CN210489574U - Circuit breaker contact system - Google Patents

Abstract

A circuit breaker contact system belongs to the technical field of low-voltage electrical appliances. The movable contact is closed or separated from the static contact after swinging, the movable contact comprises a movable contact piece, the movable contact piece is formed by a plurality of movable contact piece conductors in parallel, a movable contact is welded on the movable contact piece conductors, a movable arc contact part is arranged on the movable contact piece conductors, the static contact comprises a static contact matched with the movable contact in an electric contact manner and a static arc contact part matched with the movable arc contact part in an electric contact manner, and when the contact system is closed, the movable arc contact part is in contact with the static arc contact part before the movable contact part is in contact with the static contact part; and a first bending-resistant part is arranged on one side of the movable contact piece conductor close to the fixed contact, and the first bending-resistant part is positioned between the movable contact and the movable arc contact part. The advantages are that: the strain at the welding position of the movable contact is reduced, the stress amplitude is reduced, the generation of fatigue cracks is delayed, the movable contact piece is effectively prevented from being broken, and the service life of the circuit breaker is prolonged.

Description

Circuit breaker contact system

Technical Field

The utility model belongs to the technical field of low-voltage apparatus, concretely relates to circuit breaker contact system.

Background

The low-voltage universal circuit breaker is a component of low-voltage electrical equipment with large capacity, is mainly used in an industrial power system, and can ensure the connection and disconnection of a circuit under a rated load and automatically disconnect the circuit under an abnormal state (such as overload, short circuit, undervoltage and the like) of the circuit, thereby completely isolating the load from a power supply.

As shown in fig. 1 to 4, in the structure of the circuit breaker in the prior art, a contact system is an important component of the circuit breaker for making or breaking current. The contact system comprises a moving contact 1 and a fixed contact 2, wherein the moving contact 1 swings and then is closed or separated from the fixed contact 2. When fault current occurs in the circuit, the intelligent controller detects the fault current and sends an action signal to the operating mechanism, the operating mechanism drives the moving contact 1 to swing, the moving contact 1 and the static contact 2 are rapidly separated, electric arcs are extinguished in the arc extinguishing chambers above the moving contact 1 and the static contact 2, and therefore the current is cut off. The contact system of the prior art circuit breaker comprises the following two structures:

the structure of the contact system is shown in fig. 1 and fig. 2, wherein the moving contact 1 is a swinging member, and the stationary contact 2 is a fixed member. The moving contact 1 comprises a moving contact piece 11, and a moving contact 111 is welded on the moving contact piece 11. The movable contact piece 11 is provided with a movable arc contact part 112; the static contact 2 comprises a static contact conductive block 21, a static contact 22 is welded on the position of the static contact conductive block 21 corresponding to the movable contact 111, and a static arc contact part 23 is welded on the position corresponding to the movable arc contact part 112. The movable contact 111 is in electrical contact with the fixed contact 22, and the movable arc contact 112 is in electrical contact with the fixed arc contact 23. The moving contact 11 is composed of a plurality of moving contact conductors 1101 arranged side by side, a moving contact 111 is fixedly mounted on the moving contact conductors 1101, and specifically, the moving contact 111 is fixedly mounted on the moving contact conductors 1101 in a welding mode. When the moving contact 1 and the static contact 2 perform a closing operation, the moving arc contact part 112 and the static arc contact part 23 contact with each other before the moving contact 111 and the static contact 22 contact with each other. Because the moving arc contact part 112 contacts with the static arc contact part 23 first and forms an impact, the impact forms a bending moment on the moving contact 1, and due to the difference of the material characteristics of the moving contact 111 and the moving contact piece conductor 1101 on the moving contact 1, the welding part 1111 welded by the moving contact 111 and the moving contact piece conductor 1101 has high local stress and large strain due to the action of the bending moment, and is easy to form fatigue fracture to cause the breakage of the moving contact piece conductor 1101.

As shown in fig. 3 and 4, the moving arc contact portion 112 is a moving arc contact block 1121 fixed to the moving contact 11, and the fixed arc contact portion 23 is a fixed arc contact block 231 fixed to the fixed contact conductive block 21. The movable contact 111 is electrically contacted and matched with the fixed contact 22, and the movable arc contact part 112 is electrically contacted and matched with the fixed arc contact part 23, that is, the movable arc contact block 1121 and the fixed arc contact block 231 are also electrically contacted and matched.

