CN216214274U - Conductive connector, jack box and power supply distribution device - Google Patents

Abstract

The utility model relates to the technical field of electrical equipment, and provides a conductive connector, a jack box and a power supply distribution device, wherein the conductive connector is applied to the power supply distribution device, the power supply distribution device comprises a bus duct, the conductive connector comprises a conductive insulating shell, a limiting structure and a connector conductor, the conductive insulating shell comprises an installation part, the limiting structure comprises a first limiting part and a second limiting part, the first limiting part and the second limiting part are arranged on the inner wall of the shell structure at intervals from top to bottom, the connector conductor comprises a first connecting part and a bent part which are connected with each other, the bent part is arranged in the shell structure, and the top and the bottom of the bent part are respectively abutted against the first limiting part and the second limiting part; the first connecting part is arranged outside the shell structure and is suitable for being connected with the bus duct; the utility model effectively prevents the joint conductor from separating from the conductive insulating shell, thereby ensuring the quality and the service life of the conductive joint.

Description

Conductive connector, jack box and power supply distribution device

Technical Field

The utility model relates to the technical field of electrical equipment, in particular to a conductive connector, a jack box and a power supply distribution device.

Background

The jack box is used as a functional unit of a power transmission bus duct and plays a role in electric energy distribution in a bus duct system. The top plate of the jack box is provided with a conductive head, and the jack box is connected with a conductive busbar in the bus duct through the conductive head, so that the switching of electric energy is realized. The conductive head in the prior art comprises a conductive shell and a joint conductor, wherein the joint conductor is embedded into the conductive shell, but the joint conductor and the conductive busbar in the conductive head are connected in a plugging process due to the fact that the joint conductor is a straight plate conductor, and the problem that looseness occurs between the joint conductor and the conductive shell frequently occurs, so that the quality and the service life of the conductive head are influenced.

SUMMERY OF THE UTILITY MODEL

The utility model solves the problem of how to design a conductive connector with a more stable structure.

In order to solve the above problems, the present invention provides a conductive connector, including:

the conductive insulating shell comprises an installation part which is a shell structure with a hollow interior;

the limiting structure comprises a first limiting part and a second limiting part, and the first limiting part and the second limiting part are arranged on the inner wall of the shell structure at intervals up and down;

the joint conductor comprises a first connecting part and a bent part which are connected with each other, the bent part is arranged in the shell structure, and the top and the bottom of the bent part are respectively abutted against the first limiting part and the second limiting part; the first connecting portion is arranged outside the shell structure and is suitable for being connected with the bus duct.

Optionally, the conductive insulating housing further includes an insertion portion, the insertion portion is connected to the top end of the mounting portion, the insertion portion is provided with a plurality of insertion slots arranged at intervals, the number of the joint conductors is multiple, and each first connection portion of each joint conductor is located in each insertion slot.

Optionally, the insertion part comprises a first insertion piece and a second insertion piece which are arranged oppositely, the mounting part comprises a first mounting shell and a second mounting shell which are arranged oppositely, the first insertion piece is connected with the top end of the first mounting shell, and the second insertion piece is connected with the top end of the second mounting shell; the first plug connector and the second plug connector are respectively provided with a plurality of first plug-in grooves and a plurality of second plug-in grooves which are arranged at intervals, and the first plug-in grooves are correspondingly communicated with the second plug-in grooves to form the slots.

Optionally, the electrically insulating shell further comprises a plurality of isolation structures, and the bent portion in the joint conductor is disposed between two adjacent isolation structures; the isolation structure comprises a plurality of first isolators and a plurality of second isolators, wherein the first isolators are arranged on the inner wall of the first installation shell at intervals, and the second isolators are arranged on the inner wall of the second installation shell at intervals.

Optionally, the conductive insulation shell further includes a plurality of first studs and a plurality of second studs, the plurality of first studs are disposed on the inner wall of the first mounting shell at intervals, and the plurality of second studs are disposed on the inner wall of the second mounting shell at intervals; and each first stud is connected with each second stud through a connecting bolt.

