by the operation described above, and the latch 27 is rotated counterclockwise in the drawing, the display latch 73 rotates clockwise and the earth leakage display piece 72 is interlocked therewith. Push down). As a result, the trip lever 65 is again engaged with the ground fault display piece 72, and the reset of the ground fault display mechanism 71 is also performed at the same time. To test the trip operation, the test button 69 is pushed down in FIG. Here, the resistance element 78 is fixed to the lower side of the test circuit contact 68, one terminal thereof is opposed to the free end of the test circuit contact 68, and the other terminal is connected to the right side of the right electrode through a lead wire (not shown). It is connected in the vicinity of the terminal 12 of the vehicle conductor 49. Thus, when the test button 69 is pushed down to bring the test circuit contact 68 into contact with the terminal of the resistance element 78 as the fixed contact, the primary conductors 22 and 49 of the magnetic pole are positioned at the image displacement 61. Short circuit. As a result, an unbalance occurs in the current flowing through each of the primary conductors 22 and 49, and the trip operation is performed.

25 shows a configuration in which the latch 27 is pressed so that it does not come out of the case partition 13a. That is, an arc-shaped projection 35d is integrally formed on the leg portion 35b formed by being bent at both ends of the lower end portion of the fixed iron core 35 of the overcurrent trip element 20. This protrusion 35d is close to the side of the latch 27 as shown, and the latch 27 is bent under the spring force of the opening / closing spring 30 (FIG. 17) to come out of the case partition wall 13a. Press this when

In addition, although the overcurrent trip element is two elements in the above-mentioned embodiment of the earth leakage breaker, it can of course be configured that the overcurrent trip device is one element.

In this case, the fixed iron core 52 (FIG. 18) of the overcurrent trip element 46 on the right side is left as it is, and instead of the bimetal 47, a conductor such as a brass plate is fixed to the brass plate 1 through the relay conductor 66. It is preferable to connect the conductor 49. The movable contact 25 and the brass plate are connected by the flexible conductor 48 as in the case of the two elements.

26 and 27 show a circuit breaker incorporating an alarm switch. In FIG. 26, the alarm switch 78 made of a micro switch is disposed along the case partition wall 13a by fitting two mounting holes for screwing into a projection 79 integrally formed to protrude laterally from the case partition wall 13a. It is. The alarm switch 78 is constrained in a state where the actuator 78a is pushed at the tip of the latch 27 latched by the armature 37 at all times. The lead wire 78c of the alarm switch 76 is pulled out through the groove of the case 13. The alarm switch 78 is sandwiched and fixed between the case partition wall 13a by a cover 14 (FIG. 7) attached to the case 13.

27 shows a trip state. When the overcurrent occurs, the latch 27 is released by the armature 37 and the latch 27 is rotated clockwise in FIG. 27 by the tension of the opening / closing spring 30. As a result, the actuator 78a is pushed away from the latch 27, and the button 78b which is released from the restraints protrudes. As a result, the contact point of the alarm switch 78 is changed and a trip signal is sent out through the lead wire 78c. The circuit breaker of the illustrated configuration can obtain a trip signal by simply adding a standard micro switch, and can also incorporate the alarm switch 78 without changing the 25 mm wide convention dimension by following the case partition wall 13a.

According to the present invention described above, the following effects can be obtained.

(1) Since the switching part and overcurrent trip device of 2 pole 1 element and 2 pole 2 element are all configured within the agreed width type, the block terminal for 100V circuit is unnecessary and 200V circuit can be supported by one wiring breaker. At the same time, the wiring work is simplified. In addition, by installing the earth leakage trip element in the wiring breaker, an earth leakage breaker having a common external dimension with the wiring breaker can be easily configured.

(2) In this case, the left and right poles are separately arranged on both sides of the case having a partition in the center, and the members of the movable contactor or the overcurrent trip element are used as flat plates, and each of these members is placed along the case partition wall. Since the stack is attached on both sides of the bulkhead, the width dimension can be reduced and the insulation between the left and right poles is sufficiently secured.

