KR20190127165A - Trip Assembly of Molded Case Circuit Breaker - Google Patents

Abstract

The present invention relates to a molded case circuit breaker, and more specifically, to a trip assembly of a molded case circuit breaker. A trip device of a molded case circuit breaker includes a trip part case installed on the load side of the molded case circuit breaker according to an embodiment of the present invention and provided with a plurality of phases; a trip part cover coupled to the upper part of the trip part case; and a crossbar installed inside the trip part case. The crossbar can be disposed between a support part formed on a first partition wall between the phases of the trip part case and the cover part formed on the second partition wall of the trip part cover. It is possible to improve assembly and insulation.

Description

Trip Assembly of Molded Case Circuit Breaker

The present invention relates to a circuit breaker, and more particularly, to a trip assembly of a circuit breaker.

In general, a molded case circuit breaker (MCCB) is an electrical device that protects a circuit and a load by automatically cutting off a circuit in the event of an electrical overload or a short circuit.

The circuit breaker is a terminal part which can be connected to the power supply side or the load side largely, a contact part including a fixed contactor and a movable contactor connected to or separated from the fixed contactor, and opening / closing to move the movable contactor to provide power for opening and closing the circuit. And a trip part for detecting an overcurrent or a short circuit current flowing on a circuit and inducing a trip operation of the opening and closing mechanism, and a arcing part for extinguishing an arc generated when the abnormal current is interrupted.

1 is a longitudinal cross-sectional view of a circuit breaker according to the prior art, and FIG. 2 is a perspective view of a trip assembly. Rotating the fixed contactor (1) and movable contactor (2) for extinguishing or supplying power from the electric line to the load side, and the extinguishing device (3) and the movable contactor (2) for extinguishing the arc in case of accidental current interruption. And an opening / closing mechanism part 4 for enabling electricity supply or interruption of the electric line, and a trip part (trip device, trip assembly) 5 which detects and operates an accident current.

Here, the trip part 5 includes an armature 6, a magnet 7, a crossbar 9, a shooter 10, and a load side provided in the trip part case 11. It comprises a terminal (load terminal or heater) 12, bimetal (14) and the like.

When an accident current (large current) flows into the breaker, specifically, when flowing to the heater 12, an electromagnetic force is generated in the magnet 7 and the magnet 7 attracts the armature 6. At this time, the armature 6 moving in the direction of the magnet 7 pushes the lower protrusion 8 of the crossbar 9, and as a result, the catch of the shooter 10 is released while the crossbar 9 rotates to open and close the mechanism 4. ) Operates to cut off the current.

When an overcurrent (small current) flows through the heater 12, the bimetal 14 coupled to the heater 12 is curved to press the upper protrusion (or the gap adjusting member 13) of the crossbar 9 to crossbar 9. The shooter 10 is released by rotating.

The crossbar 9 of the trip assembly according to the prior art has a through hole formed along the axial direction, and is coupled to the rotating shaft 15 made of a metal member. The rotary shaft 15 is fitted into the shaft hole 16 of the trip part case 11, and the crossbar 9 is rotatable along the rotary shaft 15.

By the way, the trip assembly according to the prior art is formed in such a way that the rotary shaft (pin) is separately assembled to the crossbar body, thereby assembling the crossbar 9 to the rotary shaft 15 while fitting the rotary shaft 15 to the shaft hole 16. It is difficult to assemble and increase assembly time. In addition, since the rotation shaft 15 is made of a metal member, there is a possibility that insulation breakdown occurs with the peripheral components, thereby reducing the insulation performance.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a tripping assembly of a circuit breaker having an integrated rotary bar crossbar and improved assemblability and improved insulation.

A trip part case installed on the load side of the circuit breaker according to an embodiment of the present invention and provided with a plurality of phases; A trip part cover coupled to an upper part of the trip part case; And a cross bar installed inside the trip part case, wherein the cross bar includes a support part formed on a first partition wall between each phase of the trip part case, and a cover part formed on a second partition wall of the trip part cover. It is characterized in that disposed between.