The above-described contact system has a structure in which the welded portion 1111 of the movable contact 111 is liable to generate fatigue cracks to cause the movable contact conductor 1101 to break, thereby limiting the improvement of the life of the circuit breaker, and therefore, it is necessary to reasonably improve the structure of the contact system of the conventional circuit breaker. The applicant has therefore made an advantageous design, in the context of which the solution to be described below is made.

Disclosure of Invention

An object of the utility model is to provide a circuit breaker contact system can reduce the dependent variable of the welding department of movable contact, reduces stress amplitude, delays fatigue crack and generates, prevents not hard up or drop of movable contact effectively, improves the life-span of circuit breaker.

The utility model aims at achieving like this, a circuit breaker contact system, including moving contact and static contact, the moving contact swing after with the static contact realize closure or separation, the moving contact include the movable contact spring, the movable contact spring form by the multi-disc movable contact spring conductor side by side, the movable contact spring conductor on weld have the movable contact, the movable contact spring conductor on be equipped with the movable arc contact site, the static contact include with the movable contact electrical contact complex stationary contact and with the movable arc contact site electrical contact complex stationary arc contact site, when contact system closed, the contact of movable arc contact site and stationary arc contact site contact prior to movable contact and stationary contact site; and a first bending-resistant part is arranged on one side of the movable contact piece conductor close to the fixed contact, and the first bending-resistant part is positioned between the movable contact and the movable arc contact part.

In a specific embodiment of the present invention, the moving contact is kept away from the other side of the first bending-resistant portion, and a second bending-resistant portion is provided, the second bending-resistant portion is adjacent to the moving contact, and the second bending-resistant portion is manufactured by an extrusion process.

In another specific embodiment of the present invention, the movable contact further includes a pair of contact supports, a rotating shaft, and contact side plates, the contact side plates are fixed on two sides of the contact supports respectively, and the movable contact is rotatably disposed on the contact side plates through the rotating shaft.

In another specific embodiment of the present invention, the first bending-resisting portion is a groove, the groove is opened on a side surface of the moving contact conductor close to the fixed contact, and an opening of the groove faces the fixed contact.

In a further embodiment of the invention, the cross-section of the groove is semicircular or circular arc-shaped or triangular or square or trapezoidal.

In another specific embodiment of the present invention, the moving arc contact portion is a moving arc contact block welded to the moving contact conductor, and the static arc contact portion is a static arc contact block welded to the static contact conductive block of the static contact.

In yet another specific embodiment of the present invention, the first bending-resistant portion is a counter bore, and the counter bore is formed by extending from a surface of the movable contact piece conductor close to the fixed contact toward the inside of the movable contact piece conductor.

In a more specific embodiment of the present invention, the shape of the counterbore formed on the surface of the movable contact piece conductor is a circle, a semicircle, a triangle or a square.

In yet another specific embodiment of the present invention, the first bending-resistant portion is manufactured by an extrusion process.

In yet another specific embodiment of the present invention, the first bending-resistant portion is closely attached to the movable contact.

The utility model discloses owing to adopted above-mentioned structure, the beneficial effect who has: firstly, a first bending-resistant part is arranged above the welding part of the movable contact, so that the strain of the welding part of the movable contact when stressed is reduced, the stress amplitude is reduced, and the generation of fatigue cracks is delayed, thereby effectively preventing the movable contact from being broken and prolonging the service life of the circuit breaker; secondly, the first bending-resistant part is manufactured by extrusion forming, compared with the mode of removing partial materials, the extrusion forming mode can form a material layer with higher density at the edge of the first bending-resistant part, and the material layer with higher density has higher tensile strength, and the fatigue life of the movable contact piece can be prolonged, so that the service life of the circuit breaker is further prolonged; and thirdly, the second bending resistant part is arranged, so that the material near the lower side of the movable contact is not easy to bend, the deformation of the welding surface of the whole welding part due to bending moment is reduced, and the welding stability of the movable contact is improved.

Drawings

Fig. 1 is a schematic view of a prior art contact system without a moving arcing contact block and a stationary arcing contact block.

Figure 2 is a schematic view of a prior art moving contact without a moving arc contact block.

Fig. 3 is a schematic view of a prior art contact system with a moving arcing contact block and a stationary arcing contact block.

Fig. 4 is a schematic view of a prior art moving contact with a moving arc contact block.

Fig. 5 is a schematic structural diagram of a contact system without a moving arcing contact block and a stationary arcing contact block according to an embodiment of the present invention.

Fig. 6 is an exploded view of the moving contact without the moving arc contact block according to the embodiment of the present invention.

