KR102081390B1 - Receptacle connector - Google Patents

Abstract

The present invention relates to a receptacle connector that improves the structure of a shield contact to prevent malfunction or burnout of a contact terminal. The receptacle connector of the present invention includes an insulating block in which insulating resin is injection molded; A pair of shield contacts including an insert portion inserted into the insulating block and a support portion protruding out of the insulating block, the shield contacts being coupled to the insulating block at both sides of the insulating block; A first contact composed of a plurality of contact terminal arrays and coupled to a bottom surface of the insulating block; A second contact composed of a plurality of contact terminal arrays and coupled to an upper surface of the insulating block; And a housing that is injection molded to surround the assembly in which the insulating block, the shield contact, the first contact, and the second contact are coupled to each other.

Description

Receptacle connector

The present invention relates to a receptacle connector installed in an electronic device in order to connect a USB type plug connector, and more particularly, to a receptacle connector which improves the structure of a shield contact and prevents malfunction or burnout of a contact terminal.

In general, a connector includes a plug connector and a receptacle connector. The receptacle connector is mounted on a printed circuit board (PCB) and fastened to the plug connector. The receptacle connector includes a plurality of contact terminals, and the contact terminals satisfy, for example, a pin specification of a universal serial bus (USB). Is arranged in the form of.

1 is a front view showing a main configuration of a receptacle connector according to the related art, FIG. 2 is a plan view showing a shield contact as a main part of FIG. 1, and FIG. 3 is an enlarged view showing the main part of FIG. 1 in detail.

As shown in these figures, the conventional receptacle connector has a first contact 10 and a second contact 20, a first contact, and a second contact disposed when they are symmetrical with each other on both surfaces via an insulating member 30. The metal shell 50 coupled to surround the insulating member while securing a space 51 into which a shield contact 40 and a plug connector (not shown) are inserted between the contacts, are inserted. Include.

The first contact 10 and the second contact 20 constitute an array in which a plurality of contact terminals are arranged at predetermined intervals, and the contact terminals of the first and second contacts 10 and 20 do not interfere with each other. It is disposed so as to be spaced apart through the insulating member 30. In addition, the contact terminals of the first contact 10 and the second contact 20 are arranged to be symmetrical with each other in the left and right and up and down directions so that the plug connector can be connected regardless of the direction.

The shield contact 40 is integrally formed with the insulating member 30 by insert injection to support the insulating member 30 and to ground the receptacle connector. The shield contact 40 may include the ground terminals 11 and 21 ′ and the transmission terminal 12, among the contact terminals of the first contact 10 and the second contact 20, at both sides of the insulating member 30. 22 ').

In the receptacle connector having the above-described configuration, the shield contact 40 has an insulation hole 41 for insulation between other terminals including power terminals 13 and 23 ', which are the central regions of the insulation member 30. Form. The insulation hole 41 secures an insulation distance D1 between the shield contact 40 and the power supply terminals 13 and 23 ', and the insulation distance D1 is formed to be about 0.5 mm so that the shield contact 40 is formed. Reduces the risk of a short between the power supply terminals 13 and 23 ', and eventually prevents the risk of fire or damage to the electronic device due to the short.

However, in the conventional receptacle connector, since the inner end of the shield contact 40 protrudes to the transmission terminals 12 and 22 ', deformation such as pushing or bending due to the injection pressure of the resin for forming the insulating member 30 in the insert injection process. This can easily occur. Therefore, the receptacle connector fixes the shield contact 40 using the support core 60 to form the insulation member 30 by insert injection, and supports the insulation member 30 after the support core 60 is separated. The core hole 61 by the core 60 is shown.

Meanwhile, as shown in FIG. 3, when the receptacle connector is placed in a humid environment, fine moisture particles h are adsorbed along the surface of the insulation member 30, and the moisture particles h are insulated from the insulation member 30. Distribution along the surface and the surface of the core hole 61 electrically shorts the transmission terminals 12 and 22 'and the shield contact 40, which may result in malfunction or damage of the receptacle connector.

In addition, in the conventional receptacle connector, an insulating hole 41 is formed between a plurality of contact terminals in the central region of the insulating member 30. At this time, the moisture particles flowing along the core hole 61 may flow into the insulating hole 41 along the bonding surface (interface) of the shield contact 40 and the insulating member 30, and the insulating hole 41. Moisture particles (h) introduced into the inside easily short-circuit the shield contact 40 and the power terminals 13 and 23 ', resulting in an insulation distance between the shield contact 40 and the power terminals 13 and 23'. There is a disadvantage that D1) becomes meaningless.

