TWI850635B - Electrical connector and its manufacturing method and upper-layer oblique insertion assembly stand and its assembly method thereof - Google Patents

Abstract

An electrical connector and its manufacturing method and an upper-layer oblique insertion assembly stand and its an assembly method thereof. The provided electrical connector and the upper-layer oblique insertion assembly stand can provide shielding to conductive terminals through a shielding body to reduce the interference of the signal transmission of the conductive terminals, and achieve electrical connection between some conductive terminals on the electrical connector, and suppress the coupled crosstalk interference when transmitting high-speed signals. Therefore, the electrical connector and the upper-layer oblique insertion assembly stand of the present application can meet the customized requirements of the electrical connector for transmitting high-speed signals. In addition, the components of the electrical connector of the present application are assembled by oblique insertion, which can reduce the height dimension of the electrical connector, thereby reducing the internal space occupied by the electrical connector of the electronic device, so that the electronic device can continue to develop in the direction of light, thin and short.

Description

Electrical connector and manufacturing method thereof, upper layer oblique insertion assembly and assembly method thereof

This application relates to the technical field of electrical connectors, and in particular, to an electrical connector capable of transmitting high-speed signals and reducing size, and its manufacturing method, and an upper oblique insertion assembly and its assembly method.

In modern electronic devices, electrical connectors are usually provided to provide signal transmission. However, in response to the special needs and development of electronic devices, the number and structure of the conductive oblique plug conductive terminals of the electrical connector will be required to be customized. However, after the design of the current electrical connector is completed, the number and structure of the conductive oblique plug conductive terminals will be determined and cannot be customized, making it difficult to meet the signal transmission requirements of the electronic device. This will limit the technical (functional) development of the electronic device.

In addition, electrical connectors are prone to generate coupled crosstalk interference when transmitting high-speed signals, which causes interference attenuation in the transmission of high-speed signals. Furthermore, with the development trend of electronic devices becoming thinner and shorter, the internal space of electronic devices has been greatly reduced, resulting in limited space inside electronic devices for installing electrical connectors.

In view of this, how to provide an electrical connector that can suppress crosstalk interference so that the electrical connector can meet the transmission requirements of high-speed signals and reduce the internal space occupied by the electrical connector in electronic devices so that electronic devices can continue to develop in the direction of being thinner and smaller has become a technical issue that the industry is eager to challenge and overcome.

In view of the shortcomings of the above-mentioned prior art, the main purpose of this application is to provide an electrical connector and its manufacturing method and an upper layer oblique insertion assembly and its assembly method, so that the electrical connector can meet the transmission requirements of high-speed signals.

Another purpose of this application is to provide an electrical connector and a manufacturing method thereof, and an upper layer oblique insertion assembly and an assembly method thereof, which can simplify and reduce the size of the electrical connector.

In view of the above-mentioned shortcomings of the prior art, the present application provides an upper oblique plug assembly member, which is matched with an electrical connector body, and the upper oblique plug assembly member includes: an upper oblique plug conductive terminal group, the upper oblique plug conductive terminal group has a plurality of upper layer jumper oblique plug conductive terminals and an upper layer non-jumper oblique plug conductive terminal; an upper layer jumper body, the upper layer jumper body is extended above the upper layer oblique plug conductive terminal group, crosses the upper layer non-jumper oblique plug conductive terminals, and electrically jumps the plurality of upper layer jumper oblique plug conductive terminals. Terminal; an upper shielding body, which extends below the upper obliquely inserted conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper obliquely inserted conductive terminal set; and an upper obliquely inserted assembly stand body, which provides positioning for the upper obliquely inserted conductive terminal set, and the upper obliquely inserted assembly stand body is obliquely inserted into the electrical connector body, so that the upper obliquely inserted assembly stand body is assembled on the electrical connector body, and the upper obliquely inserted conductive terminal set is obliquely inserted into the electrical connector body.

In addition, the present application also provides an electrical connector, comprising: an electrical connector body, the electrical connector body having a body oblique insertion space; an upper oblique insertion assembly member, the upper oblique insertion assembly member having an upper oblique insertion conductive terminal group, an upper shielding body, an upper oblique insertion assembly member body and an upper jumper body, wherein the upper oblique insertion conductive terminal group has a plurality of upper jumper oblique insertion conductive terminals and an upper non-jumper oblique insertion conductive terminal, and the upper jumper body extends above the upper oblique insertion conductive terminal group and crosses over the upper non-jumper The upper shielding body extends below the upper obliquely inserted conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper obliquely inserted conductive terminal set; and the upper obliquely inserted assembly body provides positioning for the upper obliquely inserted conductive terminal set, and the upper obliquely inserted assembly body is obliquely inserted into the oblique insertion space of the body, so that the upper obliquely inserted assembly body is assembled on the electrical connector body, and the upper obliquely inserted conductive terminal set is obliquely inserted into the oblique insertion space of the body.

Preferably, the electrical connector of the present application further comprises: a shielding shell, the shielding shell having a shell oblique insertion port, the upper oblique insertion assembly body is inserted obliquely into the body oblique insertion space through the shielding shell through the shell oblique insertion port; wherein, when the upper oblique insertion assembly body is assembled on the electrical connector body, the shielding shell extends above the upper oblique insertion conductive terminal set, so that the shielding shell provides shielding for the upper part of the upper oblique insertion conductive terminal set.

Preferably, the electrical connector of the present application further comprises: a lower oblique plug assembly member, the lower oblique plug assembly member having a lower oblique plug conductive terminal group, a lower shielding body, a lower oblique plug assembly member body and a lower jumper body, wherein the lower oblique plug conductive terminal group has a plurality of lower jumper oblique plug conductive terminals and a lower non-jumper oblique plug conductive terminal, and the lower jumper body extends above the lower oblique plug conductive terminal group, crosses over the lower non-jumper oblique plug conductive terminals, and electrically jumps over the plurality of lower jumper oblique plug conductive terminals, and the lower shielding body extends below the lower oblique plug conductive terminal group, so that the lower shielding body extends below the lower oblique plug conductive terminal group. The shielding body provides shielding for the lower layer obliquely inserted conductive terminal set; and the lower layer obliquely inserted component body provides positioning for the lower layer obliquely inserted conductive terminal set, and the lower layer obliquely inserted component body is obliquely inserted into the body oblique insertion space, so that the lower layer obliquely inserted component body is assembled on the electrical connector body, and the lower layer obliquely inserted conductive terminal set is obliquely inserted into the body oblique insertion space; when the upper layer obliquely inserted component body and the lower layer obliquely inserted component body are respectively assembled on the electrical connector body, the upper layer shielding body extends above the lower layer obliquely inserted conductive terminal set, so that the upper layer shielding body provides shielding for the upper part of the lower layer obliquely inserted conductive terminal set.

Preferably, in the electrical connector of the present application, the upper shielding body has an upper shielding body overlap structure, and the lower shielding body has a lower shielding body overlap structure. When the upper obliquely inserted assembly body and the lower obliquely inserted assembly body are respectively assembled on the electrical connector body, the upper shielding body overlap structure electrically overlaps the lower shielding body overlap structure, so that the upper shielding body electrically overlaps the lower shielding body.

Preferably, in the electrical connector of the present application, the electrical connector body also has a body oblique insertion guide structure, and the body oblique insertion guide structure guides the upper oblique insertion assembly body and the lower oblique insertion assembly body to be obliquely inserted into the body oblique insertion space respectively.

Preferably, in the electrical connector of the present application, the body oblique insertion guide structure has a body upper oblique insertion guide substructure and a body lower oblique insertion guide substructure, the body upper oblique insertion guide substructure is provided to guide the upper oblique insertion assembly body to be obliquely inserted into the body oblique insertion space at an upper oblique angle, and the body lower oblique insertion guide substructure is provided to guide the lower oblique insertion assembly body to be obliquely inserted into the body oblique insertion space at a lower oblique angle, wherein the upper oblique angle is the same as the lower oblique angle.

Preferably, in the electrical connector of the present application, the electrical connector body also has a body oblique insertion stroke limiting structure, which is used to stop the upper oblique insertion assembly body and the lower oblique insertion assembly body, thereby limiting the insertion stroke of the upper oblique insertion assembly body and the lower oblique insertion assembly body respectively obliquely inserted into the body oblique insertion space.

