KR101624440B1 - Circuit breaker - Google Patents

Abstract

In order to obtain a circuit breaker in which a permanent magnet for driving an arc at the time of interruption is not exposed to high heat of an arc, the present invention is characterized by comprising a base 11 and a power source side terminal 24 A stationary contactor 27 having a stationary contact 21 and a movable contact 23 having a movable contact 22 to be brought into contact with the stationary contact 21, An SOHO device 50 that extinguishes an arc generated between the fixed contact 21 and the movable contact 22 and a permanent magnet 54 provided on the power source side terminal 24 side of the SOHO device 50 will be.

Description

Circuit breaker {CIRCUIT BREAKER}

The present invention relates to a circuit breaker capable of increasing an arc drive force by a permanent magnet.

In the case of a circuit breaker using a circuit breaker for AC electric circuit and a DC electric circuit for a DC electric circuit, it is difficult to block a high voltage because AC current does not have a current zero point.

As for the energization current in a large current region (for example, rated current exceeding 100 A), an arc voltage increase due to an increase in the number of arc extinguishing plates, ) The driving force for driving the arc to the soho plate side by the increase of the magnetic driving force by the reduction of the resistance and the arrangement of the insulating member for generating the gas of the smallness around the arc and the pressure gradient of the gas, , It is possible to increase the rated voltage of the direct current and increase the voltage without using the permanent magnet.

However, since the electric current is small and the gas driving force by the pressure gradient of the gas and the magnetic driving force by the above-mentioned small-sized plate is small, the permanent electric current (for example, It is general to arrange the magnets on both sides near the both contacts and to drive the arc at the time of interruption by the magnetic force of the permanent magnet using the Fleming's law toward the grid of the SOHO device.

In order to prevent the permanent magnet from being exposed to a high temperature by the arc, it is also known to cover the permanent magnet with a resin (for example, refer to Patent Document 1).

Patent Document 1: JP-A-2011-129385

As described above, in the conventional circuit breaker, the arc is driven by disposing the permanent magnet in the vicinity of the two contacts. However, since the driving direction of the arc and the driving force are largely changed due to the deviation of the arrangement of the permanent magnets, It is necessary to consider opening and closing durability (hereinafter referred to as " electrification endurance performance "). As described in the international standard (IEC60947-2), the electrification durability performance needs to satisfy 1500 times or more according to the energizing current. In the case where the permanent magnets are disposed on the left and right sides near the two contacts, The residual magnetic flux density does not completely coincide with each other, so that the driving force pulled by the permanent magnet is larger than the driving force by the Fleming's law. In this state, the arc is attracted in the direction of the permanent magnet, and the resin covering the magnet may be destroyed depending on the number of opening and closing. When this resin is broken, the permanent magnet is exposed to the high heat of the arc, And there is a problem that the blocking performance may be deteriorated.

An object of the present invention is to provide a circuit breaker in which a permanent magnet for driving an arc at the time of interruption is not exposed to a high temperature of an arc.

A circuit breaker according to the present invention includes: a base; an external terminal arranged on the base with an interval therebetween; a fixed contact connected to the external terminal, the fixed contact having a fixed contact; A movable contact having a movable contact which is provided between the positive and negative contacts and between the positive and negative contacts and between the positive and negative contacts and which extinguishes an arc generated between the positive and negative contacts, And a permanent magnet provided on the side of the external terminal of the SOHO device and having a magnetic pole on the side of the external terminal and the SOHO device.

According to the present invention, since the permanent magnets for driving the arcs generated between the two contact points are provided on the side of the external terminals of the SOH apparatus, the permanent magnets are not exposed to the high heat of the arc, .

