CN115497772A

CN115497772A - Multi-phase electromagnetic relay

Info

Publication number: CN115497772A
Application number: CN202210970467.3A
Authority: CN
Inventors: 钟叔明; 代文广; 李方能; 殷剑锋; 江子煜
Original assignee: Xiamen Hongfa Electric Power Controls Co Ltd
Current assignee: Xiamen Hongfa Electric Power Controls Co Ltd
Priority date: 2021-06-18
Filing date: 2021-06-18
Publication date: 2022-12-20
Also published as: CN113611575A

Abstract

The invention discloses a multiphase electromagnetic relay, which comprises a plurality of outgoing terminals and a plurality of movable and static contact matching structures, wherein each outgoing terminal comprises an incoming terminal and an outgoing terminal, and a movable and static contact matching structure is matched between the incoming terminal and the outgoing terminal of the same path; a plurality of incoming wire terminal sets up move, one side of stationary contact mating structure, it is a plurality of terminal outgoing lines sets up move, the opposite side of stationary contact mating structure, it is a plurality of between the incoming wire terminal, a plurality of between the terminal outgoing lines a plurality of incoming wire terminal and a plurality of separate each other between the terminal outgoing lines not crisscross, a plurality of incoming wire terminal and a plurality of terminal outgoing lines's outer link all extends towards same direction, and the outer link of incoming wire terminal on the same way and terminal outgoing lines's outer link are in the corresponding setting in both sides of moving, stationary contact mating structure.

Description

Multi-phase electromagnetic relay

Technical Field

The invention relates to the technical field of electric power, in particular to a multiphase electromagnetic relay.

Background

The multiphase electromagnetic relay is mainly applied to an electric power system, for example, the three-phase electromagnetic relay is internally provided with three groups of contact parts consisting of three groups of moving and static spring parts, and can realize the control of the on or off of three-phase power of the load. The multiphase electromagnetic relay generally comprises a shell and a plurality of outgoing terminals led out from the shell, wherein each outgoing terminal comprises an incoming terminal and an outgoing terminal, the incoming terminals and the outgoing terminals in the same path are respectively communicated with the same group of movable and static contact structures in the shell, when the movable contacts and the static contacts in the same group are in contact, the incoming terminals and the outgoing terminals in the same path are communicated, and when the movable contacts and the static contacts in the same group are separated, the incoming terminals and the outgoing terminals in the same path are not communicated. In the multi-phase electromagnetic relay in the prior art, the incoming line terminals and the outgoing line terminals in the same path are usually led out from the housing in a mutually adjacent manner, and due to the requirement of external flat cables, for example, the requirement of one-to-eight-out flat cables of the three-phase electromagnetic relay, some incoming line terminals or outgoing line terminals need to be led out by crossing over the incoming line terminals or outgoing line terminals in other paths, so that a part of the incoming line terminals and outgoing line terminals need to be distributed in a staggered manner. In addition, in the multi-phase electromagnetic relay in the prior art, the incoming line terminal and the outgoing line terminal of the same path respectively adopt a static spring sheet and a movable spring leading-out sheet, and the movable spring part and the static spring part in the relay form a Z-bending structure structurally, thereby causing the defects of high copper consumption and high cost.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a multiphase electromagnetic relay, which can avoid the staggered arrangement of copper pieces (namely leading-out terminals) through structural improvement, further solve the complex problems of insulation and spot welding and reduce copper consumption; on the other hand, copper consumption of the movable spring part and the static spring part in the relay can be saved, and further cost is reduced.

The technical scheme adopted by the invention for solving the technical problems is as follows: a multiphase electromagnetic relay comprises a shell, a plurality of paths of leading-out terminals leading out from the shell and a plurality of movable and static contact matching structures arranged in the shell, wherein each path of leading-out terminal comprises an incoming line terminal and an outgoing line terminal; the shell is rectangular; each incoming line terminal is led out from one first side wall of the four side walls of the shell, each outgoing line terminal is led out from the second side wall of the shell, and the second side wall and the first side wall are distributed oppositely; each incoming line terminal and each outgoing line terminal are bent outside a shell in a non-staggered interval mode to the outside of a third side wall of the shell, the outer connecting end of each incoming line terminal and the outer connecting end of each outgoing line terminal are arranged outside the third side wall to form a row parallel to the third side wall, and the incoming line terminals and the outgoing line terminals in the same path are respectively located at corresponding positions on two sides of the same row; the third sidewall is connected between the first sidewall and the second sidewall.

