KR20200009589A - Trip Unit of Miniature Circuit Breaker - Google Patents

Abstract

The present invention relates to a miniature circuit breaker with the delay characteristics in shutdown operation and, more specifically, to a trip unit of a miniature circuit breaker. According to one embodiment of the present invention, the trip unit of the miniature circuit breaker comprises: a bobbin having a hollow unit; a coil circled on an outer circumferential surface of the bobbin; a fixed core fixed and installed at one side of the bobbin; a movable core installed to be slidable in the bobbin and in contact with or separated from the fixed core; a moving plate provided between the fixed core and the movable core; a first spring provided between the movable core and the moving plate; and a second spring provided between the moving plate and the fixed core.

Description

Trip unit of miniature circuit breaker

The present invention relates to a small circuit breaker, and more particularly to a trip mechanism of the small circuit breaker.

In general, a circuit breaker (simply a circuit breaker) is an electric device installed on a part of a transmission / transmission line or an electric circuit to protect an electric facility and a load by cutting off a circuit in the event of an opening or closing of a load or a short circuit.

Among these, a small circuit breaker (small circuit breaker) is installed in a small distribution panel forming a low voltage circuit (15 to 30 A) of AC 110 / 220V and used for overcurrent protection and short circuit protection. Small circuit breaker is a switch for home, shopping mall, office, department store, etc., and is used as a device that can conveniently open and close multiple loads in one place. In addition, it is also used for opening and closing the power supply of the machine tool, factory facilities and the like.

Small circuit breaker is a contact part composed of fixed contact point and movable contact point, open / close mechanism part for opening / closing contact point, detector part for detecting abnormal current, open / close mechanism part for abnormal current such as over current or short circuit current. It consists of a trip part which protects a line and a load by opening a circuit, and a fire part which functions to extinguish and cool down the arc generated at the time of interruption.

In Fig. 1 a miniature circuit breaker according to the prior art is shown. The conventional miniature circuit breaker transmits the rotational force of the handle (2) to the movable contactor (4) to maintain the insulation from the outside and to fix and support the position of each part, the handle (2) for operating the mechanism part, and the handle (2). At the same time, a latch 3 holding a fixed state, a movable contactor 4 fixed to the latch 3 to regulate the flow of electricity, and a terminal portion 6 connected to a power source or a load. On the other hand, a trip mechanism (coil assembly) 10 is provided to trip the movable contactor 4 when overcurrent and short-circuit current occur.

The operation of the breaker is as follows. When the handle 2 is rotated counterclockwise, the movable contactor 4 connected to the latch 3 rotates to contact the fixed contactor 5 so that the circuit is energized.

The trip mechanism is shown in FIG. The trip mechanism is also called a trip assembly or coil assembly.

The coil assembly 10 includes a yoke 11 fixed to the case 1, a cylindrical bobbin 12, a coil 13 pivoted on an outer circumferential surface of the bobbin 12, and a fixed core fixed to one side of the bobbin 12. 14, a movable core 15 slidably installed on the other side of the bobbin 12, an actuating lever 16 coupled to the movable core 15 to trip the movable contactor 4, and a fixed core 14 ) And a spring (not shown) provided between the movable core 15 and the like.

If an overcurrent or an accident current occurs in the energized circuit, the current is not applied to the coil assembly 10, and the movable core 15 inside the coil assembly 10 is fixed by the magnetic force generated by the coil assembly 10. Inhaled toward (14).

As the movable core 15 moves, the movable core 15 moves in the direction of the fixed core 14 while overcoming the elastic force of the spring (not shown) inside the bobbin 12, and the actuating lever 16 moves the movable contactor 4. Push to break the circuit.

By the way, in the tripping mechanism of the circuit breaker according to the prior art, it is impossible to set a time delay at the time of breaking operation due to the simple fixed core, movable core, and spring configuration as described above. In other words, the blocking operation has a fixed set value. Accordingly, it is impossible to adjust the blocking order when using a plurality of breakers.

The present invention has been made to solve the above problems, and an object thereof is to provide a tripping mechanism of a small circuit breaker having a delay characteristic in the breaking operation.

Trip mechanism of the small circuit breaker according to an embodiment of the present invention is a bobbin having a hollow; A coil pivoted on an outer circumferential surface of the bobbin; A fixed core fixedly installed at one side of the bobbin; A movable core slidably installed in the bobbin and in contact with or separated from the fixed core; A moving plate provided between the fixed core and the movable core; A first spring provided between the movable core and the movable plate; And a second spring provided between the movable plate and the fixed core.

