CN108987979B

CN108987979B - Connector with a locking member

Info

Publication number: CN108987979B
Application number: CN201810716296.5A
Authority: CN
Inventors: 简敏隆; 张明勇; 谢宗勋
Original assignee: Advanced-Connectek (kun-Shan) Ltd
Current assignee: Advanced-Connectek (kun-Shan) Ltd
Priority date: 2013-05-31
Filing date: 2014-04-08
Publication date: 2020-09-15
Anticipated expiration: 2034-04-08
Also published as: CN108987979A; CN104009308A; CN104009308B; CN203813082U; TWM476383U

Abstract

The invention provides a connector, which comprises an insulating body, a plurality of signal terminals, a power terminal and a grounding terminal. The insulating body is provided with a rubber core and a tongue plate, the tongue plate extends outwards from the rubber core, the signal terminals, the power supply terminal and the grounding terminal are fixed on the rubber core and positioned on the tongue plate, and the power supply terminal and the grounding terminal are respectively provided with a flange, so that the widths of the power supply terminal and the grounding terminal are larger than the widths of the signal terminals, the impedance of the power supply terminal and the grounding terminal is reduced, and larger current can pass through.

Description

Connector with a locking member

The patent application of the invention is a divisional application of Chinese invention patent application with the application date of 2014, 4, 8, and the application number of 201410136640.5, and the name of connector.

Technical Field

The present invention relates to a connector, and more particularly, to a connector which increases the width of a terminal to allow a large current to pass therethrough.

Background

In the application of the conventional Universal Serial Bus (USB) connector, in addition to transmitting signals, an electronic device can be charged, and if a rapid charging is desired, the passing current is preferably 3.0 amperes or more and 5.0 amperes or more, in such a case, the number of terminals can be increased so that a larger current can pass through the connector, but the increase of the number of terminals is easy to increase the manufacturing cost, and the increase of the number of terminals also increases the design burden in a limited space.

Disclosure of Invention

The present invention is directed to a connector in which a power supply terminal and a ground terminal have a larger width than a signal terminal, so that a larger current can flow through the power supply terminal and the ground terminal having the larger width.

To achieve the above objective, the present invention provides a connector, which includes an insulative housing, a plurality of signal terminals, a power terminal, and a ground terminal. The insulation body is provided with a rubber core and a tongue plate, and the tongue plate extends outwards from the rubber core. Each signal terminal is provided with a signal terminal body, each signal terminal body is provided with a signal contact part, a signal connecting part and a signal welding part, each signal connecting part is fixed on the rubber core and is connected with the corresponding signal contact part and the corresponding signal welding part, and each signal contact part is positioned on the corresponding tongue plate. The power terminal is arranged adjacent to the signal terminals and is provided with a power terminal body, the power terminal body is provided with a power contact part, a power connecting part and a power welding part, the power connecting part is fixed on the rubber core and is connected with the power contact part and the power welding part, and the power contact part is positioned on the tongue plate. The grounding terminal is arranged adjacent to the equal signal terminals and is provided with a grounding terminal body, the grounding terminal body is provided with a grounding contact part, a grounding connecting part and a grounding welding part, the grounding connecting part is fixed on the rubber core and is connected with the grounding contact part and the grounding welding part, and the grounding contact part is positioned on the tongue plate. The power terminal has a first flange extending outwardly from a power terminal body to make the power terminal wider than the signal terminals, and the ground terminal has a second flange extending outwardly from a ground terminal body to make the ground terminal wider than the signal terminals.

In an embodiment of the invention, the first flange extends from the power connection portion and the power soldering portion in a direction away from the signal terminals, and the second flange extends from the ground connection portion and the power soldering portion in a direction away from the signal terminals.

In one embodiment of the present invention, the power terminal further includes a third flange extending from the power connection portion in a direction approaching the equal signal terminals, and the ground terminal further includes a fourth flange extending from the ground connection portion in a direction approaching the equal signal terminals.