And an outer connecting end of a zero line incoming wire and an outer connecting end of a zero line outgoing wire are also distributed between the outer connecting end of each incoming wire terminal and the outer connecting end of each outgoing wire terminal, and the outer connecting end of the zero line incoming wire and the outer connecting end of the zero line outgoing wire are connected through a first electric connecting sheet.

An outer connecting piece is arranged at each outer connecting end and comprises at least one annular terminal and a soldering lug, the at least one annular terminal is movably matched with one end of the soldering lug, and the other end of the soldering lug is welded and fixed with one corresponding one of the incoming line terminal, the outgoing line terminal and the first electric connecting piece; the ring terminal is also fitted with a screw.

Each incoming terminal and each outgoing terminal are of a sheet-type structure, each incoming terminal and each outgoing terminal respectively comprise a first portion extending outwards from the inside of the shell in a mode of being perpendicular to the side wall of the shell and a second portion connected with the first portion in a bent mode, and the outer connecting end is located at the second portion.

The first part and the second part are integrally connected at the bent part.

The first part and the second part are two independent parts, and the first part and the second part are welded and fixed at the bent part.

The second portion of each of the inlet terminals includes a splitter vane structure for collecting the current signal.

The movable contact and the fixed contact matching structure comprise a first fixed spring, a first fixed contact, a first movable spring, a first movable contact, a second fixed spring, a second fixed contact, a second movable spring and a second movable contact; the first fixed contact is fixed with one end of the first fixed spring piece and one end of the first movable spring piece, the first movable contact is fixed at the other end of the first movable spring piece, the second fixed contact is fixed with one end of the second fixed spring piece and one end of the second movable spring piece, and the second movable contact is fixed at the other end of the second movable spring piece; the first fixed contact is matched with the second movable contact correspondingly, and the second fixed contact is matched with the first movable contact correspondingly; the first static reed is an incoming terminal, and the second static reed is an outgoing terminal.

A plurality of slots are respectively arranged in the first side wall and the second side wall of the shell; each first static spring plate is respectively inserted into a slot of a first side wall of the shell, and one end of each first static spring plate is closer to the first side wall relative to the second side wall; each second static spring plate is respectively inserted into the slot of the second side wall of the shell, and one end of each second static spring plate is closer to the second side wall relative to the first side wall.

The first movable spring plate and the second movable spring plate are distributed in a substantially parallel manner, and the first movable spring plate and the second movable spring plate are respectively formed by overlapping a plurality of spring plates; the first movable spring is provided with a first bending part protruding towards the second spring, the second movable spring is provided with a second bending part protruding towards the first spring, and the first bending part and the second bending part are in staggered distribution.

The multiphase electromagnetic relay also comprises a magnetic circuit part and a push card; the shell is provided with a partition plate in the middle of the thickness so as to divide the shell into an upper layer and a lower layer; the magnetic circuit part is arranged on the upper layer of the shell; the movable contact and the static contact matching structure are arranged on the lower layer of the shell; the magnetic circuit part comprises an armature component, the armature component is provided with a pushing arm, and the pushing arm penetrates through the lower layer of the shell and is matched with a movable reed in the movable contact and static contact matching structure through the pushing card.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, each incoming line terminal is respectively led out from one first side wall of the four side walls of the shell, each outgoing line terminal is respectively led out from the second side wall of the shell, and the second side wall and the first side wall are distributed oppositely; each incoming line terminal and each outgoing line terminal are bent outside a shell in a non-staggered interval mode to the outside of a third side wall of the shell, the outer connecting ends of each incoming line terminal and each outgoing line terminal are arranged outside the third side wall in a row parallel to the third side wall, and the incoming line terminals and the outgoing line terminals in the same path are respectively located at the corresponding positions on the two sides of the same row; the third sidewall is connected between the first sidewall and the second sidewall. The structure of the invention avoids the staggered arrangement of the copper pieces (namely the leading-out terminals), can reduce the copper consumption (the leading-out terminals are made of copper materials), reduce the cost, simplify the forming of the copper pieces (namely the leading-out terminals), facilitate the assembly, simplify the spot welding process and ensure the safe distance of a strong electric room.