Here, the stepped portion is formed on the inner peripheral surface of the bobbin, characterized in that the moving plate in contact with the stepped portion in the normal state.

In addition, the stepped portion is characterized in that the diameter is wider in the direction in which the fixed core is installed, the diameter is narrower in the direction in which the movable core is installed.

In addition, the bobbin is divided into a first moving part and a second moving part based on the stepped part, and the moving plate moves in the first moving part.

The inner diameter of the first moving part may be larger than that of the second moving part.

In addition, the diameter of the second spring is characterized in that the larger than the diameter of the first spring.

In addition, the movable core is characterized in that the movable lever for pushing the movable contactor installed outside the fixed core is coupled.

In addition, the fixed core and the moving plate is characterized in that the first through hole and the second through hole through which the movable lever is formed.

The elastic modulus of the first spring is set smaller than the elastic modulus of the second spring.

According to the tripping mechanism of the circuit breaker according to the embodiment of the present invention, at the first current value, the movable core wins (compresses) the first spring and moves in the direction of the fixed core, and the second current is larger than the first current value. Even the second spring wins (compresses) and moves the value, breaking the circuit. In this process, since a time delay by the first spring (or a time delay due to the operation of the movable core near the first current value) occurs, the user can set the range of the action time during the instantaneous trip.

In other words, the user can set the first current value at which the breaker delays time without the blocking action taking place. Here, the user may set the time delay range through mutual setting of the first current value and the second current value.

In addition, by using the time delay characteristics it is possible to set the operation order of the circuit breaker in the place where a plurality of circuit breakers are installed.

1 is an interior view of a miniature circuit breaker according to the prior art.
FIG. 2 is a front view of the trip assembly in FIG. 1. FIG.
3 and 4 are internal views of a small circuit breaker according to an embodiment of the present invention. 3 shows an energized state and FIG. 4 shows an open state, respectively.
5 is a cross-sectional view of the trip assembly in FIG. 3.
6 is a perspective view of the movable plate in FIG. 5.
7 to 9 are functional diagrams of the trip assembly.

In the following, 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 one of ordinary skill in the art to easily practice the invention, It does not mean that the technical spirit and scope of the invention are limited.

With reference to the drawings will be described in detail the opening and closing mechanism of the small circuit breaker according to an embodiment of the present invention. 3 and 4 are internal views of a small circuit breaker according to an embodiment of the present invention. 3 shows an energized state and FIG. 4 shows an open state, respectively.

Opening and closing mechanism of the small circuit breaker according to an embodiment of the present invention comprises a bobbin (42) having a hollow; A coil 45 pivoting on an outer circumferential surface of the bobbin 42; A fixed core 50 fixedly installed at one side of the bobbin 42; A movable core 55 slidably installed in the bobbin 42 to contact or separate from the fixed core 50; A moving plate 65 provided between the fixed core 50 and the movable core 55; A first spring 70 provided between the movable core 55 and the movable plate 65; And a second spring 75 provided between the movable plate 65 and the fixed core 50.

The case 20 forms an external shape of the circuit breaker, and the terminal portion 21, the opening and closing mechanism portion 25, the contact portions 28 and 29, the detector mechanism portion 30, the tripping mechanism portion 40, the arc extinguishing portion 35, and the like. It is formed to be built. The case 20 may be separated into two or more so that components can be assembled and installed therein. The case 20 may be formed of an insulator such as a synthetic resin for insulation from the outside.

The terminal portions 21 are provided on both sides of the case 20, respectively. One terminal portion 21 is connected to the power supply, the other terminal portion 21 is connected to the load.

The opening and closing mechanism 25 is provided to connect or disconnect the contact portions 28 and 29 of the circuit by a user's operation. The opening and closing mechanism 25 includes a handle 26, a latch 24, and a rotation shaft 27 protruding from the outside of the case 20.

When the user operates the handle 26 clockwise in the open state as shown in FIG. 4, the opening and closing mechanism 25 is rotated clockwise around the rotation shaft 27 such that the movable contactor 28 is connected to the fixed contactor 29. Contact (see FIG. 3). As a result, the circuit is energized.

On the contrary, when the user operates the handle 26 counterclockwise in the energized state as shown in FIG. 3, the opening / closing mechanism 25 is rotated counterclockwise about the rotation shaft 27 to fix the movable contact 28. It is separated from the contact 29 (see FIG. 4). As a result, the circuit is opened.

The detector mechanism 30 includes a bimetal 31. When the bimetal 31 is bent by detecting the overcurrent in the detector sphere 30, the opening and closing mechanism 25 is operated so that the movable contact 28 is separated from the fixed contact 29 and the circuit is opened.