In an embodiment of the present invention, a signal connection portion of the signal terminal closest to the power supply terminal among the signal terminals is formed with a first recess so as to avoid the third flange, and a signal connection portion of the signal terminal closest to the ground terminal among the signal terminals is formed with a second recess so as to avoid the fourth flange.

In an embodiment of the present invention, the first flange extends from the power supply connection portion and the power supply contact portion in a direction approaching the signal terminals, and the second flange extends from the ground connection portion and the power supply contact portion in a direction approaching the signal terminals.

In an embodiment of the present invention, a first concave portion is formed in the signal connection portion and the signal contact portion of the signal terminal closest to the power supply terminal among the signal terminals so as to yield to the first flange, and a second concave portion is formed in the signal connection portion of the signal terminal closest to the ground terminal among the signal terminals so as to yield to the second flange.

In an embodiment of the present invention, the widths of the front ends of the signal contacts, the front ends of the power contacts, and the front ends of the ground contacts are the same.

In an embodiment of the present invention, the signal terminals include at least one pair of differential signal terminals.

In an embodiment of the present invention, the connector is a connector belonging to the usb 2.0 specification.

In an embodiment of the present invention, the connector is a connector belonging to the usb 3.0 specification.

In an embodiment of the present invention, the signal terminals are disposed between the power terminal and the ground terminal.

An embodiment of the present invention further includes a metal housing disposed around the insulating body, the signal terminals, the power terminals, and the ground terminal.

The connector of the invention can allow larger current, for example, more than 5.0 amperes to pass through because of adopting the power supply terminal and the grounding terminal with larger width, and the larger current can pass through the connected electronic device through the connector of the invention, thereby rapidly charging the electronic device.

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

Drawings

Fig. 1 is a perspective view of a connector of the present invention.

Fig. 2 is a perspective view of the connector of the present invention with the metal shell removed.

Fig. 3 is a bottom view of an embodiment of the connector of the present invention with the metal shell removed in construction.

Fig. 4 is a schematic diagram of the arrangement of terminals of the embodiment of fig. 3.

Fig. 5 is a bottom view of another embodiment of the connector of the present invention with the metal shell removed in construction.

Fig. 6 is a schematic diagram of the arrangement of terminals of the embodiment of fig. 5.

Fig. 7 is a bottom view of another embodiment of the connector of the present invention with the metal shell removed in construction.

Fig. 8 is a schematic diagram of the arrangement of terminals of the embodiment of fig. 7.

Description of the symbols:

10: metal shell

12: insulating body

20: rubber core

30: tongue plate

32: groove

40: power supply terminal

41: power terminal body

42: power supply contact

44: power supply connecting part

46: power supply welding part

45: holding part

47: a first flange

48: third flange

49: a first flange

50: grounding terminal

51: grounding terminal body

52: ground contact

54: grounding connection part

55: holding part

56: grounding welding part

57: second flange

58: fourth flange

60: signal terminal

61: signal terminal body

62: signal contact part

64: signal connecting part

65: holding part

66: signal welding part

68: first concave part

68': second concave part

100: a connector is provided.

Detailed Description

Referring to fig. 1 and 2, a connector 100 according to an embodiment of the invention is shown. The connector 100 of the present invention includes a metal housing 10, an insulating body 12, and five

terminals

40, 50, 60. The metal shell 10 covers the exterior of the insulating body 12 and the

terminals

40, 50, 60, so as to protect the insulating body 12 and the

terminals

40, 50, 60 and to exert the electromagnetic shielding effect. The insulating body 12 includes a core 20 and a tongue plate 30, the tongue plate 30 extends outward from the core 20, and the

terminals

40, 50, 60 are disposed on the core 20 and the tongue plate 30.