Here, the crossbar is characterized in that it comprises a shaft body consisting of a solid bar of insulating material.

In addition, the first partition wall is composed of a double wall, the support portion is characterized in that provided on any one or more walls of the double wall.

In addition, the support portion is characterized in that composed of a plurality of support plates.

In addition, the support portion of the round shape is formed on the upper portion of the support.

In addition, the lower cover portion is characterized in that the round groove is formed.

In addition, the night needle groove and the cover groove is characterized in that formed larger than the outer diameter of the shaft body of the crossbar.

In addition, the crossbar is characterized in that the gap adjusting portion is provided with a circumferential projection is inserted between the supporting plate.

The circumferential protrusions may be provided in plural numbers spaced apart at predetermined intervals.

According to the trip assembly of the circuit breaker according to the exemplary embodiment of the present invention, the rotating shaft is integrally formed on the crossbar to improve the assemblability.

In addition, since the rotating shaft of the metal material is removed, the insulation performance is improved.

1 is an internal structure diagram of a circuit breaker according to the prior art.
2 is a perspective view of a trip part of a circuit breaker according to the related art.
3 is a diagram illustrating an internal structure of a circuit breaker according to an exemplary embodiment of the present invention.
4 is a perspective view of a trip part of a circuit breaker according to an exemplary embodiment of the present invention. The trip part cover is disassembled.
5 and 6 are perspective views of a trip part case and a crossbar applied to a trip part of a circuit breaker according to an exemplary embodiment of the present invention.
7 and 8 are a partial perspective view and a cutaway perspective view of an inside of a trip part of a circuit breaker according to an exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to explain in detail enough to enable those skilled in the art to easily carry out the invention, and thus the present invention. It is not intended that the technical spirit and scope of the invention be limited.

3 is an internal structural view of a circuit breaker according to an embodiment of the present invention, FIG. 4 is a perspective view of a tripping part of a circuit breaker, and FIGS. 5 and 6 are a perspective view of a trip part case and a crossbar applied to a tripping part of a circuit breaker. 7,8 is an internal partial perspective view and a cutaway perspective view of the trip part of the wiring breaker. The trip assembly of the circuit breaker according to the exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The trip assembly of the circuit breaker according to the exemplary embodiment of the present invention includes a trip part case 40 installed at a load side of the circuit breaker and provided with a plurality of phases; A trip part cover 50 coupled to an upper part of the trip part case 40; And a cross bar 60 installed inside the trip part case 40, wherein the cross bar 60 includes a support part 43 formed on the first partition wall 42 between the images and the trip. It is characterized in that disposed between the cover portion 53 formed in the second partition wall 52 of the secondary cover (50).

The enclosure 20 is formed schematically in a box shape. The enclosure 20 may be made of synthetic resin. Inside the enclosure 20, a contact portion, a terminal portion, an opening / closing mechanism portion, a tripping portion, a arc extinguishing portion and the like are accommodated.

Inside the enclosure 20, a contact portion comprising a fixed contactor 21a, 21b connected to a power source or a load, and a movable contactor 22 for contacting or separating the fixed contactor 21a, 21b to energize or cut off a circuit. It is provided. The movable contact 22 is coupled to the shaft 23 and moves as a mover assembly (or shaft assembly) integrally.

In the case of a double circuit breaker, the fixed contacts 21a and 21b are provided on the power supply side (left side in FIG. 3) and on the load side (right side in FIG. 3), respectively. The fixed contactor 21a provided on the power supply side is connected to the power supply side terminal 71, and the fixed contactor 21b provided on the load side is connected to the load side terminal 72. Here, the fixed contactor 21a may be integrally formed with the terminal 71.

On the other hand, the movable contactor 22 is formed to be able to contact both the power supply side fixed contactor 21a and the load side fixed contactor 21b. For example, the movable contact 22 may be formed symmetrically 180 degrees. Both ends of the movable contact 22 are provided with movable contacts (unsigned), respectively, and are contacted or separated from the fixed contacts (unsigned) of the fixed contacts 21a and 21b. The movable contact 22 is rotatably coupled to the shaft 23 to form a mover assembly (or shaft assembly).