2. The invention adopts the design that the matching structure of the movable contact and the fixed contact comprises a first fixed spring, a first fixed contact, a first movable spring, a first movable contact, a second fixed spring, a second fixed contact, a second movable spring and a second movable contact; the first fixed contact is fixed with one end of the first fixed spring piece and one end of the first movable spring piece, the first movable contact is fixed at the other end of the first movable spring piece, the second fixed contact is fixed with one end of the second fixed spring piece and one end of the second movable spring piece, and the second movable contact is fixed at the other end of the second movable spring piece; the first fixed contact is matched with the second movable contact correspondingly, and the second fixed contact is matched with the first movable contact correspondingly; the first static reed is an incoming terminal, and the second static reed is an outgoing terminal. The structure of the invention designs the matching structure of the movable contact and the static contact into a double movable spring component parallel structure, which can save the copper consumption of the movable spring part and the static spring part in the relay and further reduce the cost.

The invention is further explained in detail with the accompanying drawings and the embodiments; a multiphase electromagnetic relay of the present invention is not limited to the embodiment.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present invention;

FIG. 2 is a front view of an embodiment of the present invention;

FIG. 3 is a top view of an embodiment of the present invention;

FIG. 4 is a side view of the invention shown in FIG. 3;

FIG. 5 is an exploded perspective view of an embodiment of the present invention;

FIG. 6 is a schematic perspective view of an embodiment of the present invention (with the upper housing removed);

FIG. 7 is a schematic perspective view of an embodiment of the present invention (bottom up and with the lower housing removed);

FIG. 8 is a schematic view of various moving and stationary contact mating structures of an embodiment of the present invention;

FIG. 9 is a top view of various moving and stationary contact mating structures of an embodiment of the present invention;

FIG. 10 is a schematic view of the engagement of the various moving and stationary contact engagement structures with the magnetic circuit portion and the pusher card of the embodiment of the present invention;

FIG. 11 is a schematic view (bottom up) of the engagement of the magnetic circuit portion and the push card with the respective moving and stationary contact engagement structures of the embodiment of the present invention;

fig. 12 is a schematic diagram of the mating of the movable spring, pusher card and armature assembly of an embodiment of the invention.

Detailed Description

Examples

Referring to fig. 1 to 12, the multiphase electromagnetic relay of the present invention includes a housing 1, multiple paths of leading-out terminals led out from the housing, and multiple moving and static contact matching structures installed in the housing, where each path of leading-out terminal includes an incoming terminal 2 and an outgoing terminal 3, and a moving and static contact matching structure is matched between the incoming terminal 2 and the outgoing terminal 3 in the same path; the embodiment is a three-phase electromagnetic relay used for controlling a three-phase power supply in a power system; the incoming terminal 2 has three

incoming terminals

21, 22, 23, and the outgoing terminal 3 also has three

outgoing terminals

31, 32, 33; incoming line terminal 21 and outgoing line terminal 31 are the same path, incoming line terminal 22 and outgoing line terminal 32 are the same path, and incoming line terminal 23 and outgoing line terminal 33 are the same path; the shell 1 is rectangular; the shell 1 is composed of an upper shell 11, a shell 12 and a lower shell 13, wherein the upper shell 11 and the lower shell 13 are respectively fixed at the upper end and the lower end of the shell 12; the three

inlet terminals

21, 22, and 23 are respectively led out from one first sidewall 121 of the four sidewalls of the housing 1, the first sidewall 121 is one of the four sidewalls of the housing, the three

outlet terminals

31, 32, and 33 are respectively led out from a second sidewall 122 of the housing, the second sidewall 122 is also located in the housing, and the second sidewall 122 and the first sidewall 121 are distributed oppositely; the three

incoming lines

21, 22, 23 and the three

outgoing lines

31, 32, 33 are respectively bent outside the housing 1 without intervals in a staggered manner to the outside of the third sidewall 123 of the housing, and the external connection ends 211, 221, 231 of the three

incoming lines

21, 22, 23 and the external connection ends 311, 321, 331 of the three

outgoing lines

31, 32, 33 are arranged in a row parallel to the third sidewall 123 outside the third sidewall 123, and the incoming lines and the outgoing lines in the same path are respectively located at the corresponding positions on two sides of the same row, as shown in fig. 3, the incoming line 23 in the first position on the left and the outgoing line 33 in the first position on the right belong to the same path, the incoming line 22 in the second position inward on the left and the outgoing line 32 in the second position inward on the right belong to the same path, and the incoming line 21 in the third position inward on the left and the outgoing line 31 in the third position on the right belong to the same path; the third sidewall 123 is connected between the first sidewall 121 and the second sidewall 122; the third side wall 123 of the housing is also located in the housing 12.

