阅读说明：本技术 电连接器及其制造方法 (Electric connector and manufacturing method thereof ) 是由 陈盈仲 黄睦容 于 2019-08-23 设计创作，主要内容包括：本发明提供电连接器及其制造方法,其中,电连接器具有固定绝缘基座、悬浮绝缘插座、第一导电端子、第二导电端子、第一持力端子和第二持力端子。其中,第一导电端子和第二导电端子可变形,以令悬浮绝缘插座可相对固定绝缘基座移动而对准对接物,以解决电连接器与对接物无法正常对接的问题；第一持力端子和第二持力端子可提供止挡,以令悬浮绝缘插座无法离开固定绝缘基座；固定绝缘基座和悬浮绝缘插座借由注胶方式同步成形,以减少制造程序而降低成本。(The invention provides an electric connector and a manufacturing method thereof, wherein the electric connector is provided with a fixed insulating base, a suspension insulating socket, a first conductive terminal, a second conductive terminal, a first holding terminal and a second holding terminal. The first conductive terminal and the second conductive terminal can be deformed, so that the suspension insulation socket can move relative to the fixed insulation base to align to the butt joint object, and the problem that the electric connector cannot be normally butted with the butt joint object is solved; the first holding terminal and the second holding terminal can provide a stop so that the floating insulation socket cannot leave the fixed insulation base; the fixed insulating base and the suspension insulating socket are synchronously formed by the glue injection method, so that the manufacturing procedures are reduced and the cost is reduced.)

1. An electrical connector disposed on a circuit substrate and mated with a mating object, the electrical connector comprising:

the fixing and insulating base is provided with a plurality of base side walls, a first fixing side and a second fixing side which are opposite, a third fixing side and a fourth fixing side which are opposite, the plurality of base side walls are arranged to form a base inner space, and the base inner space is provided with a base inserting port;

the suspension insulation socket is accommodated in the inner space of the base, separates the side walls of the base and is exposed out of the base socket interface, and the suspension insulation socket is provided with a first suspension side and a second suspension side which are opposite;

the first conductive terminal is arranged on the circuit substrate and is provided with a first fixing section, a first elastic arm section, a first connection section and a first suspension section which are sequentially connected into a whole, wherein the first fixing section is embedded into the fixed insulating base at the first fixing side; the first floating section is embedded into the floating insulation socket at the first floating side; the first engagement section extends to the floating insulation socket to engage both the fixed insulation base and the floating insulation socket; the first elastic arm section is exposed in a space separating the suspension insulation socket and each base side wall, so that the elastic deformation enables the first connecting section to draw the suspension insulation socket to move, the suspension insulation socket can be displaced relative to the fixed insulation base on the first suspension side to align with the butt joint object, and the butt joint object can enter the base inner space through the base inserting port to butt joint the suspension insulation socket;

the second conductive terminal is arranged on the circuit substrate and is provided with a second fixed section, a second elastic arm section, a second connection section and a second suspension section which are sequentially connected into a whole, wherein the second fixed section is embedded into the fixed insulating base at the second fixed side; the second floating section is embedded into the floating insulation socket at the second floating side; the second engagement section extends to the floating insulation socket to engage both the fixed insulation base and the floating insulation socket; the second elastic arm section is exposed in a space between the suspension insulation socket and each base side wall, so that the second connection section can pull the suspension insulation socket to move due to elastic deformation, the suspension insulation socket can be displaced relative to the fixed insulation base at the second suspension side to align with the butt joint object, and the butt joint object can enter the base inner space through the base insertion port to butt joint the suspension insulation socket;

the first holding terminal is arranged on the circuit substrate and embedded on the fixed insulating base at the third fixed side, and the first holding terminal is provided with a first stopping structure extending to the base inserting port so that the suspended insulating socket is stopped at the third fixed side and leaves the fixed insulating base through the base inserting port; and

the second holding terminal is arranged on the circuit substrate, the fourth fixing side of the second holding terminal is embedded on the fixed insulating base, and the second holding terminal is provided with a second stopping structure extending to the base inserting port, so that the suspended insulating socket is stopped at the fourth fixing side and leaves the fixed insulating base through the base inserting port.