Korea Patent Publication 10-2017-0030186 (published Mar. 17, 2017, Shield Contact & Receptacle Connector for Receptacle Connector) Korea Patent Publication 10-2016-0101520 (published Aug. 25, 2016, Receptacle Connector)

The present invention has been proposed to solve the above problems, and in the insert injection process for manufacturing the shield contact and the insulating member integrally, the core hole is not generated by minimizing the region corresponding to the middle region of the shield contact. It is an object of the present invention to provide a receptacle connector which can prevent moisture particles from penetrating into the insulating member and prevent damage of the electrical short and the connector caused by the moisture particles.

It is also an object of the present invention to provide a receptacle connector capable of stably protecting contact terminals from electrical short by further extending the insulation distance between the shield contact and the contact terminals.

In addition, an object of the present invention is to provide a receptacle connector that can effectively prevent a short between each contact terminal by filling an insulating resin between the first contact and the second contact.

The receptacle connector of the present invention for achieving the above object comprises an insulating block in which an insulating resin is injection molded, an insert portion inserted into the insulating block and a support portion protruding to the insulating block side and the amount of the insulating block A shield contact coupled to the insulation block at a side, a first contact including a plurality of contact terminal arrays and coupled to a bottom surface of the insulation block, a second contact including a plurality of contact terminal arrays and coupled to an upper surface of the insulation block, and And a housing that is injection molded while surrounding the assembly in which the insulating block, the shield contact, the first contact, and the second contact are coupled, wherein the insert part includes contact terminals of the first contact and the second contact. Coupled to the insulation block so as to overlap only the outermost contact terminal, the insulation block being shielded The core and the first contact as an insert are formed integrally by primary injection, and the housing is formed by the secondary injection with the insulating block formed integrally with the second contact as an insert, It is not formed so that moisture particles through the core hole are prevented from penetrating into the insulating member.

In addition, the receptacle connector may be configured to insulate the first contact from the second contact by filling a resin of the insulating block between the contact terminals inside the first contact and the contact terminals inside the second contact. It features.

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In addition, the insulating block may form a plurality of assembling grooves into which contact terminals are inserted on an upper surface thereof, and the second contact may include a plurality of contact terminals inserted into and coupled to the assembling grooves.

In addition, the assembling groove, a plurality of assembling protrusions having a hook shape is formed on the insulating block upper surface, characterized in that formed between the pair of the assembling projections facing each other.

In addition, the shield contact is characterized in that the front end portion includes a reinforcing portion extending in the width direction.

In addition, the shield contact is characterized in that it comprises a groove portion to avoid the overlap of the insert portion and the outermost contact terminal of the first contact is recessed inside the tip portion of the insert portion.

In addition, the shield contact may be configured as a separate type coupled to both sides of the insulating block, or may be configured as an integral type in which the front end portion is connected by a connection part.

In the receptacle connector of the present invention, core holes are not generated in the insulating block during insert injection of the shield contact, the insulating block, and the contact. Insulation breakdown can be prevented.

In addition, the receptacle connector of the present invention further increases the insulation distance between the shield contact and the contact terminals, thereby stably protecting the contact terminals from the electrical short.

1 is a front view showing the main configuration of a receptacle connector according to the prior art,
2 is a plan view showing a shield contact which is a main part of FIG.
3 is an enlarged view showing the main part of FIG. 1 in detail;
4 is an exploded perspective view showing a receptacle connector according to an embodiment of the present invention;
FIG. 5 is a cross-sectional view illustrating the receptacle connector of FIG. 4; FIG.
6 is an enlarged view showing in detail the main part of FIG.
7 is a plan view showing a shield contact which is a main part of FIG.
8a to 8d is a process diagram showing the main drawing of the manufacturing process of the receptacle connector according to the embodiment of the present invention;
9 is a process chart showing the assembly process of the second contact according to an embodiment of the present invention,
10 is a plan view showing a shield contact according to another embodiment of the present invention.

The technical problem achieved by the present invention and the practice of the present invention will be apparent from the preferred embodiments described below. In the description of the present invention, expressions such as first, second, before, after, up and down indicate relative order or position relative to each other, and the constitution of the invention is not necessarily limited to the names. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is an exploded perspective view illustrating a receptacle connector according to an exemplary embodiment of the present invention, FIG. 5 is a cross-sectional view illustrating a receptacle connector of FIG. 4, FIG. 6 is an enlarged view showing the main part of FIG. 5 in detail, and FIG. 4 is a plan view showing a shield contact, which is a main part of FIG.

