RU217378U1 - CIRCUIT BREAKER - Google Patents

Abstract

The utility model relates to the field of electrical appliances, and in particular to a circuit breaker. The technical result consists in providing a modular assembly characterized by a reliable connection, reduced width and convenient detection and maintenance. A circuit breaker is provided, comprising a main circuit breaker unit and a leakage circuit breaker unit. The leakage circuit breaker unit contains a leakage circuit breaking function module and a transformer module. The leakage circuit breaking function module and the main circuit breaker box are located next to each other. The output terminal of the main circuit breaker unit and the output terminal of the leakage circuit breaking function module are located on the same side. The input terminal of the transformer module is located on the output terminal of the main circuit breaker unit and the output terminal of the leakage circuit breaking function module. The transformer module is releasably connected to the main circuit breaker unit and releasably connected to the leakage circuit breaking function module. The block of the main circuit breaker contains the first casing, as well as a contact assembly, a disconnecting mechanism and a magnetic protection assembly, which are located in the first casing. 9 w.p. f-ly, 10 ill.

Description

Technical field

The utility model relates to the field of electrical appliances, in particular to a circuit breaker.

Prerequisites for creating a utility model

At present, the structure of the leakage circuit breaker mainly has two forms, which are modular assembly or integral assembly, respectively. The modular assembly usually includes a main circuit breaker module and a leakage release module. The main circuit breaker module is connected to the leakage release module by using a long wire. The above structure has large resistance, high temperature, and large dimensions after assembly. Once installed on the junction box body, the design takes up a lot of space, which limits the expansion of the circuit. In particular, the multi-pole leakage protection product is complex in terms of wiring and difficult to dismantle.

At present, in the integrally assembled leakage circuit breaker, compared with the modular assembly, the size of the leakage function module is slightly reduced, the manufacturing process is complicated, and the assembly is difficult, resulting in a relatively long production and assembly time for a single circuit breaker and high technical requirements for assemblers. In addition, since the main circuit breaker module and the leakage circuit breaker module are co-located in the same enclosure, a functional failure of either module may cause failure or obsolescence of the entire products. Due to the complex structure, such products are not easy to maintain and have high production and manufacturing costs.

The essence of the utility model

The utility model is mainly to provide a circuit breaker that uses a modular assembly with independent functions to achieve a reliable connection and reduce the width.

To achieve the above object, the utility model provides a circuit breaker comprising a main circuit breaker unit and a leakage circuit breaker unit. The leakage circuit breaker unit contains a leakage circuit breaking function module and a transformer module. The leakage circuit breaking function module and the main circuit breaker box are located next to each other. The output terminal of the main circuit breaker unit and the output terminal of the leakage circuit breaking function module are located on the same side. The input terminal of the transformer module is located on the output terminal of the main circuit breaker unit and the output terminal of the leakage circuit breaking function module. The block of the main circuit breaker contains the first casing, as well as a contact assembly, a disconnecting mechanism and a magnetic protection assembly, which are located in the first casing.

By applying the technical solution of the utility model, the leakage circuit breaker unit is divided into two parts, which are a leakage circuit breaking function module and a transformer module. The transformer module is located at the output terminal of the main circuit breaker unit and the output terminal of the leakage circuit breaking function module. Therefore, the transformer module is closer to the output terminals of the main circuit breaker unit and the leakage circuit breaking function module to achieve a more convenient and reliable connection. In addition, the overall width of the circuit breaker can be effectively reduced by the above structure. The block of the main circuit breaker contains a contact assembly, a disconnecting mechanism and a magnetic protection assembly, which are located in the first casing.

In some embodiments, the transformer module is releasably connected to the main circuit breaker unit and releasably connected to the leakage circuit breaking function module, the transformer module includes a second casing, an annular transformer housing, a conductive assembly, and a terminal block. The annular transformer housing, conductive assembly and terminal block are located in the second casing. The conductive assembly passes through the inner hole of the annular transformer housing. The first end of the conductive node is connected to the terminal block. The second end of the conductive assembly is releasably connected to the main circuit breaker unit and releasably connected to the leakage circuit breaking function module. In the above construction, due to the detachable connection between the conductive assembly and the leakage circuit breaking function module, the assembly between the transformer module and the leakage circuit breaking function module is more convenient. The magnetic protection unit is located between the transformer module and the contact unit. The magnetic protection unit can provide rotation of the tripping mechanism; and the disconnecting mechanism drives the contact assembly.