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a longitudinal sectional view showing the entire configuration of a circuit breaker according to Embodiment 1 of the present invention. FIG.
2 is an enlarged perspective view showing the SOHO apparatus of FIG.
3 is a side enlarged view showing the SOHO apparatus of FIG.
4 is a view showing a line of magnetic force passing through the SOHO apparatus of FIG.
5 is a view showing the circuit breaker and the external wiring of the circuit breaker according to the first embodiment of the present invention.
6 is a view showing the circuit breaker and the external wiring of the circuit breaker according to the second embodiment of the present invention.
7 is a view showing an external wiring when the circuit breaker according to the third embodiment of the present invention and the circuit breaker are used in a DC electric circuit.
8 is a view showing a magnetic line of force that passes through the loop apparatus of the circuit breaker according to the fourth embodiment of the present invention.
9 is a diagram showing an external wiring when the circuit breaker and the circuit breaker in the fourth embodiment of the present invention are used in a DC electric circuit.
10 is a view showing an external wiring when the circuit breaker and the circuit breaker in the fifth embodiment of the present invention are used in a DC electric circuit.
11 is a diagram showing an external wiring when the circuit breaker according to the sixth embodiment of the present invention and the circuit breaker are used in a DC electric circuit.
12 is an enlarged view of a longitudinal section showing the sohbo plate according to the seventh embodiment.
13 is a perspective view showing the soffal plate of the seventh embodiment.

Embodiment 1

Fig. 1 is a vertical cross-sectional view showing an overall configuration of a circuit breaker according to a first embodiment of the present invention, Fig. 2 is an enlarged perspective view showing the extinguisher of Fig. 1, Fig. 3 is a side enlarged view of the extinguisher of Fig. Fig. 5 is a diagram showing a bipolar (pole) circuit breaker in the first embodiment and an external wiring in the case where the circuit breaker is used in a dc electric circuit. Fig.

As shown in Fig. 1, a circuit breaker 101 is constituted by using a case 10 composed of a base 11 and a cover 12 formed of an insulating material. A circuit breaker unit 20 as many as the number of poles is arranged on the base 11 with a gap therebetween and a well known toggle link mechanism The opening / closing mechanism portion 30 is disposed. The cover 12 covers the circuit breaker unit 20 and the opening and closing mechanism 30 on each pole on the base 11 and the operating handle 31 of the opening and closing mechanism 30 (Window hole) 12a of the handle 12 of the cover 12. As shown in Fig.

The circuit breaker units 20 of the respective poles are configured to have the same structure and the crossbars 32 are common to the circuit breaker units 20 of the respective poles, Is disposed on the base (11) so as to be orthogonal to the circuit breaker unit (20). The crossbar 32 is rotated by its opening and closing mechanism portion 30 about its axis and each movable contact 23 of each circuit breaker unit 20 Respectively. The respective movable contacts 23 of the circuit breaker units 20 of the respective poles are rotated at the same time when the cross bar 32 is rotated around the axis thereof and by the rotation of the movable contacts 23, The movable contact 22 is brought into contact with and separated from the stationary contact 21. The opening and closing mechanism unit 30 is composed of a known toggle link mechanism and has a known trip bar 33 driven by a tripping device 40.

The circuit breaker unit 20 of each pole includes a power source side terminal 24 provided on the base 11, a fixed contact 21 provided on a fixed contactor 27 extending from the power source side terminal 24, A movable contact 22 which is brought into contact with the fixed contact 21, a movable contact 23 which is provided at one end of the movable contact 22 and is rotatably held by the crossbar 32, A tripping device 40 connected to the contactor 23 via a movable contact holder 26 and a load side terminal 25 extending from the tripping device 40 and a fixed contact 27 And an SOH apparatus 50 provided in the vicinity of the both contacts 21 and 22 for extinguishing an arc generated between the two contacts 21 and 22. The stationary contact 21 and the movable contact 22 constitute an open / close contact for opening and closing an electric circuit. When the movable contact 22 comes into contact with the fixed contact 21, the electric circuit between the terminals 24 and 25 is turned on. When the movable contact 22 is separated from the fixed contact 21, The electric circuit between the terminals 24 and 25 is turned off. At this time, the arc generated between the movable contact 22 and the stationary contact 21 is extinguished by the SOH apparatus 50. The "external terminal" described in the claims is the power source side terminal 24 described above.

As shown in FIGS. 2 to 4, a plurality of grid plates 51 and an uppermost grid plate 52, which are magnetic steel plates constituting the SOH apparatus 50, Shaped notch 51a is provided on one side. By using a plurality of grid plates 51 and a single uppermost grid plate 52 and sandwiching the grid plates 52 at predetermined intervals with support plates 53a and 53b made of an insulating material The SOHO device 50 is configured. The SOH apparatus 50 is installed such that the U-shaped notch 51a of the grid plate 51 and the uppermost grid plate 52 faces the fixed contact 21 and the movable contact 22, And the movable contactor 23 rotates in a space formed by the U-shaped notch 51a. The uppermost grid plate 52 is provided with a bent portion 52a so that the arc can easily flow from the movable contact 23.

