CN217983721U - Combined type electric connector - Google Patents

Abstract

The utility model provides an assemblage formula electric connector, the assemblage formula electric connector that provides constitute through the assemblage of a plurality of assemblage components, reach customization adjustment electric connector's conductive terminal's quantity and structure to satisfy electronic equipment's development and to electric connector's special demand. In addition, the assembly type electric connector can lead the shell assembly component through the wire rod, so that the conductive wire rod on the assembly type electric connector extends towards a specific direction, the conductive wire rod on the assembly type electric connector is prevented from influencing the arrangement of electronic components in an electronic product, and the electronic equipment using the assembly type electric connector can be developed towards the thinning direction.

Description

Combined electric connector

Technical Field

The present invention relates to an assembled electrical connector, and more particularly, to an assembled electrical connector capable of customized adjustment of the number and structure of conductive terminals.

Background

However, after the design of the conventional electrical connector is completed, the number and the structure of the conductive terminals are determined and cannot be customized and adjusted, and the signal transmission requirements of the electronic device are difficult to meet, so that the technical (functional) development of the electronic device is limited.

In addition, the electrical connector can be matched with a conductive wire, and as the electronic device is developed towards the thinning direction, the conductive wire on the electrical connector used in the electronic device is often required to extend towards a specific direction, so as to avoid the conductive wire on the electrical connector from influencing the layout of the electronic components in the electronic product.

Therefore, it is a technical issue to be solved by the present invention that the number and structure of the conductive terminals of the electrical connector can be adjusted and the conductive wires of the electrical connector extend in a specific direction.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned shortcomings of the prior art, the present invention provides an assembled electrical connector for solving the problem that the number and structure of the conductive terminals of the electrical connector in the prior art can be determined and cannot be customized and adjusted, so that the conductive wires on the electrical connector cannot extend in a specific direction.

To achieve the above and other related objects, the present invention provides an assembled electrical connector, comprising: the rubber core assembling component is provided with at least one first row of assembling rubber core sockets and at least one second row of assembling rubber core sockets, the first row of assembling rubber core sockets and the second row of assembling rubber core sockets are arranged into at least two rows, the main side of the first row of assembling rubber core sockets is provided with a first row of socket main clamping structure, and the main side of the second row of assembling rubber core sockets is provided with a second row of socket main clamping structure; the first row of terminal assembly components are provided with at least one first row of assembly conductive terminals, and the main side of each first row of assembly conductive terminal is provided with a first row of terminal main clamping structure; the second row of terminal assembly component is provided with at least one second row of assembly conductive terminals, and the main side of each second row of assembly conductive terminal is provided with a second row of terminal main clamping structure; the first row of assembled conductive terminals and the first row of assembled conductive terminals have different structures; the first row of assembling conductive terminals can be inserted into the first row of assembling rubber core sockets, so that the first row of terminal main clamping structures are clamped with the first row of socket main clamping structures, and the first row of terminal assembling components are assembled on the rubber core assembling components; and the second row of the assembly conductive terminals can be inserted into the second row of the assembly rubber core socket, so that the second row of the terminal main clamping structure is clamped with the second row of the socket main clamping structure, and the second row of the terminal assembly component is assembled on the rubber core assembly component.

Preferably, in the assemblage formula electric connector of this application, the main joint structure of first row socket is joint hole structure, the main joint structure of first row terminal makes but the atress of the main joint structure of first row terminal warp and reach the joint the main joint structure of first row socket.

Preferably, in the assemblage formula electric connector of this application, the main joint structure of first row socket is joint arm structure, the main joint structure of first row terminal is joint hole structure, makes the main joint structure of first row socket atress warp and reach the joint the main joint structure of first row terminal.

Preferably, in the assemblage formula electric connector of this application, the main joint structure of socket is the joint hole structure in the row of second, the main joint structure of terminal is the joint arm structure in the row of second, makes the main joint structure of terminal atress of row of second warp and reaches the joint the main joint structure of socket is arranged to the second.

Preferably, in the assemblage formula electric connector of this application, the main joint structure of socket is arranged to the second is joint arm structure, the main joint structure of terminal is arranged to the second is joint hole structure, makes the main joint structure of socket is arranged to the second atress warp and reaches the joint the main joint structure of terminal is arranged to the second.