In some embodiments, the conductive assembly comprises a first conductive element and a second conductive element. The first metal conductive plate is located on the end part of the first conductive element. The second metal conductive plate is located on the end portion of the second conductive element. The block of the main circuit breaker further comprises a third metal conductive plate located outside the first casing. The leakage circuit breaking function module contains a fourth metal conductive plate. The first metal conductive plate and the third metal conductive plate are inclined and connected to each other. The second metal conductive plate and the fourth metal conductive plate are inclined and connected to each other. Considering the oblique arrangement of the first metal conductive plate, the second metal conductive plate, the third metal conductive plate, and the fourth metal conductive plate in terms of two aspects, in one aspect, the connection area can be guaranteed, and in the other aspect, the total area of the circuit breaker can be reduced , so that the whole structure can be more compact.

In some embodiments, the internal angle between the first metal conductive plate and the horizontal direction is different from the internal angle between the second metal conductive plate and the horizontal direction. Due to the above structure, the angle of the first metal conductive plate connected to the main circuit breaker unit is different from the angle of the second metal conductive plate connected to the leakage circuit breaking function unit. When the main circuit breaker unit is assembled with the leakage circuit breaking function module and the transformer module, the connection position of the main circuit breaker unit and the leakage circuit breaking function module can be quickly determined by metal conductive plates with different angles. In this way, assembly efficiency can be improved.

In some embodiments, the first metal conductive plate is provided with a first elliptical hole. The second metal conductive plate is provided with a second elliptical hole. The third metal conductive plate is provided with a first circular hole. The fourth metal conductive plate is provided with a second circular hole. In the above construction, the first metal conductive plate is conveniently connected to the third metal conductive plate by arranging the first elliptical hole. The second metal conductive plate is conveniently connected to the fourth metal conductive plate by arranging the second elliptical hole.

In some embodiments, the first elliptical hole is connected to the first circular hole by a first screw; and the second elliptical hole is connected to the second circular hole by a second screw. By using the first screw and the second screw to achieve the connection, simple assembly and low cost are realized.

In some embodiments, the second case is releasably connected to the first case via the first cover plate and is releasably connected to the leakage circuit breaking function module via the second cover plate. Between adjacent side surfaces of the main circuit breaker unit and the leakage circuit breaker unit, there is a dowel pin. The first cover plate and the second cover plate have a simple structure. Due to the arrangement of the first cover plate and the second cover plate, the main circuit breaker unit and the leakage circuit breaking function module are connected to the transformer module.

In some embodiments, the transformer module further comprises a support base. The support base extends through the inner opening of the annular transformer housing and supports the annular transformer housing. The conductive assembly is mounted on a support base. The support base is located in the above structure. The support base supports and positions the annular transformer body and the conductive assembly so that the positions of the annular transformer body and the conductive assembly are fixed and not easily loosened and disturbed. In addition, the assembly of the transformer module is simplified by the arrangement of the support base, so that convenient operation is achieved.

In some embodiments, the implementation of the first conductive element contains the first U-shaped enameled wire. The second conductive element contains a second U-shaped enamelled wire. The first U-shaped enameled wire and the second U-shaped enameled wire are symmetrically located along the center line of the annular transformer body and have opposite openings. The annular case of the transformer is located in the opening of the first U-shaped enameled wire and the opening of the second U-shaped enameled wire. The first U-shaped enameled wire and the second U-shaped enameled wire are made of hard conductive materials, so that the connection is more convenient and the structure is more stable. In addition, the first U-shaped enameled wire and the second U-shaped enameled wire can limit the annular body of the transformer so that loosening is prevented, thereby further improving the stability of the transformer module.

In some embodiments, the support base is provided with a first groove accommodating the first U-shaped enameled wire and a second groove accommodating the second U-shaped enameled wire. The first U-shaped enameled wire may be installed by means of the first groove to ensure that the first U-shaped enameled wire is in a stable position. The second U-shaped enameled wire can be installed by means of the second groove to ensure the stable position of the second U-shaped enameled wire.