An insulating member 55 made of a resin that generates a small gas is provided in the vicinity of the contacts 21 and 22 and the SOH apparatus 50. [ 3, the permanent magnet 54 is held by the insulating member 55 at the bottom of the power source side terminal 24 side of the SOH apparatus 50, and the permanent magnet 54 is covered by the insulating member 55, As shown in FIG. The permanent magnets 54 are arranged such that their magnetic poles are on the power source side terminal 24 and the SOHO device 50 side. In the present embodiment, as shown in Fig. 4, the side of the power source side terminal 24 is the N pole and the side of the SOH apparatus 50 is the S pole. This is because, on the side of the power source side terminal 24, The N pole may be provided on the side of the magnet 50. [ In the same circuit breaker, the polarity of the magnetic poles of the permanent magnets 54 may be different for each of the circuit breaker units 20.

Next, the breaking operation of the circuit breaker 101 will be described.

When the current exceeding a predetermined value flows into the interrupting unit 20, the tripping device 40 rotates and pushes the trip bar 33, so that the opening / closing mechanism 30 is driven to rotate the movable contact 23. The movable contact 22 is detached from the fixed contact 21 by the rotation of the movable contact 23. When the movable contact 22 is dropped, an arc due to the flowing current tries to keep the shortest distance between the fixed contact 21 and the movable contact 22.

At this time, when the energization current is in a large current region (for example, the rated current exceeds 100 A), the arc is guided by the grid plate 51 to form a plurality of grids The magnetic flux passing through the U-shaped notch 51a of the plate 51 is radiated to the inside of the space formed by the U-shaped notches 51a of the plurality of grid plates 51 24) in order to drive the arc magnetically. In addition, a high-temperature arc generates a low-pressure gas generated from the insulating member 55, and the arc is driven toward the small-diameter plate 51 by the gas driving force by the pressure gradient. The arc moved to the small plate 51 side is divided into a short arc between the grid plates 51 by the plurality of grid plates 51 to cause a voltage drop and the arc voltage for maintaining the arc is raised, When the voltage is higher than the power supply voltage, the arc is extinguished.

On the other hand, when the energizing current is in a small current region (for example, the rated current is 100 A or less), the gas driving force due to the magnetic driving force by the arc and the pressure gradient of the gas is weak, And the arc continues to flow through the space between them. Therefore, the arc driving force is assisted by the magnetic force of the permanent magnet 54 provided in the vicinity of the SOH apparatus 50.

Hereinafter, the arc driving force by the permanent magnet 54 will be described.

The permanent magnet 54 is held by the insulating member 55 near the arc runner 27a of the stationary contactor 27 and on the power source side terminal 24 side of the SOH apparatus 50, (Magnetic poles) are disposed on the power source side terminal 24 and the SOHO device 50 side. 4, the magnetic line of force 54a coming out of the N pole of the permanent magnet 54 once comes out of the permanent magnet 54 toward the power source side terminal 24, Passes through the U-shaped notch 51a of the yoke plate 51 and passes through the route returning to the S-pole of the permanent magnet 54. As a result,

In this case, since the direction of the magnetic line of force 54a is bent in a direction perpendicular to the arranging direction from the arranging direction of the shielding unit 20 in the vicinity of the two contacts 21 and 22, Arc is driven in the direction of the leg 51b of the small board 51, not in the current flowing direction. That is, when the arc current flows from the fixed contact point 21 to the movable contact point 22, it is driven in the direction of the lower leg 51b (the direction of A in Fig. 4) Is driven in the direction of the upper leg 51b from the paper surface of Fig. 4 when the movable contact 22 flows from the movable contact 22 to the fixed contact 21. [

The arc driven toward the leg 51b is divided into a short arc between the grid plates 51 by the plurality of grid plates 51 to cause a voltage drop so that the arc voltage for maintaining the arc is raised, When the voltage becomes higher than the power supply voltage, the arc disappears.