Referring to fig. 3 and 4, an embodiment of the connector 100 of the present invention is shown. The connector of the present embodiment belongs to a Universal Serial Bus (USB) 2.0 standard connector, and more precisely, the connector of the present embodiment is a mini USB interface connector, which has a total of five terminals including a power terminal 40, a ground terminal 50 and three signal terminals 60, and among the three signal terminals 60, a pair of differential signaling terminals may be included. The power terminal 40, the ground terminal 50, and the signal terminal 60 are coupled to the insulating body 12 by insert molding (insert molding), and the power terminal 40 and the ground terminal 50 are arranged on both sides of the signal terminal 60. The power terminal 40 has a power terminal body 41, the power terminal body 41 has a power contact portion 42, a power connection portion 44 and a power soldering portion 46, the power connection portion 44 is connected to the power contact portion 42 and the power soldering portion 46, the power connection portion 44 is fixed in the rubber core 20 of the insulating body 12 and is reinforced and fixed in the rubber core 20 by the protruding fixing portion 45, the power contact portion 42 is positioned in the groove 32 of the tongue plate 30, the power terminal 40 further has a first flange 47, and the first flange 47 extends from the side edges of the power connection portion 44 and the power soldering portion 46 of the power terminal body 41 to a direction (towards the x-axis direction of fig. 4) away from the signal terminal 60. Further, the total width of the power supply connecting portion 44 and the first flange 47 is larger than the width of the power supply contact portion 42. Similarly, the ground terminal 50 has a ground terminal body 51, the ground terminal body 51 has a ground contact portion 52, a ground connection portion 54 and a ground soldering portion 56, the ground connection portion 54 connects the ground contact portion 52 and the ground soldering portion 56, the ground connection portion 54 is fixed in the rubber core 20 of the insulating body 12 and is reinforced and fixed in the rubber core 20 by the clamping force provided by the protruded holding portion 55, the ground contact portion 52 is located in the groove 32 of the tongue plate 30, the ground terminal 50 further has a second flange 57, and the second flange 57 extends from the side edges of the ground connection portion 54 and the ground soldering portion 56 of the ground terminal body 51 in a direction away from the signal terminal 60 (in a direction opposite to the x-axis of fig. 4). The total width of the ground connection portion 54 and the second flange 57 is larger than the width of the ground contact portion 52. In addition, each signal terminal 60 has a signal contact portion 62, a signal connection portion 64 and a signal soldering portion 66, the signal connection portion 64 connects the signal contact portion 62 and the signal soldering portion 66, the signal connection portion 64 is fixed in the rubber core 20 of the insulating body 12 and is enhanced and fixed in the rubber core 20 by the engagement force provided by the protruded holding portion 65, and the signal contact portion 62 is positioned in the groove 32 of the tongue plate 30.

In the above-mentioned structure, the widths of the power connection portion 44 and the power soldering portion 46 of the power terminal 40 and the first flange 47 are greater than the widths of the signal connection portion 64 and the signal soldering portion 66 of the signal terminal 60, and similarly, the widths of the ground connection portion 54 and the ground soldering portion 56 of the ground terminal 50 and the second flange 57 are greater than the widths of the signal connection portion 64 and the signal soldering portion 66 of the signal terminal 60, so that the impedance of the power terminal 40 and the ground terminal 50 becomes lower due to the increased widths of the power terminal 40 and the ground terminal 50, and a larger current can be allowed to pass through, and thus the connector of the present invention can be applied to quick charging.