Brief description of graphic materials

The accompanying drawings of the description provided herein are used to provide additional understanding of the utility model and form part of this application. The exemplary embodiments and descriptions of the utility model are used to explain the utility model and do not constitute an undue limitation of the utility model. The graphics are as follows.

In FIG. 1 is a schematic 3D construction of an embodiment of a circuit breaker according to the utility model.

In FIG. 2 is an exploded view of the circuit breaker shown in FIG. 1.

In FIG. 3 is a schematic top view of the circuit breaker shown in FIG. 1.

In FIG. 4 is a schematic 3D construction of a main circuit breaker unit related to the circuit breaker shown in FIG. 1.

In FIG. 5 is a schematic representation of the internal structure of the main circuit breaker box shown in FIG. 4.

In FIG. 6 is a schematic representation of a three-dimensional construction of the transformer module of the circuit breaker shown in FIG. 1.

In FIG. 7 is an exploded view of the transformer module shown in FIG. 6.

In FIG. 8 is a schematic 3D construction of a partial construction of the transformer module shown in FIG. 6.

In FIG. 9 is a schematic side view of a partial construction of the transformer module shown in FIG. 8.

In FIG. 10 is a schematic representation of a three-dimensional construction of the support member and conductive assembly of the transformer module shown in FIG. 6.

The above accompanying graphics contain the following reference numerals.

10. Main circuit breaker box 11. First cover 12. Contact assembly 13. Breaking mechanism 14. Magnetic protection assembly 15. Third metal conductive plate 151. First circular hole 20. Leakage circuit breaker assembly leakage 22. Transformer module 221. Second housing 222. Annular transformer housing 223. Conductor assembly 2231. First conductive element 2231a. The first metal conductive plate 2231b. First elliptical hole 2232. Second conductive element 2232a. The second metal conductive plate 2232b. Second elliptical hole 224. Terminal block 225. Support base 31. First cover plate 32. Second cover plate.

Detailed description of embodiments

The technical solutions in the embodiments of the utility model will be clearly and completely described below in conjunction with the drawings in the embodiments of the utility model. Obviously, the described embodiments are only a part of the embodiments of the utility model, and not all of the embodiments. The following description of at least one exemplary embodiment is illustrative only and is in no way intended to limit the utility model and its application or use in any way. Based on the embodiments of the utility model, all other embodiments obtained by specialists of average qualification in this field of technology without creative work are included in the scope of legal protection of the utility model.

In the prior art, the leakage circuit breaker box is located on the side of the main circuit breaker box, and connected to the transformer module in the main circuit breaker box and the leakage circuit breaker box using a long wire, resulting in complicated wiring, inconvenient dismantling and maintenance and a large overall width of the circuit breaker.

In view of the above objects, a circuit breaker is provided in this application. As shown in FIG. 1-5, an embodiment of the circuit breaker according to this application provides a main circuit breaker unit 10 and a leakage circuit breaker unit 20 . The leakage circuit breaker unit 20 includes a leakage circuit breaking function unit 21 and a transformer unit 22. The leakage circuit breaking function unit 21 and the main circuit breaker unit 10 are disposed adjacent to each other. The output terminal of the main circuit breaker box 10 and the output terminal of the leakage circuit breaking function module 21 are located on the same side (in Fig. 3, the output terminal of the main circuit breaker box 10 is located at the bottom of the main circuit breaker box, and the output terminal of the module 21 Leakage Circuit Breaker function is located at the bottom of the Leakage Circuit Breaker Module). The input terminal of the transformer module 22 (in Fig. 3, the input terminal of the transformer module 22 is located at the top of the transformer module) is located at the output terminal of the main circuit breaker unit 10 and the output terminal of the leakage circuit breaking function module 21. The transformer module 22 is detachably connected to the main circuit breaker unit 10 and is detachably connected to the leakage circuit breaking function module 21 . The block 10 of the main circuit breaker contains the first casing 11, as well as the contact assembly 12, the disconnecting mechanism 13 and the magnetic protection assembly 14, which are located in the first casing 11. The magnetic protection assembly 14 is located between the transformer module 22 and the contact assembly 12. The magnetic protection assembly 14 can provide rotation of the tripping mechanism 13; and the tripping mechanism 13 drives the contact assembly 12.