Next, the connection of the DC electric circuit 60 and the load 61 when the circuit breaker 101 is used in the DC electric circuit will be described. The DC circuit 60 is connected to the power supply side terminals 24a and 24b and the load 61 is connected to the load side terminals 25a and 25b, respectively, since the circuit breaker 101 is a two- It is all right to connect to the network. 5, the positive (positive) side of the DC electric circuit 60 is connected to the power source side terminal 24a and the negative (negative) side of the DC electric circuit 60 is connected to the power source side terminal 24b However, it does not matter.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, the permanent magnets 54 Is not exposed to the high heat of the arc, and the deterioration of the breaking performance can be prevented.

In the conventional circuit breaker in which the permanent magnet is disposed in the vicinity of the contact point, since the permanent magnet is set so as to form a magnetic field in a direction to drive the arc toward the yoke plate, (Polarity) indication is required. For example, when the power supply side of the right pole is +, the magnetic field is a magnetic field in the right direction with the power source side of the product facing up. In the case where the left pole is negative, Magnetic field), and the polarity (polarity) assembling direction of the magnet is different by the right and left poles. However, since the permanent magnet 54 is disposed such that the magnetic pole thereof is on the side of the power source side terminal 24 and the SOH apparatus 50, it is necessary to consider the polarity of the permanent magnet 54 at the time of assembling And it is possible to prevent a problem caused by the number of assembling mistakes.

Since the permanent magnets 54 are arranged so as to have magnetic poles on the side of the power source side terminal 24 and the side of the SOH apparatus 50, it is possible to use not only the DC circuit but also the AC electric circuit .

Embodiment 2 Fig.

6 is a diagram showing a three-pole circuit breaker and an external wiring in the case where the circuit breaker is used in a DC electric circuit according to the second embodiment of the present invention.

Although Embodiment 1 is an example of a bipolar (circuit) circuit breaker, the present embodiment is different from Embodiment 1 in that three circuit breaker units 20 similar to those in Embodiment 1 are used to constitute a three-pole circuit breaker 102 will be. Since the circuit breaker unit 20 is the same as that of the first embodiment, a description thereof will be omitted.

The positive side of the DC electric circuit 60 is connected to the power source side terminal 24a and the positive side of the DC electric circuit 60 is connected to the power source side terminal 24c as shown in Fig. 6 when the circuit breaker 102 is used for the dc electric circuit And the load side terminal 25a and the power source side terminal 24b are connected to each other. The load 61 connects the positive side to the load side terminal 25b and the negative side to the load side terminal 25c.

When used in a three-wire AC electric circuit, power may be supplied to each of the power source side terminals 24a, 24b, and 24c, and a load may be connected to each of the load side terminals 25a, 25b, and 25c.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, the permanent magnets 54 Is not exposed to the high heat of the arc, and the deterioration of the breaking performance can be prevented.

Since the permanent magnets 54 are disposed such that their magnetic poles are on the power source side terminals 24 and the SOH apparatus 50 side, it is necessary to consider the polarity of the permanent magnets 54 at the time of assembly And it is possible to prevent a problem caused by the number of assembling mistakes.

Since the permanent magnet 54 is arranged so as to have magnetic poles on the terminal 24 and the SOH apparatus 50 side, it is possible to use not only a DC circuit but also an AC circuit Can be used.

When the circuit breaker 102 is applied to a dc electric circuit, it can be applied to a dc electric circuit of a higher voltage by means of a wiring whose current is cut off at three points as shown in Fig.

Embodiment 3:

Fig. 7 is a diagram showing a wiring in the case where the four-pole circuit breaker and the circuit breaker in the third embodiment of the present invention are used in a dc electric circuit. Fig.

Although Embodiment 1 is an example of a circuit breaker with two poles and Embodiment 2 is a circuit breaker with three poles, this embodiment uses four circuit breaker units 20, which are the same as Embodiment 1, Pole circuit breaker 103 is constructed. Since the circuit breaker unit 20 is the same as that of the first embodiment, a description thereof will be omitted.

The positive side of the DC electric circuit 60 is connected to the power source side terminal 24a and the positive side of the DC electric circuit 60 is connected to the power source side terminal 24d as shown in Fig. The load side terminal 25a and the power source side terminal 24b are connected to each other and the load side terminal 25d and the power source side terminal 24c are connected to each other. The load 61 connects the positive side to the load side terminal 25b and the negative side to the load side terminal 25c.

In addition, when used in a three-phase (four-wire) AC electric circuit, a power source (power source) is connected to each power source side terminal 24 and a load (load) is connected to each load side terminal 25.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, It is not exposed to the high temperature of the arc, and deterioration of the breaking performance can be prevented.