Preferably, in the assembled electrical connector of the present application, a secondary side of the first row of assembled rubber core sockets has a first row of socket secondary clamping structures, and a secondary side of the first row of assembled conductive terminals has a first row of terminal secondary clamping structures; when the first row of assembling conductive terminals are inserted into the first row of assembling rubber core sockets, the first row of terminal secondary clamping structure can be clamped with the first row of socket secondary clamping structure, and the first row of terminal assembling components are assembled on the rubber core assembling components.

Preferably, in the assembled electrical connector of the present application, the first row of terminal secondary clamping structure and the first row of socket secondary clamping structure are a concave-convex structure or a fastening structure with a matched structure.

Preferably, in the assemblage formula electric connector of this application, the secondary joint structure of first row socket is joint arm structure, the secondary joint structure of first row terminal is joint hole structure, makes the secondary joint structure of first row terminal atress warp and reach the joint the secondary joint structure of first row socket.

Preferably, in the assemblage formula electric connector of this application, the secondary joint structure of first row socket is joint hole structure, the secondary joint structure of first row terminal is joint arm structure, makes the secondary joint structure of first row terminal atress warp and reach the joint the secondary joint structure of first row socket.

Preferably, in the assemblage formula electric connector of this application, first row assemblage gluey core socket has a first row socket lid, a first row socket cell body and a first row rotating-structure, first row socket main clamping structure set up in first row socket lid, first row rotating-structure connects first row socket lid with first row socket cell body makes first row socket lid can be relative first row socket cell body rotates, and makes first row socket lid joint first row socket cell body, or relieve first row socket lid is right the joint of first row socket cell body works as first row socket lid joint during first row socket cell body, first row socket lid makes first row socket main clamping structure joint first row terminal main clamping structure.

Preferably, in the assembly electrical connector of the present application, the assembly electrical connector can be matched with a conductive wire, and the assembly electrical connector further includes a wire guiding housing assembly member, the wire guiding housing assembly member has a housing engagement structure and a wire guiding structure, the housing engagement structure is provided to engage with the rubber core assembly member, and the wire guiding housing assembly member is assembled on the rubber core assembly member, so that the conductive wire is guided by the wire guiding structure to extend toward a predetermined direction.

Preferably, in the assembled electrical connector of the present application, the housing engagement structure is a concave-convex structure or a buckling structure, and the wire guiding structure is a cavity structure.

Compared with the prior art, the assembled electric connector provided by the application is formed by assembling a plurality of assembled components, so that the number and the structure of the conductive terminals of the electric connector are customized and adjusted to meet the special requirements of the development of electronic equipment on the electric connector. In addition, the assembly type electric connector can lead the shell assembly component through the wire rod, so that the conductive wire rod on the assembly type electric connector extends towards a specific direction, the conductive wire rod on the assembly type electric connector is prevented from influencing the arrangement of electronic components in an electronic product, and the electronic equipment using the assembly type electric connector can be developed towards the thinning direction.

Drawings

Fig. 1 is a perspective view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 2 is a perspective view of the assembled electrical connector according to the embodiment of the present invention.

Fig. 3 is a front view of the assembled electrical connector of the present invention.

Fig. 4 is a bottom view of the assembled electrical connector of the present invention.

Fig. 5 is a cross-sectional view of the member of fig. 3 taken along line AA.

Fig. 6 shows a schematic cross-sectional view of the component shown in fig. 3, cut along line BB.

Fig. 7 is an assembled schematic view of an embodiment of the assembled electrical connector of the present invention.

Fig. 8 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 9 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 10 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 11 is an assembly diagram of the assembled electrical connector according to the embodiment of the present invention.

Fig. 12 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

FIG. 13 is a cross-sectional view of the member of FIG. 12 taken along line C-C.

Fig. 14 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 15 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 16 is a perspective view of the assembled electrical connector according to the embodiment of the present invention.

Fig. 17 is a front view of the assembled electrical connector of the present invention.

FIG. 18 is a cross-sectional view of the member of FIG. 17 taken along line DD.

Fig. 19 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 20 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Figure 21 is a cross-sectional view of the member of figure 20 taken along line EE.

Fig. 22 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

Fig. 23 is a perspective view of the assembled electrical connector according to the embodiment of the present invention.

Fig. 24 is a perspective view of the assembled electrical connector according to the embodiment of the present invention.

Fig. 25 is a front view of the assembled electrical connector of the present invention.

FIG. 26 is a cross-sectional view of the component of FIG. 25 taken along line FF.

Fig. 27 is an assembled schematic view of an assembled electrical connector according to an embodiment of the present invention.

FIG. 28 is a cross-sectional view of the member of FIG. 27 taken along line G-G.

