CN218351400U

CN218351400U - Circuit breaker

Info

Publication number: CN218351400U
Application number: CN202222498964.6U
Authority: CN
Inventors: 邱广庭; 张海燕; 许瑞祥; 李�杰
Original assignee: Eaton Huineng Low Voltage Electrical Appliances Jiangsu Co ltd
Current assignee: Eaton Huineng Low Voltage Electrical Appliances Jiangsu Co ltd
Priority date: 2022-09-21
Filing date: 2022-09-21
Publication date: 2023-01-20
Anticipated expiration: 2032-09-21

Abstract

The utility model discloses a circuit breaker, including contact system, insulator arrangement and arc control device, the contact system includes pivot, moving contact and static contact, and the moving contact is fixed mounting in the pivot, drives the moving contact rotation through the pivot, realizes the contact and the separation of moving contact and static contact; the arc extinguishing device comprises a connecting plate, an equipotential connecting line, an upper arc striking plate, a lower arc striking plate and an arc extinguishing grid group; the upper arc striking sheet is connected with the connecting plate through an equipotential connecting line, the connecting plate is connected with the moving contact through flexible connection, and the upper arc striking sheet and the moving contact are equipotential; one end of the lower arc striking piece is fixedly connected with the fixed contact, and the other end of the lower arc striking piece is fixedly connected with the insulating device; the arc-extinguishing grid group is fixedly installed on the insulating device, and the upper arc striking plate and the lower arc striking plate are embedded in the middle concave part of the arc-extinguishing grid group. This scheme can shift the electric arc that the separating brake produced, concentrates the arc extinguishing again, and the arc extinguishing ability obtains very big promotion.

Description

Circuit breaker

Technical Field

The utility model relates to a circuit breaker, concretely relates to circuit breaker.

Background

When fault current occurs in an electric power system, a tripping system of the circuit breaker unlocks an original mechanism, drives a rotating shaft system to rotate, and finally separates a movable contact from a fixed contact, when the voltage in the system exceeds 12-20V, the cut-off current exceeds 0.25-1A, and an air medium between the movable contact and the fixed contact is broken down to form electric arcs. If the arc cannot be extinguished quickly, the contact surface is burnt and high-temperature ionic gas is generated to damage the shell of the circuit breaker, and the internal pressure of the arc extinguish chamber is increased to cause the high-temperature gas to flow out of the shell of the circuit breaker, so that the health of equipment around the circuit breaker and workers around the circuit breaker is influenced. In particular, the arc contains metal ions, which easily causes short-circuiting of electrical equipment or conductive parts around the circuit breaker. Based on the condition of above circuit breaker, for the arc extinguishing performance that increases the circuit breaker, electric arc is generally extinguished to current circuit breaker through arc extinguishing bars group, and the concrete mode is that guide electric arc gets into arc extinguishing chambers bars group, cuts into several short arcs with electric arc through arc extinguishing bars piece to this improves arc voltage, reaches the purpose of extinguishing electric arc, but this scheme has the difficult problem of electric arc transfer, in addition, still has arc extinguishing bars piece in small quantity and arc extinguishing bars piece group utilization inefficiency.

Therefore, how to improve the arc extinguishing performance of the circuit breaker is very important, and the quality of the arc extinguishing performance of the circuit breaker can directly influence the breaking capacity of the circuit breaker on fault current, the electric service life of the circuit breaker and the electric performance characteristics of the circuit breaker. In order to improve the breaking capacity and the breaking reliability of the circuit breaker, the utility model discloses carry out optimal design to the arc extinguishing system.

SUMMERY OF THE UTILITY MODEL

Utility model purpose: an object of the utility model is to provide a circuit breaker can shift the electric arc that the separating brake produced, concentrates the arc extinguishing again, and the arc extinguishing ability obtains very big promotion.

The technical scheme is as follows: the utility model comprises a contact system, an insulating device and an arc extinguishing device, wherein the contact system comprises a rotating shaft, a moving contact and a static contact, the moving contact is fixedly arranged in the rotating shaft and is driven by the rotating shaft to move so as to realize the contact and separation of the moving contact and the static contact; the arc extinguishing device comprises a connecting plate, an equipotential connecting wire, an upper arc striking plate, a lower arc striking plate and an arc extinguishing grid group; the upper arc striking sheet is connected with the connecting plate through an equipotential connecting line, the connecting plate is connected with the moving contact through flexible connection, and the upper arc striking sheet and the moving contact are equipotential; one end of the lower arc striking piece is fixedly connected with the fixed contact, and the other end of the lower arc striking piece is fixedly connected with the insulating device; the arc-extinguishing grid group is fixedly installed on the insulating device, and the upper arc striking plate and the lower arc striking plate are embedded in the middle concave part of the arc-extinguishing grid group.