Preferably, in the electrical connector of the present application, the body oblique insertion stroke limiting structure has a body upper oblique insertion stroke limiting substructure and a body lower oblique insertion stroke limiting substructure, the body upper oblique insertion stroke limiting substructure limits the upper oblique insertion assembly body to be inserted obliquely into the body oblique insertion space with an upper insertion stroke, and the body lower oblique insertion stroke limiting substructure limits the lower oblique insertion assembly body to be inserted obliquely into the body oblique insertion space with a lower insertion stroke, wherein the upper insertion stroke is the same as the lower insertion stroke.

Preferably, in the electrical connector of the present application, the upper oblique insertion stroke limiting substructure of the body is adjacent to the upper oblique insertion guiding substructure of the body, the upper oblique insertion guiding substructure of the body is adjacent to the lower oblique insertion stroke limiting substructure of the body, and the lower oblique insertion stroke limiting substructure of the body is adjacent to the lower oblique insertion guiding substructure of the body, so that the upper oblique insertion stroke limiting substructure of the body, the upper oblique insertion guiding substructure of the body, the lower oblique insertion stroke limiting substructure of the body and the lower oblique insertion guiding substructure of the body form a ladder-like structure.

Preferably, in the electrical connector of the present application, the electrical connector body also has a body oblique insertion channel, and the body oblique insertion channel extends at a channel inclination angle to form the body oblique insertion space, wherein the channel inclination angle, the upper layer inclination angle and the lower layer inclination angle are the same.

Preferably, in the electrical connector of the present application, the electrical connector body also has a body oblique insertion guide structure, and the body oblique insertion guide structure guides the upper shielding body and the lower shielding body to be obliquely inserted into the body oblique insertion space respectively.

Preferably, in the electrical connector of the present application, the body oblique insertion guide structure has a body upper oblique insertion guide substructure and a body lower oblique insertion guide substructure, the body upper oblique insertion guide substructure is provided to guide the upper shielding body to be obliquely inserted into the body oblique insertion space at an upper oblique angle, and the body lower oblique insertion guide substructure is provided to guide the lower shielding body to be obliquely inserted into the body oblique insertion space at a lower oblique angle, wherein the upper oblique angle is the same as the lower oblique angle.

Preferably, in the electrical connector of the present application, the upper shielding body, the lower shielding body, the upper jumper body and the lower jumper body are plastic conductors or metal conductors; the shielding shell is a metal conductor; the electrical connector body, the upper oblique plug assembly body and the lower oblique plug assembly body are insulators.

Preferably, in the electrical connector of the present application, the upper jumper has a plurality of upper jumper embedding positioning structures, each of which embeds and positions one of the plurality of upper jumper obliquely inserted conductive terminals, so that the upper jumper electrically jumps over the plurality of upper jumper obliquely inserted conductive terminals; the lower jumper has a plurality of lower jumper embedding positioning structures, each of which embeds and positions one of the plurality of lower jumper obliquely inserted conductive terminals, so that the lower jumper electrically jumps over the plurality of lower jumper obliquely inserted conductive terminals.

Preferably, in the electrical connector of the present application, when the upper obliquely inserted assembly body and the lower obliquely inserted assembly body are respectively assembled on the electrical connector body, the shielding shell also extends to the sides of the upper obliquely inserted conductive terminal set and the lower obliquely inserted conductive terminal set, so that the shielding shell provides shielding for the sides of the upper obliquely inserted conductive terminal set and the lower obliquely inserted conductive terminal set, respectively.

Preferably, in the electrical connector of the present application, the upper shielding body extends along the side of the upper obliquely inserted conductive terminal set, so that the upper shielding body provides shielding for the side of the upper obliquely inserted conductive terminal set; the lower shielding body extends along the side of the lower obliquely inserted conductive terminal set, so that the lower shielding body provides shielding for the side of the lower obliquely inserted conductive terminal set.

Furthermore, the present application also provides an upper layer oblique plug assembly assembly method, which is used in conjunction with an electrical connector body, and the upper layer oblique plug assembly assembly method includes: providing an upper layer oblique plug conductive terminal group, an upper layer shielding body, an upper layer oblique plug assembly body and an upper layer jumper body, wherein the upper layer oblique plug assembly body provides positioning for the upper layer oblique plug conductive terminal group, and the upper layer oblique plug conductive terminal group has a plurality of upper layer jumper oblique plug conductive terminals and an upper layer non-jumper oblique plug conductive terminal, and the upper layer jumper body is on the upper layer. The upper layer shielding body extends above the upper layer oblique plug conductive terminal set, crosses the upper layer non-bridged oblique plug conductive terminal, and electrically bridges the plurality of upper layer bridged oblique plug conductive terminals. The upper layer shielding body extends below the upper layer oblique plug conductive terminal set, so that the upper layer shielding body provides shielding for the lower part of the upper layer oblique plug conductive terminal set; and the upper layer oblique plug assembly body is obliquely inserted into the electrical connector body, so that the upper layer oblique plug assembly body is assembled on the electrical connector body, and the upper layer oblique plug conductive terminal set is obliquely inserted into the electrical connector body.

In addition, the present application also provides a method for manufacturing an electrical connector, which includes: providing an electrical connector body and an upper oblique plug-in assembly, wherein the upper oblique plug-in assembly has an upper oblique plug-in conductive terminal group, an upper shielding body, an upper oblique plug-in assembly body and an upper jumper, wherein the upper oblique plug-in assembly body provides positioning for the upper oblique plug-in conductive terminal group, and the upper oblique plug-in conductive terminal group has a plurality of upper jumper oblique plug-in conductive terminals and an upper non-jumper oblique plug-in conductive terminal, and the upper jumper is located between the upper oblique plug-in conductive terminals. The upper shield extends above the upper non-crossing oblique plug conductive terminal and electrically crosses the plurality of upper cross-connecting oblique plug conductive terminals. The upper shield extends below the upper oblique plug conductive terminal group so that the upper shield provides shielding for the lower part of the upper oblique plug conductive terminal group. The electrical connector body has a body oblique plug space. The upper oblique plug assembly body is obliquely inserted into the body oblique plug space, so that the upper oblique plug assembly body is assembled on the electrical connector body, and the upper oblique plug conductive terminal group is obliquely inserted into the body oblique plug space.

Preferably, the manufacturing method of the electrical connector of the present application further comprises: providing a lower layer oblique plug assembly, wherein the lower layer oblique plug assembly has a lower layer oblique plug conductive terminal group, a lower layer shielding body, a lower layer oblique plug assembly body and a lower layer jumper, wherein the lower layer oblique plug assembly body provides positioning for the lower layer oblique plug conductive terminal group, and the lower layer oblique plug conductive terminal group has a plurality of lower layer jumper oblique plug conductive terminals and a lower layer non-jumper oblique plug conductive terminals, and the lower layer jumper extends above the lower layer oblique plug conductive terminal group, crosses over the lower layer non-jumper oblique plug conductive terminals, and electrically jumps over the plurality of lower layer jumper oblique plug conductive terminals. , the lower shielding body extends below the lower obliquely inserted conductive terminal set, so that the lower shielding body provides shielding for the lower part of the lower obliquely inserted conductive terminal set; and the lower obliquely inserted component body is obliquely inserted into the body obliquely inserted space, so that the lower obliquely inserted component body is assembled on the electrical connector body, and the lower obliquely inserted conductive terminal set is obliquely inserted into the body obliquely inserted space; wherein, when the upper obliquely inserted component body and the lower obliquely inserted component body are respectively assembled on the electrical connector body, the upper shielding body extends above the lower obliquely inserted conductive terminal set, so that the upper shielding body provides shielding for the upper part of the lower obliquely inserted conductive terminal set.

Preferably, in the electrical connector manufacturing method of the present application, when the upper obliquely inserted assembly body and the lower obliquely inserted assembly body are respectively assembled on the electrical connector body, the upper shielding body is electrically overlapped with the lower shielding body.