Description of the element reference numerals

1. Combined electric connector

11. Rubber core assembling component

111. First row assembled rubber core socket

1111. Main clamping structure of first row socket

1112. Secondary clamping structure of first row of sockets

1113. First row socket cover

1114. First row socket groove body

1115. First row rotating structure

112. Second row assembled rubber core socket

1121. Main clamping structure of second row socket

12. First row terminal assembling component

121. First row assembled conductive terminal

1211. Main clamping structure of first row of terminals

1212. Secondary clamping structure of first row of terminals

13. Second row terminal assembling component

131. Second row of assembled conductive terminals

1311. Main clamping structure of second row of terminals

14. Wire guide housing assembly member

141. Shell body jointing structure

142. Wire guiding structure

2. Conductive wire

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

Please refer to fig. 1 to 28. It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope that the technical content disclosed in the present invention can cover without affecting the function that the present invention can produce and the purpose that the present invention can achieve. In addition, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are used for clarity of description only, and are not used to limit the scope of the present invention, and the relative relationship between the terms may be changed or adjusted without substantial technical changes.

For the technical idea of the present application, please refer to the disclosure of fig. 1 to fig. 28 together.

In the embodiment shown in fig. 1 to 8, the present application provides a stand-up electrical connector 1 comprising: a rubber core assembly member 11, a first row terminal assembly member 12 and a second row terminal assembly member 13. The core assembly member 11 may be made of an insulating material and has a plurality of first row assembly core receptacles 111 arranged in at least one row and a plurality of second row assembly core receptacles 112 arranged in at least one row. In the present embodiment, the first row of terminal assembly members 12 and the second row of terminal assembly members 13 have different structures to meet the special requirements of the development of electronic devices for electrical connectors.

In the present embodiment, the first row of assembled core receptacles 111 and the second row of assembled core receptacles 112 are separately arranged in at least two rows, and as shown in fig. 5 to fig. 6, the main side of the first row of assembled core receptacles 111 has a first row of receptacle main latching structure 1111 for latching the first row of terminal assembly members 12, and the main side of the second row of assembled core receptacles 112 has a second row of receptacle main latching structure 1121 for latching the second row of terminal assembly members 13.

In the embodiment shown in fig. 5 to 8, the first row terminal assembling member 12 has a plurality of first row assembling conductive terminals 121 arranged in at least one row for transmitting signals, and in this embodiment, the first row assembling conductive terminals 121 can be inserted into the first row assembling core sockets 111, and the main side of the first row assembling conductive terminals 121 has a first row terminal main clamping structure 1211 for clamping the first row assembling core sockets 111.

It should be noted that, in the present embodiment, the first row terminal main clamping structure 1211 and the first row socket main clamping structure 1111 are, for example, a concave-convex structure or a buckling structure with matching structures, so that when the first row of assembled conductive terminals 121 are inserted into the first row assembled plastic core socket 111, the first row terminal main clamping structure 1211 can be clamped with the first row socket main clamping structure 1111, so as to assemble the first row terminal assembling member 12 on the plastic core assembling member 11.

In the embodiment shown in fig. 13, the first row of main socket engaging structures 1111 is a engaging hole structure, and correspondingly, the first row of terminal main engaging structures 1211 is a engaging arm structure, so that the first row of terminal main engaging structures 1211, which is the engaging arm structure, can be deformed by force to achieve the first row of socket main engaging structures 1111 engaged with the engaging hole structure, thereby achieving the purpose of assembling the first row of terminal assembling members 12 on the rubber core assembling member 11. However, the present application is not limited thereto, and as shown in the embodiment shown in fig. 5, the first row of socket main clamping structure 1111 is a clamping arm structure, and correspondingly, the first row of terminal main clamping structure 1211 is a clamping hole structure, so that the first row of socket main clamping structure 1111, which is a clamping arm structure, can be deformed by force to achieve the first row of terminal main clamping structure 1211 clamped in the clamping hole structure, thereby achieving the purpose of assembling the first row of terminal assembling member 12 to the rubber core assembling member 11.

In addition, as shown in the embodiment of fig. 18 to 19, the secondary side of the first row of assembled core sockets 111 has a first row of socket secondary snap structures 1112 for snap-fitting the first row of terminal assembly members 12, and correspondingly, the secondary side of the first row of assembled conductive terminals 121 has a first row of terminal secondary snap structures 1212 for snap-fitting the first row of assembled core sockets 111.