Optionally, a limiting groove is formed on the bending portion, and each of the first studs and each of the second studs are located in the limiting groove of the bending portion in each of the corresponding joint conductors.

Optionally, each joint conductor further includes an extension portion and a second connecting portion, the top end of the extension portion is connected to the bottom end of the bending portion, the second connecting portion includes a plurality of wire pressing pipes with different calibers, and the plurality of wire pressing pipes are arranged at intervals on the bending portion and/or the extension portion.

Optionally, the limiting structure further includes a plurality of third limiting portions, the third limiting portions are disposed in the casing structure at intervals, positioning grooves are formed in the third limiting portions, and the bending portions of the joint conductors are embedded in the positioning grooves of the third limiting portions.

Compared with the prior art, the bent part is arranged in the conductive insulating shell which is of a shell structure, and the first connecting part in the joint conductor is arranged outside the mounting part, so that a worker can hold the mounting part in the conductive insulating shell conveniently and can carry out safe adaptive splicing on the first connecting part and the bus duct; through installing the kink in shell structure, and make the top and the bottom of kink offset with the spacing portion of first spacing portion and second respectively, thereby at the frequent plug in-process with first connecting portion and bus duct, first spacing portion and the spacing portion of second play and spacing about butt joint conductor and bus duct in the plug orientation, prevent effectively that the joint conductor from breaking away from the electrically conductive insulating shell, guarantee the installation stability of joint conductor in the electrically conductive insulating shell, and then guarantee the quality and the life of electrically conductive connector.

The utility model also provides a jack box, which comprises the conductive connector, a box body, a connecting plate and a switch structure, wherein the middle mounting part of the conductive connector is connected with the box body through the connecting plate, the switch structure is arranged in the box body, the middle bending part of the conductive connector is electrically connected with the switch structure, and the beneficial effects of the jack box are the same as those of the conductive connector, which are not repeated herein.

The utility model also provides a power supply distribution device, which comprises the jack box and a bus duct, wherein the bus duct comprises a conductive bus bar, a first connecting part in a conductive connector of the jack box is suitable for being arranged in a manner of being tightly attached to the conductive bus bar, and the beneficial effects of the power supply distribution device are the same as those of the jack box, and are not repeated herein.

Drawings

Fig. 1 is a schematic structural diagram of a conductive connector according to an embodiment of the utility model;

FIG. 2 is an exploded view of an embodiment of a conductive connector according to the present invention;

fig. 3 is a partial schematic structural view of a conductive connector according to an embodiment of the utility model;

FIG. 4 is a schematic structural diagram of a joint conductor according to an embodiment of the present invention;

FIG. 5 is a second partial schematic view of the conductive connector according to the second embodiment of the present invention;

fig. 6 is a third schematic partial structure diagram of the conductive connector according to the embodiment of the utility model;

FIG. 7 is a schematic diagram of a jack box according to an embodiment of the present invention;

FIG. 8 is an exploded view of an embodiment of the utility model;

fig. 9 is an exploded view of a power distribution apparatus according to an embodiment of the present invention;

fig. 10 is a second schematic diagram illustrating an exploded structure of a power distribution apparatus according to an embodiment of the present invention.

Description of reference numerals:

3-bus duct; 31-a conductive busbar; 32-busbar mounting seat; 41-an electrically conductive insulating shell; 411-a first plug connector; 4111-a first plug groove; 412-a second plug; 4121-a second plug groove; 413-a first mounting shell; 414 — a second mounting shell; 415-a first spacer; 416 — a first stud; 42-a first limit part; 43-a second limiting part; 44-a joint conductor; 441-a first connection; 442-a bending section; 443-an extension; 444-line pressing pipe; 45-a third limiting part; 71-a tank body; 72-a connecting plate; 73-a switch structure; 74-socket.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the coordinate system XYZ provided herein, the X axis represents the left direction in the forward direction, the X axis represents the right direction in the reverse direction, the Y axis represents the front direction, the Y axis represents the rear direction in the reverse direction, the Z axis represents the upper direction in the forward direction, and the Z axis represents the lower direction in the reverse direction. Also, it is noted that the terms "first," "second," and the like in the description and claims of the present invention and in the above-described drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the utility model described herein are capable of operation in sequences other than those illustrated or described herein.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be a mechanical connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description herein, references to the terms "an embodiment," "one embodiment," and "one implementation," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or implementation is included in at least one embodiment or example implementation of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or implementation. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or implementations.