An arc striking groove is formed in the middle of each of the upper arc striking plate and the lower arc striking plate, and the width of each arc striking groove is 1-2 times of the thickness of the corresponding arc striking plate, so that electric arcs can fully enter the arc extinguishing grid group, and the arc extinguishing capacity of the arc extinguishing grid group is improved.

The arc-extinguishing grid group comprises a first arc-extinguishing grid group, a second arc-extinguishing grid group, a third arc-extinguishing grid group, a fourth arc-extinguishing grid group, a left arc-isolating wall and a right arc-isolating wall; first arc extinguishing grid piece group, second arc extinguishing grid piece group, third arc extinguishing grid piece group, fourth arc extinguishing grid piece group transverse arrangement in proper order, at the whole both sides installation left side flash barrier wall and right flash barrier wall that a plurality of grid piece groups are constituteed, arc extinguishing grid piece group transverse placement can be in limited circuit breaker volume, increase arc extinguishing grid piece quantity as much as possible, and arc extinguishing grid piece quantity increase will divide into more short arcs the produced electric arc of breaking fault current, can improve arc voltage, increases arc extinguishing device's ability of extinguishing electric arc.

The arc-extinguishing grid group also comprises a left gas-generating piece and a right gas-generating piece, and the first barrier rib of the left gas-generating piece is inserted into the gap of the arc-extinguishing grid group; and the second barrier rib of the right gas generating piece is inserted into the gap of the arc extinguishing grid group. When electric arcs are generated, the left gas generating piece and the right gas generating piece are eroded by the electric arcs to generate gas, so that the gas pressure in the cavity of the arc extinguish chamber is increased to form gas blowing, the electric arcs can enter the arc extinguish grating group conveniently, and meanwhile, the electric arc plasma beams are blown by high-speed gas flow, and the electric arcs can be cooled conveniently.

The movable contact is provided with a movable silver point at the position contacted with the fixed contact, and the fixed contact is provided with a fixed silver point corresponding to the movable silver point, so that the conductive capacity of the loop can be improved, the use frequency of the conductor is increased, and the contact effect is improved.

The insulation device comprises a first insulation piece and a second insulation piece; the first insulating part is provided with a groove and a first boss, the first insulating part is arranged in a groove between the left gas generating part and the right gas generating part through the groove, and the first boss is inserted into the corresponding groove of the base for splicing; and a second boss is arranged on the second insulating part, and the second insulating part is inserted into the corresponding groove of the base through the second boss for splicing. The first insulating part is mainly used for providing insulation between the static contact and the arc extinguishing device, and the second insulating part is mainly used for providing insulation between the connecting plate screw and the arc extinguishing device.

The insulation device comprises a third insulation piece, a fourth insulation piece and a fifth insulation piece; the third insulating piece is fixed on the base through a plurality of holes and is used for providing insulation between the rotating shaft and the arc extinguishing device; the fourth insulating part is arranged on a hole of the moving contact through a rivet and is used for providing insulation between the rotating shaft and the arc extinguishing device when the moving contact repels away; and the fifth insulating part is fixed in the groove of the base through a screw and is used for providing insulation between the rotating shaft and the arc extinguishing device.

Has the advantages that: compared with the prior art, the technical scheme of the utility model, its beneficial effect lies in:

(1) By adding an equipotential connecting line between the connecting plate and the upper arc striking plate, the moving contact, the connecting plate and the upper arc striking plate have the same potential, and the static contact and the lower arc striking plate have the other potential, so that the transfer time of an electric arc from the contact to the arc striking plate can be shortened, the arc extinguishing capability can be improved, the arc striking effect of the arc striking plate can be improved, and the arc extinguishing performance is more beneficial;

(2) Compare with most current arc control device vertically placed, the utility model discloses adopted transversely to place on arc control device placing means, this mode can be in limited circuit breaker volume, as far as possible increased arc extinguishing bars piece quantity, arc extinguishing bars piece quantity increase will divide into more short arcs to divide the produced electric arc of disconnected fault current into, can improve arc voltage, increase arc control device extinguishes the ability of electric arc. And the high-temperature gas generated in the breaking process of the breaker can be prevented from being sprayed out, the adverse effect on the external environment can be eliminated, and the flashover distance can be reduced.