Preferably, the electrical connector manufacturing method of the present application further includes: extending the upper shielding body to the side of the upper obliquely inserted conductive terminal group so that the upper shielding body provides shielding for the side of the upper obliquely inserted conductive terminal group; and extending the lower shielding body to the side of the lower obliquely inserted conductive terminal group so that the lower shielding body provides shielding for the side of the lower obliquely inserted conductive terminal group.

Preferably, the electrical connector manufacturing method of the present application further includes: providing a shielding shell; and extending the shielding shell above the upper layer obliquely inserted conductive terminal set, so that the shielding shell provides shielding for the upper layer obliquely inserted conductive terminal set.

Preferably, the electrical connector manufacturing method of the present application further includes: allowing the shielding shell to extend along the side of the upper layer obliquely inserted conductive terminal set, so that the shielding shell provides shielding for the side of the upper layer obliquely inserted conductive terminal set respectively.

Compared to the prior art, the present application provides an electrical connector and a manufacturing method thereof, and an upper layer oblique insertion assembly and an assembly method thereof. The provided electrical connector and upper layer oblique insertion assembly can provide shielding for the conductive terminals through a shielding body to reduce interference in the signal transmission of the conductive terminals, and achieve electrical connection between the conductive terminals on the upper part of the electrical connector, thereby suppressing the crosstalk interference caused by coupling when transmitting high-speed signals. Therefore, the electrical connector and upper layer oblique insertion assembly of the present application can meet customized requirements such as the electrical connector transmitting high-speed signals. In addition, the components of the electrical connector of this application are assembled by tilting the insertion method, which can reduce the height of the electrical connector, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

1:Electrical connector

11: Electrical connector body

111: The main body is inserted diagonally into the space

112: Main body oblique insertion guiding structure

1121: The guide structure is inserted obliquely into the upper layer of the main body

1122: The guide structure is inserted obliquely into the lower layer of the main body

113: Main body oblique insertion stroke limiting structure

1131: The upper layer of the main body has an oblique insertion stroke limiting substructure

1132: The lower layer of the main body has a travel limit substructure for oblique insertion

114: Main body oblique insertion channel

12: Upper layer oblique insertion assembly

121: Upper layer obliquely inserted conductive terminal set

1211: Upper layer jumper obliquely inserted conductive terminal

1212: Upper non-jumping oblique conductive terminal

122: Upper shielding body

1221: Upper shielding body overlap structure

123: Upper layer oblique insertion assembly body

124: Upper layer jumper

1241: Upper layer jumper body embedded positioning structure

13: Shielding shell

131: Oblique insertion port of the outer shell

14: Lower layer oblique insertion assembly

141: Lower layer obliquely inserted conductive terminal group

1411: Lower layer jumper obliquely inserted conductive terminal

1412: Lower layer non-jumping obliquely inserted conductive terminal

142: Lower shielding body

1421: Lower shielding body overlap structure

143: Lower layer oblique insertion assembly body

144: Lower layer jumper

1441: Lower layer cross-connect body embedded positioning structure

The above and other aspects, features and other advantages of this application will be more clearly understood through the following description of embodiments in conjunction with the drawings.

Figure 1 is a three-dimensional schematic diagram of an embodiment of the electrical connector of this application.

Figure 2 is a three-dimensional schematic diagram of an embodiment of the electrical connector of this application.

Figure 3 is a bottom view of an embodiment of the electrical connector of the present application.

Figure 4 is a top view schematic diagram of an embodiment of the electrical connector of this application.

Figure 5 is a front view schematic diagram of an embodiment of the electrical connector of the present application.

Figure 6 is a side view schematic diagram of an embodiment of the electrical connector of the present application.

Figure 7 is a rear view schematic diagram of an embodiment of the electrical connector of the present application.

Figure 8 is a schematic cross-sectional view of the component shown in Figure 5 cut along the AA line segment.

Figure 9 is a schematic cross-sectional view of the component shown in Figure 5 cut along line segment BB.

Figure 10 is a schematic diagram of an exploded view of an embodiment of the electrical connector of the present application.

Figure 11 is a schematic diagram of an exploded view of an embodiment of the electrical connector of the present application.

Figure 12 is a schematic diagram of the assembly of an embodiment of the electrical connector of this application.

Figure 13 is a schematic diagram of the assembly of an embodiment of the electrical connector of this application.

Figure 14 is a schematic diagram of an assembly of an embodiment of the electrical connector of this application.

Figure 15 is a schematic diagram of an assembly of an embodiment of the electrical connector of this application.

Figure 16 is a schematic assembly diagram of an embodiment of the electrical connector of this application.

Figure 17 is a schematic assembly diagram of an embodiment of the electrical connector of this application.

Figure 18 is a schematic diagram of an assembly of an embodiment of the electrical connector of this application.

Figure 19 is a schematic diagram of an assembly of an embodiment of the electrical connector of this application.

Figure 20 is a schematic diagram of an assembly of an embodiment of the electrical connector of this application.

Figure 21 is a schematic assembly diagram of an embodiment of the electrical connector of this application.

Figure 22 is a schematic diagram of the components of an embodiment of the electrical connector of this application.

Figure 23 is a schematic cross-sectional view of the component shown in Figure 22 cut along the CC line segment.

Figure 24 is a schematic assembly diagram of an embodiment of the electrical connector of this application.

Figure 25 is a schematic assembly diagram of an embodiment of the electrical connector of this application.

Figure 26 is a schematic diagram of the components of an embodiment of the electrical connector of this application.

Figure 27 is a schematic cross-sectional view of the component shown in Figure 26 cut along the DD line segment.

Figure 28 is a schematic diagram of the components of an embodiment of the electrical connector of this application.

Figure 29 is a schematic diagram of the components of an embodiment of the electrical connector of this application.

Figure 30 is a top view schematic diagram of an embodiment of the electrical connector of the present application.

Figure 31 is a bottom view of an embodiment of the electrical connector of the present application.

The following content will be accompanied by drawings to illustrate the technical content of this application through specific concrete embodiments. People familiar with this technology can easily understand other advantages and functions of this application from the content disclosed in this specification. This application can also be implemented or applied through other different specific embodiments. The details in this specification can also be modified and changed in various ways based on different viewpoints and applications without departing from the spirit of this application. In particular, the proportional relationship and relative position of each component in the drawings are only for exemplary purposes and do not represent the actual situation of the implementation of this application.

The electrical connector of this application can be connected to wires, so that the electrical connector of this application can constitute a wire electrical connector to provide signal transmission for the wires.

For the disclosure of the electrical connector and its upper oblique insertion assembly of this application, please refer to Figures 1 to 31.

As shown in FIGS. 1 to 11 , the electrical connector 1 of the present application may include an electrical connector body 11, an upper oblique insertion assembly 12, a shielding shell 13, and a lower oblique insertion assembly 14. The electrical connector body 11 is, for example, an insulator, and as shown in FIG. 29 , the electrical connector body 11 has a body oblique insertion space 111 and a body oblique insertion guide structure 112. As shown in FIGS. 12 to 13 , the upper oblique insertion assembly 12 has an upper oblique insertion conductive terminal set 121, an upper shielding body 122, an upper oblique insertion assembly body 123, and an upper jumper 124, and the upper oblique insertion conductive terminal set 121 has a plurality of upper jumper oblique insertion conductive terminals 1211 and upper non-jumper oblique insertion conductive terminals 1212. The upper shielding body 122 and the upper jumper 124 are, for example, plastic conductors or metal conductors. The upper shielding body 122 can extend below the upper obliquely inserted conductive terminal set 121, so that the upper shielding body 122 provides shielding for the lower part of the upper obliquely inserted conductive terminal set 121, thereby reducing the degree of interference (such as EMI or noise interference) in the signal transmission of the upper obliquely inserted conductive terminal set 121, so as to meet the signal transmission requirements of the electrical connector. In the present application, the upper jumper 124 extends above the upper obliquely inserted conductive terminal set 121, crosses the upper non-jumping obliquely inserted conductive terminal 1212, and electrically jumps over a plurality of upper jumper obliquely inserted conductive terminals 1211, so that the upper jumper 124 is electrically connected to each upper jumper obliquely inserted conductive terminal 1211, and forms a circuit that can transmit, for example, a ground signal, to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals, and to prevent the high-speed signals transmitted by the electrical connector from being interfered with and attenuated, so as to meet customized requirements such as the transmission of high-speed signals by the electrical connector.