The mover assembly is moved by a switchgear. The opening and closing mechanism includes a handle 25 receiving a user's manipulation force, a handle lever 26 coupled to the handle to rotate about the lever shaft, a main spring 28 coupled to the handle lever 26 and the link shaft 27, An upper link (not shown) and a lower link (not shown) coupled to the upper and lower portions of the link shaft 27, the shaft pin 29 is coupled to the lower link.

The mover assembly is rotated by the power of the opening and closing mechanism by the shaft pin 29. The contact portion and the mover assembly are provided for each phase and the opening and closing mechanism is provided on one phase. The shaft pin 29 moving under the power of the opening and closing mechanism is connected to all phases so that the plurality of phases move together.

A fire extinguishing unit (also called a fire extinguishing device or an arc chute) 30 is provided in the vicinity of the contact portion to extinguish an arc generated when an accident current is interrupted. The extinguishing part 30 is provided in both the contact parts on both sides.

The trip part A is provided on the load side to detect an accident current and perform a trip operation. The trip part A may be provided in an assembly form provided in the trip part case 40.

The trip part A includes a magnet 75, an armature 76, a heater 70, a crossbar 60, a bimetal 78, and the like, which are installed in the trip part case 40.

The trip part case 40 is shown in FIGS. 4 and 5. The trip part case 40 is formed of an insulating material. For example, the trip part case 40 may be made of synthetic resin. The trip part case 40 is formed in a box shape in which the front and top surfaces are opened as a whole (in this specification, the load side is front (front) and the power side is rear (rear)).

The trip part case 40 is provided with a plurality of images. Each phase is partitioned off by the first partition 42. That is, the first partition 42 is provided between each image. For example, in the case of a circuit breaker composed of R, S, T, and N four poles (four phases), three first partition walls 42 are formed between both sidewalls 41 of the trip part case 40. Four receptacles 49 are provided for the four images. Here, the first partition wall 42 may be formed as a double wall. That is, the first partition wall 42 is provided with holes or grooves to increase the inter-phase distance, thereby increasing the insulation performance.

A support portion 43 is formed on the first partition wall 42. The supporting part 43 may be provided in each of the double walls of the first partition wall 42 or any one of the double walls. Although not shown separately, the support 43 may be provided separately from the first partition 42.

The supporting portion 43 is composed of a plurality of supporting plates 43a and 432b (see notation in FIG. 8). As a result, the bearing capacity increases. For example, the supporting portion 43 may be composed of two supporting plates. This will be divided into a first base plate 43a and a second base plate 432b.

A support groove 44 is formed at an upper portion of the support 43. Support groove 44 may be formed in a round shape. The supporting groove 44 may be formed to be the same as or larger than the outer diameter of the crossbar 60. Although not separately illustrated, the support groove 44 may be formed in another polygonal shape such as a right angle groove or a triangular groove. The crossbar 60 is installed in a state where it is placed on the support groove 44. The supporting part 43 supports the crossbar 60. The crossbar 60 may rotate in a state of being installed in the support groove 44.

The supporting portion 43 is provided on any two or more first partitions 42 of the plurality of first partitions 42. For example, in the case of the trip part case 40 consisting of R, S, T, and N phases, the first partition 42 between the R and S phases and the first partition 42 between the T and N phases, respectively, are used. It may be provided.

The rear part of the trip part case 40 is closed to form a closing part 45. The closing part 45 is provided so that the magnet 75 is not exposed when viewed from the rear of the trip part case 40.

The rear of the trip part case 40 has a terminal hole 46 through which the trip part terminal 73 of the heater 70 can be exposed. The terminal hole 46 is formed above the closure 45. The trip part terminal 73 of the heater 70 is exposed through the terminal hole 46.