Drawings

Fig. 1 is a perspective view of the present invention;

FIG. 2 is a general assembly drawing of the present invention;

FIG. 3 is an exploded view of an arc extinguishing device and contact system;

FIG. 4 is a schematic view of an assembled arc extinguishing device and contact system;

fig. 5 is a schematic structural view of an arc extinguishing grid group;

FIG. 6 is a schematic view showing a state in which the insulator is mounted in FIG. 5;

FIG. 7 is a schematic structural view of a left gas generating member;

FIG. 8 is a schematic structural view of a right gas generating member;

FIG. 9 is an assembly view of the first insulator and the base;

FIG. 10 is an assembly view of the second insulating member, the fifth insulating member and the base;

FIG. 11 is an assembly view of the connection plate and the equipotential bonding wire with the base;

FIG. 12 is an assembly view of the third insulator and base;

fig. 13 is an assembly view of a stationary contact and a base;

FIG. 14 is an assembly view of the upper and lower tab and the base;

FIG. 15 is a general assembly view of the insulator assembly;

figure 16 is a distribution diagram of the internal cavity of the circuit breaker housing;

FIG. 17 is a current profile of arc extinguishing system operation when fault current is not present;

FIG. 18 is a current trend diagram of the arc extinguishing system just beginning to operate when a fault current occurs;

FIG. 19 is a current direction diagram showing the state that the movable contact moves to the maximum distance and the arc is not transferred when the fault current occurs;

fig. 20 is a current flow diagram in a state that the movable contact acts to the maximum opening distance and the arc transfer is completed when the fault current occurs.

Detailed Description

The technical solution of the present invention will be described in detail with reference to the following detailed description and the accompanying drawings.

As shown in fig. 1-4, the utility model discloses a circuit breaker arc extinguishing system includes contact system, insulator arrangement and arc control device three, and contact system includes pivot 1, moving contact 3 and static contact 10, and moving contact 3 fixed mounting makes moving contact 3 rotatory in pivot 1 through the motion of mechanism drive pivot 1 in pivot 1, realizes the contact and the separation of moving contact 3 and static contact 10, and then realizes the switch-on or the break-off in return circuit. In the scheme, a movable silver point 2 is arranged at the position where a movable contact 3 is contacted with a fixed contact 10, the movable silver point 2 is fixed on the movable contact 3 in a welding mode, and the movable contact is made of silver alloy generally; the static contact 10 is provided with a static silver point 8 corresponding to the dynamic silver point 2, the static silver point 8 is fixed on the static contact 10 by welding, the material of the static contact is generally silver alloy, and the dynamic silver point 2 and the static silver point 8 are arranged to improve the conductive capacity of a loop, increase the use frequency of a conductor and increase the contact effect.

The arc extinguishing device comprises a connecting plate 5, an equipotential connecting wire 6, an upper arc striking plate 7, a lower arc striking plate 9 and an arc extinguishing grid group. The upper arc striking plate 7 is connected with the connecting plate 5 through an equipotential connecting wire 6, and the connecting plate 5 is connected with the moving contact 3 through the flexible connection 4, so that the upper arc striking plate 7 and the moving contact 3 are equipotential, the transfer time of electric arc from the contact to the arc striking plate is shortened, and the arc extinguishing capability is improved. As shown in fig. 13, one end of the static contact 10 is connected and fixed to the base 21 of the insulating device through screws on the first through hole 101 and the second through hole 102, and the other end of the static contact 10 is fixedly connected to the static silver point 8 by welding. One end of the upper arc striking plate 7 is connected with the fourth through hole 63 at one end of the equipotential connecting line 6 at the third through hole 71 by a screw, and the other end of the upper arc striking plate 7 is fixed on the base 21 at the fifth through hole 72 by a screw. As shown in fig. 11, the other end of the equipotential connecting line 6 is fixedly connected to the eighth through hole 51 and the ninth through hole 52 of the connecting plate 5 at the sixth through hole 61 and the seventh through hole 62 by using screws. One end of the lower arc striking piece 9 is welded on the static contact 10, the lower arc striking piece 9 is positioned below the static silver point 8, and the other end of the lower arc striking piece 9 is fixed on the base 21 at the tenth through hole 91 by a screw. Two ends of the flexible connection 4 are respectively fixed on the movable contact 3 and the connecting plate 5 in a welding mode. The upper arc striking plate 7 and the lower arc striking plate 9 are arranged, so that electric arcs can be guided into the arc extinguishing device more completely, more arc extinguishing grid plates are enabled to act, and the arc extinguishing performance is improved. In this embodiment, an arc striking groove is formed in the middle of each of the upper arc striking plate 7 and the lower arc striking plate 9, and the width of the arc striking groove is 1 to 2 times the thickness of the corresponding arc striking plate, as shown in fig. 14.