Fig. 7 is a schematic view of the moving contact without the moving arc contact block according to the embodiment of the present invention.

Fig. 8 is a schematic structural diagram of a contact system with a moving arcing contact block and a stationary arcing contact block according to an embodiment of the present invention.

Fig. 9 is an exploded view of the moving contact with the moving arc contact block according to the embodiment of the present invention.

Fig. 10 is a schematic view of the movable contact with the movable arc contact block according to the embodiment of the present invention.

Fig. 11 is a schematic view of the moving contact with the moving arc contact block according to another embodiment of the present invention.

Fig. 12 is a schematic cross-sectional view of the movable contact piece in the contact system of the circuit breaker of the present invention.

In the figure: 1. the contact comprises a moving contact, 11 parts of a moving contact piece, 1101 parts of a moving contact piece conductor, 111 parts of a moving contact, 1111 parts of a welding part, 112 parts of a moving arc contact part, 1121 parts of a moving arc contact block, 113 parts of a first bending resisting part, 114 parts of a rotating mounting hole, 115 parts of a second bending resisting part, 12 parts of a contact support, 121 parts of a spring cavity, 13 parts of a rotating shaft, 14 parts of a contact side plate, 141 parts of a mounting hole and 15 parts of a contact spring; 2. the static contact, 21, the static contact conducting block, 22, the static contact, 23, the static arc contact part, 231, the static arc contact block.

Detailed Description

The following detailed description of the embodiments of the present invention will be described with reference to the accompanying drawings, but the description of the embodiments by the applicant is not intended to limit the technical solutions, and any changes made according to the present invention rather than the essential changes should be considered as the protection scope of the present invention.

In the following description, any concept relating to the directions or orientations of up, down, left, right, front, and rear is based on the position shown in the corresponding drawings, and thus should not be construed as particularly limiting the technical solution provided by the present invention.

Example 1

As shown in fig. 5 and 6. The embodiment relates to a contact system of a circuit breaker, which comprises a moving contact 1 and a fixed contact 2, wherein the moving contact 1 is contacted with or separated from the fixed contact 2 after swinging. The moving contact 1 comprises a moving contact piece 11, a contact support 12, a rotating shaft 13, a contact side plate 14 and a contact spring 15, wherein the moving contact piece 11 is rotatably arranged on the contact side plate 14 through the rotating shaft 13. The rotating shaft 13 is the swing center of the movable contact piece 11. The contact side plates 14 are a pair and fixed to both sides of the contact holder 12. Thereby ensuring that said movable contact piece 11 can swing with respect to said contact support 12. The contact support 12 serves as a support for other components of the moving contact 1, and the contact support 12 is usually made of an insulating and heat-resistant material, such as DMC or BMC. The contact support 12 is rotatably arranged, one end of the contact spring 15 abuts against the movable contact piece 11, and the other end abuts against the spring cavity 121 of the contact support 12, so that contact pressure close to the fixed contact 2 is provided for the movable contact piece 11.

As shown in fig. 5, 6 and 7, the movable contact 11 is formed by arranging a plurality of movable contact conductors 1101. The moving contact conductor 1101 is a conductive member, typically made of a conductive metal material, preferably copper. Each moving contact piece conductor 1101 is provided with a rotating mounting hole 114, the moving contact piece 11 is a swinging piece, the rotating mounting hole 114 on each moving contact piece conductor 1101 is sleeved on the rotating shaft 13, and the moving contact piece 11 is rotatably arranged on the mounting hole 141 of the contact side plate 14 through the rotating shaft 13. The movable contact piece 11 can swing around the rotating shaft 13. A movable contact 111 is welded on one side surface of each movable contact piece conductor 1101 close to the fixed contact 2, and the movable contact 111 is fixed on the movable contact piece conductor 1101 by adopting a welding mode. A movable arc contact portion 112 is provided on the side of the swing end of the movable contact piece conductor 1101, the movable arc contact portion 112 being located on the side of the movable contact 111 away from the rotation mounting hole 114. The static contact 2 comprises a static contact conductive block 21, a static contact 22 electrically contacted and matched with the movable contact 111 is welded on the static contact conductive block 21, and a static arc contact part 23 electrically contacted and matched with the movable arc contact part 112 is also arranged on the static contact 2. When the contact system is closed, the movable contact 1 rotates, the movable contact piece 11 moves along with the contact support 12, the movable arc contact part 112 is contacted with the fixed arc contact part 23, along with the continuous rotation of the movable contact 1, the movable contact piece 11 rotates relative to the contact support 12, the movable contact 111 is contacted with the fixed contact 22, then the movable contact 111 is kept contacted with the fixed contact 22, and the movable arc contact part 112 is separated from the fixed arc contact part 23. In the process, the contact between the movable arc contact part 112 and the fixed arc contact part 23 occurs before the movable contact 111 contacts with the fixed contact 22, when the movable contact 1 and the fixed contact 2 are closed and stabilized, the movable contact 111 contacts with the fixed contact 22, and the movable arc contact part 112 is separated from the fixed arc contact part 23, that is, the movable arc contact part 112 does not contact. The moving arc contact portion 112 and the fixed arc contact portion 23 are respectively a part of the moving contact piece 11 and the fixed contact conductive block 21, that is, a part of the moving contact piece 11 and the fixed contact conductive block 21 which are in electrical contact with each other.