(3) The two-pole two-element product adds a second overcurrent trip element to the neutral pole side of the one-pole one-element product, and the operation of the second overcurrent trip element transfers the first overcurrent trip element through the transfer member. It is easy to readjust between a 2-pole 2-element and a 2-pole 2-element.

1 is an external perspective view of a circuit breaker showing an embodiment of the present invention.

2 is an internal front view of a distribution panel using the circuit breaker of FIG.

3 is an enlarged view of a portion P of FIG. 2.

4 is a side view of the left electrode side in a state where the cover of the wiring breaker of FIG. 1 is removed.

Fig. 5 is a side view of the right pole side with the cover of the circuit breaker of Fig. 1 composed of a two-pole one-element product removed.

6 is a cross-sectional view taken along the line VI-VI of FIG.

7 is a cross-sectional view taken along the line VII-VII in FIG.

8 is an exploded perspective view of the movable contact portion in FIG.

9 is a schematic enlarged perspective view of the overcurrent trip element in FIG. 4;

FIG. 10 is a side view of the main portion showing a state in which the overcurrent trip element is removed in FIG. 4; FIG.

11 is an enlarged perspective view of the main portion of FIG.

12 is a cross-sectional view taken along the line XII-XII of FIG.

13 is an enlarged view of the main part of FIG.

Fig. 14 is a side view of the right pole side with the cover of the circuit breaker of Fig. 1 configured as a two-pole two-element product removed.

FIG. 15 is a cross-sectional view taken along line XV-XV in FIG.

FIG. 16 is a diagram in which the armature of FIG. 15 is aspirated. FIG.

Fig. 17 is a side view of the left pole side in a state where the cover of the earth leakage breaker showing the embodiment of the present invention is removed;

Fig. 18 is a side view of the right pole side with the same cover of the earth leakage breaker of Fig. 17 removed.

FIG. 19 is a view of some parts of FIG. 17. FIG.

FIG. 20 is a view of part 18 mined.

FIG. 21 is a cross sectional view along line XXI-XXI in FIG. 17; FIG.

22 is a diagram when the trip coil unit of FIG. 17 operates.

FIG. 23 is an exploded perspective view showing a connection configuration of a conductor and a bimetal in FIG. 17; FIG.

24 is an exploded perspective view showing the attachment configuration of the test button in FIG. 17. FIG.

Fig. 25 is a sectional view showing the principal parts of a structure in which a latch is pressed by a fixed iron core of an overcurrent trip element.

Fig. 26 is a side view showing an embodiment in which an alarm switch is incorporated in the wiring breaker of Fig. 4;

FIG. 27 is a view showing a tripped circuit breaker of FIG. 26; FIG.

Fig. 28 is an external perspective view of a circuit breaker showing a conventional example.

29 is an internal front view of a distribution panel using the circuit breaker of FIG. 28;

30 is an enlarged view of a portion Q of FIG. 29;

* Description of the symbols for the main parts of the drawings *

1. Wiring breaker 3. Opening and closing handle

4. Power Side Terminal 5. Load Side Terminal

6. Distribution board 11. Power terminal

12. Load terminal 13. Case

13a. Case bulkhead 14. Cover

15. Cover 18. Movable Contactor

19. Conductor 20. Overcurrent trip element

21.Bimetal 22.Conductor

25. Movable contactor 26. Conductor

27. Latch 27a. toenail

30. Opening spring 32. Connecting piece

35. Iron core 37. Amateur

38. Return spring 39. Adjusting screw

40. Insulation washer 45. Pressurized latch

46. Overcurrent trip element 47. Bimetal

48. Conductor 49. Conductor

50.Return spring 51.Amateur

52. Fixing core 53. Adjusting screw

54. Adjustment hole 56. Transmission member

60. Leakage trip element 61. Current transformer

62. Earth Leakage Detection Circuit 63. Plunger

64. Trip coil unit 65. Trip lever

68. Test circuit contact 69. Test button

71. Earth Leakage Indicator 72. Earth Leakage Indicator

73. Marking latch 75. Fixed iron core

76.Trip Coils 77.York

78. Alarm switch

Claims (17)