The lower oblique insertion assembly 14 comprises a lower oblique insertion conductive terminal set 141, a lower shielding body 142, a lower oblique insertion assembly body 143 and a lower jumper 144. The lower oblique insertion conductive terminal set 141 comprises a plurality of lower jumper oblique insertion conductive terminals 1411 and lower non-jumper oblique insertion conductive terminals 1412. The lower shielding body 142 and the lower jumper 144 are, for example, plastic conductors or metal conductors. The lower shielding body 142 can extend below the lower obliquely inserted conductive terminal set 141, so that the lower shielding body 142 provides shielding for the lower portion of the lower obliquely inserted conductive terminal set 141, thereby reducing the degree of interference (such as external interference such as EMI or noise interference) to the signal transmission of the lower obliquely inserted conductive terminal set 141, thereby meeting the signal transmission requirements of the electrical connector. In the present application, the lower layer jumper 144 extends above the lower layer obliquely inserted conductive terminal set 141, crosses over the lower layer non-jumping obliquely inserted conductive terminal 1412, and electrically jumps over a plurality of lower layer jumper obliquely inserted conductive terminals 1411, so that the lower layer jumper 144 is electrically connected to each lower layer jumper obliquely inserted conductive terminal 1411, and forms a circuit for transmitting a signal such as a ground signal, so as to suppress the crosstalk interference generated by coupling when the electrical connector transmits a high-speed signal, and avoid the high-speed signal transmitted by the electrical connector from being interfered and attenuated, so as to meet the customized requirements of the electrical connector for transmitting high-speed signals.

The upper oblique insertion assembly body 123 is, for example, an insulator, and provides positioning for the upper oblique insertion conductive terminal set 121, the upper shielding body 122, and the upper jumper 124. As shown in FIGS. 10 and 11, the upper oblique insertion assembly body 123 can be guided by the body oblique insertion guide structure 112 to be obliquely inserted into the body oblique insertion space 111, so that the upper The oblique insertion assembly body 123 is assembled on the electrical connector body 11, and the upper oblique insertion conductive terminal assembly 121 is obliquely inserted into the body oblique insertion space 111. In this way, as shown in Figures 8 and 9, the height of the electrical connector can be reduced, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

The lower oblique insertion assembly body 143 is, for example, an insulator, and provides positioning for the lower oblique insertion conductive terminal set 141, the lower shielding body 142, and the lower jumper 144. As shown in FIGS. 10 to 11, the lower oblique insertion assembly body 143 can be guided by the body oblique insertion guide structure 112 to be obliquely inserted into the body oblique insertion space 111, so that the lower oblique insertion assembly body 143 is assembled on the electrical connector body 11, and the lower oblique insertion conductive terminal set 141 is obliquely inserted into the body oblique insertion space 111. In this way, as shown in FIGS. 8 to 9, the height of the electrical connector can be reduced, thereby reducing the internal space of the electronic device occupied by the electrical connector, so that the electronic device can continue to develop in the direction of being thinner and smaller.

Specifically, as shown in Fig. 29, the body oblique insertion guiding structure 112 comprises a body upper oblique insertion guiding substructure 1121 and a body lower oblique insertion guiding substructure 1122. The body upper oblique insertion guiding substructure 1121 is, for example, a guiding ramp, which can provide guidance for the upper oblique insertion assembly body 123 or the upper shielding body 122 to be obliquely inserted into the body oblique insertion space 111 at an upper oblique angle. The lower layer oblique insertion guide structure 1122 of the body is provided to guide the lower layer oblique insertion assembly body 143 or the lower layer shielding body 142 to be obliquely inserted into the body oblique insertion space 111 at a lower layer oblique angle, wherein the upper layer oblique angle and the lower layer oblique angle can be the same, so that the upper layer oblique insertion assembly body 123 and the lower layer oblique insertion assembly body 143 are obliquely inserted into the body oblique insertion space 111 in the same manner, or the upper layer shielding body 122 and the lower layer shielding body 142 are obliquely inserted into the body oblique insertion space 111 in the same manner, so that the size of the electrical connector can be reduced, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

As shown in FIG. 28 and FIG. 29 , the electrical connector body 11 has a body oblique insertion channel 114 , and the body oblique insertion channel 114 extends at a channel inclination angle to form a body oblique insertion space 111 . It should be noted that in this application, the channel tilt angle, the upper layer tilt angle and the lower layer tilt angle can be the same, so that the upper layer oblique insertion assembly body 123 and the lower layer oblique insertion assembly body 143 are tilted and inserted into the body oblique insertion space 111 in the same way, or the upper layer shielding body 122 and the lower layer shielding body 142 are tilted and inserted into the body oblique insertion space 111 in the same way. In this way, the size of the electrical connector can be reduced, and then the internal space occupied by the electrical connector in the electronic device can be reduced, so that the electronic device can continue to develop in the direction of being light, thin and short.

In addition, as shown in FIG. 23 and FIG. 27 , the upper shielding body 122 has an upper shielding body overlapping structure 1221 , and correspondingly, the lower shielding body 142 has a lower shielding body overlapping structure 1421 . When the upper obliquely inserted assembly body 123 and the lower obliquely inserted assembly body 143 are respectively assembled on the electrical connector body 11, the upper shielding body overlap structure 1221 electrically overlaps the lower shielding body overlap structure 1421, so that the upper shielding body 122 electrically overlaps the lower shielding body 142, and the upper shielding body 122 is electrically connected to the lower shielding body 142, thereby reducing the degree of interference to signal transmission (the external interference is, for example, EMI electromagnetic interference or noise interference) to meet the signal transmission requirements of the electrical connector. It should be noted that the upper shielding body overlap structure 1221 and the lower shielding body overlap structure 1421 are, for example, structurally matched track structures, so that the upper shielding body overlap structure 1221 can effectively and electrically overlap the lower shielding body overlap structure 1421.

In addition, as shown in FIG. 27 , when the upper obliquely inserted assembly body 123 and the lower obliquely inserted assembly body 143 are respectively assembled on the electrical connector body 11, the upper shielding body 122 extends above the lower obliquely inserted conductive terminal set 141, so that the upper shielding body 122 provides shielding for the upper part of the lower obliquely inserted conductive terminal set 141, thereby reducing the degree of interference (such external interference is, for example, EMI electromagnetic interference or noise interference) in the signal transmission of the lower obliquely inserted conductive terminal set 141, so as to meet the signal transmission requirements of the electrical connector.

In addition, as shown in FIG. 13 , the upper jumper 124 has a plurality of upper jumper engagement positioning structures 1241, each of which is, for example, a clamping structure, and can be engaged and positioned by clamping one of the plurality of upper jumper obliquely inserted conductive terminals 1211, so that the upper jumper 124 is electrically connected to the plurality of upper jumper obliquely inserted conductive terminals 1211, thereby forming a circuit for transmitting, for example, a ground signal, so as to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals. As shown in FIG. 13 , the lower jumper 144 has a plurality of lower jumper embedding positioning structures 1441, each of which is, for example, a clamping structure, and can be embedded and positioned by clamping one of the plurality of lower jumper obliquely inserted conductive terminals 1411, so that the lower jumper 144 is electrically connected to the plurality of lower jumper obliquely inserted conductive terminals 1411, thereby forming a circuit for transmitting, for example, a ground signal, so as to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals.

As shown in FIG. 28 , the electrical connector body 11 also has a body oblique insertion stroke limiting structure 113, which is used to stop the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143, and limit the insertion stroke of the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 respectively inserted obliquely into the body oblique insertion space 111, thereby preventing the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 from being excessively inserted into the body oblique insertion space 111, so that the oblique insertion state of the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 meets expectations.