Of course, as shown in fig. 8 to 10, the moving arc contact portion 112 may be a moving arc contact block 1121 welded to the moving contact conductor 1101, and the fixed arc contact portion 23 may be a fixed arc contact block 231 welded to the fixed contact conductive block 21 of the fixed contact 2.

As shown in fig. 5 to 10, in this embodiment, a first bending-resistant portion 113 is disposed on the side of the movable contact 111 away from the rotation mounting hole 114 of the movable contact conductor 1101, that is, the first bending-resistant portion 113 is disposed between the movable contact 111 and the movable arcing contact portion 112, so as to reduce the stress concentration at the welding portion 1111 where the movable contact 111 and the movable contact conductor 1101 are welded, thereby effectively preventing the movable contact 111 from loosening or falling off from the movable contact conductor 1101, and improving the service life of the circuit breaker. In this embodiment, the first bending-resistant portion 113 is a groove opened on a surface of the movable contact piece conductor 1101 on a side close to the stationary contact 2. The groove may be parallel to the axial direction of the rotating shaft 13, or may form a certain angle with the axial direction of the rotating shaft 13. And more preferably parallel to the axial direction of the rotation shaft 13. The groove penetrates both side surfaces of the movable contact piece conductor 1101. It is of course possible that the groove does not penetrate both sides of the moving contact conductor 1101, but it is more preferable to penetrate both sides of the moving contact conductor 1101. The cross-sectional shape of the groove formed on the plane perpendicular to the rotating shaft 13 is not limited at all, and may be a semicircle, an arc, a triangle, a square, a trapezoid, etc., and in this embodiment, a semicircle is preferably selected, that is, the groove is a semicircular groove. In this embodiment, the groove is formed by extrusion molding, and compared with a method of removing a part of material, the extrusion molding method can form a material layer with higher density at the edge of the groove, and the material layer with higher density has higher tensile strength, so that the fatigue life of the movable contact piece 11 is prolonged, and the service life of the circuit breaker is further prolonged. In this embodiment, the groove is tightly attached to the moving contact 111, that is, the welded portion 1111 where the moving contact 111 and the moving contact piece conductor 1101 are welded is connected to the groove surface of the groove, and at this time, the strain and stress amplitude of the welded portion 1111 is reduced to the maximum extent, and the generation of fatigue cracks is delayed, thereby improving the service life of the circuit breaker.

Example 2

As shown in fig. 11, the contact system according to the present embodiment differs from embodiment 1 in that: the first bending-resistant portion 113 is a counter bore, and the counter bore is formed by extending from a side surface of the movable contact piece conductor 1101 close to the fixed contact 2 to the inside of the movable contact piece conductor 1101 in a direction perpendicular to the rotating shaft 13. The shape of the counterbore formed on the surface of the movable contact conductor 1101 is not limited, and may be circular, semicircular, triangular, square, etc., and circular is preferred in this embodiment. Similarly, the counterbore is located between the moving contact 111 and the moving arc contact 112. The counter bore can reduce the strain and stress acting on the welding position of the movable contact 111, delay the generation of fatigue cracks and further prolong the service life of the circuit breaker. In this embodiment, the counter bore is manufactured by extrusion molding, and compared with a mode of removing part of the material, the extrusion molding can form a material layer with higher density at the edge of the counter bore, and the material layer with higher density has higher tensile strength, so that the fatigue life of the movable contact piece 11 is prolonged, and the service life of the circuit breaker is further prolonged. In this embodiment, the counterbore is connected to the inner wall surface of the counterbore at a weld 1111 that is tightly attached to the movable contact 111, i.e., where the movable contact 111 is welded to the movable contact conductor 1101. At this moment, the counter bore can greatly reduce the original strain and stress amplitude acting on the fixed position of the movable contact 111, so that the problem in the existing structure is improved to the greatest extent, and the service life of the circuit breaker is prolonged. The other structures in this embodiment are the same as those in embodiment 1.