By applying the technical solution of the utility model, the leakage circuit breaker unit 20 is divided into two parts, which are the leakage circuit breaking function module 21 and the transformer module 22. The input terminal of the transformer module 22 is located at the output terminal of the main circuit breaker unit 10, and output terminal of module 21 of the leakage circuit breaking function. Thus, the transformer module 22 is closer to the output terminals of the main circuit breaker unit 10 and the leakage circuit breaking function module 21 to achieve a more convenient and reliable connection. In addition, the overall width of the circuit breaker can be effectively reduced by the above structure. The transformer module 22 is detachably connected to the main circuit breaker unit 10 and is detachably connected to the leakage circuit breaking function module 21 . Therefore, the main circuit breaker unit 10, the leakage circuit breaking function unit 21, and the transformer unit 22 are independent from each other so that each unit can be separately detected and maintained. The block 10 of the main circuit breaker contains a contact assembly 12, a tripping mechanism 13 and a magnetic protection assembly 14, which are located in the first casing 11. One end of the magnetic protection assembly 14 is detachably connected to the transformer module 22, and the other end is connected to the contact assembly 12. Assembly 14 magnetic protection can provide rotation of the tripping mechanism 13; and the tripping mechanism 13 drives the contact assembly 12. The contact assembly 12 includes a fixed contact and a moving contact, the fixed contact connected to the magnetic protection assembly 14, the tripping mechanism 13 drives the moving contact.

In this embodiment, as shown in FIG. 6-10, the transformer module 22 includes a second case 221, an annular transformer case 222, a conductive assembly 223, and a terminal block 224. The annular transformer case 222, the conductive assembly 223, and the terminal block 224 are located in the second case 221. The conductive assembly 223 extends through the inner hole. ring-shaped case 222 of the transformer. The first end of the conductive node 223 is connected to the terminal block. The second end of the conductive assembly 223 is releasably connected to the main circuit breaker unit 10 and is releasably connected to the leakage circuit breaking function module 21 . In the above construction, due to the detachable connection between the conductive assembly 223 and the leakage circuit breaking function unit 21, the assembly between the transformer unit 22 and the leakage circuit breaking function unit 21 is more convenient. The second casing 221 includes a plinth and a cover body. The base is detachably connected to the cover body. A accommodating groove configured to receive the terminal block 224 is formed between the base and the cover body. The cover body is provided with a prevent hole configured to prevent the terminal screw of the terminal block 224 from entering.

As shown in FIG. 8, the conductive assembly 223 includes a first conductive element 2231 and a second conductive element 2232. The first metal conductive plate 2231a is located at the end of the first conductive element 2231. The second metal conductive plate 2232a is located at the end of the second conductive element 2232. The first metal conductive plate 2231a is formed with the possibility of connection with the block 10 of the main circuit breaker, and the second metal conductive plate 2232a is made with the possibility of connection with the module 21 of the function of breaking the circuit in case of leakage. The first metal conductive plate 2231a and the second metal conductive plate 2232a form the input terminals of the transformer module 22. There may be a plurality of main circuit breaker units 10, and usually there is only one leakage breaking function module 21. In the case of having a plurality of main circuit breaker units 10, there are also several first metal conductive plates 2231a. In this embodiment, there are two main circuit breaker units 10, one leakage circuit breaking function module 21, two first metal conductive plates 2231a, and one second metal conductive plate 2232a.

As shown in FIG. 4, the main circuit breaker unit 10 further comprises a third metal conductive plate 15 located on the outside of the first case 11. The third metal conductive plate 15 forms an output terminal of the main circuit breaker unit 10. The first metal conductive plate 2231a and the third metal conductive plate 15 are inclined and connected to each other. The leakage breaking function module 21 includes a fourth metal conductive plate. The fourth metal conductive plate forms the output terminal of the leakage interruption function module 21 . The second metal conductive plate 2232a and the fourth metal conductive plate are inclined and connected to each other. Considering the oblique arrangement of the first metal conductive plate 2231a, the second metal conductive plate 2232a, the third metal conductive plate 15, and the fourth metal conductive plate from two aspects, in one aspect, the connection area can be guaranteed, and in another aspect, the total area of the circuit breaker can be reduced, whereby the whole structure can be more compact.