To solve the above technical problem, with reference to fig. 1 to 6, an embodiment of the present invention provides a conductive connector applied to a power distribution device, where the power distribution device includes a bus duct 3, and the conductive connector includes:

the conductive insulation shell 41, the conductive insulation shell 41 includes a mounting portion, and the mounting portion is a hollow shell structure;

the limiting structure comprises a first limiting part 42 and a second limiting part 43, and the first limiting part 42 and the second limiting part 43 are arranged on the inner wall of the shell structure at intervals up and down;

the joint conductor 44 includes a first connecting portion 441 and a bent portion 442 connected to each other, the bent portion 442 is disposed in the housing structure, and the top and the bottom of the bent portion 442 abut against the first position-limiting portion 42 and the second position-limiting portion 43, respectively; the first connecting portion 441 is disposed outside the housing structure and is adapted to be connected to the bus duct 3.

In this embodiment, the bent portion 442 is mounted in the conductive insulating shell 41 having a shell structure, and the first connecting portion 441 of the tab conductor 44 is disposed outside the mounting portion, so that a worker can hold the mounting portion of the conductive insulating shell 41 by hand and safely mate and plug the first connecting portion 441 with the bus duct 3; through installing kink 442 in shell structure, and make the top and the bottom of kink 442 offset with spacing portion 42 of first spacing portion and the spacing portion 43 of second respectively, thereby in the frequent plug in-process with first connecting portion 441 and bus duct 3, spacing portion 42 of first spacing portion and second 43 play and spacing about butt joint conductor 44 and bus duct 3 are in the plug orientation, prevent effectively that joint conductor 44 from breaking away from electrically conductive insulating shell 41, guarantee the installation stability of joint conductor 44 in electrically conductive insulating shell 41, and then guarantee the quality and the life of electrically conductive connector.

In the present embodiment, as shown in fig. 3 to 6, the insulating conductive shell 41 is made of an insulating material, and the inside of the mounting portion of the shell structure is hollow, so that the bent portion of the joint conductor 44 can be conveniently mounted in the mounting portion of the insulating conductive shell 41, thereby performing insulation protection on the bent portion of the joint conductor 44; the first limiting part 42 can be a limiting plate matched with the top of the bending part, the second limiting part 43 can be a limiting block matched with the bottom of the bending part; the joint conductor 44 may be a conductive copper sheet, and the bottom end of the first connection portion 441 and the top end of the bending portion may be an integrally formed structure, so as to ensure that the joint conductor 44 has a certain mechanical strength; the bending part can be in a shape of a [, and the side wall of the first connecting part 441 is tightly attached to the conductive busbar 31 in the bus duct 3, so that the conductive connector is electrically connected with the bus duct 3 in a contact manner.

In an embodiment of the present invention, as shown in fig. 2, 3, 5 and 6, the conductive insulating housing 41 further includes a plug portion, the plug portion is connected to the top end of the mounting portion, the plug portion is provided with a plurality of slots arranged at intervals, the number of the joint conductors 44 is multiple, and each first connection portion 441 in each joint conductor 44 is located in each slot.