As shown in the drawing, the receptacle connector of the present invention includes a pair of shield contacts 100, an insulating block 200 integrally formed with the shield contact 100, and a contact 300 coupled to the insulating block 200. And a housing 400 for integrating the shield contact 100, the insulating block 200, and the contact 300, and a metal shell 500 coupled to the housing 400.

Specifically, the shield contact 100 is a conductive plate made of a metal material to reinforce the rigidity of the insulating block 200, and to ground the substrate to remove the EMI or noise that may be generated during the connection with the plug connector and the contact terminal. Function to protect. In particular, the present invention minimizes the width inserted into the insulating block 200 and the region overlapping the contact 300 to prevent damage or malfunction of the receptacle connector. The shield contact 100 is composed of a plate having a predetermined width in the horizontal direction (x direction) and a predetermined length in the front-rear direction (y direction), and the insulating block 200 on both sides of the insulating block 200. Are integrally combined.

The shield contact 100 may include an insert part 110 on the inside and a support part 120 on the outside with respect to the width direction (x direction). The insert part 110 is inserted into and coupled to the insulating block 200 when inserting the insert, and the support 120 is exposed to the outside of the insulating block 200 and fixed to the support core 600 when inserting the insert.

The insert part 110 forms the minimum width that the insert injection can be made with the insulating block 200. In the present invention, as shown in Figs. 6 and 7, the insert part 110 is connected to the ground terminal of the contact 300. 311,321 '). That is, the insert portion 110 of the shield contact 100 intervenes only between the ground terminals 311 and 321 ′, which are outermost contact terminals of the first contact 310 and the second contact 320, and the first terminal, which is the second terminal. There is no interference between the transmission terminals 312 and 322 '. Accordingly, the shield contact 100 may minimize the influence of the injection pressure in the insert injection process, and the insulation distance D2 from the power supply terminals 313 and 323 'may be increased to about 1.25 mm to effectively prevent electrical short. . The support part 120 is formed to protrude or extend outward from the insert part 110 and may protrude in the form of a plurality of protrusions or extend in the form of one rib.

In addition, referring to FIG. 7, the shield contact 100 forms a reinforcement part 130 in which the tip portion protrudes in the width direction (x direction or −x direction). The reinforcement part 130 extends in an inner direction in which tip ends of the pair of shield contacts 100 face each other. The reinforcement part 130 of the metal material is molded into the housing 400 in the insert injection process, and reinforces the rigidity of the housing 400 which is first contacted with the plug connector when the plug connector is connected.

In addition, the shield contact 100 forms a groove 140 recessed inward between the insert 110 and the reinforcement 130. The groove portion 140 is formed by recessing a portion of the tip portion of the insert portion 110 inwardly, and as shown in FIG. 7, the tip portion of the shield contact 100 is inserted into the insert portion 110, the support portion 120, and the reinforcement. The unit 130 is connected in a 'c' shape. The groove part 140 may avoid the insert part 110 so that the contact terminals of the first contact 310 overlapping the insert part 110, that is, the ground terminals 311 and 311 ′ do not overlap the insert part 110. In the process of injecting the insulating block 200, the support core 600 may support the ground terminals 311 and 311 ′ from above and below.

The insulating block 200 is configured to fix their positions while electrically separating the shield contact 100 and the contact 300. The insulating block 200 may be formed by injection molding using a resin of a non-conductive material, and may be formed by an insert injection process using the shield contact 100 and the first contact 310 made of metal as insert objects. It is formed integrally with. That is, the insert block 110 of the shield contact 100 is inserted into both sides of the insulating block 200, and a plurality of contact terminals constituting the first contact 310 are coupled to the lower surface of the insulating block 200.

The contact 300 is a plurality of contact terminals having functions such as signal transmission, power supply, ground, and the like, and is formed on the upper surface of the first contact 310 and the insulating block 200 coupled to the lower surface of the insulating block 200. The second contact 320 is coupled. The first contact 310 is integrally coupled to the insulating block 200 by an insert injection process, and the second contact 320 is coupled to the insulating block 200 by an assembly process, and then the insulating block ( 200 and integrally formed with the housing 400. The first contact 310 and the second contact 320 constitute an array in which a plurality of contact terminals are arranged at predetermined intervals, and the contact terminal array of the first contact 310 and the contact terminals of the second contact 320 are provided. The array is symmetrical with each other in the left and right directions.