The arc extinguishing unit 35 extinguishes the arc generated at the time of blocking. The arc extinguishing part 35 includes a plurality of grids 37 spaced apart at predetermined intervals from the side plate 36. The arc generated at the contact points 28 and 29 at the time of interruption is attracted and divided into the grid 37, and is cooled while the current decreases and disappears. An arc runner 38 may be provided to guide the arc from the contact portions 28, 29 to the arc extinguishing portion 35.

The trip mechanism part 40 is also called instantaneous trip device or trip assembly or coil assembly. The trip mechanism 40 is applied to overcurrent and short-circuit current trips, whereas the detector mechanism 30 is applied to overcurrent trips.

Reference is further made to FIG. 5. The trip mechanism 40 includes the yoke 41, the bobbin 42, the coil 45, the fixed core 50, the movable core 55, the movable lever 60, the movable plate 65, and the first spring 70. ), And a second spring 75.

The yoke 41 is fixed to the case 20. The yoke 41 supports the bobbin 42. The yoke 41 functions as part of the circuit and also as part of the magnetic path. One side of the yoke 41 is connected to the terminal 22, and the other side of the yoke 41 is connected to the fixed contactor 29.

The bobbin 42 is installed in the case 20. The bobbin 42 is supported by the yoke 41. The bobbin 42 may be formed in a pipe shape having a hollow part therein. Both ends of the bobbin 42 may be flanged.

The bobbin 42 is formed with a stepped portion 43 on the inner side. The stepped portion 43 has a wide diameter in the direction in which the fixed core 50 is installed, and a narrow diameter in the direction in which the movable core 55 is provided. That is, the bobbin 42 is divided into a first moving part 42a and a second moving part 42b based on the stepped part 43. In this case, the first moving part 42a may be disposed on the load side (right side in the drawing), and the second moving part 42b may be disposed on the power side (left side in the drawing). Here, the inner diameter of the first moving part 42a is larger than the inner diameter of the second moving part 42b.

The moving plate 65 is provided on the stepped portion 43. The step part 43 sets a limit of movement of the moving plate 65. The moving plate 65 moves in the first moving part 42a.

The fixed core 50 is fixedly installed at one side (direction in which the movable contactor is installed, load side) of the bobbin 42. The fixed core 50 is preferably formed of a metal member such that a magnetic field is advantageously formed. The fixed core 50 is formed with a first through hole 51 so that the movable lever 60 can be inserted therein.

The movable core 55 is provided in the other side (power supply side) of the bobbin 42 so that sliding (or linear movement) is possible. The movable core 55 is preferably formed of a metal member such that a magnetic field is advantageously formed.

The movable lever 60 is fixed to the movable core 55. The movable lever 60 may be formed in the form of a pin. The head of the movable lever 60 is fixedly installed in the insertion groove of the movable core 55. The leg of the movable lever 60 is inserted into the second through hole 66 of the movable plate 65 and the first through hole 51 of the fixed core 50 to be disposed toward the movable contact 28.

The movable lever 60 moves with the movable core 55. The movable lever 60 pushes the movable contactor 28 to cut off the circuit. The movable lever 60 is installed through the fixed core 50 and the moving plate 65. The movable lever 60 may be integrally formed with the movable core 55.

The moving plate 65 is installed to move linearly inside the bobbin 42. The moving plate 65 moves between the stepped portion 43 and the fixed core 50. That is, the moving plate 65 moves in the first moving part 42a. A second through hole 66 is formed in the moving plate 65 so that the movable lever 60 can be inserted. The moving plate 65 is provided with a first spring 70 on one surface and a second spring 75 on the other surface to receive a force.

The moving plate 65 is formed in the form of a flange. The second spring 75 is attached to the flange portion 67 of the moving plate 65.

The first spring 70 is installed between the movable core 55 and the moving plate 65. The moving plate 65 is subjected to a force directed to the fixed core 50 by the first spring 70.

The second spring 75 is installed between the fixed core 50 and the moving plate 65. The moving plate receives the force directed to the movable core 55 by the second spring 75. The second spring 75 may have a larger diameter than the first spring 70.

The first spring 70 and the second spring 75 may have different elastic modulus (or spring constant). That is, the first spring 70 may have a smaller spring constant than the second spring 75. That is, the elastic force of the first spring 70 may be set smaller than the elastic force of the second spring 75.

The operation of the tripping mechanism of the small circuit breaker according to an embodiment of the present invention will be described.