Since the permanent magnets 54 are disposed such that their magnetic poles are on the power source side terminals 24 and the SOH apparatus 50 side, it is necessary to consider the polarity of the permanent magnets 54 at the time of assembly And it is possible to prevent a problem caused by the number of assembling mistakes.

Since the permanent magnet 54 is arranged so as to have magnetic poles on the terminal 24 and the SOH apparatus 50 side, it is possible to use not only a DC circuit but also an AC circuit Can be used.

In addition, when the circuit breaker 103 is applied to a DC electric circuit, it can be applied to a DC electric circuit of a higher voltage by means of a wiring whose current is cut off at four points as shown in FIG.

Embodiment 4.

Fig. 8 is a view showing magnetic force lines of the SOHO apparatus 50 according to the fourth embodiment of the present invention. Fig. 9 is a schematic view showing a case where the bipolar (pole) circuit breaker in the fourth embodiment and the circuit breaker Fig.

In the present embodiment, it is intended to further increase the arc length and to further increase the voltage, which is specialized for a DC electric circuit.

8, the permanent magnets 54 are held so as to be covered by the insulating member 55 and arranged so as to have magnetic poles in the array direction of the power source side terminals 24, ) Are arranged such that the N pole and the S pole drive the arc in the direction of the SOHO device. That is, the magnetic lines of force 54b coming out of the N pole of the permanent magnet 54 come out to the right from the power source side terminal 24 on the ground surface side of the Fig. 8 toward the both contacts 21, 22, Passes through the U-shaped notch 51a of the small board 51 and enters into the leg 51b2 on the opposite side from the leg 51b1 , Passes through the leg 51b2 and passes through the route returning to the S pole of the permanent magnet 54. [ The rest of the configuration is the same as that of the first embodiment, and a description thereof will be omitted.

In this case, the direction of the magnetic line of force 54b is the arrangement direction of the shielding unit 20 in the U-shaped notch 51a. Therefore, when the direction of the magnetic pole (pole) (The direction of B in Fig. 8) of the notch 51a. The arc driven toward the small plate 51 is divided into a short arc between the grid plates 51 by a plurality of grid plates 51 to cause a voltage drop and an arc voltage for raising the arc is raised, When the arc voltage becomes higher than the power supply voltage, the arc disappears.

Next, the external connection of the two-pole (pole) circuit breaker 104 and the directions of the magnetic poles of the permanent magnets 54 of the respective poles will be described.

The positive side of the DC electric circuit 60 is connected to the power source side terminal 24a and the negative side of the DC electric circuit 60 is connected to the power source side terminal 24b respectively, The positive side of the load 61 is connected to the load side terminal 25a and the negative side of the load 61 is connected to the load side terminal 25b.

In the case of this connection, the pole in which the current flows in the order of the power source side terminal 24a, the fixed contact 21, the movable contact 22, and the load side terminal 25a in this order is the load side terminal The arc is driven inward of the U-shaped notch 51a when the permanent magnets 54 are arranged so that the N pole is on the left side and the S pole is on the right side as viewed from the power source side terminal 24a. On the other hand, the current flowing from the load side terminal 25b to the movable contact 22 to the stationary contact 21 to the power source side terminal 24b flows from the load side terminal 25b to the power source side terminal 24b to the right side, When the permanent magnet 54b is arranged so as to be the S pole on the left side and the pole on the left side, the arc is driven inward of the U-shaped notch 51a.

The rest of the configuration is the same as that of the first embodiment, and a description thereof will be omitted.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, the permanent magnets 54 Is not exposed to the high heat of the arc, and the deterioration of the breaking performance can be prevented.

The permanent magnet 54 has a magnetic pole in the arrangement direction of the power source side terminal 24 and the N pole and the S pole of the permanent magnet 54 are connected to each other through the arc to the SOH apparatus 50 and the power source side terminal 24 Direction, the arc length can be further elongated and the breaking performance can be improved.

Embodiment 5:

10 is a view showing a wiring in the case of using a three-pole (pole) circuit breaker and the circuit breaker in the fifth embodiment in a DC electric circuit.

Although the fourth embodiment is an example of a bipolar (pole) circuit breaker, the present embodiment is different from the fourth embodiment in that three circuit breaker units 20 similar to those of the fourth embodiment are used to constitute a three-pole circuit breaker 105 will be.