A case 13 having a partition 13a at the center and covers 14 and 15 assembled together with the case 13, and having first and second storage spaces on both sides of the partition 13a, respectively. The main body (2) of the insulation of the established width, An opening / closing handle 3 rotatably connected to the case 13, Two-pole movable contactors disposed in the first storage space and the second storage space along the partition 13a, respectively having movable contacts 17 and 24 at one end thereof, and rotatably connected to the opening / closing handle ( 18, 25), Fixed contacts 16 and 23 facing the movable contacts 17 and 24 are attached, and first terminals 4 and 11 are integrally formed, and two-pole fixed contactors are disposed on both sides of one end of the partition wall, respectively. (4a, 11a), An opening and closing mechanism for contacting and separating the movable contactors 17 and 24 from the fixed contactors 4a and 11a by opening and closing the opening and closing handle 13; A first overcurrent trip element disposed in the first accommodating space and detecting an overcurrent, releasing the engagement with the opening / closing mechanism to open and separate the movable contactor 18 contained in the first accommodating space from the fixed contactor from the fixed contact; 20, One terminal 5 disposed on both sides of the other end of the partition 13a and electrically connected to the movable contact 18 disposed in the first storage space via the first overcurrent trip element 20; A circuit breaker having a second terminal (15, 12) having the other terminal (12) electrically connected to a movable contact (25) arranged in a second storage space. The method of claim 1, A second overcurrent disposed in the second storage space and detecting an overcurrent to trip the latch of the opening / closing mechanism to open and separate the movable contact 25 disposed in the second storage space among the movable contacts from the fixed contact; Trip element 46, The transfer member 56 penetrates the partition wall 13a of the main body 21 to connect the first and second overcurrent trip elements, and transfers the operation of the second overcurrent trip element to the first overcurrent trip element. Equipped with The second overcurrent trip element 46 is electrically connected to a movable contact 25 disposed in the second storage space and a terminal 12 connected to the movable contact 25 among the second terminals. Circuit breaker characterized in that. The method of claim 1, The first overcurrent trip element 20 is a c-shape consisting of a first bimetal 21, a first substrate 35a of a plate and two first legs 35b formed on both sides of the first substrate 35a. A first fixed iron core 35 surrounding the first bimetal 21 between both sides of the first leg with a ruler having a cross section of The first armature 37 and the first armature 37 of the plate opposite to the first fixed iron core 35 and the first pole of the other end is rotatably supported at the first fixed iron core A first return spring 38 biasing the opposite side to 35 and configured such that the first amateur 37 is disposed on one side of the partition along the partition 13a, It is provided in the first overcurrent trip element 20 and inserted into the first bimetal 21 and the first amateur 37 to twist the first amateur 37 and the first bimetal 21. And a first adjusting screw 39 having a first head portion 39a facing the first bimetal 21 and the first amateur 37 through a predetermined gap. breaker. The method of claim 2, The second overcurrent trip element 46 has a c-shaped cross section consisting of a second bimetal 47, a flat plate having a second substrate, and two second leg portions formed on both sides of the second substrate. A second fixed iron core 52 surrounding the second bimetal 47 between the second leg portions, parallel to the second bimetal 47 and rotatably supported at one end thereof, and A second recovery spring for urging the second armature 51 and the second armature 51 opposite the second fixed iron core 52 toward the second fixed iron core 52; 50, wherein the second substrate of the second fixed iron core 52 is disposed along the partition 13a on the other side of the partition 13a, Provided in the second overcurrent trip element 46 and inserted into the second bimetal 47 and the second amateur 51 to twist the second amateur 51 and the second bimetal 47. And a second adjusting screw (53) having a second head which faces the second bimetal (47) and the second armature (51) through a predetermined gap. The method according to claim 3 or 4, The opening and closing mechanism is disposed between the case partition wall and the first overcurrent trip element 20 along the partition wall 13a of the case, is rotatably supported by the case at one end and protrudes laterally from the other end. A latch 27 having a projection for hanging