7 is an energized state. The current flows from the power supply side terminal 22 to the load side via the yoke 41, the fixed contactor 29, and the movable contactor 28. The movable lever 60 is in a state of being separated from the fixed core 50 together with the movable core 55. The moving plate 65 is in contact with the step portion 43 by the elastic force of the second spring 75. The movable core 55 is in a state as far as possible from the fixed core 50 by the first spring 70.

When overcurrent occurs in the circuit, a magnetic field is generated in the coil 45 and the fixed core 50 is magnetized. Therefore, a suction force for sucking the movable core 55 is generated in the fixed core 50.

When an overcurrent exceeding a first current value (these values are set values, for example, eight times the rated current) flows through the circuit, the movable core 55 overcomes the elastic force of the first spring 70 (first spring). And then move in the direction of the fixed core 50. However, this first current value is not a force to overcome the elastic force of the second spring (75). Therefore, as shown in FIG. 8, the movable core 55 and the movable lever 60 move in the direction of the fixed core 50, but do not touch the movable contact 28. The circuit remains energized.

When an overcurrent exceeding a second current value (these values are set values, for example, 12 times the rated current) flows through the circuit, the movable core 55 causes the elastic force of the first spring 70 and the second spring 75 to flow. ) And to move in the direction of the fixed core 50 (compresses the first and second springs). Here, the second current value is larger than the first current value. Accordingly, as shown in FIG. 9, the movable core 55, the movable lever 60, and the movable plate 65 move in the direction of the fixed core 50, and the movable lever 60 pushes the movable contactor 28 to block the circuit. do. At this time, the moving plate 65 is in contact with or close to the fixed core 50.

According to the tripping mechanism of the circuit breaker according to the embodiment of the present invention, at the first current value, the movable core wins (compresses) the first spring and moves in the direction of the fixed core, and the second current is larger than the first current value. Even the second spring wins (compresses) and moves the value, breaking the circuit. In this process, since a time delay by the first spring (or a time delay due to the operation of the movable core near the first current value) occurs, the user can set the range of the action time during the instantaneous trip.

In other words, the user can set the first current value at which the breaker delays time without the blocking action taking place. Here, the user may set the time delay range through mutual setting of the first current value and the second current value.

In addition, by using the time delay characteristics it is possible to set the operation order of the circuit breaker in the place where a plurality of circuit breakers are installed.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, all such modifications and modifications being attached It is obvious that the claims belong to the claims.

20 Case 21 Terminal Block
22 terminal 24 latch
25 Handle 26 Handle
27 Rotary shaft 28 Movable contactor
29 Fixed contactor 30 Detector section
31 Bimetal 35 Arc Soho
36 shroud 37 grid
38 arc runner 40 trip mechanism
41 York 42 Bobbin
42a first moving part 42b second moving part
43 Step 45 Coil
50 Fixed core 51 First through hole
55 movable core 60 movable lever
65 Moving Plate 66 Second Through Hole
67 Flange 70 First spring
75 2nd spring

Claims (9)

Bobbins having hollow parts;
A coil pivoted on an outer circumferential surface of the bobbin;
A fixed core fixedly installed at one side of the bobbin;
A movable core slidably installed in the bobbin to be in contact with or separated from the fixed core;
A moving plate provided between the fixed core and the movable core;
A first spring provided between the movable core and the movable plate; And
And a second spring provided between the moving plate and the fixed core. The tripping mechanism of claim 1, wherein a stepped portion is formed on an inner circumferential surface of the bobbin, and the moving plate is in contact with the stepped portion in a normal state. The tripping mechanism of claim 2, wherein the stepped portion has a wider diameter in a direction in which the fixed core is installed, and a smaller diameter in a direction in which the movable core is installed. The tripping mechanism of claim 2, wherein the bobbin is divided into a first moving part and a second moving part based on the stepped part, and the moving plate moves within the first moving part. The tripping mechanism of the miniature breaker according to claim 4, wherein an inner diameter of the first moving part is larger than an inner diameter of the second moving part. The trip mechanism of claim 1, wherein a diameter of the second spring is larger than a diameter of the first spring. The tripping mechanism of the miniature breaker according to claim 1, wherein the movable core is coupled with a movable lever for pushing the movable contactor installed outside the fixed core. The tripping mechanism of the miniature breaker according to claim 7, wherein the fixed core and the moving plate are formed with first and second through holes, respectively, through which the movable lever penetrates. The tripping mechanism of claim 1, wherein the elastic modulus of the first spring is set smaller than the elastic modulus of the second spring.

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