For example, the first contact 310 and the second contact 320 may be configured as an array of contact terminals having a 12-pin structure, and the first contact 310 having the 12-pin structure has a first ground for grounding from one side. Terminal 311, two first transmission terminals 312 for high-speed signal transmission, the first power terminal 313 for power supply, the first recognition terminal 314 for plug connector recognition, the first for data transmission 1,2 data terminal 315, first auxiliary terminal 314 ', second power terminal 313' for power supply, two second transmission terminals 312 'for high speed signal transmission, grounding The second power terminals 311 ′ may be arranged in order, and the contact terminals of the second contacts 320 may be arranged in the reverse order of the contact terminals constituting the first contact 310.

In addition, each of the contact terminals of the first contact 310 and the second contact 320 is exposed to the outside of the insulating block 200 to be soldered to the substrate.

The housing 400 fixes the coupling of the shield contact 100, the insulating block 200, the first contact 310, and the second contact 320, and forms an inner body of the receptacle connector. The housing 400 is integrally formed with an insert injection process using, as insert water, an assembly in which the shield contact 100, the insulating block 200, the first contact 310, and the second contact 320 are combined. The soldering parts of the first contact 310 and the second contact 320 are exposed to the rear of the housing 400, and the contact surface 310 ′ of the first contact 310 is exposed to the bottom surface of the housing 400. The contact surface 320 ′ of the second contact 320 is exposed on the upper surface.

In addition, the housing 400 is configured to expose the contact surface 310 ′, 320 ′ of the first contact 310 and the second contact 320 to the front end portion to form a connection 410 in which electrical connection is made with the plug connector. Then, the coupling portion 420 is coupled to the metal shell at the rear end.

The metal shell 500 is coupled to the housing 400 to block shock or noise to protect the shield contact 100, the insulating block 200, the first contact 310, and the second contact 320. . The metal shell 500 is composed of an insertion part 510 having a front opening and a rear fastening part 520 fastened to the housing 400. The insertion part 510 secures a plug insertion space 530 into which a plug connector is inserted between the connection parts 410 of the housing 400, and the fastening part 520 is a coupling part 420 of the housing 400. And fastening protrusions for fastening to the other side. The metal shell 500 accommodates the shield contact 100, the first contact 310, and the second contact 320 made of a metal material coupled to the housing 400 in the plug insertion space 530 to be physically connected from the outside. Protect them from shock and electrical noise.

The receptacle connector having the above configuration does not show a core hole in the process of insert injection of the shield contact 100, the insulating block 200, and the first contact 310, and the first contact 310 and the second contact 320. Insulation resin is filled between each contact terminal of the C) to block moisture inflow. In addition, the receptacle connector may increase the insulation distance between the shield contact 100 and the power terminals 313 and 323 'of the contact 300, thereby ensuring stable insulation therebetween.

8A to 8D are process diagrams showing main views of a manufacturing process of a receptacle connector according to an embodiment of the present invention.

First, as shown in FIG. 8A, a pair of shield contacts 100 and a plurality of contact terminals constituting the first contact 310 are prepared, and the insulating block 200 is formed by an injection process using the insert water. In this case, the shield contact 100 overlaps only the ground terminal 311, which is the outermost contact terminal of the first contact 310, and overlaps the first transmission terminal 312, which is the second contact terminal. It is arranged not to be.

In the shield contact 100, the outer support 120 is supported by the support core (600 in FIG. 7) in the injection process, and at the same time, the insert is inserted into the insulating block 200 with the minimum width to deform according to the injection pressure. Does not appear. The shield contact 100 is coupled to both sides of the insulating block 200, and the first contact 310 is coupled to the bottom surface of the insulating block 200. In addition, a plurality of assembly grooves 210 are formed on the top surface of the insulating block 200 to assemble the second contact 320.

As illustrated in FIG. 8B, a plurality of contact terminals constituting the second contact 320 are respectively inserted into the assembling grooves 210 of the upper surface of the insulating block 200 to shield the contact 100 and the first contact 310. The insulating block 200 and the second contact 320 are combined into an integrated assembly. In this case, the contact terminals of the first contact 310 and the second contact 320 are symmetric with each other with the insulating block 200 interposed therebetween.

In addition, as shown in FIG. 8C, the housing 400 is injection molded to fix the second contact 320. The housing 400 is formed by an insert injection process using the shield contact 100, the first contact 310, the second contact 320, and the insulating block 200 assembly as insert water. In this case, the contact surface 310 ′ of the first contact 310 is exposed to the lower surface of the housing 400, and the contact surface 320 ′ of the second contact 320 is exposed to the upper surface of the housing 400.

As such, the insulating block 200 and the housing 400 are formed by a second insert injection process. In particular, the insulation block 200 is filled between the shield contact 100 and the contact terminals of the contact 300 in the first injection process, so that the insulation can be stably maintained between them.