Specifically, as shown in FIG. 28 , the body oblique insertion stroke limiting structure 113 includes a body upper oblique insertion stroke limiting substructure 1131 and a body lower oblique insertion stroke limiting substructure 1132. The body upper oblique insertion stroke limiting substructure 1131 limits the upper oblique insertion assembly body 123 from being inserted obliquely into the body oblique insertion space 111 with an upper insertion stroke. Correspondingly, the body lower oblique insertion stroke limiting substructure 1132 limits the lower oblique insertion assembly body 143 from being inserted obliquely into the body oblique insertion space 111 with a lower insertion stroke.

It should be noted that the upper layer insertion stroke and the lower layer insertion stroke can be the same, so that the upper layer oblique insertion assembly body 123 and the lower layer oblique insertion assembly body 143 are obliquely inserted into the body oblique insertion space 111 in the same manner, so as to reduce the size of the electrical connector, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

As shown in Figures 28 and 29, the upper oblique insertion stroke limiting substructure 1131 of the main body is adjacent to the upper oblique insertion guiding substructure 1121 of the main body, and the upper oblique insertion guiding substructure 1121 of the main body is adjacent to the lower oblique insertion stroke limiting substructure 1132 of the main body, and the lower oblique insertion stroke limiting substructure 1132 of the main body is adjacent to the lower oblique insertion guiding substructure 1122 of the main body. In this way, the upper oblique insertion stroke limiting substructure 1131 of the main body, the upper oblique insertion guiding substructure 1121 of the main body, the lower oblique insertion stroke limiting substructure 1132 of the main body and the lower oblique insertion guiding substructure 1122 of the main body can form a stepped structure to meet the use requirements.

The shielding shell 13 is, for example, a metal conductor, and as shown in FIG. 28 , the shielding shell 13 has a shell oblique insertion port 131. It should be noted that the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 are respectively inserted obliquely into the body oblique insertion space 111 through the shielding shell 13 through the shell oblique insertion port 131, so as to assemble the upper oblique insertion assembly 12 and the lower oblique insertion assembly 14 to the electrical connector body 11.

In addition, it should be explained that, as shown in Figures 8 and 9, when the upper oblique plug assembly body 123 and the lower oblique plug assembly body 143 are respectively assembled on the electrical connector body 11, the shielding shell 13 extends above the upper oblique plug conductive terminal group 121 and the lower oblique plug conductive terminal group 141, so that the shielding shell 13 provides shielding for the upper oblique plug conductive terminal group 121 and the lower oblique plug conductive terminal group 141, thereby reducing the degree of interference (the external interference is, for example, EMI electromagnetic interference or noise interference) in the signal transmission of the upper oblique plug conductive terminal group 121 and the lower oblique plug conductive terminal group 141, so as to meet the signal transmission requirements of the electrical connector. When the upper oblique plug assembly body 123 and the lower oblique plug assembly body 143 are respectively assembled on the electrical connector body 11, the shielding shell 13 also extends to the sides of the upper oblique plug conductive terminal set 121 and the lower oblique plug conductive terminal set 141, so that the shielding shell 13 provides shielding for the sides of the upper oblique plug conductive terminal set 121 and the lower oblique plug conductive terminal set 141, and reduces the degree of interference (such external interference is EMI electromagnetic interference or noise interference) of the signal transmission of the upper oblique plug conductive terminal set 121 and the lower oblique plug conductive terminal set 141, so as to meet the signal transmission requirements of the electrical connector.

In addition, as shown in FIG. 24 , the upper shielding body 122 extends along the side of the upper obliquely inserted conductive terminal set 121, so that the upper shielding body 122 provides shielding for the side of the upper obliquely inserted conductive terminal set 121, thereby reducing the degree of interference (such as external interference such as EMI electromagnetic interference or noise interference) to the signal transmission of the upper obliquely inserted conductive terminal set 121, thereby satisfying the signal transmission requirements of the electrical connector. As shown in FIG. 24 , the lower shielding body 142 extends from the side of the lower obliquely inserted conductive terminal set 141, so that the lower shielding body 142 provides shielding for the side of the lower obliquely inserted conductive terminal set 141, thereby reducing the degree of interference (such as external interference such as EMI electromagnetic interference or noise interference) in the signal transmission of the lower obliquely inserted conductive terminal set 141, so as to meet the signal transmission requirements of the electrical connector.

It should be noted that in the electrical connector of the present application, some of the aforementioned components can be omitted. For example, the electrical connector of the present application includes: an electrical connector body and an upper oblique insertion assembly. The electrical connector body has a body oblique insertion space. The upper oblique insertion assembly has an upper oblique insertion conductive terminal set, an upper shielding body, an upper oblique insertion assembly body, and an upper jumper.

The upper oblique plug conductive terminal set has a plurality of upper cross-connected oblique plug conductive terminals and an upper non-cross-connected oblique plug conductive terminal. The upper cross-connect body extends above the upper oblique plug conductive terminal set, crosses over the upper non-cross-connected oblique plug conductive terminal, and electrically crosses over the plurality of upper cross-connected oblique plug conductive terminals. The upper shielding body extends below the upper oblique plug conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper oblique plug conductive terminal set.

In addition, the upper oblique insertion assembly body provides positioning for the upper oblique insertion conductive terminal set, and the upper oblique insertion assembly body is inserted obliquely into the body oblique insertion space, so that the upper oblique insertion assembly body is assembled on the electrical connector body, and the upper oblique insertion conductive terminal set is inserted obliquely into the body oblique insertion space.

Furthermore, in the upper oblique insertion assembly of the present application, some of the aforementioned components can be omitted. For example, the upper oblique insertion assembly of the present application includes: an upper oblique insertion conductive terminal set, an upper jumper, an upper shielding body, and an upper oblique insertion assembly body.

The upper oblique plug conductive terminal set has a plurality of upper crossover oblique plug conductive terminals and an upper non-crossover oblique plug conductive terminal. The upper crossover body extends above the upper oblique plug conductive terminal set, crosses over the upper non-crossover oblique plug conductive terminal, and electrically crosses over a plurality of upper crossover oblique plug conductive terminals. The upper shielding body extends below the upper oblique plug conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper oblique plug conductive terminal set. The upper oblique plug assembly stand body provides positioning for the upper oblique plug conductive terminal set, and the upper oblique plug assembly stand body is obliquely inserted into the electrical connector body, so that the upper oblique plug assembly stand body is assembled on the electrical connector body, and the upper oblique plug conductive terminal set is obliquely inserted into the electrical connector body.

For the disclosure of the manufacturing method of the electrical connector of this application, please refer to Figures 1 to 31.

The electrical connector manufacturing method of the present application includes the following steps: First, in step 1, as shown in Figures 10 and 11, an electrical connector body 11, an upper oblique insertion assembly 12, a shielding shell 13 and a lower oblique insertion assembly 14 are provided.

It should be noted that, as shown in FIG29, the electrical connector body 11 has a body oblique insertion space 111 and a body oblique insertion guide structure 112. As shown in FIG12 to FIG19, the upper oblique insertion assembly 12 has an upper oblique insertion conductive terminal set 121, an upper shielding body 122, an upper oblique insertion assembly body 123 and an upper jumper 124, wherein the upper oblique insertion assembly body 123 can provide positioning for the upper oblique insertion conductive terminal set 121, the upper shielding body 122 and the upper jumper 124, and the upper oblique insertion conductive terminal set 121 has a plurality of upper jumper oblique insertion conductive terminals 1211 and upper non-jumper oblique insertion conductive terminals 1212. As shown in FIG. 18 , the upper shield 122 extends below the upper obliquely inserted conductive terminal set 121, so that the upper shield 122 provides shielding for the lower part of the upper obliquely inserted conductive terminal set 121, and as shown in FIG. 16 , the upper jumper 124 extends above the upper obliquely inserted conductive terminal set 121, crosses the upper non-jumping obliquely inserted conductive terminal 1212, and electrically jumps a plurality of upper jumper obliquely inserted conductive terminals 1211, thereby forming a circuit for transmitting, for example, a ground signal, to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals.