It should be noted that, the insertion part is disposed on the mounting part, i.e. the bottom end of the insertion part is connected with the top end of the mounting part, and the insertion part and the mounting part can adopt an integrally formed structure, so as to ensure that the conductive insulating shell 41 in the conductive connector has a certain mechanical strength and prolong the service life thereof; the insertion part is provided with a plurality of slots which are arranged at intervals, the number of the joint conductors 44 is also a plurality, and the first connecting part 441 in each joint conductor 44 is respectively positioned in each slot, so that the first connecting part 441 is insulated and protected by using each slot on the insertion part; and the number of the conductive busbars 31 of the bus duct 3 is also matched with the slots of the joint conductors 44 and the slots, so that when each conductive busbar 31 in the bus duct 3 is respectively positioned in each slot of the plugging part, the first connecting part 441 of each joint conductor 44 is closely attached to the conductive busbar 31, and the contact electrical connection between the joint conductor 44 and the conductive busbar 31 is realized.

In one embodiment of the present invention, the plug part includes a first plug 411 and a second plug 412 which are oppositely arranged, the mounting part includes a first mounting shell 413 and a second mounting shell 414 which are oppositely arranged, the first plug 411 is connected with the top end of the first mounting shell 413, and the second plug 412 is connected with the top end of the second mounting shell 414; the first plug connector 411 and the second plug connector 412 are respectively provided with a plurality of first plug-in grooves 4111 and a plurality of second plug-in grooves 4121 which are arranged at intervals, and each first plug-in groove 4111 is correspondingly communicated with each second plug-in groove 4121 to form each slot.

It should be noted that the first plug connector 411 and the first mounting shell 413 are of an integrally formed structure, and the second plug connector 412 and the second mounting shell 414 are of an integrally formed structure, so that the first plug connector 411 and the first mounting shell 413, and the second plug connector 412 and the second mounting shell 414 all have certain mechanical strength, and accordingly, the service life of the conductive insulating shell 41 is prolonged; the first mounting shell 413 and the second mounting shell 414 are oppositely arranged and detachably connected, so that the bent part 442 in the joint conductor 44 is conveniently mounted in the mounting part comprising the first mounting shell 413 and the second mounting shell 414, and the first plug connector 411 and the second plug connector 412 are oppositely arranged and detachably connected, so that the first connecting part 441 in the joint conductor 44 is conveniently placed in the slot formed by the first plug-in groove 4111 and the second plug-in groove 4121, and the specific position of the first connecting part 441 in the corresponding slot can be adjusted, so that the tightness of the tight arrangement of the first connecting part 441 and the conductive bus bar 31 is adjusted; referring to fig. 7, the sum of the lengths of the first insertion groove 4111 and the second insertion groove 4121 in the X-axis direction in the coordinate system matches the length of the insertion groove, and the length of the joint conductor 44 in the X-axis direction matches the length of the insertion groove, so that the joint conductor 44 is completely installed in the electrically conductive insulating housing 41, and the insulation protection of the joint conductor 44 is realized.

In an embodiment of the present invention, as shown in fig. 2, 3, 5, 6 and 7, the electrically conductive insulating shell 41 further includes a plurality of isolation structures, and the bent portion 442 of the joint conductor 44 is disposed between two adjacent isolation structures; the isolation structure includes a plurality of first isolators 415 and a plurality of second isolators, wherein the plurality of first isolators 415 are disposed on the inner wall of the first mounting case 413 at intervals, and the plurality of second isolators are disposed on the inner wall of the second mounting case 414 at intervals.

It should be noted that, by installing a plurality of isolation structures on the inner wall of the installation portion, and arranging two adjacent isolation structures at intervals, the bent portion 442 in the joint conductor 44 is arranged between two adjacent isolation structures, so that each joint conductor 44 is isolated by the isolation structures, a certain safety distance is ensured between the joint conductors 44, and a short-circuit accident between two adjacent joint conductors 44 is prevented; a plurality of first spacers 415 are spaced apart from each other in the first mounting case 413 so that a side of the joint conductor 44 facing the first mounting case 413 is located between two adjacent first spacers 415, and a plurality of second spacers are spaced apart from each other in the second mounting case 414 so that a side of the joint conductor 44 facing the second mounting case 414 is located between two adjacent second spacers (not shown), thereby ensuring that opposite ends of the entire structure of each joint conductor 44 are shielded. The first spacer 415 and the second spacer are symmetrical in the X-axis direction in the coordinate system.