Referring to fig. 5 and 6, another embodiment of the connector 100 of the present invention is shown. The connector of the present embodiment is also a mini USB interface connector, which has a total of five terminals, including a power terminal 40, a ground terminal 50 and three signal terminals 60, wherein the power terminal 40, the ground terminal 50 and the signal terminals 60 are combined with the insulating body 12 by insert molding (insert molding), and the power terminal 40 and the ground terminal 50 are arranged on two sides of the signal terminals 60 respectively. The power terminal 40 has a power terminal body 41, the power terminal body 41 has a power contact portion 42, a power connection portion 44 and a power soldering portion 46, the power connection portion 44 is connected to the power contact portion 42 and the power soldering portion 46, the power connection portion 44 is fixed in the rubber core 20 of the insulating body 12 and is enhanced and fixed in the rubber core 20 by the engagement force provided by the protruded holding portion 45, the power contact portion 42 is positioned in the groove 32 of the tongue plate 30, as in the embodiment of fig. 3 and 4, the power terminal 40 further has a first flange 47, the first flange 47 extends from the side of the power connection portion 44 and the power soldering portion 46 of the power terminal body 41 in a direction away from the signal terminal 60 (in the direction of the x-axis of fig. 6), in the present embodiment, the power terminal 40 further includes a third flange 48, and the third flange 48 extends from the side edges of the power contact portion 42 and the power connection portion 44 toward the signal terminal 60 (toward the direction opposite to the x-axis in fig. 6). Similarly, the ground terminal 50 has a ground terminal body 51, the ground terminal body 51 has a ground contact portion 52, a ground connection portion 54 and a ground soldering portion 56, the ground connection portion 54 is connected with the ground contact portion 52 and the ground soldering portion 56, the ground connection portion 54 is fixed in the rubber core 20 of the insulating body 12 and is enhanced and fixed in the rubber core 20 by the engagement force provided by the protruded holding portion 55, the ground contact portion 52 is located in the groove 32 of the tongue plate 30, the ground terminal 50 further has a second flange 57, the second flange 57 extends from the side edges of the ground connection portion 54 and the ground soldering portion 56 of the ground terminal body 51 in the direction away from the signal terminal 60 (in the direction opposite to the x-axis of fig. 6, i.e. toward the outside of the connector 100) as in the embodiment, the ground terminal 50 further has a fourth flange 58, and the fourth flange 58 extends from the side edges of the ground contact portion 52 and the ground connection portion 54 in the direction toward the signal terminal 60 (in the direction toward the signal terminal 60 of fig The direction of the x-axis, i.e., toward the interior of the connector 100). In addition, each signal terminal 60 has a signal contact portion 62, a signal connection portion 64 and a signal soldering portion 66, the signal connection portion 64 connects the signal contact portion 62 and the signal soldering portion 66, the signal connection portion 64 is fixed in the rubber core 20 of the insulating body 12 and is enhanced and fixed in the rubber core 20 by the engagement force provided by the protruded holding portion 65, and the signal contact portion 62 is positioned in the groove 32 of the tongue plate 30.

In the above-described configuration, since the power terminal 40 has the third flange 48 extending toward the signal terminal 60, the first recess 68 is formed in the signal contact portion 62 and the signal connection portion 64 of the signal terminal 60 adjacent to the power terminal 40 so as to give way to the third flange 48, and similarly, since the ground terminal 50 has the fourth flange 58 extending toward the signal terminal 60, the second recess 68' is formed in the signal connection portion 64 of the signal terminal 60 adjacent to the ground terminal 50 so as to give way to the fourth flange 58. In addition, since the width of the power terminal 40 together with the first and

third flanges

47 and 48 is larger than the width of the signal terminal 60, and similarly, the width of the ground terminal 50 together with the second and

fourth flanges

57 and 58 is larger than the width of the signal terminal 60, the impedance of the power terminal 40 and the ground terminal 50 becomes lower due to the increase in the width of the power terminal 40 and the ground terminal 50, and a larger current can be allowed to pass through, so that the connector of the present invention can be applied to quick charging.

Although the third flange 48 extends from the side of the power connection portion 44 toward the signal terminal 60 (in the direction opposite to the x-axis in fig. 6), the third flange 48 may extend from the side of the power connection portion 44 toward the signal terminal 60 (in the direction opposite to the x-axis in fig. 6) (not shown). Correspondingly, a first recess 68 is formed in the signal connection portion 64 of the signal terminal 60 adjacent to the power terminal 40 to give way to the third flange 48 (not shown). Similarly, in the present embodiment, the fourth flange 58 extends from the side edge of the ground contact portion 52 and the ground connection portion 54 toward the signal terminal 60 (toward the x-axis direction in fig. 6, i.e., toward the inside of the connector 100), but the fourth flange 58 may extend only from the side edge of the ground connection portion 54 toward the signal terminal 60 (toward the x-axis direction in fig. 6, i.e., toward the inside of the connector 100) (not shown). A second recess 68' is correspondingly formed in the signal connecting portion 64 of the signal terminal 60 adjacent to the ground terminal 50 to give way to the fourth flange 58 (not shown).