The external connection of the circuit breaker 105 and the directions of the magnetic poles of the permanent magnets 54 at the respective poles will be described.

The positive side of the DC electric circuit 60 is connected to the power source side terminal 24a and the negative side of the DC electric circuit 60 is connected to the power source side terminal 24c respectively, Further, the load side terminal 25a and the power source side terminal 24b are connected. The load 61 connects the positive side to the load side terminal 25b and the negative side to the load side terminal 25c.

In the case of this connection, the poles flowing in this order of the energizing current in the order of the power supply side terminal 24a, the fixed contact 21, the movable contact 22, and the load side terminal 25a are the same as the load side terminal When the permanent magnets 54a are arranged so as to be N poles on the left side and S poles on the right side from the side of the power source side terminal 24a from the side of the power source side terminal 24a, the arc is driven inward of the U-shaped notch 51a. The center pole of the energized current flowing from the power source side terminal 24b to the fixed contact 21 to the movable contact 22 to the load side terminal 25b is a distance from the load side terminal 25b to the power source side terminal 24b side , The permanent magnet 54b is arranged so as to be the N pole on the left side and the S pole on the right side, and the arc is driven inward of the U-shaped notch 51a. The pole in which the energizing current flows in the order of the load side terminal 25c → the movable contact 22 → the fixed contact 21 → the power source side terminal 24c is the side from the load side terminal 25c to the power source side terminal 24c When the permanent magnets 54c are arranged so as to be N poles on the right side of the bore and S poles on the left side of the bore, the arc is driven inward of the U-shaped notch 51a.

The rest of the configuration is the same as that of the fourth embodiment, and a description thereof will be omitted.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, the permanent magnets 54 Is not exposed to the high heat of the arc, and the deterioration of the breaking performance can be prevented.

The permanent magnet 54 has a magnetic pole in the arrangement direction of the power source side terminal 24 and the N pole and the S pole of the permanent magnet 54 are connected to each other through the arc to the SOH apparatus 50 and the power source side terminal 24 Direction, the arc length can be further elongated and the breaking performance can be improved.

Further, the present invention can be applied to a DC electric circuit of a higher voltage by means of a wiring whose current is cut off at three points as shown in Fig.

Embodiment 6:

11 is a view showing a wiring in the case where the four-pole circuit breaker and the circuit breaker in the sixth embodiment are used in a DC electric circuit.

Embodiment 4 is an example of a circuit breaker with two poles and Embodiment 5 is a three-pole circuit breaker. In this embodiment, four circuit breaker units 20, which are the same as those of Embodiment 4, Pole circuit breaker 106 as shown in FIG.

The external connection of the circuit breaker 106 and the directions of the magnetic poles of the permanent magnets 54 at the respective poles will be described.

The positive side of the DC electric circuit 60 is connected to the power source side terminal 24a and the negative side of the DC electric circuit 60 is connected to the power source side terminal 24d respectively, The load side terminal 25a and the power source side terminal 24b are connected to each other and the load side terminal 25d and the power source side terminal 24c are connected. The load 61 connects the positive side to the load side terminal 25b and the negative side to the load side terminal 25c.

In the case of this connection, the pole in which the current flows in the order of the power source side terminal 24a, the fixed contact 21, the movable contact 22, and the load side terminal 25a in this order is the load side terminal When the permanent magnets 54a are arranged so as to be N poles on the left side and S poles on the right side from the side of the power source side terminal 24a from the side of the power source side terminal 24a, the arc is driven inward of the U-shaped notch 51a. The polarity of the current flowing from the power source side terminal 24b to the fixed contact 21 to the movable contact 22 to the load side terminal 25b can be determined by looking at the side of the load side terminal 25b to the side of the power source side terminal 24b When the permanent magnets 54b are disposed so as to have the N pole on the left side and the S pole on the right side, the arc is driven inward of the U-shaped notch 51a. The pole in which the energizing current flows in the order of the load side terminal 25c → the movable contact 22 → the fixed contact 21 → the power source side terminal 24c is the side from the load side terminal 25c to the power source side terminal 24c side And the permanent magnet 54c is arranged so as to be the N pole on the right side and the S pole on the left side, the arc is driven inward of the U-shaped notch 51a. The pole in which the energizing current flows in the order of the load side terminal 25d → the movable contact point 22 → the fixed contact point 21 → the power source side terminal 24d flows from the load side terminal 25d to the power source side terminal 24d side And the permanent magnet 54c is arranged so as to be the N pole on the right side and the S pole on the left side, the arc is driven inward of the U-shaped notch 51a.