2. The electrical connector of claim 1, wherein the floating dielectric receptacle further comprises a plurality of receptacle sidewalls, each of the receptacle sidewalls being arranged to define a receptacle interior space, the receptacle interior space having a receptacle mating opening, the first floating section having a first electrical landing configuration, the second floating section having a second electrical landing configuration, the first electrical landing configuration and the second electrical landing configuration extending beyond one of the plurality of receptacle sidewalls, respectively, such that the receptacle mating openings are exposed to electrically contact the mating objects.

3. The electrical connector of claim 2, wherein the first floating segment has a first embedding structure at an end facing away from the first electrical landing structure, the first embedding structure extending in a direction perpendicular to the first electrical landing structure and embedding into one of the plurality of receptacle sidewalls to locate the first electrical landing structure; the second suspension section is provided with a second embedded structure at one end departing from the second electrical lapping structure, and the second embedded structure extends towards the direction perpendicular to the second electrical lapping structure and is embedded into one of the side walls of the plurality of sockets so as to position the second electrical lapping structure.

4. The electrical connector of claim 2, wherein the first electrical landing structure has a first abutment portion that abuts one of the plurality of receptacle sidewalls to locate the first electrical landing structure; the second electrical bonding structure is provided with a second abutting part abutting against one of the socket side walls so as to position the second electrical bonding structure.

5. The electrical connector of claim 1, wherein the floating dielectric receptacle further comprises a plurality of receptacle sidewalls and a receptacle tongue, each of the receptacle sidewalls being arranged to define a receptacle interior space, the receptacle interior space having a receptacle mating opening, the receptacle tongue being received in the receptacle interior space, the first floating section having a first electrical landing configuration, the second floating section having a second electrical landing configuration, the first and second electrical landing configurations extending beyond the receptacle tongue, respectively, such that the receptacle mating opening is exposed for electrically landing the mating object.

6. The electrical connector of claim 5, wherein the first floating section has a first engaging structure at an end facing away from the first electrical landing structure, the first engaging structure extending in a direction perpendicular to the first electrical landing structure to engage the socket tongue to position the first electrical landing structure; the second suspension section is provided with a second embedded structure at one end departing from the second electrical lapping structure, the second embedded structure extends towards the direction perpendicular to the second electrical lapping structure and is embedded into the socket tongue part to position the second electrical lapping structure.

7. The electrical connector of claim 5, wherein the first electrical landing feature has a first abutment portion that abuts the socket tongue to locate the first electrical landing feature; the second electrical bonding structure is provided with a second abutting part abutting against the socket tongue part so as to position the second electrical bonding structure.

8. The electrical connector of claim 1, wherein the first fixing section has a first electrical soldering structure, the second fixing section has a second electrical soldering structure, and the first electrical soldering structure and the second electrical soldering structure respectively extend out of the fixing insulating base, so that the fixing insulating base is exposed to electrically solder the circuit substrate.

9. An electrical connector manufacturing method for manufacturing the electrical connector of claim 1, comprising:

providing a forming die;

respectively arranging the first conductive terminal and the second conductive terminal at preset positions in the forming die;

injecting glue into the forming mold to synchronously form the fixed insulating base and the suspension insulating socket, so that the first fixed section and the second fixed section are synchronously embedded into the fixed insulating base, and the first suspension section and the second suspension section are synchronously embedded into the suspension insulating socket to form a semi-finished product of the electric connector; and

embedding the first holding terminal and the second holding terminal into the fixed insulating base in the electric connector semi-finished product respectively.

10. The method of claim 9, wherein the first conductive terminal is a plurality of first conductive terminals and the second conductive terminal is a plurality of second conductive terminals, and the method further comprises:

providing at least one first separating piece and at least one second separating piece, respectively arranging the first separating piece and the second separating piece in a forming mould, enabling the first separating piece to separate and position adjacent two of the plurality of first conductive terminals, and enabling the second separating piece to separate and position adjacent two of the plurality of second conductive terminals.