In addition, as shown in Figures 12 to 19, the lower layer oblique insertion assembly 14 has a lower layer oblique insertion conductive terminal group 141, a lower layer shielding body 142, a lower layer oblique insertion assembly body 143 and a lower layer jumper 144, wherein the lower layer oblique insertion assembly body 143 can provide positioning for the lower layer oblique insertion conductive terminal group 141, the lower layer shielding body 142 and the lower layer jumper 144, and the lower layer oblique insertion conductive terminal group 141 has a plurality of lower layer jumper oblique insertion conductive terminals 1411 and lower layer non-jumper oblique insertion conductive terminals 1412. As shown in FIG. 18 , the lower shielding body 142 extends below the lower obliquely inserted conductive terminal set 141, so that the lower shielding body 142 provides shielding for the lower part of the lower obliquely inserted conductive terminal set 141, and as shown in FIG. 16 , the lower jumper 144 extends above the lower obliquely inserted conductive terminal set 141, crosses over the lower non-jumping obliquely inserted conductive terminal 1412, and electrically jumps over a plurality of lower jumper obliquely inserted conductive terminals 1411, thereby forming a circuit for transmitting, for example, a ground signal, to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals.

As shown in FIG. 20 , the upper shielding body 122 is extended to the side of the upper obliquely inserted conductive terminal set 121 so that the upper shielding body 122 provides shielding for the side of the upper obliquely inserted conductive terminal set 121; and as shown in FIG. 20 , the lower shielding body 142 is extended to the side of the lower obliquely inserted conductive terminal set 141 so that the lower shielding body 142 provides shielding for the side of the lower obliquely inserted conductive terminal set 141.

Furthermore, as shown in FIG8 , when the upper obliquely inserted assembly body 123 and the lower obliquely inserted assembly body 143 are respectively assembled on the electrical connector body 11, the shielding shell 13 extends above the upper obliquely inserted conductive terminal set, so that the shielding shell 13 provides shielding for the upper obliquely inserted conductive terminal set 121 and the lower obliquely inserted conductive terminal set 141. In addition, as shown in FIG8 , the shielding shell 13 can also extend to the sides of the upper obliquely inserted conductive terminal set 121 and the lower obliquely inserted conductive terminal set 141, so that the shielding shell 13 provides shielding for the sides of the upper obliquely inserted conductive terminal set 121 and the lower obliquely inserted conductive terminal set 141.

Next, in step 2, as shown in FIGS. 8 and 9 , the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 are passed through the shielding shell 13 and are respectively inserted obliquely into the body oblique insertion space 111 under the guidance of the body oblique insertion guide structure 112 , so that the upper oblique insertion assembly body 123 and the lower oblique insertion assembly body 143 are assembled on the electrical connector body 11 , and the upper oblique insertion conductive terminal set 121 and the lower oblique insertion conductive terminal set 141 are respectively inserted obliquely into the body oblique insertion space 111 , so that the size of the electrical connector can be reduced, thereby reducing the internal space of the electronic device occupied by the electrical connector, so that the electronic device can continue to develop in the direction of being thinner and smaller. It should be noted that, as shown in FIG. 27 , when the upper obliquely inserted assembly body 123 and the lower obliquely inserted assembly body 143 are respectively assembled on the electrical connector body 11 , the upper shielding body 122 extends above the lower obliquely inserted conductive terminal set 141 , so that the upper shielding body 122 provides shielding for the upper part of the lower obliquely inserted conductive terminal set 141 , and reduces the degree of interference (such as EMI electromagnetic interference or noise interference) in the signal transmission of the lower obliquely inserted conductive terminal set 141 , so as to meet the signal transmission requirements of the electrical connector. .

In addition, when the upper obliquely inserted assembly body 123 and the lower obliquely inserted assembly body 143 are respectively assembled on the electrical connector body 11, as shown in FIG. 23 and FIG. 27, the upper shielding body 122 is electrically overlapped with the lower shielding body 142, thereby reducing the degree of interference to signal transmission (the external interference is, for example, EMI electromagnetic interference or noise interference) to meet the signal transmission requirements of the electrical connector. .

It should be noted that the electrical connector of the present application is manufactured by assembling components. Therefore, after the design of the electrical connector is completed, the structural design of the electrical connector can still be customized by adjusting the assembled components to meet the special needs and development of electronic equipment.

It should be noted that in the manufacturing method of the electrical connector of the present application, some of the aforementioned steps can be omitted. For example, the manufacturing method of the electrical connector of the present application includes the following steps: providing an electrical connector body and an upper oblique plug-in assembly, wherein the upper oblique plug-in assembly has an upper oblique plug-in conductive terminal group, an upper shielding body, an upper oblique plug-in assembly body, and an upper jumper body, wherein the upper oblique plug-in assembly body provides positioning for the upper oblique plug-in conductive terminal group, and the upper oblique plug-in conductive terminal group has a plurality of upper jumper oblique plug-in conductive terminals and upper non-jumper oblique plug-in conductive terminals, and the upper jumper The body extends above the upper oblique plug conductive terminal set, crosses the upper non-bridged oblique plug conductive terminal, and electrically bridges a plurality of upper bridged oblique plug conductive terminals. The upper shielding body extends below the upper oblique plug conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper oblique plug conductive terminal set. The electrical connector body has a body oblique plug space, and the upper oblique plug assembly body is guided by the body oblique plug guide structure to be obliquely inserted into the body oblique plug space, so that the upper oblique plug assembly body is assembled on the electrical connector body, and the upper oblique plug conductive terminal set is obliquely inserted into the body oblique plug space.

For the disclosure of the assembly method of the upper oblique insertion assembly of this application, please refer to Figures 1 to 31.

The upper layer oblique insertion assembly assembly method of the present application includes the following steps: First, in step 1, as shown in Figures 10 and 11, an upper layer oblique insertion conductive terminal set 121, an upper layer shielding body 122, an upper layer oblique insertion assembly body 123 and an upper layer jumper 124 are provided.

It should be noted that, as shown in FIGS. 13 to 18 , the upper oblique insertion assembly body 123 provides positioning for the upper oblique insertion conductive terminal set 121, the upper shielding body 122 and the upper jumper body 124, and the upper oblique insertion conductive terminal set 121 has a plurality of upper jumper oblique insertion conductive terminals 1211 and upper non-jumper oblique insertion conductive terminals 1212. As shown in FIG. 16 , the upper shield 122 extends below the upper obliquely inserted conductive terminal set 121, so that the upper shield 122 provides shielding for the lower part of the upper obliquely inserted conductive terminal set 121, and the upper jumper 124 extends above the upper obliquely inserted conductive terminal set 121, crossing the upper non-jumping obliquely inserted conductive terminal 1212, and electrically jumpering a plurality of upper jumper obliquely inserted conductive terminals 1211, thereby forming a circuit for transmitting, for example, a ground signal, to suppress the crosstalk interference generated by coupling when the electrical connector transmits high-speed signals.

Next, in step 2, the upper oblique insertion assembly body 123 is guided by the body oblique insertion guide structure 112 to be inserted obliquely into the body oblique insertion space 111, so that the upper oblique insertion assembly body 123 is assembled on the electrical connector body 11, and the upper oblique insertion conductive terminal set 121 is inserted obliquely into the body oblique insertion space 111, so that the size of the electrical connector is reduced, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

It should be noted that in the upper layer oblique plug assembly assembly method of the present application, some of the aforementioned steps can be omitted. For example, the upper layer oblique plug assembly assembly method of the present application includes the following steps: providing an upper layer oblique plug conductive terminal group, an upper layer shielding body, an upper layer jumper body and an upper layer oblique plug assembly body, wherein the upper layer oblique plug assembly body provides positioning for the upper layer oblique plug conductive terminal group, and the upper layer oblique plug conductive terminal group has a plurality of upper layer jumper oblique plug conductive terminals and upper layer non-jumper oblique plug conductive terminals, and the upper layer oblique plug conductive terminal group is provided with a plurality of upper layer jumper oblique plug conductive terminals and upper layer non-jumper oblique plug conductive terminals. The upper jumper extends above the upper oblique plug conductive terminal set, crosses over the upper non-jumping oblique plug conductive terminal, and electrically jumps over a plurality of upper jumper oblique plug conductive terminals; the upper shield extends below the upper oblique plug conductive terminal set, so that the upper shield provides shielding for the lower part of the upper oblique plug conductive terminal set; and the upper oblique plug assembly body is tiltedly inserted into the electrical connector body, so that the upper oblique plug assembly body is assembled on the electrical connector body, and the upper oblique plug conductive terminal set is tiltedly inserted into the electrical connector body.