As shown in fig. 5 to 12, in embodiment 1 and embodiment 2, a second bending resistance portion 115 may be further provided on the other side of the movable contact 111 from the first bending resistance portion 113, and the second bending resistance portion 115 is adjacent to the movable contact 111, that is, a welding portion 1111 where the movable contact 111 is welded to the movable contact piece conductor 1101 is connected to the second bending resistance portion 115. The second bending resistant portion 115 is a groove formed by an extrusion process, and may have other shapes such as a hole, similar to the first bending resistant portion 113 in terms of processing and functions. Since the second bending resistance part 115 is manufactured through the extrusion process, the material in the vicinity of the second bending resistance part 115 has a higher material density and a higher tensile strength, so that the movable contact piece 11 has a higher fatigue life.

To sum up, the utility model discloses a set up first anti-bending part 113 and/or set up second anti-bending part 115 and reduce the strain and the stress amplitude that act on the welding department 1111 of movable contact 111, delay fatigue crack's production, improve the fatigue life of movable contact piece 11.

Claims (10)

1. A circuit breaker contact system comprises a moving contact (1) and a fixed contact (2), wherein the moving contact (1) is closed or separated with the fixed contact (2) after swinging, the moving contact (1) comprises a moving contact (11), the moving contact (11) is formed by a plurality of moving contact conductors (1101) in parallel, a moving contact (111) is welded on the moving contact conductor (1101), a moving arc contact part (112) is arranged on the moving contact conductor (1101), the fixed contact (2) comprises a fixed contact (22) in electric contact fit with the moving contact (111) and a fixed arc contact part (23) in electric contact fit with the moving arc contact part (112), and when the contact system is closed, the moving arc contact part (112) is in contact with the fixed arc contact part (23) before the moving contact (111) is in contact with the fixed contact (22); the method is characterized in that: a first bending-resistant part (113) is arranged on one side of the moving contact sheet conductor (1101) close to the static contact (2), and the first bending-resistant part (113) is positioned between the moving contact (111) and the moving arc contact part (112).

2. A circuit breaker contact system as claimed in claim 1 wherein a second anti-bowing region (115) is provided on the other side of said movable contact (111) from said first anti-bowing region (113), said second anti-bowing region (115) being adjacent to said movable contact (111), said second anti-bowing region (115) being formed by an extrusion process.

3. The contact system of the circuit breaker according to claim 1, wherein the movable contact (1) further comprises a contact support (12), a rotating shaft (13), and a pair of contact side plates (14), the pair of contact side plates (14) are respectively fixed on two sides of the contact support (12), and the movable contact (11) is rotatably disposed on the contact side plates (14) through the rotating shaft (13).

4. A circuit breaker contact system as claimed in claim 1 wherein said first anti-bowing portion (113) is a recess, said recess opening onto a side surface of the moving contact conductor (1101) adjacent to the stationary contact (2), said recess opening towards the stationary contact (2).

5. The circuit breaker contact system of claim 4, wherein the cross-section of the groove is semicircular, circular arc, triangular, square, or trapezoidal.

6. A contact system for a circuit breaker according to claim 1 wherein said moving arcing contact (112) is a moving arcing contact block (1121) welded to a moving contact conductor (1101), and said stationary arcing contact (23) is a stationary arcing contact block (231) welded to a stationary contact conductive block (21) of a stationary contact (2).

7. A circuit breaker contact system as claimed in claim 1, wherein said first anti-bending portion (113) is a counter-bore, and said counter-bore is formed to extend from a surface of said movable contact conductor (1101) on a side thereof adjacent to said stationary contact (2) toward an inside of said movable contact conductor (1101).

8. A circuit breaker contact system as claimed in claim 7 wherein said counter bore is formed in the surface of the movable contact conductor (1101) in the shape of a circle or semi-circle or triangle or square.

9. A circuit breaker contact system as claimed in any one of claims 1 to 8 wherein the first bend resistant portion (113) is formed by an extrusion process.

10. A circuit breaker contact system as claimed in any one of claims 1 to 8 wherein said first bend resistant portion (113) abuts said movable contact (111).

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