Technical Field

The present invention relates to an electrical connector, and more particularly, to an electrical connector disposed on a circuit board and mated with an object to be mated.

Background

The electrical connector often faces a situation that the electrical connector cannot be normally mated with the mating object due to a processing error, and when the electrical connector cannot be normally mated with the mating object, a problem that the electrical connector or the mating object is damaged and deformed due to compression may be generated.

In view of the above, it is desirable to provide an electrical connector to solve the problem that the electrical connector and the mating object cannot be mated normally.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, the present invention provides an electrical connector and a method for manufacturing the same, wherein the electrical connector is disposed on a circuit substrate and mated with a mating object, the electrical connector includes: the fixing and insulating base is provided with a plurality of base side walls, a first fixing side and a second fixing side which are opposite, a third fixing side and a fourth fixing side which are opposite, the plurality of base side walls are arranged to form a base inner space, and the base inner space is provided with a base inserting port; the suspension insulation socket is accommodated in the inner space of the base, separates the side walls of the base and is exposed out of the base socket interface, and the suspension insulation socket is provided with a first suspension side and a second suspension side which are opposite; the first conductive terminal is arranged on the circuit substrate and is provided with a first fixing section, a first elastic arm section, a first connection section and a first suspension section which are sequentially connected into a whole, wherein the first fixing section is embedded into the fixed insulating base at the first fixing side; the first suspension section is embedded into the suspension insulation socket at the first suspension side; the first connecting section extends to the suspension insulation socket to connect the fixed insulation base and the suspension insulation socket; the first elastic arm section is exposed in the separated space between the suspension insulation socket and each base side wall, so that the first connecting section can pull the suspension insulation socket to move through elastic deformation, the suspension insulation socket can move relative to the fixed insulation base at the first suspension side to align to the butt joint object, and the butt joint object can enter the base inner space through the base insertion port to butt joint the suspension insulation socket; the second conductive terminal is arranged on the circuit substrate and is provided with a second fixed section, a second elastic arm section, a second connection section and a second suspension section which are sequentially connected into a whole, wherein the second fixed section is embedded into the fixed insulating base at the second fixed side; the second suspension section is embedded into the suspension insulation socket at the second suspension side; the second connecting section extends to the suspension insulation socket to connect the fixed insulation base and the suspension insulation socket; the second elastic arm section is exposed in the separated space between the suspension insulation socket and each base side wall, so that the second connection section can pull the suspension insulation socket to move through elastic deformation, the suspension insulation socket can move relative to the fixed insulation base at the second suspension side to align to the butt joint object, and the butt joint object can enter the base inner space through the base insertion port to butt joint the suspension insulation socket; the first holding terminal is arranged on the circuit substrate and embedded on the fixed insulating base at the third fixed side, and the first holding terminal is provided with a first stopping structure extending to the base socket so that the suspended insulating socket is stopped at the third fixed side to leave the fixed insulating base through the base socket; and the second holding terminal is arranged on the circuit substrate and is embedded on the fixed insulating base at the fourth fixed side, and the second holding terminal is provided with a second stopping structure extending to the base socket so as to stop the suspension insulating socket from leaving the fixed insulating base through the base socket at the fourth fixed side.

Optionally, in the electrical connector, the floating insulating socket further has a plurality of socket sidewalls, each of the socket sidewalls is arranged to form a socket internal space, the socket internal space has a socket insertion port, the first floating section has a first electrical overlapping structure, the second floating section has a second electrical overlapping structure, and the first electrical overlapping structure and the second electrical overlapping structure respectively extend out of one of the socket sidewalls, so that the socket insertion port is exposed to electrically overlap the mating object.