In this embodiment, an outer connecting end 411 of a neutral wire and an outer connecting end 412 of a neutral wire are further distributed between the outer connecting

ends

211, 221, 231 of the three

incoming terminals

21, 22, 23 and the

outer connecting ends

311, 321, 331 of the three

outgoing terminals

31, 32, 33, and the outer connecting end 411 of the neutral wire and the outer connecting end 412 of the neutral wire are connected through a first electrical connecting sheet 41.

In this embodiment, each external connection end is provided with an external connection member, and the same external connection member 5 is used at each external connection end (including the external connection ends 211, 221, 231 of the three

incoming lines

21, 22, 23, the external connection ends 311, 321, 331 of the three

outgoing lines

31, 32, 33, the external connection end 411 of the neutral incoming line, and the external connection end of the neutral outgoing line).

In this embodiment, the outer connecting member 5 includes two annular terminals 51 and a soldering lug 52, the two annular terminals 51 are movably fitted at one end of the soldering lug 52, the other end of the soldering lug 52 is fixed to a corresponding one of the incoming line terminal, the outgoing line terminal and the first electrical connection lug in a welding manner, for example, the other end of the soldering lug 52 of the outer connecting member 5 for the incoming line terminal is fixed to the incoming line terminal in a welding manner, the other end of the soldering lug 52 of the outer connecting member 5 for the outgoing line terminal is fixed to the outgoing line terminal in a welding manner, the other end of the soldering lug 52 of the outer connecting member 5 for the incoming line terminal is fixed to the incoming line terminal in a welding manner, and the other end of the soldering lug 52 of the outer connecting member 5 for the neutral line incoming line and the neutral line outgoing line is fixed to the first electrical connection lug 41 in a welding manner; the ring terminal 51 is also fitted with a screw 53 by which an external wiring is fixed to one end of the tab 52, so that the ring terminal 51 is also fixed.

In this embodiment, the three

incoming terminals

21, 22, 23 and the three

outgoing terminals

31, 32, 33 are all of a sheet type structure, each of the incoming terminals and each of the outgoing terminals includes a first portion extending outward from the housing in a manner perpendicular to the side wall of the housing, and a second portion bent and connected to the first portion, and the external connection end is located at the second portion. Specifically, the wire inlet terminal 21 includes a first portion 212 extending outward from the housing in a manner perpendicular to the first sidewall 121 of the housing, and a second portion 213 connected to the first portion 212 in a bent manner, and the outer connecting end 211 is located at the second portion 213; wire terminal 22 includes a first portion 222 extending outwardly from the housing perpendicular to first sidewall 121 of the housing and a second portion 223 joined by a bend to first portion 222, wherein outer connection end 221 is at second portion 223; the wire terminal 23 comprises a first portion 232 extending outward from the housing in a manner perpendicular to the first sidewall 121 of the housing, and a second portion 233 connected to the first portion 232 by bending, wherein the outer connecting end 231 is located at the second portion 233; the outlet terminal 31 comprises a first part 312 extending outwards from the inside of the shell in a manner of being perpendicular to the second side wall 122 of the shell and a second part 313 connected with the first part 312 in a bending way, wherein the outer connecting end 311 is positioned in the second part 313; the outlet terminal 32 includes a first portion 322 extending outward from the housing perpendicular to the second sidewall 122 of the housing, and a second portion 323 connected to the first portion 322 by bending, wherein the external connection end 321 is located at the second portion 323; the outlet terminal 33 includes a first portion 332 extending outwardly from the housing perpendicular to the second side wall 122 of the housing and a second portion 333 bent into engagement with the first portion 332, the outer terminal 331 being located in the second portion 333.

In this embodiment, the first portion 212 and the second portion 213 of the incoming terminal 21 are integrally connected at the bend; first portion 222 and second portion 223 of wire terminal 22 are integrally joined at a bend; the first part 232 and the second part 233 of the wire terminal 23 are two independent parts, and the first part 232 and the second part 233 are welded and fixed at the bent part; the first part 312 and the second part 313 of the outlet terminal 31 are integrally connected at the bent part; the first part 322 and the second part 323 of the outlet terminal 32 are integrally connected at the bent part; the first part 332 and the second part 333 of the outlet terminal 33 are two independent parts, and the first part 332 and the second part 333 are welded and fixed at the bent part.

In this embodiment,

second portions

213, 223, 233 of three

inlet terminals

21, 22, 23 include

splitter vane structures

214, 224, 234, respectively, for collecting current signals. A splitter structure 413 for collecting current signals is also provided on the first electrical connection tab 41.

