KR102516102B1 - High speed connector - Google Patents

Abstract

The present invention relates to a cable connector having a vertical connection structure capable of high-speed signal transmission by efficiently removing noise with one metal shell, comprising: a plug for accommodating a pair of cables on both sides; and a housing to which the plug is coupled, a plurality of contact terminals coupled to the housing and in contact with the signal electrode of the cable, and a plurality of ground terminals in contact with the ground electrode of the cable, coupled to surround the housing. A receptacle including a metal shell; by coupling the plug and the receptacle, the contact terminal is in contact with the signal electrode on the inner side of the cable to transmit a signal to the board, and the ground terminal is on the outer side of the cable It is configured to ground the cable to the substrate by contacting the ground electrode.
The present invention solves the noise problem with only one metal shell, thereby reducing the number of parts, reducing manufacturing costs, and improving assembly efficiency.

Description

Connector for high-speed signal transmission {High speed connector}

The present invention relates to a connector, and more particularly, to a cable connector having a vertical connection structure capable of high-speed signal transmission by efficiently removing noise with a single metal shell.

Recently, as electronic products become smaller and higher in performance, a large number of electronic devices are disposed on a printed circuit board (PCB), and accordingly, a plurality of signals are input to or output from the product in parallel. For electrical connection and signal transmission of these elements, a flexible flat cable (FFC) or a flexible printed circuit (FPC) is widely used. The FFC or FPC (hereinafter collectively referred to as 'cable') constitutes one cable with a plurality of electrodes arranged side by side, and exhibits a higher design freedom than a rigid PCB. Such a cable is detachably connected to a receptacle mounted on a board in a state of being coupled to the plug, and electrical connection is made to the board via the plug and the receptacle.

1 and 2 are perspective and cross-sectional views showing a connector and its coupling structure according to the prior art.

As shown in these figures, the conventional connector has a horizontal connection structure, a plug 10 to which the cable 1 is coupled, and a receptacle mounted on the board 2 to accommodate the insertion of the plug 10 ( 20).

The plug 10 includes a plug housing 11 in which a cable receiving portion 12 for receiving and fixing the cable 1 is formed, and a plug metal shell coupled to the cable receiving portion 12 of the plug housing 11 ( 13). The plug metal shell 13 includes at least one ground terminal 14, and a contact portion of the ground terminal 14 protrudes into the cable receiving portion 12.

In addition, the receptacle 20 is mounted on the receptacle housing 21 forming the plug accommodating portion 22 having an open center and the substrate 2 while surrounding the upper portion of the receptacle housing 21 to form a receptacle housing 21 It includes a receptacle metal shell 23 for fixing, and a plurality of contact terminals 25 coupled to the receptacle housing 21 so that the contact portion protrudes into the plug receiving portion 22. The receptacle metal shell 23 includes at least one ground terminal 24 , and a contact portion of the ground terminal 24 protrudes into the plug receiving portion 22 .

As shown in FIG. 2, the connector having the above structure is inserted into the plug accommodating portion 22 of the receptacle housing 21 at the front end of the plug housing 11 so that the plug 10 and the receptacle 20 are connected. It is done. At this time, the contact terminal 25 of the receptacle 20 forms a signal path S1 between the plug 10 and the receptacle 20 while being in contact with the signal electrode 1a on one side of the cable 1, and the receptacle 20 The ground terminal 24 of ) forms a ground path S2 while being in contact with the ground electrode 1b on the other side of the cable 1.

Since the signal transmission between the cable 1 and the board 2 is performed through the shortest path through the contact terminal 25, the connector has the advantage of enabling high-speed signal transmission. In addition, in the connector, external noise is blocked by the receptacle metal shell 23 and the plug metal shell 13, and internal noise is emitted to the outside through the ground terminals 14 and 24 of each metal shell 13 and 23 Thus, signals of good quality can be transmitted at high speed.

However, since the conventional connector as described above requires metal shells 13 and 23 to be provided on both sides of the plug 10 and the receptacle 20 to block and emit noise, manufacturing costs increase due to the increase in parts, However, there is a problem in that the assembly process becomes difficult. In addition, since the noise of the cable 1 is emitted to the outside via both the plug metal shell 13 and the receptacle metal shell 23 from the ground electrode 1b, it is difficult to rapidly emit noise, and the plug metal Since a space for contact between the metal shells 13 and 23 must be secured between the shell 13 and the cable 1, the connector has a disadvantage in that the overall thickness of the connector becomes thick.