Optionally, in the electrical connector, the first floating section has a first embedding structure at an end away from the first electrical bridging structure, and the first embedding structure extends in a direction perpendicular to the first electrical bridging structure and is embedded into one of the sidewalls of the plurality of sockets to position the first electrical bridging structure; the second suspension section is provided with a second embedded structure at one end departing from the second electric lapping structure, and the second embedded structure extends towards the direction vertical to the second electric lapping structure and is embedded into one of the plurality of socket side walls so as to position the second electric lapping structure.

Optionally, in the electrical connector, the first electrical bonding structure has a first abutting portion abutting against one of the sidewalls of the plurality of sockets to position the first electrical bonding structure; the second electrical bonding structure is provided with a second abutting part which abuts against one of the plurality of socket side walls so as to position the second electrical bonding structure.

Optionally, in the above electrical connector, the floating insulation socket further includes a plurality of socket sidewalls and a socket tongue, each of the socket sidewalls is arranged to form a socket inner space, the socket inner space has a socket insertion opening, the socket tongue is accommodated in the socket inner space, the first floating section has a first electrical overlapping structure, the second floating section has a second electrical overlapping structure, and the first electrical overlapping structure and the second electrical overlapping structure respectively extend out of the socket tongue so that the socket insertion opening is exposed to electrically overlap the mating object.

Optionally, in the electrical connector, the first floating section has a first embedding structure at an end facing away from the first electrical overlapping structure, and the first embedding structure extends in a direction perpendicular to the first electrical overlapping structure and is embedded into the socket tongue to position the first electrical overlapping structure; the second suspension section is provided with a second embedded structure at one end departing from the second electric lapping structure, and the second embedded structure extends towards the direction vertical to the second electric lapping structure and is embedded into the socket tongue part to position the second electric lapping structure.

Optionally, in the electrical connector, the first electrical bonding structure has a first abutting portion abutting against the socket tongue portion to position the first electrical bonding structure; the second electrical bonding structure has a second abutting portion abutting against the socket tongue portion to position the second electrical bonding structure.

Optionally, in the electrical connector, the first fixing section has a first electrical soldering structure, the second fixing section has a second electrical soldering structure, and the first electrical soldering structure and the second electrical soldering structure respectively extend out of the fixing insulating base, so that the fixing insulating base is exposed to electrically solder the circuit substrate.

In addition, the invention also provides a manufacturing method of the electric connector, which comprises the following steps: providing a forming die; arranging the first conductive terminal and the second conductive terminal at preset positions in the forming die respectively; injecting glue into the forming mold to synchronously form the fixed insulating base and the suspension insulating socket, so that the first fixed section and the second fixed section are synchronously embedded into the fixed insulating base, and the first suspension section and the second suspension section are synchronously embedded into the suspension insulating socket to form a semi-finished product of the electric connector; and the first holding terminal and the second holding terminal are respectively embedded into the fixed insulating base in the electric connector semi-finished product.

Optionally, in the above method for manufacturing an electrical connector, the first conductive terminals are a plurality of first conductive terminals, the second conductive terminals are a plurality of second conductive terminals, and the method further includes: providing at least one first separating piece and at least one second separating piece, respectively arranging the first separating piece and the second separating piece in a forming mould, and enabling the first separating piece to separate and position adjacent two of the plurality of first conductive terminals, and enabling the second separating piece to separate and position adjacent two of the plurality of second conductive terminals.

Compared with the prior art, the invention provides an electric connector and a manufacturing method thereof, wherein the electric connector is provided with a fixed insulating base, a suspension insulating socket, a first conductive terminal, a second conductive terminal, a first holding terminal and a second holding terminal. The first conductive terminal and the second conductive terminal can be deformed, so that the suspension insulation socket can move relative to the fixed insulation base to align to the butt joint object, and the problem that the electric connector cannot be normally butted with the butt joint object is solved; the first holding terminal and the second holding terminal can provide a stop so that the floating insulation socket cannot leave the fixed insulation base; the fixed insulating base and the suspension insulating socket are synchronously formed by the glue injection method, so that the manufacturing procedures are reduced and the cost is reduced.