In this embodiment, the three moving and stationary

contact mating structures

61, 62, 63 correspondingly disposed between the three

incoming terminals

21, 22, 23 and the three

outgoing terminals

31, 32, 33 are identical in structure, and the moving and stationary contact mating structure 62 correspondingly disposed between the incoming terminal 22 and the outgoing terminal 32 is taken as an example to illustrate the moving and stationary contact mating structure. The movable contact and fixed contact matching structure 62 comprises a first fixed spring 621, a first fixed contact 622, a first movable spring 623, a first movable contact 624, a second fixed spring 625, a second fixed contact 626, a second movable spring 627 and a second movable contact 628; the first fixed contact 622 is fixed with one end of the first fixed spring 621 and one end of the first movable spring 623, the first movable contact 624 is fixed with the other end of the first movable spring 623, the second fixed contact 626 is fixed with one end of the second fixed spring 625 and one end of the second movable spring 627, and the second movable contact 628 is fixed with the other end of the second movable spring 627; the first stationary contact 622 is correspondingly mated with the second movable contact 628, and the second stationary contact 626 is correspondingly mated with the first movable contact 624; the first stationary reed 621 is an incoming terminal 22, and the second stationary reed 625 is an outgoing terminal 32.

In this embodiment, three slots 124 are respectively disposed in the first side wall 121 and the second side wall 122 of the housing 1; each first stationary spring (i.e. the corresponding inlet terminal) is inserted into the insertion slot 124 of the first side wall 121 of the housing 1, and one end of the first stationary spring is closer to the first side wall relative to the second side wall; each second stationary spring (i.e., the corresponding outlet terminal) is inserted into the insertion slot 124 of the second sidewall 122 of the housing 1, and one end of the second stationary spring is closer to the second sidewall than to the first sidewall.

In this embodiment, taking the movable and stationary contact mating structure 62 correspondingly disposed between the incoming terminal 22 and the outgoing terminal 32 as an example, the first movable spring plate 623 and the second movable spring plate 627 are distributed substantially in parallel, and the first movable spring plate 623 and the second movable spring plate 727 are respectively formed by stacking a plurality of spring plates; the first movable spring 623 is provided with a first bending portion 6231 protruding toward the second spring, the second movable spring 627 is provided with a second bending portion 6271 protruding toward the first spring, and the first bending portion 6231 and the second bending portion 6271 are distributed in a staggered manner.

In the present embodiment, the multiphase electromagnetic relay further includes a magnetic circuit portion 7 and a push card 8; the shell 1 is provided with a partition plate 14 in the middle of the thickness so as to divide the shell 1 into an upper layer and a lower layer; the magnetic circuit part 7 is arranged on the upper layer of the shell 1; the movable contact and the static contact matching structure are arranged on the lower layer of the shell 1; the magnetic circuit part 7 comprises an armature assembly 71, the armature assembly 71 is provided with two pushing arms 72, the pushing arms 72 penetrate to the lower layer of the shell 1 and are matched with the movable reeds in the movable contact and static contact matching structures through the pushing clamp 8, and the number of the pushing clamps 8 is two.

The invention relates to a multiphase electromagnetic relay, which is characterized in that each

incoming line terminal

21, 22 and 23 is respectively led out from one first side wall 121 of four side walls of a shell 1, each

outgoing line terminal

31, 32 and 33 is respectively led out from a second side wall 122 of the shell 1, and the second side wall 122 and the first side wall 121 are distributed oppositely; each of the

incoming terminals

21, 22, 23 and each of the

outgoing terminals

31, 32, 33 are respectively bent outside the housing 1 in a non-staggered spaced manner to the outside of the third side wall 123 of the housing, and the external connection ends 211, 221, 231 of each of the

incoming terminals

21, 22, 23 and the external connection ends 311, 321, 331 of each of the

outgoing terminals

31, 32, 33 are arranged outside the third side wall in a row parallel to the third side wall 123, and the incoming terminals and the outgoing terminals in the same path are respectively located at corresponding positions on two sides of the same row; the third sidewall 123 is vertically connected between the first sidewall 121 and the second sidewall 122. The structure of the invention avoids the staggered arrangement of the copper pieces (namely the leading-out terminals), can reduce the copper consumption (the leading-out terminals are made of copper materials), reduce the cost, simplify the forming of the copper pieces (namely the leading-out terminals), facilitate the assembly, simplify the spot welding process and ensure the safe distance of a strong electric room.