As shown in fig. 4, 5, 7 and 8, the arc-extinguishing grid set includes a left arc-isolating wall 11, a left gas-generating component 12, a first arc-extinguishing grid set 13, a second arc-extinguishing grid set 14, a third arc-extinguishing grid set 15, a fourth arc-extinguishing grid set 16, a right gas-generating component 17 and a right arc-isolating wall 18. The first arc-extinguishing grid piece group 13, the second arc-extinguishing grid piece group 14, the third arc-extinguishing grid piece group 15 and the fourth arc-extinguishing grid piece group 16 are sequentially and transversely arranged, and the number of the arc-extinguishing grid pieces can be increased as much as possible in the limited volume of the circuit breaker. The left arc-insulating wall 11 and the right arc-insulating wall 18 are arranged on two sides of the whole body formed by the first arc-insulating grid group 13, the second arc-insulating grid group 14, the third arc-insulating grid group 15 and the fourth arc-insulating grid group 16, a plurality of arc-insulating grid plates are sequentially riveted on square holes of the left arc-insulating wall 11 and the right arc-insulating wall 18, the arc-insulating grid plates are vertically arranged relative to the left arc-insulating wall 11 and the right arc-insulating wall 18, and the left arc-insulating wall 11 and the right arc-insulating wall 18 are utilized to separate a plurality of arc-insulating grid plates contained by the first arc-insulating grid group 13, the second arc-insulating grid group 14, the third arc-insulating grid group 15 and the fourth arc-insulating grid group 16. The interval all exists between two adjacent arc extinguishing bars piece, and the several arc extinguishing bars piece can be cut apart into more short arcs with the produced electric arc of breaking fault current, can improve arc voltage, increases arc extinguishing device's ability of quenching electric arc. When an arc is generated, the left gas generating piece and the right gas generating piece are eroded by the arc to generate gas, so that the gas pressure in the cavity of the arc extinguish chamber is raised to form gas blowing, which is favorable for the arc to enter the arc extinguish grid set, and simultaneously, the high-speed gas flow blows the arc plasma beam, which is also favorable for cooling the arc.

As shown in fig. 15 and 16, the insulating device includes a base 21, a bottom sealing plate 25, a small cover 26, a middle cover 27, and a plurality of insulating members, wherein the base 21, the bottom sealing plate 25, the small cover 26, and the middle cover 27 form a housing of the circuit breaker. The inside of casing with the circuit breaker is divided into different cavities, when the combination concatenation between different cavities, combines together through the mode that increases rectangular recess and rectangular boss on the casing to increase the insulating properties of circuit breaker. Specifically, the small lid 26 and the middle lid 27 form a first chamber 28, the middle lid 27 and the base 21 form a second chamber 29, and the base 21 and the bottom closure panel 25 form a third chamber 30. The first chamber 28 is used to store the accessories of the circuit breaker. The rotating shaft 1, the moving contact 3, the flexible connection 4, the connecting plate 5 and the equipotential connecting line 6 are arranged in the second cavity 29, specifically, a groove is formed in the base 21 and used for storing the equipotential connecting line 6, and an insulating part is arranged above the equipotential connecting line 6, so that the equipotential connecting line 6 is completely sealed in the groove; in addition, the insulating member cooperates with the movable contact 3, the rotating shaft 1 and the base 21 to form a closed area, so as to isolate the second chamber 29 from the third chamber 30. The static contact 10, the arc extinguishing grid group, the upper arc striking plate 7 and the lower arc striking plate 9 are arranged in the third chamber 30. The arc extinguishing grid plate group is installed at the bottom of the third chamber 30, specifically, the arc extinguishing grid plate group is fixedly installed above the sealing bottom plate 25, and the upper arc striking plate 7 and the lower arc striking plate 9 are embedded in the middle concave part of the arc extinguishing grid plate group. The base 21 and the cover plate 25 provide a mounting and fixing space for the entire arc extinguishing system, and a plurality of insulating members are used to provide insulation between different components. The insulating part provides reliable insulating properties for whole arc extinguishing system, and insulating properties of whole arc extinguishing device cavity has been guaranteed in insulating device's setting. The method specifically comprises the following steps: the plurality of insulating members includes a first insulating member 19 and second, third, fourth and fifth insulating