The first row of terminal secondary clamping structure 1212 and the first row of socket secondary clamping structure 1112 are, for example, a concave-convex structure or a buckling structure with a matching structure, so that when the first row of assembly conductive terminals 121 are inserted into the first row of assembly plastic core sockets 111, the first row of terminal secondary clamping structure 1212 can clamp the first row of socket secondary clamping structure 1112, thereby assembling the first row of terminal assembly member 12 on the plastic core assembly member 11.

In the embodiment shown in fig. 18, the first row of terminal secondary clamping structures 1212 is a clamping hole structure, and correspondingly, the first row of socket secondary clamping structures 1112 is a clamping arm structure, so that the first row of socket secondary clamping structures 1112 in the clamping arm structure can be deformed by force to achieve the first row of terminal secondary clamping structures 1212 clamped in the clamping hole structure. However, it is not limited to this, alternatively, the first row of socket secondary clamping structures 1112 is a clamping hole structure, and correspondingly, the first row of terminal secondary clamping structures 1212 is a clamping arm structure, so that the first row of terminal secondary clamping structures 1212, which is the clamping arm structure, can be deformed by force to achieve the first row of socket secondary clamping structures 1112 clamped as the clamping hole structure.

Further, as shown in the embodiment of fig. 16 to 21, the first row of the gang core sockets 111 has first row socket covers 1113, first row socket grooves 1114 and first row rotation structures 1115. In this embodiment, the first row socket main latching structure 1111 is disposed on the first row socket cover 1113, and the first row rotating structure 1115 is connected to the first row socket cover 1113 and the first row socket groove 1114 respectively, so that the first row socket cover 1113 can rotate relative to the first row socket groove 1114 to engage the first row socket cover 1113 with the first row socket groove 1114 as shown in fig. 18, or disengage the first row socket cover 1113 from the first row socket groove 1114 as shown in fig. 21.

It should be noted that, in this embodiment, when the first row of socket covers 1113 engages the first row of socket grooves 1114, the first row of socket covers 1113 makes the first row of socket main latching structures 1111 latch with the first row of terminal main latching structures 1211, so as to assemble the first row of terminal assembling members 12 to the core assembling member 11. When the first row of socket cover 1113 disengages the first row of socket slots 1114, the first row of socket cover 1113 makes the first row of socket main engaging structure 1111 leave the first row of terminal main engaging structure 1211, and releases the first row of socket main engaging structure 1111 from the first row of terminal main engaging structure 1211, so as to release the assembly of the first row of terminal assembly member 12 to the rubber core assembly member 11.

In the embodiment shown in fig. 5 to 8, the second row terminal assembly member 13 has a plurality of second row assembly conductive terminals 131 arranged in at least one row for transmitting signals, and in this embodiment, the second row assembly conductive terminals 131 can be inserted into the second row assembly plastic core sockets 112, and the main side of the second row assembly conductive terminals 131 has a second row terminal main clamping structure 1311 for clamping the second row assembly plastic core sockets 112.

It should be noted that, in the present embodiment, the second row of conductive terminals 131 and the first row of conductive terminals 121 have different structures, so as to meet the special requirements of the development of electronic devices for the electrical connector. The second row terminal main clamping structure 1311 and the second row socket main clamping structure 1121 are, for example, a concave-convex structure or a buckling structure with matching structures, so that when the second row assembly conductive terminals 131 are inserted into the second row assembly plastic core socket 112, the second row terminal main clamping structure 1311 can be clamped with the second row socket main clamping structure 1121, so as to assemble the second row terminal assembly member 13 on the plastic core assembly member 11.

In the embodiment shown in fig. 6, the second row socket main clamping structure 1121 is a clamping hole structure, and correspondingly, the second row terminal main clamping structure 1311 is a clamping arm structure, so that the second row terminal main clamping structure 1311 which is a clamping arm structure can be deformed by force to achieve the second row socket main clamping structure 1121 which is clamped into the clamping hole structure, and the second row terminal assembling member 13 is assembled to the rubber core assembling member 11. Optionally, the second row socket main clamping structure 1121 is a clamping arm structure, and correspondingly, the second row terminal main clamping structure 1311 is a clamping hole structure, so that the second row socket main clamping structure 1121, which is a clamping arm structure, can be deformed by force to achieve the second row terminal main clamping structure 1311 clamped as the clamping hole structure, and the second row terminal assembling member 13 is assembled to the rubber core assembling member 11.