The terminal cover part 47 that surrounds the trip part terminal 73 is protruded from the rear part of the trip part case 40. The terminal cover part 47 may be formed to surround the top and side surfaces of the trip part terminal 73. In other words, the terminal cover portion 47 is formed in the form of a box with a lower surface opened. The lower surface of the terminal cover portion 47 is opened so that the lower surface of the trip portion terminal 73 can contact the load side fixed contactor 21a. The terminal cover part 47 may be integrally formed with the trip part case 40. The terminal cover part 47 may be formed of the same insulating material as the trip part case 40. Since the upper and side surfaces of the trip part terminal 73 are covered by the terminal cover part 47, the insulation performance of the trip part A is further improved.

The shooter 79 is provided at an upper portion of the rear part of the trip part case 40. The shooter 79 is in a state of being restrained by the crossbar 60, and activates the opening and closing mechanism when the restraint of the crossbar 60 is released.

The trip part cover 50 is provided. The trip part cover 50 is formed in a box shape having an open bottom surface and is coupled to an upper part of the trip part case 40.

The second partition wall 52 is formed in the trip part cover 50. The cover 53 is provided on the second partition wall 52. The second partition wall 52 and the cover part 53 may be integrally formed. The cover 53 is formed with a cover groove 54. The cover groove 54 may be formed in a round shape. The cover groove 54 may be formed to be the same as or larger than the outer diameter of the crossbar 60.

The operation part support plate 51 for installing operation mechanisms, such as the knob 55, is provided in the trip part cover 50. As shown in FIG.

The trip part cover 50 is provided with a knob 55 for adjusting the distance from the bimetal 78. The knob 55 is provided on the operation unit support plate 51 so that the head part is exposed to the upper surface of the trip part cover 50. The lower part of the knob 55 is provided with an adjuster 56 is formed eccentric (biased). When the knob 55 rotates, the adjuster 56 rotates about a predetermined radius about the axis of the knob 55.

The crossbar 60 is provided. The crossbar 60 is provided in the form of a solid bar, that is, a shaft hole is not formed. The length of the crossbar 60 is formed shorter than the distance between both side walls 41. Accordingly, the crossbar 60 is movable left and right between both side walls 41.

The crossbar 60 has an axial body 61. The shaft body 61 may be formed in a circular shaft. The shaft body 61 is installed in such a way as to be mounted on the support groove 44 of the support portion 43.

The upper pressing portion 62 protrudes upward from the shaft body 61 of the crossbar 60. When the bimetal 78 is in contact with the upper pressing portion 62, the upper pressing portion 62 rotates and the shaft body 61 rotates accordingly. The upper pressing portion 62 is formed with a fastening hole 63 to which the gap adjusting member 69 can be coupled.

The lower pressing portion 64 protrudes downward from the shaft body 61 of the crossbar 60. When the armature 76 is in contact with the lower pressing portion 64, the lower pressing portion 64 is rotated and thus the shaft body 61 is rotated.

The center portion of the crossbar 60 is provided with a restraint portion 65. The restraint 65 restrains the shooter 79 in the steady state. When the crossbar 60 rotates in the clockwise direction, the restraint part 65 releases the restraint on the shooter 79 so that the opening and closing mechanism part operates.

A shaft connecting portion 61 of the crossbar 60 is provided with a knob connecting portion 67. The knob connecting portion 67 is a portion into which the adjuster 56 of the knob 55 is fitted. The knob connection 67 may be composed of a pair of protrusions. The adjuster 56 of the knob 55 is sandwiched between the pair of protrusions. When the knob 55 is rotated, the adjuster 56 rotates to a predetermined radius, and the adjuster 56 is fitted to the knob connecting portion 67 to move the knob connecting portion 67. At this time, since the shaft body 61 is caught in the support groove 44 of the support 43, the shaft body 61 may not move in the front-rear direction but may move only in the left-right direction. That is, as the knob 55 moves, the knob connecting portion 67 moves left and right, and the crossbar 60 moves left and right accordingly. When the crossbar 60 moves, the upper press part 62 and the gap adjusting member 69 move, so that the gap between the head of the bimetal 78 changes. The head of the bimetal 78 is formed in a triangular cross section so that the distance to the crossbar 60 is different for each part.