In addition, in the conventional connector, while the ground electrode 1b of the cable 1 is in contact with the ground terminal 24 of the plug metal shell 13, the front end of the ground electrode 1b collides with the ground terminal 24. their contact takes place. The ground electrode 1b is composed of a flexible conductive tape and is easily damaged during collision with the rigid ground terminal 24 made of metal. Therefore, in the conventional connector, contact failure due to damage to the ground electrode 1b frequently occurs.

On the other hand, the type or number of signals to be transmitted gradually increases among recent electronic devices, whereas the conventional connector has a structure in which one cable 1 is connected to the board 2. In order to meet these demands, the width of cables and connectors must be increased or signals must be transmitted through a plurality of cables and connectors. However, in order to mount a wide connector or a large number of connectors on a board, structural design for efficient use of space is difficult.

In order to solve this problem, Korean Patent Publication No. 10-2004-0105566 proposes a connector capable of collectively connecting a plurality of cables. However, the connector of the prior art document simply has a disadvantage in that it cannot solve the noise problem at all and cannot be applied to high-speed signal transmission due to a complicated signal transmission path.

Korean Patent Publication No. 10-2004-0105566 (published on December 16, 2004, plug-type connector and electrical connector including the same)

The present invention has been proposed to solve the above problems, and the object of the present invention is to provide a connector for high-speed signal transmission capable of reducing manufacturing costs and improving assembly efficiency by solving noise problems while minimizing the number of parts. do.

Another object of the present invention is to provide a connector for high-speed signal transmission that can efficiently utilize space by connecting dual cables.

Another object of the present invention is to provide a connector for high-speed signal transmission capable of improving connection reliability by preventing collision between a terminal of a connector and an electrode of a cable during connection and minimizing damage to the electrode.

The present invention for achieving the above object is a plug for accommodating a pair of cables on both sides; and a housing to which the plug is coupled, a plurality of contact terminals coupled to the housing and in contact with the signal electrode of the cable, and a plurality of ground terminals in contact with the ground electrode of the cable, coupled to surround the housing. A receptacle including a metal shell; by coupling the plug and the receptacle, the contact terminal is in contact with the signal electrode on the inner side of the cable to transmit a signal to the board, and the ground terminal is on the outer side of the cable It is configured to ground the cable to the substrate by contacting the ground electrode.

The plug has terminal guide holes on both sides of the plug through which the ground terminal is inserted, and a ground contact part of the ground terminal is configured to come into contact with the ground electrode while sliding along the terminal guide hole.

In addition, in the plug, the terminal guide hole includes a terminal guide protrusion preventing the ground contact portion from colliding with the distal end of the ground electrode, and the terminal guide protrusion is formed to a thickness greater than that of the cable.

In addition, the terminal guide hole is formed at a position forming an asymmetrical structure with respect to both side surfaces of the plug to prevent misinsertion into the receptacle.

In addition, the ground terminal has a ground arm bent toward the plug accommodating portion of the housing.

The present invention solves the noise problem with only one metal shell, thereby reducing the number of parts, reducing manufacturing costs, and improving assembly efficiency.

In addition, the present invention provides an effect of efficiently utilizing a connection space by connecting two cables to a board through one connector.

In addition, in the process of connecting the plug housing and the receptacle housing, the ground terminal does not collide with the front end of the ground electrode of the cable, thereby minimizing damage to the ground electrode and improving connection reliability.

1 is a perspective view showing a connector according to the prior art;
Figure 2 is a coupling cross-sectional view showing the connector of Figure 1;
3 is a perspective view showing a connector according to an embodiment of the present invention;
Figure 4 is a cross-sectional view showing the connector of Figure 3;
5 is a cross-sectional view showing a coupling structure of a connector according to an embodiment of the present invention;
Figure 6 is a cross-sectional view showing a main part of the plug of Figure 5;
Figure 7 is a bottom view showing the main part of the plug housing of Figure 5;
8A to 8C are cross-sectional views illustrating a connection process between a plug and a receptacle;

The technical problems achieved by the present invention and its practice will be clarified by the preferred embodiments described below. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing a connector according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view showing the connector of FIG. 3 .

As shown, the connector of the present invention is composed of a plug 100 to which a pair of cables 200 are coupled, and a receptacle 300 mounted on and fixed to a board 400, and the plug 100 is in a vertical direction. to form a vertical connection structure connected to the receptacle 300.

Specifically, the plug 100 is composed of a plug housing 110 in which a pair of cable accommodating portions 130 each accommodating the cables 200 are formed therein to which the pair of cables 200 are coupled. . The plug housing 110 may be formed of an injection molded body using an insulating material such as plastic.