It should be noted that the assembled electrical connector 1 of the present application is formed by assembling the rubber core assembling member 11, the first row terminal assembling member 12 and the second row terminal assembling member 13, that is, the assembled electrical connector 1 of the present application is formed by assembling a plurality of assembling members, so that after the design of the assembled electrical connector is completed, the number and structure of the conductive terminals of the electrical connector can be customized and adjusted by adjusting or replacing the assembling members, so as to meet the special requirements of the development of electronic devices.

In the embodiment shown in fig. 23 to 28, the assembled electrical connector 1 is matched with the conductive wires 2, and accordingly, the assembled electrical connector 1 has the wire guide housing assembly member 14 for guiding the extending direction of the conductive wires 2. In the embodiment, the wire guiding housing assembly member 14 has a housing engagement structure 141, such as a concave-convex structure or a buckling structure, and a wire guiding structure 142, such as a cavity structure, wherein the housing engagement structure 141 is provided to engage with the core assembly member 11, and the wire guiding housing assembly member 14 is assembled on the core assembly member 11, so that the conductive wire 2 is guided by the wire guiding structure 142 to extend in a predetermined direction, so that the conductive wire 2 can extend to avoid electronic components inside the electronic device, and the conductive wire 2 on the assembly type electrical connector 1 is prevented from affecting the arrangement of the electronic components inside the electronic device, so that the electronic device using the assembly type electrical connector 1 of the present application can be developed in a direction of thinning.

It should be noted that, in the present embodiment, the housing engaging structure 141 engages with two opposite sides of the core assembly member 11, but not limited thereto, the cover engaging structure 141 may engage with only one side of the core assembly member 11.

It should be noted that, the assembled electrical connector provided in the present application may also omit some of the features described above, for example, in the present application, the assembled electrical connector includes: the rubber core assembling component, the first row of terminal assembling components and the second row of terminal assembling components. The rubber core assembling component is provided with at least one first row of assembling rubber core sockets and at least one second row of assembling rubber core sockets. The first row of assembled rubber core sockets and the second row of assembled rubber core sockets are arranged into at least two rows, the main side of the first row of assembled rubber core sockets is provided with a first row of socket main clamping structure, and the main side of the second row of assembled rubber core sockets is provided with a second row of socket main clamping structure. The first row of terminal assembly members are provided with at least one first row of assembly conductive terminals, and the main side of each first row of assembly conductive terminal is provided with a first row of terminal main clamping structure. The second row terminal assembly member has at least one second row assembly conductive terminal, and the main side of the second row assembly conductive terminal has a second row terminal main clamping structure. The first row of assembled conductive terminals and the first row of assembled conductive terminals have different structures. The first row of assembling conductive terminals can be inserted into the first row of assembling rubber core sockets, so that the first row of terminal main clamping structure is clamped with the first row of socket main clamping structure, and the first row of terminal assembling components are assembled on the rubber core assembling components. The second row of the assembled conductive terminals can be inserted into the second row of the assembled rubber core socket, so that the second row of the terminal main clamping structure is clamped with the second row of the socket main clamping structure, and the second row of the terminal assembling component is assembled on the rubber core assembling component.

In summary, the present application provides an assembled electrical connector, which is formed by assembling a plurality of assembling members, so as to achieve the customized adjustment of the number and structure of the conductive terminals of the electrical connector, thereby meeting the development of electronic devices and the special requirements of the electrical connector. In addition, the assembly type electric connector can lead the shell assembly component through the wire rod, so that the conductive wire rod on the assembly type electric connector extends towards a specific direction, the conductive wire rod on the assembly type electric connector is prevented from influencing the arrangement of electronic components in an electronic product, and the electronic equipment using the assembly type electric connector can be developed towards the thinning direction.

The above embodiments are merely illustrative of the principles and functions of the present application and are not intended to limit the present application. Modifications and variations can be made to the above-described embodiments by those of ordinary skill in the art without departing from the spirit and scope of the present application. Therefore, the scope of protection of the present application shall be covered by the claims of the present invention.