The gap adjusting unit 66 is protruded from the crossbar 60. The gap adjusting unit 66 may be configured of a plurality of circumferential protrusions protruding in an arc shape along the circumferential surface of the shaft body 61. Here, a plurality of circumferential protrusions are provided. The gap adjusting part 66 is fitted to the supporting part 43 of the crossbar 60. In one example, a circumferential protrusion of the gap adjusting part 66 is fitted between the first base plate 43a and the second base plate 43b. Accordingly, the crossbar 60 does not move from side to side unless the special external force is applied to maintain a fixed position.

If the user manipulates the knob 55 to apply a force to the knob connecting portion 67 and the circumferential protrusion inserted between the first supporting plate 43a and the second supporting plate 43b is out of the supporting portion 43, the crossbar 60 ) Moves left or right along the axial direction.

According to the trip assembly of the circuit breaker according to the exemplary embodiment of the present invention, the rotating shaft is integrally formed on the crossbar to improve the assemblability. That is, the crossbar 60 is composed of a solid bar without a hollow hole and is disposed in a state where the crossbar 60 is placed on the base 43 of the trip part case 40. The crossbar 60 is rotatable while being supported between the support part 43 of the trip part case 40 and the cover part 53 of the trip part cover 50.

In addition, since the rotating shaft of the metal material is removed, the insulation performance is improved. The crossbar 60 is made of an insulating material such as a synthetic resin, and thus does not cause dielectric breakdown with peripheral components, thereby improving insulation performance.

Embodiments described above are embodiments for implementing the present invention, and those skilled in the art may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

20 Enclosure 21 Fixed Contact
21a, 21b fixed contactor 22 movable contactor
23 shafts with 25 handles
26 Handle lever 27 Link shaft
28 spring 29 shaft pin
30 SOHO 40 trip part case
41 side wall 42 first partition wall
43 Base 43a, 432b First & Second Base Plate
44 Supporting groove 45 Closure
46 Terminal hole 47 Terminal cover
49 Receptacle 50 Trip cover
51 Control panel support plate 52 Second bulkhead
53 Cover part 54 Cover groove
55 knob 56 adjuster
60 crossbar 61 shaft body
62 Upper press section 63 Tightening hole
64 Lower presser 65 Constraints
66 Spacing section 67 Knob connection
69 Spacing member 70 Heater
71 Power terminal 72 Load side terminal
73 Trip Terminal Terminal 75 Magnet
76 Amateur 78 Bimetal
79 Shooter

Claims (9)

A trip part case provided on the load side of the circuit breaker and provided with a plurality of phases;
A trip part cover coupled to an upper part of the trip part case;
And a crossbar installed inside the trip part case.
And the crossbar is disposed between a support portion formed on the first partition wall between the respective phases of the trip part case and a cover part formed on the second partition wall of the trip part cover. The tripping device of a circuit breaker according to claim 1, wherein the crossbar includes an axis body formed of a solid bar of insulating material. The circuit breaker tripping device according to claim 1, wherein the first partition wall is formed of a double wall, and the support part is provided on at least one wall of the double wall. The tripping device of a circuit breaker according to claim 1, wherein the support part comprises a plurality of support plates. The tripping device of a circuit breaker according to claim 2, wherein a round support groove is formed at an upper portion of the support portion. The tripping device of a circuit breaker according to claim 5, wherein a round groove is formed in a lower portion of the cover part. The circuit breaker tripping device according to claim 6, wherein the support groove and the cover groove are formed larger than the outer diameter of the shaft body. The tripping device of a circuit breaker according to claim 4, wherein the crossbar is provided with a gap adjusting part configured with a circumferential protrusion fitted between the support plates. The tripping device of a circuit breaker according to claim 8, wherein the circumferential protrusion is provided in plural numbers spaced apart at predetermined intervals.

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