Referring to fig. 7 and 8, another embodiment of the connector 100 of the present invention is shown. The connector of the present embodiment is also a mini USB interface connector, which has a total of five terminals, including a power terminal 40, a ground terminal 50 and three signal terminals 60, wherein the power terminal 40, the ground terminal 50 and the signal terminals 60 are combined with the insulating body 12 by insert molding (insert molding), and the power terminal 40 and the ground terminal 50 are arranged on two sides of the signal terminals 60 respectively. The power terminal 40 has a power terminal body 41, the power terminal body 41 has a power contact portion 42, a power connection portion 44 and a power soldering portion 46, the power connection portion 44 connects the power contact portion 42 and the power soldering portion 46, the power connection portion 44 is fixed in the rubber core 20 of the insulating body 12 and is reinforced and fixed in the rubber core 20 by the protruding holding portion 45, the power contact portion 42 is positioned in the groove 32 of the tongue plate 30, the power terminal 40 further has a first flange 49, and the first flange 49 extends from the side edges of the power contact portion 42 and the power connection portion 44 of the power terminal body 41 toward the direction approaching the signal terminal 60 (toward the direction opposite to the x-axis of fig. 8). Similarly, the ground terminal 50 has a ground terminal body 51, the ground terminal body 51 has a ground contact portion 52, a ground connection portion 54 and a ground soldering portion 56, the ground connection portion 54 connects the ground contact portion 52 and the ground soldering portion 56, the ground connection portion 54 is fixed in the rubber core 20 of the insulating body 12 and is reinforced and fixed in the rubber core 20 by the clamping force provided by the protruded holding portion 55, the ground contact portion 52 is positioned in the groove 32 of the tongue plate 30, the ground terminal 50 further has a second flange 59, and the second flange 59 extends from the side edges of the ground contact portion 52 and the ground connection portion 54 of the ground terminal body 51 toward the signal terminal 60 (toward the x-axis direction of fig. 8). In addition, each signal terminal 60 has a signal contact portion 62, a signal connection portion 64 and a signal soldering portion 66, the signal connection portion 64 connects the signal contact portion 62 and the signal soldering portion 66, the signal connection portion 64 is fixed in the rubber core 20 of the insulating body 12 and is enhanced and fixed in the rubber core 20 by the engagement force provided by the protruded holding portion 65, and the signal contact portion 62 is positioned in the groove 32 of the tongue plate 30. In the above-described configuration, since the power terminal 40 has the first flange 49 extending toward the signal terminal 60, the first recess 68 is formed in the signal contact portion 62 and the signal connection portion 64 of the signal terminal 60 adjacent to the power terminal 40 so as to give way to the first flange 49, and similarly, since the ground terminal 50 has the second flange 59 extending toward the signal terminal 60, the second recess 68' is formed in the signal connection portion 64 of the signal terminal 60 adjacent to the ground terminal 50 so as to give way to the second flange 59. In addition, since the width of the power terminal 40 and the first flange 49 is greater than the width of the signal terminal 60, similarly, the width of the ground terminal 50 and the second flange 59 is greater than the width of the signal terminal 60, the total width of the power terminal body 41 and the first flange 49 is greater than the width of the power contact portion 42, and the total width of the ground terminal body 51 and the second flange 59 is greater than the width of the ground contact portion 52, the impedance of the power terminal 40 and the ground terminal 50 is lowered due to the increased width of the power terminal 40 and the ground terminal 50, and a larger current can be allowed to pass through, the connector of the present invention can be applied to quick charging.