In an embodiment of the present invention, as shown in fig. 2, 3, 5, 6 and 7, the electrically insulating conductive shell 41 further includes a plurality of first studs 416 and a plurality of second studs, the plurality of first studs 416 are disposed at intervals on an inner wall of the first mounting shell 413, and the plurality of second studs are disposed at intervals on an inner wall of the second mounting shell 414; each of the first studs 416 is connected to each of the second studs by a respective connecting bolt.

It should be noted that, by arranging a plurality of first studs 416 at intervals on the inner wall of the first mounting shell 413, and arranging a plurality of second studs (not shown in the drawings) at intervals on the inner wall of the second mounting shell 414, and connecting each first stud 416 and each second stud by a connecting bolt, the first mounting shell 413 and the second mounting shell 414 can be detachably connected, so as to facilitate the installation of the bent portion 442 of the joint conductor 44 in the installation portion; the first stud 416 and the second stud are symmetrical in the X-axis direction in the coordinate system.

In an embodiment of the present invention, as shown in fig. 5 and 6, the bent portion 442 is provided with a limiting groove, and each of the first studs 416 and each of the second studs are located in the limiting groove of the bent portion 442 in each of the corresponding joint conductors 44.

It should be noted that, by presetting a limiting groove on the bent portion 442, that is, the inner side of the bent portion 442 is a limiting groove, when the bent portion 442 of the plurality of joint conductors 44 is installed in the installation portion, each first stud 416 and each second stud are located in the limiting groove of the bent portion 442 of each corresponding joint conductor 44, so that the first stud 416 and each second stud can also limit the joint conductor 44 located at the corresponding position in the vertical direction, and further prevent the joint conductor 44 and the bus duct from moving up and down in the plugging and unplugging direction, so as to achieve stable installation of the joint conductor 44 in the electrically insulating conductive shell 41.

In an embodiment of the present invention, as shown in fig. 4, each of the joint conductors 44 further includes an extending portion 443, a top end of the extending portion 443 is connected to a bottom end of the bent portion 442, and the second connecting portion includes a plurality of pressure tubes 444 with different calibers, and the plurality of pressure tubes 444 are disposed on the bent portion 442 and/or the extending portion 443 at intervals.

It should be noted that, in each joint conductor 44, an extending portion 443 is further provided at the bottom end of the bent portion 442, the extending portion 443 is a plate-shaped copper sheet in the vertical direction, the wire pressing tubes 444 with different calibers may be all disposed on the extending portion 443 at intervals, may also be disposed on the bent portion 442 at intervals, and may also be disposed on the bent portion 442 and the extending portion 443 at intervals, and the wire pressing tubes 444 with different calibers are conveniently connected with wires with different cross sections, so as to facilitate connection of loads with different sizes through wires with different cross sections. The first connecting portion 441, the bent portion 442, and the extending portion 443 can be integrally formed, so as to ensure that the tab conductor has sufficient mechanical strength.

In an embodiment of the present invention, as shown in fig. 5 and fig. 6, the limiting structure further includes a plurality of third limiting portions 45, the plurality of third limiting portions 45 are disposed in the casing structure at intervals, positioning grooves are formed in the third limiting portions 45, and the bent portion 442 of each joint conductor 44 is embedded in the positioning groove of each third limiting portion 45.

It should be noted that a plurality of third limiting portions 45 are arranged on the inner wall of the shell structure at intervals, wherein the third limiting portions 45 may be limiting plates or limiting blocks arranged horizontally, positioning grooves are further formed in the third limiting portions 45, when the bending portion 442 of the joint conductor 44 is installed in the installation portion, a partial structure of the bending portion 442 is embedded in the positioning grooves, so that the limitation of the bending portion 442 in the horizontal direction can be achieved, and the installation stability of the bending portion 442 of the joint conductor 44 on the horizontal plane in the installation portion is ensured.