As shown in FIG. 8 and FIG. 9, in this embodiment, the inner angle between the first metal conductive plate 2231a and the horizontal direction is different from the inner angle between the second metal conductive plate 2232a and the horizontal direction. Due to the above construction, the angle of the first metal conductive plate 2231a connected to the main circuit breaker unit 10 is different from the angle of the second metal conductive plate 2232a connected to the leakage circuit breaking function unit 21. When the main circuit breaker unit 10 is assembled with the leakage circuit breaking function unit 21 and the transformer unit 22, the connection position of the main circuit breaker unit 10 and the leakage circuit breaking function unit 21 can be quickly determined by metal conductive plates with different angles. In this way, assembly efficiency can be improved. In this embodiment, the inner angle between the first metal conductive plate 2231a and the horizontal direction is larger than the inner angle between the second metal conductive plate 2232a and the horizontal direction. The inner angle A1 between the first metal conductive plate 2231a and the horizontal direction is preferably 25° to 45°. The inner angle A1 between the first metal conductive plate 2231a and the horizontal direction may be 25°, 30°, 35°, 40°, or 45°. The inner angle A2 between the second metal conductive plate 2232a and the horizontal direction is preferably 25° to 35°. The inner angle A2 between the second metal conductive plate 2232a and the horizontal direction may be 25°, 30°, or 35°.

Of course, the angle of inclination of the first metal conductive plate 2231a can also be the same as the angle of inclination of the second metal conductive plate 2232a so that the assembly can be conveniently realized by automated devices.

As shown in FIG. 8, the first metal conductive plate 2231a is provided with the first elliptical hole 2231b. The second metal conductive plate 2232a is provided with a second elliptical hole 2232b. The third metal conductive plate 15 is provided with a first circular hole 151. The fourth metal conductive plate is provided with a second circular hole. In the above construction, the first metal conductive plate 2231a is conveniently connected to the third metal conductive plate 15 by arranging the first elliptical hole 2231b. The second metal conductive plate 2232a is conveniently connected to the fourth metal conductive plate by arranging the second elliptical hole 2232b. If there is a slight error in position between the first metal conductive plate 2231a and the third metal conductive plate 15 due to processing or assembly, the first metal conductive plate and the third metal conductive plate can still be connected to each other through the first elliptical hole 2231b. If there is a slight error in position between the second metal conductive plate 2232a and the fourth metal conductive plate due to processing or assembly, the second metal conductive plate and the fourth metal conductive plate can still be connected to each other through the second elliptical hole 2232b.

As shown in FIG. 4 and FIG. 7, the first elliptical hole 2231b is connected to the first circular hole 151 by a first screw; and the second elliptical hole 2232b is connected to the second circular hole by a second screw. By using the first screw and the second screw to achieve the connection, simple assembly and low cost are realized.

As shown in FIG. 1-3, the second case 221 is releasably connected to the first case 11 via the first cover plate 31, and is releasably connected to the leakage circuit breaking function unit 21 via the second cover plate 32. The first cover plate 31 and the second cover plate 32 are of a simple structure. Due to the arrangement of the first cover plate and the second cover plate, the main circuit breaker unit 10 and the leakage circuit breaking function module 21 are connected to the transformer module 22. In order to provide a more stable connection between the second case 221 and the first cover plate 31, a slidable block and structure are provided. in the form of a sliding groove. Also disposed between the first case 11 and the first cover plate 31 is a slidable block and a sliding groove structure. The second cover plate 32 and the housing of the leakage circuit breaking function module 21 may be formed as a single structure. Between the second cover plate 32 and the second case 221, a slidable block and a sliding groove structure are disposed.