Although the mini USB interface conforming to the USB 2.0 specification is taken as an example for the above embodiment, the invention is not limited thereto, and a connector conforming to the USB 2.0 specification, a connector conforming to the micro USB interface of the USB 2.0 specification, a connector conforming to the USB 3.0 specification, or a connector conforming to other interfaces may be applied. In the embodiments of the present invention, the power terminal, the ground terminal, and the signal terminal are coupled to the insulating body by insert molding (insert molding), but the present technical feature is not limited to , and the power terminal, the ground terminal, and the signal terminal may be coupled to the insulating body by assembly.

The power terminal 40 and the ground terminal 50 of the connector of the present invention are designed to have a larger width than the signal terminal, so that the impedance of the power terminal 40 and the ground terminal 50 becomes low, and a larger current can be allowed to pass, for example, 5.0 amperes so that the connector of the present invention can be applied to quick charging.

Although the present invention has been described with reference to the preferred embodiments, it should be understood that various changes and modifications can be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims

1. A connector, characterized by: the connector includes:

the insulating body is provided with a rubber core and a tongue plate, and the tongue plate extends outwards from the rubber core;

each signal terminal is provided with a signal terminal body, each signal terminal body is provided with a signal contact part, a signal connecting part and a signal welding part, each signal connecting part is fixed on the rubber core and is connected with the corresponding signal contact part and the corresponding signal welding part, and each signal contact part is positioned on the corresponding tongue plate;

a power terminal disposed adjacent to the plurality of signal terminals and having a power terminal body, the power terminal body having a power contact portion, a power connection portion and a power soldering portion, the power connection portion being fixed to the rubber core and connecting the power contact portion and the power soldering portion, the power contact portion being positioned on the tongue plate, wherein the power terminal has a first flange extending from the power connection portion in a direction approaching the plurality of signal terminals, a total width of the power terminal body and the first flange being greater than a width of each of the signal terminal bodies, a width of the power soldering portion of the power terminal body being greater than a width of the signal soldering portion of each of the signal terminal bodies, the total width of the power connection portion and the first flange being greater than the width of the power contact portion, the signal connecting part of the signal terminal which is closest to the power supply terminal forms a first concave part so as to give way to the first flange; and

a ground terminal disposed adjacent to the signal terminals and having a ground terminal body, the ground terminal body having a ground contact portion, a ground connection portion and a ground soldering portion, the ground connection portion being disposed on the rubber core and connecting the ground contact portion and the ground soldering portion, the ground contact portion being positioned on the tongue plate, the ground terminal further having a second flange extending from the ground connection portion in a direction approaching the signal terminals, the ground terminal body and the second flange having a total width greater than a width of each of the signal terminal bodies, the ground soldering portion of the ground terminal body having a width greater than a width of the signal soldering portion of each of the signal terminal bodies, the total width of the ground connection portion and the second flange being greater than a width of the ground contact portion, and a signal connection portion of the signal terminal closest to the ground terminal among the plurality of signal terminals forms a second recess so as to give way to the second flange, and the plurality of signal terminals are disposed between the power supply terminal and the ground terminal.

2. The connector of claim 1, wherein: the power terminal further includes a third flange extending from the power connection portion in a direction away from the plurality of signal terminals, a total width of the power terminal body and the third flange is greater than a width of each of the signal terminal bodies, and the total width of the power connection portion and the third flange is greater than a width of the power contact portion.

3. The connector of claim 2, wherein: the ground terminal further includes a fourth flange extending from the ground connection portion in a direction away from the signal terminals, wherein a total width of the ground terminal body and the fourth flange is greater than a width of each of the signal terminal bodies, a width of the ground soldering portion of the ground terminal body is greater than a width of the soldering portion of each of the signal terminal bodies, and a total width of the ground connection portion and the fourth flange is greater than a width of the ground contact portion.

4. The connector according to any one of claims 1 to 3, wherein: the widths of the front ends of the plurality of signal contacts, the front ends of the power contacts, and the front ends of the ground contacts are the same.

5. The connector of claim 1, wherein: the metal shell is arranged around the insulating body, the plurality of signal terminals, the power terminals and the grounding terminal.