members

20, 22, 23 and 24. As shown in fig. 6 and 9, a groove 191 and a first boss 192 are formed on the first insulating member 19, the first insulating member 19 is installed in the groove between the left gas generating member 12 and the right gas generating member 17 through the groove 191, and the first boss 192 is inserted into the corresponding groove of the base 21 for splicing; the first insulating member 19 mainly serves to insulate the stationary contact 10 from the arc extinguishing device. As shown in fig. 10, a second boss 201 is disposed on the second insulating member 20, and the second insulating member 20 is inserted into a corresponding groove of the base 21 through the second boss 201 for splicing. The second insulating member 20 mainly serves to provide insulation between the bolt of the connection plate 5 and the arc-extinguishing device, and to prevent the mechanism above the arc-extinguishing device from being ablated. As shown in fig. 12, the third insulating member 22 is fixed on the base 21 through the

holes

221, 222, 223, 224, and mainly functions to insulate the arc extinguishing device below the base 21 from the mechanism above, and insulate the equipotential connection lines 6 below the base 21. As shown in fig. 15, a fourth insulating member 23 is mounted on the hole 31 of the movable contact 3 by a rivet, and is used for providing insulation between the rotating shaft 1 and the arc extinguishing device when the movable contact 3 is repelled; the fifth insulating member 24 is fixed in the recess 211 of the base 21 by a screw for providing insulation between the rotating shaft 1 and the arc extinguishing device.

As shown in fig. 17, when the fault current does not occur, the arc extinguishing device operates normally in a current profile. The normal working current enters from the connecting plate 5 at the inlet wire end and flows out sequentially through the flexible connection 4, the moving contact 3, the moving silver point 2, the static silver point 8 and finally the static contact 10.

As shown in fig. 18, when a fault current occurs, the current pattern in which the movable contact 3 starts to operate is shown. The fault current enters from the connecting plate 5 at the inlet wire end, and after passing through the flexible connection 4 and the moving contact 3, the moving contact 3 acts rapidly to generate a metal phase arc 11 between the moving silver point 2 and the static silver point 8, so that the fault current flows to the static silver point 8 and the static contact 10 through the arc 11.

As shown in fig. 19, when a fault current occurs, the movable contact 3 moves to the maximum open distance and the arc 11 still flows between the movable contact 3 and the stationary contact 10. The electric arc 11 will move downward continuously due to the action of air blowing and magnetic blowing until entering the arc extinguishing device completely and then is extinguished by the arc extinguishing device, and this state is a critical state that the electric arc 11 will move to the arc striking piece, because the electric arc 11 is still located between the moving silver point and the static silver point, the current trend of the whole conductive loop is consistent with that of the moving contact 3 when just moving, and still is the connecting plate 5-flexible connection 4-moving contact 3-moving silver point 2-electric arc 11-static silver point 8-static contact 10.

As shown in fig. 20, when the fault current occurs, the movable contact 3 acts to the maximum opening distance and the arc 11 has completely entered the arc extinguishing device. The current profile for this state differs from the previous arc 11 between the moving and stationary silver points by: because the upper arc striking sheet 7 is connected with the connecting plate 5 through the equipotential connecting wire 6, the upper arc striking sheet 7 and the connecting plate 5 have the same high potential, and the lower arc striking sheet 9 and the static contact 10 are connected together, the lower arc striking sheet 9 and the static contact 10 have the same low potential, and because of the potential difference between the upper arc striking sheet and the static contact, the loop current moves from the connecting plate 5 to the equipotential connecting wire 6 and then onto the upper arc striking sheet 7, and when the current moves to the tail end of the upper arc striking sheet 7, the current moves to the right through the electric arc 11 and continues to move to the tail end of the lower arc striking sheet 9, and then flows out from the lower arc striking sheet 9 to the static contact 10.