In summary, the present application provides an electrical connector and a manufacturing method thereof, and an upper oblique insertion assembly and an assembly method thereof. The provided electrical connector and upper oblique insertion assembly can provide shielding for the conductive terminal through a shielding body to reduce interference in the signal transmission of the conductive terminal, and achieve electrical connection between the conductive terminals on the upper part of the electrical connector, thereby suppressing the crosstalk interference caused by coupling when transmitting high-speed signals. Therefore, the electrical connector and upper oblique insertion assembly of the present application can meet customized requirements such as the transmission of high-speed signals by the electrical connector. In addition, the components of the electrical connector of the present application are assembled by oblique insertion, which can reduce the height of the electrical connector, thereby reducing the internal space occupied by the electrical connector in the electronic device, so that the electronic device can continue to develop in the direction of being thinner and smaller.

The above embodiments are merely illustrative of the principles and effects of this application, and are not intended to limit this application. Anyone familiar with this technology may modify and change the above embodiments without violating the spirit and scope of this application. Therefore, the scope of protection of this application should be as listed in the scope of the patent application of this application.

1:Electrical connector

11: Electrical connector body

111: The main body is inserted diagonally into the space

112: Main body oblique insertion guiding structure

12: Upper layer oblique insertion assembly

121: Upper layer obliquely inserted conductive terminal set

123: Upper layer oblique insertion assembly body

13: Shielding shell

131: Oblique insertion port of the outer shell

14: Lower layer oblique insertion assembly

141: Lower layer obliquely inserted conductive terminal group

143: Lower layer oblique insertion assembly body

Claims (24)