In addition, the plug housing 110 may form a hollow hexahedral shape having a predetermined thickness, width, and length while the central portion penetrates in the longitudinal direction (z direction, ie, the connection direction). Inside the plug housing 110, an inner frame 120 is formed that divides the cable accommodating portion 130 on both sides in the thickness direction (y direction) while crossing the hollow inner space in the width direction (x direction). Accordingly, the plug housing 110 provides a first cable accommodating portion formed on one side of the thickness direction (y direction) by the inner frame 120 and a second cable accommodating portion formed on the other side of the thickness direction (y direction).

In addition, coupling levers 140 for guiding and locking engagement with the receptacle 300 are formed on both sides of the plug housing 110 in the width direction (x direction). The coupling lever 140 is connected to the plug housing 110 while both ends of an elastic piece 141 having a predetermined length are spaced apart from the plug housing 110 by a predetermined distance, and a pressing protrusion is provided on the outside of the elastic piece 141. 142 and the locking protrusion 143 are formed, respectively. The locking protrusion 143 has a latch structure in which one surface (-z surface) in the connection direction has an inclination. Therefore, the coupling lever 140 is easily connected in the connection direction of the plug 100 without a separate operation, and when the plug 100 is disconnected, locking is performed by pressing the pressing protrusion 142 inward. It is released to allow separation from the receptacle 300.

In addition, the plug housing 110 includes a locking arm 150 for fixing the insertion of the cable 200. The locking arms 150 are formed on both frames in the thickness direction (y direction) of the plug housing 110, and it is preferable that at least two or more locking arms 150 are formed at predetermined intervals. When the cable 200 is completely inserted into the cable accommodating part 130, the locking arm 150 is inserted into a locking groove (not shown) formed in the cable 200 to prevent the cable 200 from being separated.

In addition, the plug housing 110 has a terminal guide hole 160 for guiding the ground terminal 331 when connected to the receptacle 300 . The terminal guide hole 160 is formed along the connection direction (z, that is, the longitudinal direction) of the plug housing 110 so that the ground contact portion 333 of the ground terminal 331 can slide, and the ground terminal 331 It may be formed in plurality while corresponding to the position of.

In the plug 100 configured as described above, the first cable 200 is inserted into the first cable accommodating part 130 and coupled, and the second cable 200 is inserted into the second cable accommodating part 130 and coupled thereto. do. The cable 200 may be composed of an FFC or FPC cable, and a signal electrode 210 for signal transmission is formed on one side and a ground electrode 220 for grounding is formed on the other side.

As described above, the pair of first and second cables 200 having the signal electrode 210 and the ground electrode 220 formed on both sides are inserted into the first and second cable receiving portions 130 in a symmetrical structure and coupled. In the present invention, the signal electrodes 210 are inserted into the first and second cable receiving portions 130 while facing each other. That is, the first and second cables 200 are coupled to the plug 100 such that one surface on which the signal electrode 210 is formed faces inward and the other surface on which the ground electrode 220 is formed faces outward. In this way, since the signal electrodes 210 formed on the first and second cables 200 are coupled to face each other on the inside, it can be protected from interference by external devices, and the risk of short circuit can be prevented in advance.

The receptacle 300 includes a receptacle housing 310 forming a plug accommodating portion 312, and a plurality of contact terminals coupled to the receptacle housing 310 such that the signal contact portion 323 protrudes into the plug accommodating portion 312. 320 and a metal shell 330 that surrounds the receptacle housing 310 and is mounted on the substrate 400 to fix the receptacle housing 310 to the substrate 400 .

The receptacle housing 310 induces connection between the plug 100 and the receptacle 300 by inserting the plug housing 110, and may be formed of an injection molded body using an insulating material such as plastic. The receptacle housing 310 has a hexahedral shape, a central frame 311 with a protruding central portion is formed therein, and along the circumference of the central frame 311, a track-shaped plug corresponding to the front end of the plug housing 110 is accommodated. Forms section 312 .

In addition, the receptacle housing 310 is formed on the side of the plug receiving portion 312 in the width direction (x direction) and includes a lever insertion groove 313 into which the coupling lever 140 is inserted. A locking groove (not shown) in which the locking protrusion 143 of the coupling lever 140 is elastically inserted is formed inside the lever insertion groove 313 .

In addition, the receptacle housing 310 is formed with a terminal assembly groove 314 into which the contact terminal 320 is assembled. A plurality of terminal assembly grooves 314 are formed on both sides of the central frame 311 at predetermined intervals in the width direction (x direction).