In addition, as shown in Figure 8d, after the injection of the housing 400, the metal shell 500 manufactured in a separate process is coupled to the housing 400 to complete the receptacle connector. The completed receptacle connector is coupled to the substrate as the metal shell 500 is mounted on the substrate, and at the same time, soldering portions of the contact terminals are soldered to the contact pads of the substrate and electrically connected thereto.

9 is a process chart showing the assembly process of the second contact according to an embodiment of the present invention.

In the receptacle connector of the present invention, the first contact 310 is integrally formed with the insulating block by insert injection, but the second contact 320 is manufactured separately and then assembled to the insulating block 200. In this case, a structure in which the plurality of contact terminals constituting the second contact 320 may be easily assembled and fixed is formed in the insulating block 200. That is, as illustrated, a pair of assembling protrusions 220 are formed on the top surface of the insulating block 200, and assembling grooves 210 into which contact terminals are inserted are formed between the assembling protrusions 220. The assembling protrusion 220 has a catching jaw 221 having an upper end protruding toward the assembling groove 210, and the catching jaw 221 is formed to face inward while forming a hook shape and is inserted into the assembling groove 210. Prevents contact terminals from coming off.

Therefore, the second contact 320 is fixed to the assembly by the assembly protrusion 220, and the support core for supporting the contact terminals of the second contact 320 in the secondary insert injection process for ejecting the housing 400 There is an advantage that the secondary insert injection process is easy because the number is minimized or in some cases no support core is required.

10 is a plan view illustrating a shield contact according to another embodiment of the present invention.

Shield contact 100 according to another embodiment of the present invention is configured in one piece to which the tip is connected. That is, as illustrated in FIG. 10, the pair of mid plays 100 are spaced apart from each other while the insert part 110 intervenes only between the ground terminals 311 and 321 ′, which are outermost contact terminals of the first and second contacts 310 and 320. The front ends are connected to each other by the connection part 150.

The connection unit 150 connects the shield contacts 100 spaced apart from each other to stably support the shield contacts 100. In addition, the connection part 150 is connected to the front end of the insulating block 200 by connecting them at the front end of the shield contact 100, so that the support core 600 does not interfere with the insulating block 200 in the insert injection process. It can be supported by, and in turn, it is possible to more stably protect the mid plate 100 from the injection pressure in the insert injection process.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

100: shield contact
110: insert portion 120: support portion
130: reinforcement portion 140: groove portion
150 connection
200: insulation block
210: assembly groove 220: assembly protrusion
300: Contact
310: first contact 320: second contact
400: housing
410: connection portion 420: coupling portion
500: metal shell
510: inserting portion 520: fastening portion
530: plug insertion space

Claims (8)

An insulating block into which the insulating resin is injection molded;
A shield contact including an insert part inserted into the insulating block and a support part protruding to the insulating block side and coupled to the insulating block at both sides of the insulating block;
A first contact including a plurality of contact terminal arrays and coupled to a bottom surface of the insulating block;
A second contact including a plurality of contact terminal arrays and coupled to an upper surface of the insulating block; And,
And a housing that is injection molded to surround the assembly in which the insulating block, the shield contact, the first contact, and the second contact are coupled to each other.
The insert portion is coupled to the insulating block to overlap only the outermost contact terminal among the contact terminals of the first contact and the second contact,
The insulation block is integrally formed by primary injection using the shield contact and the first contact as an insert while the support is fixed to the support core, and the housing is integrally formed with the second contact. A receptacle connector, formed by secondary injection, using a block as an insert, to prevent core particles from occurring and to prevent moisture particles from penetrating into the insulating member. The method of claim 1,
The resin of the insulating block is filled between the contact terminals inside the first contact and the contact terminals inside the second contact to insulate the first contact and the second contact. delete The method of claim 1,
The insulating block forms a plurality of assembling grooves into which contact terminals are inserted,
The second contact is a receptacle connector, characterized in that a plurality of contact terminals are inserted into the assembly groove coupled. The method of claim 4, wherein the assembling groove,
A plurality of assembling protrusions having a hook shape are formed on an upper surface of the insulating block, and the receptacle connector is formed between a pair of the assembling protrusions facing each other. The method of claim 1, wherein the shield contact,
A receptacle connector comprising a reinforcing portion extending from the front end in the width direction. The method of claim 1, wherein the shield contact,
And a recessed portion in which the inner portion of the tip portion of the insert portion is recessed to avoid overlapping of the outermost contact terminal of the insert portion and the first contact. The method of claim 1, wherein the shield contact,
Receptacle connector, characterized in that it is composed of a separate type coupled to both sides of the insulating block, or a one end portion is connected by a connecting portion.

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