Another embodiment of the present invention provides a jack box, as shown in fig. 7, 8, 9 and 10, including the above-mentioned conductive connector, further including a box body 71, a connecting plate 72 and a switch structure 73, where the bottom of the mounting portion in the conductive connector is connected to the box body 71 through the connecting plate 72, the switch structure 73 is disposed in the box body 71, and the bottom of the bent portion 442 in the conductive connector is electrically connected to the switch structure 73.

It should be noted that, a connecting plate 72 is installed on the top plate of the box body 71, wherein the connecting plate 72 and the top plate of the box body 71 may be connected by bolts or by other means, and is not limited herein; the bottom of installation department passes through in the electrically conductive connector connecting plate 72 with case body 71 is connected to realize electrically conductive connector and case body 71 in mechanical structure's connection, the bottom of kink 442 in the electrically conductive connector with switch structure 73 electricity is connected, in order to realize electrically conductive connector and case body 71 in switch structure 73 be connected in the electricity.

In this embodiment, the bottom of the mounting portion is a cylindrical structure, threading holes are formed in the connecting plate 72 and the top plate of the box body 71, when the mounting portion in the conductive connector passes through the connecting plate 72 and is connected with the top end of the box body 71, the threading tube 444 positioned on the bent portion 442 and/or the extending portion 443 in the conductive connector is connected with one end of the power conducting wire, and the other end of the conducting wire sequentially passes through the cylindrical structure, the connecting plate 72 and the top plate of the box body 71 and is electrically connected with the switch structure 73; the switch structure 73 may be a circuit breaker switch, a disconnector, etc., and the specific type of the switch structure 73 is not specifically limited herein.

The jack box further comprises a plurality of sockets 74, and the sockets 74 are electrically connected with the switch structure 73 respectively, so that the sockets 74 are controlled to be powered on or powered off through the switch structure 73, and the sockets 74 supply power to a plurality of loads.

Another embodiment of the present invention provides a power distribution device, including the jack box described in the above embodiments, and further including a bus duct 3, where the bus duct 3 includes a conductive busbar 31, and a first connection portion 441 in a conductive connector of the jack box is adapted to be disposed in close contact with the conductive busbar 31.

It should be noted that, as shown in fig. 9 and 10, the bus duct 3 further includes a bus bar housing (not shown in the drawings) and bus bar installation seats 32, wherein the bus bar installation seats 32 are detachably installed in the bus bar housing, the number of the conductive bus bars 31 is matched with the number of the bus bar installation seats 32, and if the voltage of the conductive bus bars 31 is 10KV, the number of the conductive bus bars 31 is 3; if the voltage of the conductive busbar 31 is 380V, the number of the conductive busbars 31 is four or five, the bottom of the busbar mounting seat 32 is of a semi-surrounding structure, each conductive busbar 31 is respectively mounted in each busbar mounting seat 32, the conductive busbar 31 can be a copper bar, and the busbar mounting seat 32 is a mounting seat made of an insulating material; when the joint conductor 44 is connected with the bus duct 3, each slot of the insertion part in the conductive insulating shell 41 penetrates through the bottom of the bus casing and is sleeved on the outer wall of the corresponding bus bar installation seat 32, and at this time, the first connection part 441 of each joint conductor 44 is closely attached to each conductive bus bar 31 in the bus duct 3, so that the output electric energy of the conductive bus bar 31 in the bus duct 3 is transmitted to each socket 74 through the joint conductor 44 in the conductive connector and the switch structure 73 in the plug box, and the power is supplied to the load connected with the socket 74.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the spirit and scope of the present disclosure, and these changes and modifications are intended to be within the scope of the present disclosure.