As shown in FIG. 2, between adjacent side surfaces of the main circuit breaker unit 10 and the leakage circuit breaker unit 20, a locating pin is disposed. Adjacent side surfaces of the main circuit breaker unit 10 and the leakage circuit breaker unit 20 are respectively provided with mounting holes. The two ends of the locating pin respectively pass through the two locating holes. By such an arrangement, the relative position of the main circuit breaker unit 10 and the leakage circuit breaker unit 20 can be fixed. In order to improve the stability of the connection between the main circuit breaker unit 10 and the leakage circuit breaker unit 20, a retainer may be additionally located between the main circuit breaker unit 10 and the leakage circuit breaker unit 20 for the connection.

As shown in FIG. 6, fig. 7 and FIG. 10, the transformer module 22 further includes a support base 225. The support base 225 extends through an internal opening of the annular transformer body 222 and supports the annular transformer body 222. The conductive assembly 223 is mounted on the support base 225. The support base 225 is arranged in the above structure. The support base 225 supports and positions the annular transformer body 222 and the conductive assembly 223, and can further electrically insulate the conductive assembly 223 so that the positions of the annular transformer body 222 and the conductive assembly 223 are fixed and not easily loosened and disturbed. In addition, the assembly of the transformer module 22 is simplified by the arrangement of the support base 225, so that convenient operation is achieved.

As shown in FIG. 10, the first conductive member 2231 includes a first U-shaped enamelled wire. The second conductive element 2232 includes a second U-shaped enamelled wire. The first U-shaped enameled wire and the second U-shaped enameled wire are symmetrically located along the center line of the annular transformer body 222 and have opposite openings. The annular transformer case 222 is located in the opening of the first U-shaped enameled wire and the opening of the second U-shaped enameled wire. The first U-shaped enameled wire and the second U-shaped enameled wire are made of hard conductive materials, so that the connection is more convenient and the structure is more stable. In addition, the first U-shaped enameled wire and the second U-shaped enameled wire can limit the annular transformer body 222 so that loosening is prevented, thereby further improving the stability of the transformer module 22.

Additionally, the support base 225 is provided with a first groove accommodating the first U-shaped enameled wire and a second groove accommodating the second U-shaped enameled wire. The first U-shaped enameled wire may be installed by means of the first groove to ensure that the first U-shaped enameled wire is in a stable position. The second U-shaped enameled wire can be installed by means of the second groove to ensure the stable position of the second U-shaped enameled wire.

It can be seen from the above description that the following technical effects are realized in the above embodiments of the utility model.

The leakage circuit breaker unit 20 is divided into two parts, which are the leakage breaking function unit 21 and the transformer unit 22. The transformer unit 22 is located at the output terminal of the main circuit breaker unit 10 and the output terminal of the main circuit breaker unit 21 and the leakage. Thus, the transformer module 22 is closer to the output terminals of the main circuit breaker unit 10 and the leakage circuit breaking function module 21 to achieve a more convenient and reliable connection. In addition, the overall width of the circuit breaker can be effectively reduced by the above structure. The transformer module 22 is detachably connected to the main circuit breaker unit 10 and is detachably connected to the leakage circuit breaking function module 21 . Therefore, the main circuit breaker unit 10, the leakage circuit breaking function unit 21, and the transformer unit 22 are independent from each other so that each unit can be separately detected and maintained. The block 10 of the main circuit breaker contains a contact assembly 12, a tripping mechanism 13 and a magnetic protection assembly 14, which are located in the first casing 11. One end of the magnetic protection assembly 14 is detachably connected to the transformer module 22, and the other end is connected to the contact assembly 12. Assembly 14 magnetic protection can provide rotation of the tripping mechanism 13; and the tripping mechanism 13 drives the contact assembly 12.

The foregoing is only preferred embodiments of the utility model and is not intended to limit the utility model. For specialists in this field of technology, the utility model may have various modifications and options. Any modifications, equivalent replacements, improvements, etc., carried out in accordance with the essence and principle of the utility model, are included in the scope of legal protection of the utility model.