The invention relates to a multiphase electromagnetic relay, which adopts a design that a movable contact and a fixed contact are matched to form a structure comprising a first fixed spring, a first fixed contact, a first movable spring, a first movable contact, a second fixed spring, a second fixed contact, a second movable spring and a second movable contact; the first fixed contact is fixed with one end of the first fixed spring piece and one end of the first movable spring piece, the first movable contact is fixed at the other end of the first movable spring piece, the second fixed contact is fixed with one end of the second fixed spring piece and one end of the second movable spring piece, and the second movable contact is fixed at the other end of the second movable spring piece; the first fixed contact is matched with the second movable contact correspondingly, and the second fixed contact is matched with the first movable contact correspondingly; the first static reed is an incoming terminal, and the second static reed is an outgoing terminal. The structure of the invention designs the matching structure of the movable contact and the static contact into a double movable spring component parallel structure, which can save the copper consumption of the movable spring component and the static spring component in the relay and further reduce the cost.

The foregoing is considered as illustrative of the preferred embodiments of the invention and is not to be construed as limiting the invention in any way. Although the present invention has been described with reference to the preferred embodiments, it is not intended to be limited thereto. Those skilled in the art can make many possible variations and modifications to the disclosed embodiments, or equivalent modifications, without departing from the scope of the disclosed embodiments. Therefore, any simple modification, equivalent change and modification made to the above embodiments according to the technical spirit of the present invention should fall within the protection scope of the technical scheme of the present invention, unless the technical spirit of the present invention departs from the content of the technical scheme of the present invention.

Claims

1. A multiphase electromagnetic relay comprises a plurality of lead-out terminals and a plurality of movable and static contact matching structures, wherein each lead-out terminal comprises an incoming line terminal and an outgoing line terminal, and the movable and static contact matching structures are matched between the incoming line terminal and the outgoing line terminal of the same path; the method is characterized in that: it is a plurality of incoming wire terminal sets up move, one side of stationary contact cooperation structure, it is a plurality of terminal outgoing lines sets up move, the opposite side of stationary contact cooperation structure, it is a plurality of between the incoming wire terminal, a plurality of between the terminal outgoing lines and a plurality of separate each other not crisscross between the terminal outgoing lines, it is a plurality of incoming wire terminal and a plurality of terminal outgoing lines's outer link all extends towards same direction, and the outer link of the terminal outgoing lines of same way and terminal outgoing lines's outer link are in move, the both sides of stationary contact cooperation structure are corresponding to be set up.

2. A multiphase electromagnetic relay according to claim 1, characterized in that: the outer connecting ends of the plurality of inlet terminals and the outer connecting ends of the plurality of outlet terminals are arranged in a row.

3. A multiphase electromagnetic relay according to claim 1, characterized in that: the plurality of incoming line terminals and the plurality of outgoing line terminals are arranged oppositely, each of the plurality of incoming line terminals and the plurality of outgoing line terminals comprises an L-shaped body which comprises a first portion and a second portion, and one end of the second portion is the outer connecting end.

4. A multiphase electromagnetic relay according to claim 3, characterized in that: the body is of a sheet-type structure.

5. A multiphase electromagnetic relay according to claim 3, characterized in that: the first part and the second part are of an integral structure.

6. A multiphase electromagnetic relay according to claim 3, characterized in that: the first part and the second part are two independent parts and are fixed together through welding.

7. A multiphase electromagnetic relay according to claim 3, characterized in that: a second portion of the plurality of inlet terminals includes a splitter blade for collecting a current signal.

8. A multiphase electromagnetic relay according to claim 1, characterized in that: the zero line outgoing line device is characterized in that an outer connecting end of a zero line incoming line and an outer connecting end of a zero line outgoing line are further distributed between the outer connecting end of the incoming line terminal and the outer connecting end of the outgoing line terminal, and the outer connecting end of the zero line incoming line and the outer connecting end of the zero line outgoing line are connected through an electric connecting sheet.

9. A multiphase electromagnetic relay according to claim 8, characterized in that: the outer connecting ends of the plurality of incoming line terminals, the outer connecting ends of the plurality of outgoing line terminals, the outer connecting end of the zero line incoming line and the outer connecting end of the zero line outgoing line are arranged in a row.

10. A multiphase electromagnetic relay according to claim 8, characterized in that: still include a plurality of outer connecting pieces, a plurality of outer connecting pieces set up respectively in a plurality of the outer link of incoming line terminal is with a plurality of the outer link of outgoing line terminal.