An upper oblique plug assembly stand is matched with an electrical connector body, and the upper oblique plug assembly stand comprises: an upper oblique plug conductive terminal set, the upper oblique plug conductive terminal set has a plurality of upper layer jumper oblique plug conductive terminals and an upper layer non-jumper oblique plug conductive terminal; an upper layer jumper body, the upper layer jumper body extends above the upper layer oblique plug conductive terminal set, crosses the upper layer non-jumper oblique plug conductive terminals, and electrically jumps the plurality of upper layer jumper oblique plug conductive terminals; an upper layer shielding body, the upper layer shielding body extends below the upper layer oblique plug conductive terminal set, so that the upper layer shielding body provides shielding for the lower part of the upper layer oblique plug conductive terminal set; and An upper oblique insertion assembly body, the upper oblique insertion assembly body provides positioning for the upper oblique insertion conductive terminal set, and the upper oblique insertion assembly body is obliquely inserted into the electrical connector body, so that the upper oblique insertion assembly body is assembled on the electrical connector body, and the upper oblique insertion conductive terminal set is obliquely inserted into the electrical connector body. An electrical connector includes: an electrical connector body, the electrical connector body having a body oblique insertion space; an upper oblique insertion assembly, the upper oblique insertion assembly having an upper oblique insertion conductive terminal set, an upper shielding body, an upper oblique insertion assembly body and an upper jumper, wherein, The upper obliquely inserted conductive terminal set has a plurality of upper-layer cross-connected obliquely inserted conductive terminals and an upper-layer non-cross-connected obliquely inserted conductive terminal. The upper-layer cross-connect body extends above the upper-layer obliquely inserted conductive terminal set, crosses over the upper-layer non-cross-connected obliquely inserted conductive terminal, and electrically crosses over the plurality of upper-layer cross-connected obliquely inserted conductive terminals. The upper-layer shielding body extends below the upper-layer obliquely inserted conductive terminal set, so that the upper-layer shielding body provides shielding for the lower part of the upper-layer obliquely inserted conductive terminal set; and The upper oblique insertion assembly body provides positioning for the upper oblique insertion conductive terminal set, and the upper oblique insertion assembly body is inserted obliquely into the body oblique insertion space, so that the upper oblique insertion assembly body is assembled on the electrical connector body, and the upper oblique insertion conductive terminal set is inserted obliquely into the body oblique insertion space. The electrical connector as described in claim 2, wherein the electrical connector further comprises: a shielding shell, the shielding shell having a shell oblique insertion opening, the upper oblique insertion assembly body is inserted obliquely into the body oblique insertion space through the shielding shell through the shell oblique insertion opening; wherein, when the upper oblique insertion assembly body is assembled on the electrical connector body, the shielding shell extends above the upper oblique insertion conductive terminal set, so that the shielding shell provides shielding for the upper part of the upper oblique insertion conductive terminal set. An electrical connector as described in claim 3, wherein the electrical connector further comprises: a lower oblique plug assembly, wherein the lower oblique plug assembly has a lower oblique plug conductive terminal group, a lower shielding body, a lower oblique plug assembly body and a lower jumper, wherein, the lower oblique plug conductive terminal group has a plurality of lower jumper oblique plug conductive terminals and a lower non-jumper oblique plug conductive terminal, and the lower jumper extends above the lower oblique plug conductive terminal group, crosses over the lower non-jumper oblique plug conductive terminals, and electrically jumps over the plurality of lower jumper oblique plug conductive terminals, and the lower shielding body extends below the lower oblique plug conductive terminal group, so that the lower shielding body provides shielding for the lower part of the lower oblique plug conductive terminal group; and The lower oblique insertion assembly body provides positioning for the lower oblique insertion conductive terminal set, and the lower oblique insertion assembly body is obliquely inserted into the body oblique insertion space, so that the lower oblique insertion assembly body is assembled on the electrical connector body, and the lower oblique insertion conductive terminal set is obliquely inserted into the body oblique insertion space; when the upper oblique insertion assembly body and the lower oblique insertion assembly body are respectively assembled on the electrical connector body, the upper shielding body extends above the lower oblique insertion conductive terminal set, so that the upper shielding body provides shielding for the upper part of the lower oblique insertion conductive terminal set. An electrical connector as described in claim 4, wherein the upper shielding body has an upper shielding body overlapping structure, and the lower shielding body has a lower shielding body overlapping structure. When the upper oblique insertion assembly body and the lower oblique insertion assembly body are respectively assembled on the electrical connector body, the upper shielding body overlapping structure electrically overlaps the lower shielding body overlapping structure, so that the upper shielding body electrically overlaps the lower shielding body. As described in claim 4, the electrical connector body further has a body oblique insertion guide structure, and the body oblique insertion guide structure guides the upper oblique insertion assembly body and the lower oblique insertion assembly body to be obliquely inserted into the body oblique insertion space respectively. An electrical connector as described in claim 6, wherein the main body oblique insertion guide structure has a main body upper layer oblique insertion guide substructure and a main body lower layer oblique insertion guide substructure, the main body upper layer oblique insertion guide substructure is provided to guide the upper layer oblique insertion assembly main body to be obliquely inserted into the main body oblique insertion space at an upper layer oblique angle, and the main body lower layer oblique insertion guide substructure is provided to guide the lower layer oblique insertion assembly main body to be obliquely inserted into the main body oblique insertion space at a lower layer oblique angle, wherein the upper layer oblique angle is the same as the lower layer oblique angle. An electrical connector as described in claim 7, wherein the electrical connector body also has a body oblique insertion stroke limiting structure, and the body oblique insertion stroke limiting structure is used to stop the upper oblique insertion assembly body and the lower oblique insertion assembly body, thereby limiting the insertion stroke of the upper oblique insertion assembly body and the lower oblique insertion assembly body respectively obliquely inserted into the body oblique insertion space. An electrical connector as described in claim 8, wherein the main body oblique insertion stroke limiting structure comprises a main body upper layer oblique insertion stroke limiting substructure and a main body lower layer oblique insertion stroke limiting substructure, wherein the main body upper layer oblique insertion stroke limiting substructure limits the upper layer oblique insertion assembly main body to be obliquely inserted into the main body oblique insertion space with an upper layer insertion stroke, and the main body lower layer oblique insertion stroke limiting substructure limits the lower layer oblique insertion assembly main body to be obliquely inserted into the main body oblique insertion space with a lower layer insertion stroke, wherein the upper layer insertion stroke is the same as the lower layer insertion stroke. An electrical connector as described in claim 9, wherein the upper layer oblique insertion stroke limiting substructure of the main body is adjacent to the upper layer oblique insertion guiding substructure of the main body, the upper layer oblique insertion guiding substructure of the main body is adjacent to the lower layer oblique insertion stroke limiting substructure of the main body, and the lower layer oblique insertion stroke limiting substructure of the main body is adjacent to the lower layer oblique insertion guiding substructure of the main body, so that the upper layer oblique insertion stroke limiting substructure of the main body, the upper layer oblique insertion guiding substructure of the main body, the lower layer oblique insertion stroke limiting substructure of the main body and the lower layer oblique insertion guiding substructure of the main body form a stepped structure. An electrical connector as described in claim 7, wherein the electrical connector body further has a body oblique insertion channel, and the body oblique insertion channel extends at a channel inclination angle to form the body oblique insertion space, wherein the channel inclination angle, the upper layer inclination angle and the lower layer inclination angle are the same. As described in claim 4, the electrical connector body further has a body oblique insertion guide structure, and the body oblique insertion guide structure guides the upper shielding body and the lower shielding body to be obliquely inserted into the body oblique insertion space respectively. An electrical connector as described in claim 12, wherein the main body oblique insertion guide structure has a main body upper layer oblique insertion guide substructure and a main body lower layer oblique insertion guide substructure, the main body upper layer oblique insertion guide substructure is provided to guide the upper layer shielding body to be obliquely inserted into the main body oblique insertion space at an upper layer oblique angle, and the main body lower layer oblique insertion guide substructure is provided to guide the lower layer shielding body to be obliquely inserted into the main body oblique insertion space at a lower layer oblique angle, wherein the upper layer oblique angle is the same as the lower layer oblique angle. An electrical connector as described in claim 4, wherein the upper shielding body, the lower shielding body, the upper jumper and the lower jumper are plastic conductors or metal conductors; the shielding shell is a metal conductor; and the electrical connector body, the upper oblique insertion assembly body and the lower oblique insertion assembly body are insulators. An electrical connector as described in claim 4, wherein the upper jumper has a plurality of upper jumper embedding and positioning structures, each of which embeds and positions one of the plurality of upper jumper obliquely inserted conductive terminals so that the upper jumper is electrically connected to the plurality of upper jumper obliquely inserted conductive terminals; and the lower jumper has a plurality of lower jumper embedding and positioning structures, each of which embeds and positions one of the plurality of lower jumper obliquely inserted conductive terminals so that the lower jumper is electrically connected to the plurality of lower jumper obliquely inserted conductive terminals. An electrical connector as described in claim 4, wherein, when the upper obliquely inserted assembly body and the lower obliquely inserted assembly body are respectively assembled on the electrical connector body, the shielding shell also extends to the sides of the upper obliquely inserted conductive terminal group and the lower obliquely inserted conductive terminal group, so that the shielding shell provides shielding for the sides of the upper obliquely inserted conductive terminal group and the lower obliquely inserted conductive terminal group, respectively. An electrical connector as described in claim 4, wherein the upper shielding body extends along the side of the upper obliquely inserted conductive terminal group so that the upper shielding body provides shielding for the side of the upper obliquely inserted conductive terminal group; and the lower shielding body extends along the side of the lower obliquely inserted conductive terminal group so that the lower shielding body provides shielding for the side of the lower obliquely inserted conductive terminal group. A method for assembling an upper layer oblique insertion assembly is provided in combination with an electrical connector body, and the method for assembling an upper layer oblique insertion assembly comprises: Provide an upper oblique plug conductive terminal set, an upper shielding body, an upper oblique plug set body and an upper jumper body, wherein the upper oblique plug set body provides positioning for the upper oblique plug conductive terminal set, and the upper oblique plug conductive terminal set has a plurality of upper jumper oblique plug conductive terminals and an upper non-jumper oblique plug conductive terminal, the upper jumper body extends above the upper oblique plug conductive terminal set, crosses the upper non-jumper oblique plug conductive terminals, and electrically jumps the plurality of upper jumper oblique plug conductive terminals, the upper shielding body extends below the upper oblique plug conductive terminal set, so that the upper shielding body provides shielding for the lower part of the upper oblique plug conductive terminal set; and The upper layer oblique insertion assembly body is inserted obliquely into the electrical connector body, so that the upper layer oblique insertion assembly body is assembled on the electrical connector body, and the upper layer oblique insertion conductive terminal assembly is inserted obliquely into the electrical connector body. A method for manufacturing an electrical connector includes: providing an electrical connector body and an upper oblique plug-in assembly, wherein the upper oblique plug-in assembly has an upper oblique plug-in conductive terminal group, an upper shielding body, an upper oblique plug-in assembly body and an upper jumper body, wherein the upper oblique plug-in assembly body provides positioning for the upper oblique plug-in conductive terminal group, and the upper oblique plug-in conductive terminal group has a plurality of upper jumper oblique plug conductive terminals and an upper non-jumping oblique plug Conductive terminal, the upper jumper extends above the upper oblique plug conductive terminal group, crosses the upper non-jumping oblique plug conductive terminal, and electrically jumps the plurality of upper jump oblique plug conductive terminals, the upper shield extends below the upper oblique plug conductive terminal group, so that the upper shield provides shielding for the lower part of the upper oblique plug conductive terminal group; the electrical connector body has a body oblique plug space; and the upper oblique plug assembly body is tilted and inserted into the body oblique plug space, so that the upper oblique plug assembly body is assembled on the electrical connector body, and the upper oblique plug conductive terminal group is tilted and inserted into the body oblique plug space. The method for manufacturing an electrical connector as described in claim 19, further comprising: Providing a lower oblique plug assembly, wherein the lower oblique plug assembly has a lower oblique plug conductive terminal group, a lower shielding body, a lower oblique plug assembly body and a lower jumper body, wherein the lower oblique plug assembly body provides positioning for the lower oblique plug conductive terminal group, and the lower oblique plug conductive terminal group has a plurality of lower jumper oblique plug conductive terminals and a lower The non-crossing obliquely inserted conductive terminal, the lower layer jumper extends above the lower layer obliquely inserted conductive terminal group, crosses the lower layer non-crossing obliquely inserted conductive terminal, and electrically crosses the plurality of lower layer jumper obliquely inserted conductive terminals, the lower layer shielding body extends below the lower layer obliquely inserted conductive terminal group, so that the lower layer shielding body provides shielding for the lower layer obliquely inserted conductive terminal group; and The lower oblique insertion assembly body is inserted obliquely into the body oblique insertion space, so that the lower oblique insertion assembly body is assembled on the electrical connector body, and the lower oblique insertion conductive terminal group is inserted obliquely into the body oblique insertion space; wherein, when the upper oblique insertion assembly body and the lower oblique insertion assembly body are respectively assembled on the electrical connector body, the upper shielding body extends above the lower oblique insertion conductive terminal group, so that the upper shielding body provides shielding for the upper part of the lower oblique insertion conductive terminal group. A method for manufacturing an electrical connector as described in claim 20, wherein when the upper obliquely inserted assembly body and the lower obliquely inserted assembly body are respectively assembled on the electrical connector body, the upper shielding body electrically overlaps the lower shielding body. The method for manufacturing an electrical connector as described in claim 20 further includes: extending the upper shielding body to the side of the upper obliquely inserted conductive terminal group so that the upper shielding body provides shielding for the side of the upper obliquely inserted conductive terminal group; and extending the lower shielding body to the side of the lower obliquely inserted conductive terminal group so that the lower shielding body provides shielding for the side of the lower obliquely inserted conductive terminal group. The method for manufacturing an electrical connector as described in claim 20, further comprising: Providing a shielding shell; and Extending the shielding shell above the upper layer obliquely inserted conductive terminal set so that the shielding shell provides shielding for the upper layer obliquely inserted conductive terminal set. The method for manufacturing an electrical connector as described in claim 23 further comprises: Extending the shielding shell to the side of the upper obliquely inserted conductive terminal set so that the shielding shell provides shielding to the side of the upper obliquely inserted conductive terminal set respectively.

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