Drawings

FIGS. 1A to 5 are schematic views illustrating the operation of the method for manufacturing an electrical connector according to the present invention;

fig. 6 is a schematic view of the electrical connector according to the first embodiment of the present invention in a first view;

FIG. 7 is a second perspective view of the electrical connector according to the first embodiment of the present invention;

FIG. 8 is a cross-sectional view of the electrical connector of FIG. 7 taken along line AA;

fig. 9 is an exploded view of the electrical connector shown in fig. 7;

fig. 10 is a schematic view of an electrical connector according to a second embodiment of the present invention from a first perspective;

fig. 11 is a schematic view of an electrical connector according to a second embodiment of the present invention from a second perspective;

FIG. 12 is a cross-sectional view of the electrical connector of FIG. 10 taken along line AA;

fig. 13 is an exploded view of the electrical connector shown in fig. 10;

FIG. 14 is a schematic flow chart illustrating a method of manufacturing an electrical connector according to the present invention;

FIG. 15 shows the electrical connector of the first embodiment of the present invention disposed on the circuit substrate and mated with the mating object

A schematic diagram of (a); and

FIG. 16 shows an electrical connector disposed on a circuit substrate and mated with a mating object according to a second embodiment of the present invention

Schematic representation of (a).

Description of the symbols

1 electric connector

11 fixed insulation base

111 base side wall

112 first fixed side

113 second fixed side

114 third fixed side

115 fourth fixed side

116 base inner space

1161 socket for base

12 suspension insulation socket

121 first suspension side

122 second suspended side

123 socket side wall

124 socket tongue

13 first conductive terminal

131 first fixing section

1311 first electric soldering structure

132 first spring arm section

133 first engagement section

134 first suspension section

1341 first electrical bonding structure

13411 first abutting part

1342 first embedding structure

14 second conductive terminal

141 second fixing section

1411 second electrical bonding structure

142 second spring arm section

143 second engagement section

144 second levitation section

1441 second electrical bonding structure

14411 second abutting portion

1442 second embedding structure

15 first holding terminal

151 first stopping structure

16 second holding terminal

161 second stop structure

2 butt joint object

3 Circuit board

4 forming die

41 first partition

42 second partition

43 upper die

44 lower die

5 Material strap

SP1 partitioned space

SP2 socket inner space

P1 semi-finished product of electric connector

H1 socket interface

S1-S4

Detailed Description

The present invention is described in detail with reference to the embodiments, and other advantages and effects of the present invention will be apparent to those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways. Various modifications and alterations may be made in the details of this description without departing from the spirit of the invention, from its aspects and applications. In particular, the relative positions and proportions of the various elements in the drawings are merely exemplary in nature and are not intended to represent the actual conditions in which the present invention is practiced.

In addition, the structures or components with the same or similar functions in the following embodiments will be described by using the same symbols, and the description of the same or equivalent technical features will be omitted so as to make the disclosure more concise and clear.

Please refer to fig. 1 to 16 together for the technical idea of the present invention.

As shown in the figures, the electrical connector 1 provided by the present invention is mainly used for being arranged on a circuit substrate 3 such as a flexible board or a hard board, and is butted with a butting object 2 such as an electrical connector. Specifically, the electrical connector 1 of the present invention mainly includes: the socket comprises a fixed insulating base 11, a floating insulating socket 12, at least one first conductive terminal 13, at least one second conductive terminal 14, a first holding terminal 15 and a second holding terminal 16.

As shown in fig. 9 and 13, the fixed insulating base 11 has a plurality of base sidewalls 111, first and second opposite fixing sides 112 and 113, and third and fourth opposite fixing sides 114 and 115, the plurality of base sidewalls 111 are selectively arranged on the first, second, third and fourth fixing sides 112, 113, 114 and 115 to form a base inner space 116, and the base inner space 116 is formed with a base insertion opening 1161 in the insertion direction of the mating object 2.