Claims (12)

1. An assembled electrical connector, comprising:

the rubber core assembling component is provided with at least one first row of assembling rubber core sockets and at least one second row of assembling rubber core sockets, the first row of assembling rubber core sockets and the second row of assembling rubber core sockets are arranged into at least two rows, the main side of the first row of assembling rubber core sockets is provided with a first row of socket main clamping structure, and the main side of the second row of assembling rubber core sockets is provided with a second row of socket main clamping structure;

the first row of terminal assembly components are provided with at least one first row of assembly conductive terminals, and the main side of each first row of assembly conductive terminal is provided with a first row of terminal main clamping structure;

the second row of terminal assembly component is provided with at least one second row of assembly conductive terminals, and the main side of each second row of assembly conductive terminal is provided with a second row of terminal main clamping structure; wherein, the first and the second end of the pipe are connected with each other,

the first row of assembled conductive terminals and the second row of assembled conductive terminals have different structures;

the first row of assembling conductive terminals can be inserted into the first row of assembling rubber core sockets, so that the first row of terminal main clamping structures are clamped with the first row of socket main clamping structures, and the first row of terminal assembling components are assembled on the rubber core assembling components; and

the second row of the assembly conductive terminals can be inserted into the second row of the assembly rubber core socket, so that the second row of the terminal main clamping structure is clamped with the second row of the socket main clamping structure, and the second row of the terminal assembly component is assembled on the rubber core assembly component.

2. The ganged electrical connector of claim 1, wherein: the main clamping structure of the first row of sockets is of a clamping hole structure, and the main clamping structure of the first row of terminals is of a clamping arm structure, so that the main clamping structure of the first row of terminals can be stressed to deform and clamped to the main clamping structure of the first row of sockets.

3. The ganged electrical connector of claim 1, wherein: the main clamping structure of the first row of sockets is a clamping arm structure, and the main clamping structure of the first row of terminals is a clamping hole structure, so that the main clamping structure of the first row of sockets can be stressed to deform and clamped to the main clamping structure of the first row of terminals.

4. The ganged electrical connector of claim 1, wherein: the main clamping structure of the second row of sockets is of a clamping hole structure, and the main clamping structure of the second row of terminals is of a clamping arm structure, so that the main clamping structure of the second row of terminals can be stressed and deformed to achieve clamping.

5. The ganged electrical connector of claim 1, wherein: the main clamping structure of the second row of sockets is a clamping arm structure, and the main clamping structure of the second row of terminals is a clamping hole structure, so that the main clamping structure of the second row of sockets can be stressed and deformed to achieve clamping and connection with the main clamping structure of the second row of terminals.

6. The ganged electrical connector of claim 1, wherein: the secondary side of the first row of assembling rubber core sockets is provided with a first row of socket secondary clamping structures, and the secondary side of the first row of assembling conductive terminals is provided with a first row of terminal secondary clamping structures; when the first row of assembling conductive terminals are inserted into the first row of assembling rubber core sockets, the first row of terminal secondary clamping structure can be clamped with the first row of socket secondary clamping structure, and the first row of terminal assembling components are assembled on the rubber core assembling components.

7. The ganged electrical connector of claim 6, wherein: the first row of terminal secondary clamping structure and the first row of socket secondary clamping structure are a structure-matched concave-convex structure or a buckling structure.

8. The ganged electrical connector of claim 6, wherein: the first row of socket secondary clamping structure is a clamping arm structure, the first row of terminal secondary clamping structure is a clamping hole structure, so that the first row of terminal secondary clamping structure can be stressed to deform and clamped to the first row of socket secondary clamping structure.

9. The ganged electrical connector of claim 6, wherein: the first row of socket secondary clamping structure is a clamping hole structure, the first row of terminal secondary clamping structure is a clamping arm structure, so that the first row of terminal secondary clamping structure can be stressed to deform and clamped to the first row of socket secondary clamping structure.

10. The ganged electrical connector of claim 1, wherein: first row group founds gluey core socket has a first row socket cover body, a first row socket cell body and a first row rotating-structure, first row socket main joint structure set up in first row socket cover body, first row rotating-structure connects first row socket cover body with first row socket cell body makes first row socket cover body can be relative first row socket cell body rotates, and the order first row socket cover body joint first row socket cell body, or relieve first row socket cover body is right the joint of first row socket cell body works as first row socket cover body joint during first row socket cell body, first row socket cover body makes first row socket main joint structure joint first row terminal main joint structure.

11. The ganged electrical connector of claim 1, wherein: the assembled electric connector can be matched with a conductive wire, and the assembled electric connector also comprises a wire guide shell assembling component, wherein the wire guide shell assembling component is provided with a shell connecting structure and a wire guide structure, the shell connecting structure is used for connecting the rubber core assembling component, and the wire guide shell assembling component is assembled on the rubber core assembling component so as to lead the conductive wire to extend towards a preset direction under the guidance of the wire guide structure.

12. The ganged electrical connector of claim 11, wherein: the shell body joint structure is a concave-convex structure or a buckling structure, and the wire guiding structure is a cavity structure.

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