Claims (12)

1. Circuit breaker, comprising: a main circuit breaker unit (10) and a leakage circuit breaker unit (20), wherein the leakage circuit breaker unit (20) comprises a leakage circuit breaking function module (21) and a transformer module (22); the module (21) of the function of interrupting the circuit in case of leakage and the block (10) of the main circuit breaker are located next to each other; the output terminal of the main circuit breaker unit (10) and the output terminal of the leakage circuit breaking function module (21) are located on the same side; the input terminal of the transformer module (22) is located on the output terminal of the main circuit breaker unit (10) and the output terminal of the leakage circuit breaking function module (21); the block (10) of the main circuit breaker contains the first casing (11), as well as the contact assembly (12), the disconnecting mechanism (13) and the assembly (14) of the magnetic protection, which are located in the first casing (11); the node (14) of magnetic protection is located between the transformer module (22) and the contact node (12). 2. The circuit breaker according to claim 1, characterized in that the transformer module (22) is detachably connected to the main circuit breaker unit (10) and detachably connected to the leakage circuit breaking function module (21); the transformer module (22) includes a second casing (221), an annular casing (222) of the transformer, a conductive assembly (223) and a terminal block (224); moreover, the annular case (222) of the transformer, the conductive assembly (223) and the terminal block (224) are located in the second casing (221); the conductive assembly (223) passes through the inner hole of the annular housing (222) of the transformer; the first end of the conductive node (223) is connected to the terminal block (224); and the second end of the conductive assembly (223) is releasably connected to the main circuit breaker unit (10), and releasably connected to the leakage circuit breaking function module (21); node (14) magnetic protection can provide rotation of the tripping mechanism (13); and the tripping mechanism (13) drives the contact assembly (12). 3. The circuit breaker according to claim 2, characterized in that the conductive assembly (223) contains a first conductive element (2231) and a second conductive element (2232); the first metal conductive plate (2231a) is located on the end portion of the first conductive element (2231); the second metal conductive plate (2232a) is located on the end portion of the second conductive element (2232); block (10) of the main circuit breaker further comprises a third metal conductive plate (15) located outside the first casing (11); the leakage breaking function module (21) comprises a fourth metal conductive plate; the first metal conductive plate (2231a) and the third metal conductive plate (15) are inclined and connected to each other; and the second metal conductive plate (2232a) and the fourth metal conductive plate are inclined and connected to each other. 4. Circuit breaker according to claim 3, characterized in that the inside angle between the first metal conductive plate (2231a) and the horizontal direction is different from the inside angle between the second metal conductive plate (2232a) and the horizontal direction. 5. Circuit breaker according to claim 3, characterized in that the first metal conductive plate (2231a) is provided with a first elliptical hole (2231b); the second metal conductive plate (2232a) is provided with a second elliptical hole (2232b); the third metal conductive plate (15) is provided with a first circular hole (151); and the fourth metal conductive plate is provided with a second circular hole. 6. Circuit breaker according to claim 5, characterized in that the first elliptical hole (2231b) is connected to the first circular hole (151) by the first screw; and the second elliptical hole (2232b) is connected to the second circular hole by a second screw. 7. Circuit breaker according to claim 2, characterized in that the second casing (221) is releasably connected to the first casing (11) via the first cover plate (31) and is releasably connected to the leakage circuit breaking function module (21) via the second cover plate (32); and the locating pin is located between adjacent side surfaces of the main circuit breaker unit (10) and the leakage circuit breaker unit (20). 8. Circuit breaker according to claim 3, characterized in that the transformer module (22) further comprises a support base (225); the supporting base (225) passes through the inner hole of the annular body (222) of the transformer and supports the annular body (222) of the transformer; and the conductive assembly (223) is mounted on the support base (225). 9. Circuit breaker according to claim 8, characterized in that the first conductive element (2231) contains the first U-shaped enameled wire; the second conductive element (2232) contains a second U-shaped enameled wire; the first U-shaped enameled wire and the second U-shaped enameled wire are symmetrically located along the center line of the annular case (222) of the transformer and have opposite openings; the annular case (222) of the transformer is located in the opening of the first U-shaped enameled wire and the opening of the second U-shaped enameled wire. 10. Circuit breaker according to claim 9, characterized in that the support base (225) is provided with a first groove accommodating the first U-shaped enameled wire and a second groove accommodating the second U-shaped enameled wire.

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