Claims (10)

1. An electrically conductive connector, comprising:

the conductive insulation shell (41), the conductive insulation shell (41) comprises a mounting part, and the mounting part is a shell structure with a hollow interior;

the limiting structure comprises a first limiting part (42) and a second limiting part (43), and the first limiting part (42) and the second limiting part (43) are arranged on the inner wall of the shell structure at intervals up and down;

the joint conductor (44), the joint conductor (44) includes a first connecting portion (441) and a bent portion (442) which are connected with each other, the bent portion (442) is disposed in the housing structure, and the top and the bottom of the bent portion (442) are respectively abutted against the first limiting portion (42) and the second limiting portion (43); the first connecting portion (441) is arranged outside the shell structure and is suitable for being connected with the bus duct (3).

2. The conductive connector of claim 1, wherein the conductive insulating housing (41) further includes a plug portion connected to the top end of the mounting portion, the plug portion has a plurality of slots arranged at intervals, the number of the connector conductors (44) is plural, and the first connecting portion (441) of each connector conductor (44) is respectively located in each slot.

3. The conductive connector of claim 2, wherein the insertion portion comprises a first insertion part (411) and a second insertion part (412) which are oppositely arranged, the mounting portion comprises a first mounting shell (413) and a second mounting shell (414) which are oppositely arranged, the first insertion part (411) is connected with the top end of the first mounting shell (413), and the second insertion part (412) is connected with the top end of the second mounting shell (414); the first plug connector (411) and the second plug connector (412) are respectively provided with a plurality of first plug-in grooves (4111) and a plurality of second plug-in grooves (4121) which are arranged at intervals, and each first plug-in groove (4111) is correspondingly communicated with each second plug-in groove (4121) to form each slot.

4. The electrically conductive connector according to claim 3, wherein said electrically conductive insulating shell (41) further comprises a plurality of isolation structures, said bent portion (442) of said connector conductor (44) being disposed between two adjacent isolation structures; the isolation structure comprises a plurality of first isolation pieces (415) and a plurality of second isolation pieces, wherein the first isolation pieces (415) are arranged on the inner wall of the first installation shell (413) at intervals, and the second isolation pieces are arranged on the inner wall of the second installation shell (414) at intervals.

5. The electrically conductive connector of claim 3, wherein said electrically insulating housing (41) further comprises a plurality of first studs (416) and a plurality of second studs, said plurality of first studs (416) being spaced apart from one another on an inner wall of said first mounting housing (413), said plurality of second studs being spaced apart from one another on an inner wall of said second mounting housing (414); the first studs (416) and the second studs are connected through connecting bolts respectively.

6. The conductive connector according to claim 5, wherein the bent portion (442) is provided with a limiting groove, and each of the first stud (416) and the second stud is located in the limiting groove of the bent portion (442) in each corresponding connector conductor (44).

7. The conductive connector according to claim 2, wherein each of the connector conductors (44) further includes an extending portion (443) and a second connecting portion, a top end of the extending portion (443) is connected to a bottom end of the bent portion (442), the second connecting portion includes a plurality of pressure tubes (444) with different diameters, and the plurality of pressure tubes (444) are disposed on the bent portion (442) and/or the extending portion (443) at intervals.

8. The conductive connector according to claim 7, wherein the position-limiting structure further includes a plurality of third position-limiting portions (45), the plurality of third position-limiting portions (45) are disposed in the housing structure at intervals, positioning grooves are formed in the third position-limiting portions (45), and the bent portion (442) of each of the connector conductors (44) is embedded in the positioning groove of each of the third position-limiting portions (45).

9. A jack box comprising the conductive connector according to any one of claims 1 to 8, further comprising a box body (71), a connecting plate (72), and a switch structure (73), wherein the conductive connector is connected to the box body (71) through the connecting plate (72), the switch structure (73) is disposed in the box body (71), and the bent portion (442) of the conductive connector is electrically connected to the switch structure (73).

10. A power supply distribution device, comprising a jack box according to claim 9, and further comprising a bus duct (3), wherein the bus duct (3) comprises a conductive busbar (31), and wherein a first connecting portion (441) of the conductive connectors of the jack box is adapted to be arranged in close contact with the conductive busbar (31).

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