It should be noted that, if the equipotential connecting wire 6 is not added, when the movable contact 3 moves to the position with the maximum opening distance, the upper arc striking plate 7 also has a certain arc striking capability, and the arc 11 also moves downward along with the upper arc striking plate 7, but because there is no equipotential connecting wire 6, the upper arc striking plate 7 at this time will be at a low potential, and the movable contact 3 is at a high potential, such a potential difference will be unfavorable for the transfer of the arc 11, and a situation that the arc 11 does not move all the way to the end along the upper arc striking plate 7 will occur, and if the arc 11 does not move to the end of the arc striking plate, only a part of the arc extinguishing grid plate below will also play a role in dividing the arc 11, so that the arc extinguishing capability cannot be expected. The lower arc striking plate 9 is welded on the static contact 10, and belongs to direct electric connection, and the lower arc striking plate and the static contact always keep the same low potential, so that the electric arc 11 is transferred on the lower arc striking plate 9 quite easily, namely, the arc striking effect of the whole conductive loop mainly depends on the arc striking effect of the upper arc striking plate 7.

Claims

1. A circuit breaker, characterized by: the arc extinguishing device comprises a contact system, an insulating device and an arc extinguishing device, wherein the contact system comprises a rotating shaft (1), a moving contact (3) and a static contact (10), the moving contact (3) is fixedly arranged in the rotating shaft (1), and the moving contact (3) is driven to rotate through the rotating shaft (1) so as to realize the contact and separation of the moving contact (3) and the static contact (10);

the arc extinguishing device comprises a connecting plate (5), an equipotential connecting wire (6), an upper arc striking plate (7), a lower arc striking plate (9) and an arc extinguishing grid group; the upper arc striking sheet (7) is connected with the connecting plate (5) through an equipotential connecting line (6), the connecting plate (5) is connected with the moving contact (3) through a flexible connection (4), and the upper arc striking sheet (7) and the moving contact (3) are equipotential; one end of the lower arc striking plate (9) is fixedly connected with the static contact (10), and the other end of the lower arc striking plate is fixedly connected with the insulating device; the arc-extinguishing grid group is fixedly installed on the insulating device, and the upper arc striking plate (7) and the lower arc striking plate (9) are embedded in the middle concave part of the arc-extinguishing grid group.

2. The circuit breaker of claim 1, wherein: the middle parts of the upper arc striking piece (7) and the lower arc striking piece (9) are respectively provided with an arc striking groove, and the width of each arc striking groove is 1-2 times of the thickness of the corresponding arc striking piece.

3. The circuit breaker of claim 1, wherein: the arc-extinguishing grid group comprises a first arc-extinguishing grid group (13), a second arc-extinguishing grid group (14), a third arc-extinguishing grid group (15), a fourth arc-extinguishing grid group (16), a left arc-isolating wall (11) and a right arc-isolating wall (18);

the first arc-extinguishing grid group (13), the second arc-extinguishing grid group (14), the third arc-extinguishing grid group (15) and the fourth arc-extinguishing grid group (16) are sequentially and transversely arranged, and a left arc-isolating wall (11) and a right arc-isolating wall (18) are arranged on two sides of the whole body formed by the plurality of grid groups.

4. The circuit breaker of claim 3, wherein: the arc extinguishing grid group also comprises a left gas generating piece (12) and a right gas generating piece (17), and a first spacer rib (122) of the left gas generating piece (12) is inserted into a gap of the arc extinguishing grid group; and the second spacer rib (172) of the right gas generating piece (17) is inserted into the gap of the arc extinguishing grid group.

5. The circuit breaker of claim 4, wherein: the insulation means comprises a first insulation (19) and a second insulation (20);

the first insulating part (19) is provided with a groove (191) and a first boss (192), the first insulating part (19) is arranged in a groove between the left gas generating part (12) and the right gas generating part (17) through the groove (191), and the first boss (192) is inserted into a base (21) of the insulating device for splicing;

and a second boss (201) is arranged on the second insulating part (20), and the second insulating part (20) is inserted into a corresponding groove of the base (21) through the second boss (201) for splicing.

6. The circuit breaker of claim 1, wherein: the insulation device comprises a third insulation piece (22), a fourth insulation piece (23) and a fifth insulation piece (24);

the third insulating part (22) is fixed on a base (21) of the insulating device through a plurality of holes and is used for providing insulation between the rotating shaft (1) and the arc extinguishing device;

the fourth insulating part (23) is arranged on a hole (31) of the moving contact (3) through a rivet and is used for providing insulation between the rotating shaft (1) and the arc extinguishing device when the moving contact (3) is repelled;

the fifth insulating piece (24) is fixed in a groove (211) of the base (21) through a screw and used for providing insulation between the rotating shaft (1) and the arc extinguishing device.