The contact terminal 320 electrically connects the cable 200 and the substrate 400 to provide a path through which signals are transmitted between them, and is made of a highly conductive metal material. The contact terminal 320 for this includes a signal mounting portion 321 soldered to the signal pad of the board 400, an extension portion 322 extending upward from the signal mounting portion 321, and a It includes a signal contact portion 323 protruding to one side. The plurality of contact terminals 320 configured as described above are assembled while being inserted into each terminal assembly groove 314 of the receptacle housing 310 so that the signal contact portion 323 faces the plug receiving portion 312 .

The metal shell 330 is a metal frame coupled while surrounding the receptacle housing 310, and fixes the receptacle housing 310 to the board 400 while blocking the inflow of external noise and discharging internal noise to the outside to generate a high-speed transmission signal. to prevent distortion of The metal shell 330 for this is made of a conductive metal material and is coupled while surrounding the outer surface of the receptacle housing 310 .

In addition, the metal shell 330 includes a ground terminal 331 in contact with the ground electrode 220 of the cable 200 . The ground terminal 331 includes a ground arm 332 bent toward the plug accommodating portion 312 of the receptacle housing 310 while a portion of the upper end of the metal shell 330 is cut, and an end of the ground arm 332 downward. It includes a ground contact portion 333 that protrudes toward the plug receiving portion 312 while being bent. At this time, a plurality of ground terminals 331 may be formed in the frame on both sides in the thickness direction (y direction), and in this embodiment, two are formed on each side. In addition, the ground terminals 331 are formed at different positions that are asymmetrical to each other in both frames. When the plug 100 is inserted in the opposite position, the positions of the ground terminal 331 and the terminal guide hole 160 are misaligned, preventing the plug 100 from being inserted. 100) and the receptacle 300 are prevented from being erroneously connected.

Also, the ground arm 332 of the ground terminal 331 is bent inwardly from the metal shell 330 to form a predetermined inclination. When the plug 100 and the receptacle 300 of the ground arm 332 are connected, the ground terminal 331 is pushed out of the metal shell 330 by approximately the thickness of the cable 200. Due to this deformation, the ground terminal 331 is prevented from protruding out of the metal shell 330.

In addition, the metal shell 330 includes a ground mounting part 334 soldered to the board. In the ground mounting unit 334 , a portion of the lower end of the metal shell 330 is bent and extended in a horizontal direction, and is soldered to the ground pad of the board 400 .

The receptacle 300 configured as described above is assembled by inserting the contact terminal 320 into the terminal assembly groove 314 of the receptacle housing 310, and the metal shell 330 is assembled along the outer surface of the receptacle housing 310. After that, the signal mounting part 321 of the contact terminal 320 and the ground mounting part 334 of the metal shell 330 are soldered to the signal pad and the ground pad of the board 400, respectively, and mounted on the board 400. .

5 is a cross-sectional view showing a coupling structure of a connector according to an embodiment of the present invention, FIG. 6 is a cross-sectional view showing a plug, which is a main part of FIG. 5, FIG. 7 is a bottom view showing a plug housing, which is a main part of FIG. 5, and FIG. 8A 8C are cross-sectional views illustrating a connection process between a plug and a receptacle.

As shown in FIG. 5, in the plug 100, the front end of the plug housing 110 is connected to the receptacle housing 310 in a state in which a pair of cables 200 are coupled to the first and second cable receiving portions 130, respectively. ) is connected to the receptacle 300 while being inserted into the plug receiving portion 312. In a state where the plug 100 and the receptacle 300 are completely connected, the contact terminal 320 is in contact with the signal electrode 210 on the inner surface of the cable 200, and the ground terminal 331 is on the outer surface of the cable 200. It is in contact with the ground electrode 220.

At this time, between the cable 200 and the substrate 400, a signal path S of the shortest path linearly connected via the contact terminal 320 is formed. Accordingly, high-speed signal transmission is possible between the cable 200 and the board 400 . In addition, the cable 200 is shielded from external noise by the metal shell 330 of the receptacle 300, and the ground electrode 220 is connected to the substrate along the ground path S' formed via the ground terminal 331. Since it is grounded at (400), internal noise can be quickly released. Accordingly, high-speed transmission can be efficiently performed between the cable 200 and the board 400 by minimizing the influence of noise.