the first amateur 37, At least a two-pole opening / closing spring 30, which is disposed between the partition wall 13a and the two-pole movable contacts 18 and 25, and is made of a tension spring spanned between the movable contact and the latch. Circuit breaker, characterized in that. The method of claim 1, On one side of the partition 13a, between one end of the first bimetal 21 of the first overcurrent trip element 20 and the movable contact 18 and the other of the first bimetal 21. First lead wires 19 and 22 connecting between the end and the second terminal 5, respectively; And a second lead wire connected between the other movable contact (25) and the second terminal (12) on the other side of the partition wall. The method of claim 1, A connecting piece which penetrates an opening opened in the case partition wall 13a between the ends of the movable contact sides 17 and 24 of the movable contacts 18 and 25 of the two poles, and both ends thereof are respectively coupled to the ends of the movable contactor ( 32) circuit breaker characterized in that the plug-in. The method of claim 7, wherein One end of the first bimetal 21 of the first overcurrent trip element 20 and the movable contact between the one end of the partition 13a and the other end of the first bimetal and the second terminal The first lead wires 19 and 22 respectively connecting between and A second lead wire 26 for connecting between the movable contact and the second terminal 12 on the other side of the partition wall; And a concave inlet portion (32d) for accommodating a boundary portion between the first and second lead wires joined to the movable contactor at an end of the connecting piece. The method of claim 3, A first insulating material 40 between the first head 39a of the first adjusting screw 39 and the first bimetal 21 facing the first head 39a. Circuit breaker, characterized in that the insertion. The method of claim 4, wherein A second insulating material is inserted between the second head of the second adjusting screw 53 and the second bimetal 47 facing the second head. breaker. The method of claim 3, The first head 39a of the first adjusting screw 39 is positioned on the cover side, and the first adjusting hole 41 facing the first head is provided in the cover. Circuit breaker. The method of claim 4, wherein A circuit breaker characterized by positioning a second head portion of the second adjustment screw (53) on the cover side and providing a second adjustment hole in the cover facing the second head portion. The method of claim 5, A circuit comprising a pressurization latch 45 opposed to the side of the latch 27 through a slight gap in the vicinity of the projection part, fitted into the partition wall, and the pressurization latch 45 being pushed into the cover to fix the circuit. breaker. The method of claim 5, And a stepped portion (37b) for hanging said protrusion on the side of said first amateur (37). The method of claim 5, On both sides of the case partition wall 13a, the first overcurrent trip element 20 and the left and right two-pole conductors 22 or the first and second overcurrents respectively connected between the movable contactor 18 and the terminal 5, respectively. A video current transformer 61 having primary and second bipolar conductors 22 and 49 connected between the trip elements 20 and 46 and the terminals 5 and 12, respectively, and two of the current transformer 61; An earth leakage detection circuit 62 for amplifying the difference output, a trip coil unit 64 driven by the output of the earth leakage detection circuit 62, and sucking the plunger 63 against a return spring; The earth leakage trip element which comprises the trip lever 65 which moves the 1st amateur 37 of the said 1st overcurrent trip element 20 to the fixed iron core 35 side in connection with a suction operation | movement is provided, It is characterized by the above-mentioned. Circuit breaker. The method of claim 15, It is provided to slide freely along the case partition wall 13a, and the display portion 72a of the head portion is pressed by the spring 74 in the direction protruding from the case, and at the same time, the display portion is caught by the trip lever 65 in the case. In response to the reset operation of the ground fault display piece 72 held inside the circuit and the latch after the earth fault trip, the ground fault display piece 72 is moved against the spring 74 and recombined with the trip lever 65. A circuit breaker, comprising: an earth leakage display mechanism comprising a display latch (73). The method of claim 5, The projections 35d extending toward the case partition wall 13a are integrally formed on both legs 35b of the fixed iron core 35 of the first overcurrent trip element 20, and the latches 27 are formed at the projections 35d. The circuit breaker characterized in that it is pushed toward the case partition (13a).

Images