As shown in fig. 15, the floating insulation socket 12 is accommodated in the base inner space 116 and separates each base sidewall 111, so that the floating insulation socket 12 can move in the base inner space 116 relative to each base sidewall 111 and is exposed by the base interface 1161 to be abutted with the docking object 2. Note that the travel stroke of the floating insulating receptacle 12 in the base internal space 116 is determined by the distance separating the floating insulating receptacle 12 from each base side wall 111. The floating insulated receptacle 12 has opposite first and second floating sides 121 and 122, preferably the first and second floating sides 121 and 122 correspond to the first and second fixed sides 112 and 113, respectively.

As shown in fig. 1B, the first conductive terminal 13 is disposed on the circuit substrate 3 and has a first fixed section 131, a first elastic arm section 132, a first engaging section 133 and a first floating section 134, which are connected in sequence to form a whole. As shown in fig. 8 and 12, the first fixing section 131 is embedded in the fixed insulating base 11 at the first fixing side 112, so that the body of the first conductive terminal 13 is positioned by the first fixing section 131 embedded in the fixed insulating base 11. Preferably, the first fixing segment 131 has a first electrical soldering structure 1311 protruding out of the fixing insulation base 11, so that the fixing insulation base 11 is exposed to electrically solder the circuit substrate 3 as shown in fig. 15.

As shown in fig. 8 to 9 and fig. 12 to 13, the first floating section 134 is embedded into the floating insulation socket 12 at the first floating side 121, and when the floating insulation socket 12 moves in the base inner space 116 relative to each base sidewall 111, the floating insulation socket 12 pulls the first floating section 134 to move synchronously. The first engaging section 133 extends from the first elastic arm section 132 to the floating insulation socket 12 and is connected to the first floating section 134 to engage with both the fixed insulation base 11 and the floating insulation socket 12, so as to prevent both the fixed insulation base 11 and the floating insulation socket 12 from being separated. The first spring arm section 132 is exposed in the space S1 between the floating insulation socket 12 and each of the base sidewalls 111. When the floating insulation socket 12 moves relative to the fixed insulation base 11, the floating insulation socket 12 can pull the first engaging segment 133 to move and force the first elastic arm segment 132 to elastically deform in the separated space SP1, as shown in fig. 15, so that the floating insulation socket 12 can shift relative to the fixed insulation base 11 at the first floating side 121 to align with the docking object 2, and the docking object 2 can enter the base inner space 116 through the base inserting port 1161 to dock the floating insulation socket 12.

As shown in fig. 1B, the second conductive terminal 14 is disposed on the circuit substrate 3 and has a second fixed section 141, a second elastic arm section 142, a second engaging section 143 and a second floating section 144, which are connected in sequence to form a whole. As shown in fig. 8 and 12, the second fixing section 141 is embedded in the fixed insulating base 11 at the second fixing side 113, so that the body of the second conductive terminal 14 is positioned by the second fixing section 141 embedded in the fixed insulating base 11. Preferably, the second fixing section 141 has a second electrical soldering structure 1411 protruding out of the fixing insulation base 11, so that the fixing insulation base 11 is exposed to electrically solder the circuit substrate 3 as shown in fig. 15.

As shown in fig. 8 to 9 and fig. 12 to 13, the second floating section 144 is embedded in the floating insulation socket 12 at the second floating side 122, and when the floating insulation socket 12 moves in the base inner space 116 relative to each base sidewall 111, the floating insulation socket 12 pulls the second floating section 144 to move synchronously. The second engaging section 143 extends from the second elastic arm section 142 to the floating insulation socket 12 and is connected to the second floating section 144 to engage with both the fixed insulation base 11 and the floating insulation socket 12, so as to prevent the fixed insulation base 11 and the floating insulation socket 12 from being separated. The second spring arm section 142 is exposed in the separated space SP1 between the floating insulation socket 12 and each of the base sidewalls 111. When the floating insulation socket 12 moves relative to the fixed insulation base 11, the floating insulation socket 12 can pull the second engaging section 143 to move and force the second elastic arm section 142 to elastically deform in the separated space SP1, as shown in fig. 15, so that the floating insulation socket 12 can shift relative to the fixed insulation base 11 at the second floating side 122 to align with the docking object 2, and the docking object 2 can enter the base inner space 116 through the base inserting port 1161 to dock the floating insulation socket 12.