In addition, the present invention prevents the ground electrode 220 of the cable 200 from being damaged during the connection process between the plug 100 and the receptacle 300 . To this end, as shown in FIGS. 5 and 6 , terminal guide projections 170 are formed in the terminal guide holes 160 of the plug housing 110 . The terminal guide protrusion 170 has a thickness higher than the thickness of the cable 200 including at least the ground electrode 220 and is formed in front of the terminal guide hole 160 in the connection direction. Therefore, since the cable 200 and the ground electrode 220 are located behind the terminal guide protrusion 170 and the front end 220' of the ground electrode 220 is shielded by the terminal guide protrusion 170, the plug 10 When is coupled to the receptacle 20, the guide protrusion 170 prevents the ground contact portion 333 from colliding with the front end portion 220' of the ground electrode 220.

Meanwhile, the pair of cables 200 facing each other while being symmetrical are elastically pressed from the inside to the outside of the plug housing 110 while contacting the plurality of contact terminals 320 . At this time, as shown in FIG. 7 , both frames of the cable 200 and the plug housing 110 exhibit fine bending deformation to the outside. In addition, since the ground terminal 331 is in contact with the inside of the cable 200, even if the metal shell 330 has a small number of ground terminals 331, the connection between the ground terminal 331 and the cable 200 Stability of contact between the ground electrodes 220 may be secured. Therefore, by pressurizing the ground electrode 220 of the cable 200 with a small number of ground terminals 331 , damage to the ground electrode 220 can be minimized and contact stability can be improved.

Looking at the process of connecting the plug 100 and the receptacle 300 in detail with reference to FIGS. 8A to 8C , in the initial stage of connection, the ground contact portion 333 of the ground terminal 331 is connected to the plug housing 110 as shown in FIG. 8A. It collides with the terminal guide protrusion 170. Subsequently, when the connection continues, as shown in FIG. 8B, the ground contact part 333 slides along the surface of the terminal guide protrusion 170 and moves backward, and when the connection is completed, the ground contact part 333 is ground The surface of the electrode 220 is contacted while being pressed.

In this way, in the process of connecting the plug 100 and the receptacle 300, the ground contact portion 333 of the ground terminal 331 collides with the front end portion 220' of the ground electrode 220 by the terminal guide protrusion 170. Since this is prevented, damage to the ground electrode 220 due to repetitive connection can be minimized. In addition, the ground terminal 331 contacts the ground electrode 220 prior to contact between the contact terminal 320 and the signal electrode 210, thereby removing noise in advance to protect circuitry on the signal path.

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

100: plug
110: plug housing 120: inner frame
130: cable receiving portion 140: coupling lever
150: locking arm 160: terminal guide hole
170: projection of the terminal guide
200: cable
300: receptacle
310: receptacle housing 311: center frame
312: plug receiving portion 313: lever insertion groove
314: terminal assembly groove
320: contact terminal 321: signal mounting unit
322: extension part 323: signal contact part
330: metal shell 331: ground terminal
332: ground arm 333: ground contact
334: ground mounting unit
400: Substrate

Claims (6)

A plug accommodating a pair of cables having a signal electrode formed on one side and a ground electrode protecting the signal electrode on the other side, the signal electrodes facing each other on the inside; and,
Having a housing to which the plug is coupled, a plurality of contact terminals coupled to the housing and contacting the signal electrodes of the pair of cables, and a plurality of ground terminals contacting the ground electrodes and coupled to surround the housing A receptacle including a metal shell;
By combining the plug and the receptacle, the contact terminal is in contact with the signal electrode inside the pair of cables to transmit a signal to the board, and the ground terminal is formed by cutting a part of the metal shell to form a pair of A connector for high-speed signal transmission, which is in contact with the ground electrode from the outside of the cable to ground the cable to a board. According to claim 1,
The plug has terminal guide holes on both sides of the plug to guide insertion of the ground terminal,
The connector for high-speed signal transmission, wherein the ground terminal contacts the ground electrode while a ground contact portion slides along the terminal guide hole. The method of claim 2, wherein the terminal guide hole,
A connector for high-speed signal transmission, comprising a terminal guide protrusion preventing the ground contact portion from colliding with the front end of the ground electrode. The method of claim 3, wherein the terminal guide protrusion,
A connector for high-speed signal transmission formed to a greater thickness than the cable. The method of claim 2, wherein the terminal guide hole,
A connector for high-speed signal transmission formed at a position forming an asymmetric structure with respect to both side surfaces of the plug to prevent erroneous insertion into the receptacle. The method of claim 1, wherein the ground terminal,
A connector for high-speed signal transmission having a ground arm bent toward a plug receiving portion of the housing.

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