The rest of the configuration is the same as that of the fourth embodiment, and a description thereof will be omitted.

According to the present embodiment, since the permanent magnets 54 for driving the arcs generated between the two contact points 21 and 22 are provided near the SOH apparatus 50 and on the side of the power source side terminal 24, the permanent magnets 54 Is not exposed to the high heat of the arc, and the deterioration of the breaking performance can be prevented.

The permanent magnet 54 has a magnetic pole in the arrangement direction of the power source side terminal 24 and the N pole and the S pole of the permanent magnet 54 are connected to each other through the arc to the SOH apparatus 50 and the power source side terminal 24 Direction, the arc length can be further elongated and the breaking performance can be improved.

Further, the present invention can be applied to a DC electric circuit of a higher voltage by means of a wiring whose current is cut off at four points as shown in Fig.

Embodiment 7:

12 is an enlarged view of a longitudinal section showing an SOHO apparatus in the seventh embodiment, and Fig. 13 is a perspective view showing the SOHO apparatus in Fig.

In the circuit breaker according to the first to sixth embodiments, the permanent magnets 54 are provided at the lower portion of the SOH apparatus 50. Therefore, This is weak. Therefore, there is a problem that the upper part of the arc is difficult to be driven toward the grid plate 51. [

In this embodiment, in the SOHO apparatus 50 of Embodiments 1 to 6, as shown in Figs. 12 and 13, by using the property that the arc is likely to turn into a convex shape, The small board 52 is provided with the convex portion 52a1 which protrudes in the direction of the movable contact 23 on the bent portion 52a.

The rest of the configuration is the same as those of the first to sixth embodiments, and a description thereof will be omitted.

According to the present embodiment, since the convex portion 52a1 protruding in the direction of the movable contact 23 is provided in the bent portion 52a of the uppermost arc board 52, The arc can be easily commutated to the arc portion 52a1 and the upper portion of the arc can be quickly driven toward the arc plate 51 to improve the breaking performance.

10: Case 11: Base
12: Cover 21: Fixed contact
22: movable contact 23: movable contact
24: Power side terminal 25: Load side terminal
27: fixed contactor 40: tripping device
50: SOHO apparatus 51: SOHO plate
52: Plate at the uppermost stage 54: permanent magnet
55: Insulation member 101: Circuit breaker

Claims (5)

A movable contact having a base, an external terminal arranged on the base with an interval therebetween, a fixed contact connected to the external terminal, the fixed contact having a fixed contact, and the movable contact coming into contact with the fixed contact, An SOHO device which is provided between the positive and negative contacts and between the positive and negative terminals and extinguishes an arc generated between the positive and negative contacts, And a permanent magnet provided on the side of the external terminal of the permanent magnet and having a magnetic pole on an external terminal and on the side of the extinguisher. The method according to claim 1,
Characterized in that the uppermost arc-shaped plate constituting the SOH apparatus has a convex portion protruding in the direction of the movable contact. The method according to claim 1 or 2,
Characterized in that the permanent magnet is held by a material which generates a low-temperature gas when brought into contact with an arc generated when the circuit breaker is cut off. A movable contact having a base, an external terminal arranged on the base with an interval therebetween, a fixed contact connected to the external terminal, the fixed contact having a fixed contact, and the movable contact coming into contact with the fixed contact, and, and the amount of contact and a neighborhood of the fixed contact also extinguishing device to the positive contact and is provided on a bowl of the said external terminal, wherein the amount Lo (消弧) an arc (arc) occurs between the contact and the extinguishing And a permanent magnet provided on the side of the external terminal of the device,
The arc extinguishing plate at the uppermost stage constituting the SOH apparatus has a convex portion protruding in the direction of the movable contact,
Wherein the permanent magnets are held by a material which generates a low-temperature gas when brought into contact with an arc generated when the circuit breaker is cut off. The method of claim 4,
Wherein the permanent magnet has a magnetic pole in an array direction of the external terminals, and the magnetic pole is arranged such that the N pole and the S pole drive the arc in the direction of the SOHO device.

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