As shown in fig. 6 and 10, the first holding terminal 15 is disposed on the circuit substrate 3, and the fixed insulating base 11 is embedded in the third fixing side 114 intersecting with the first fixing side 112 and the second fixing side 113, respectively, the first holding terminal 15 has a first stopping structure 151 extending to the base socket 1161, the first stopping structure 151 presses the floating insulating socket 12 at the base socket 1161, so that the floating insulating socket 12 is stopped at the third fixing side 114 and leaves the fixed insulating base 11 through the base socket 1161.

As shown in fig. 6 and 10, the second holding terminal 16 is disposed on the circuit substrate 3, and the fixed insulating base 11 is embedded in the fourth fixing side 115 intersecting the first fixing side 112 and the second fixing side 113, respectively, the second holding terminal 16 has a second stopping structure 161 extending to the base socket 1161, the second stopping structure 161 presses the floating insulating socket 12 at the base socket 1161, so that the floating insulating socket 12 is stopped at the fourth fixing side 115 and leaves the fixed insulating base 11 through the base socket 1161.

In the first embodiment of the present invention, as shown in fig. 9, the floating insulation socket 12 further has a plurality of socket side walls 123 and socket tongues 124, each socket side wall 123 is arranged to form a socket inner space SP2, and the socket inner space SP2 is formed with socket sockets H1 in the plugging direction of the counterpart 2, wherein the socket tongues 124 are received in the socket inner space SP2 and exposed at the socket sockets H1. Correspondingly, as shown in fig. 8, the first floating section 134 has a first electrical bonding structure 1341, the second floating section 144 has a second electrical bonding structure 1441, and the first electrical bonding structure 1341 and the second electrical bonding structure 1441 respectively extend out of two opposite sides of the socket tongue 124, so that the socket interface H1 is exposed to electrically bond the mating object 2 shown in fig. 15. The first electrical landing structure 1341 has a first abutting portion 13411 that abuts against the socket tongue 124 to position the first electrical landing structure 1341. The second electrical bonding structure 1441 has a second abutting portion 14411 abutting against the socket tongue 124 to position the second electrical bonding structure 1441.

Preferably, as shown in fig. 8, the first suspension section 134 has a first embedding structure 1342, such as a plate, at an end away from the first electrical landing structure 1341, the first embedding structure 1342 extends in a direction perpendicular to the first electrical landing structure 1341, and the first embedding structure 1342 is embedded in the socket tongue 124 to position the first electrical landing structure 1341 by embedding the first embedding structure 1342. As shown in fig. 8, the second suspension section 144 has a second embedded structure 1442, such as a sheet-like body, at an end facing away from the second electrical bridging structure 1441, the second embedded structure 1442 extends in a direction perpendicular to the second electrical bridging structure 1441, and is embedded in the socket tongue 124 to position the second electrical bridging structure 1441 by embedding the second embedded structure 1442. As shown in fig. 8, the first 1342 and second 1442 insert structures extend in opposite directions.

In the second embodiment of the present invention, as shown in fig. 13, the floating insulation socket 12 further has a plurality of socket side walls 123, each socket side wall 123 is arranged to form a socket inner space SP2, and the socket inner space SP2 is formed with a socket insertion opening H1 in the insertion direction of the counterpart 2. Correspondingly, as shown in fig. 12, the first floating section 134 has a first electrical bonding structure 1341, the second floating section 144 has a second electrical bonding structure 1441, and the first electrical bonding structure 1341 and the second electrical bonding structure 1441 respectively extend out of one of the socket sidewalls 123, so that the socket interface H1 is exposed to electrically bond the mating object 2 shown in fig. 15. The first electrical landing structure 1341 has a first abutting portion 13411 that can abut against one of the socket sidewalls 123 to position the first electrical landing structure 1341. The second electrical bonding structure 1441 has a second abutting portion 14411 capable of abutting against one of the socket sidewalls 123 to position the second electrical bonding structure 1441.

Preferably, as shown in fig. 12, the first suspension section 134 has a first embedding structure 1342, such as a sheet-like body, at an end away from the first electrical landing structure 1341, and the first embedding structure 1342 extends in a direction perpendicular to the first electrical landing structure 1341 and is embedded in one of the socket sidewalls 123, so as to position the first electrical landing structure 1341 by embedding the first embedding structure 1342. As shown in fig. 12, the second suspending section 144 has a second embedded structure 1442, such as a sheet-like body, at an end away from the second electrical bridging structure 1441, and the second embedded structure 1442 extends in a direction perpendicular to the second electrical bridging structure 1441 and is embedded in one of the socket sidewalls 123, so as to position the second electrical bridging structure 1441 by embedding the second embedded structure 1442. As shown in fig. 12, the first 1342 and second 1442 insert structures extend in opposite directions.

In addition, please refer to the disclosure of fig. 1 to 5 and fig. 14 and the following description for the method for manufacturing the electrical connector of the present invention:

first, in step S1, a molding die 4 is provided, and as shown in fig. 1A, the molding die 4 includes an upper die 43 and a lower die 44. Next, in step S2, as shown in fig. 1B to 3, the first conductive terminals 13 and the second conductive terminals 14 are respectively placed at predetermined positions in the lower mold 44 of the forming mold 4 through the tape 5. Then, in step S3, as shown in fig. 4 to 5, the upper mold 43 and the lower mold 44 are stacked to accommodate the first conductive terminal 13 and the second conductive terminal 14 therein, and then the molding mold 4 is injected with glue to synchronously form the fixed insulating base 11 and the floating insulating socket 12, so that the first conductive terminal 13 and the second conductive terminal 14 are synchronously embedded into the fixed insulating base 11 and the floating insulating socket 12, that is, the first fixing segment 131 and the second fixing segment 141 are synchronously embedded into the fixed insulating base 11, and the first floating segment 134 and the second floating segment 144 are synchronously embedded into the floating insulating socket 12, so as to form the electrical connector semi-finished product P1. In step S4, as shown in fig. 9 and 13, the first holding terminal 15 and the second holding terminal 16 are respectively embedded in the fixed insulating base 11 of the electrical connector semi-finished product P1 to form the electrical connector 1.

Preferably, the method for manufacturing an electrical connector of the present invention further comprises the steps of: as shown in fig. 1A to 3, a first separating member 41 and a second separating member 42 respectively disposed in the forming mold 4 are provided, so that the first separating member 41 separates and positions two adjacent ones of the plurality of first conductive terminals 13 to prevent the two adjacent ones of the plurality of first conductive terminals 13 from being electrically shorted, and the second separating member 42 separates and positions two adjacent ones of the plurality of second conductive terminals 14 to prevent the two adjacent ones of the plurality of second conductive terminals 14 from being electrically shorted.

In summary, the present invention provides an electrical connector and a method for manufacturing the same, wherein the electrical connector has a fixed insulating base, a floating insulating socket, a first conductive terminal, a second conductive terminal, a first holding terminal and a second holding terminal. The first conductive terminal and the second conductive terminal can be deformed, so that the suspension insulation socket can move relative to the fixed insulation base to align to the butt joint object, and the problem that the electric connector cannot be normally butted with the butt joint object is solved; the first holding terminal and the second holding terminal can provide a stop so that the floating insulation socket cannot leave the fixed insulation base; the fixed insulating base and the suspension insulating socket are synchronously formed by the glue injection method, so that the manufacturing procedures are reduced and the cost is reduced.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the invention. 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 invention. Therefore, the scope of the invention should be determined by the following claims.