KR101107455B1 - Connector for dual flexible circuit cable - Google Patents

Abstract

The connector 100 for a double-sided flexible circuit cable according to the present invention has a slot 111 into which an end of the double-sided flexible circuit cable 1 is inserted in a front end portion thereof, and a first terminal insertion portion 112 under the slot 111. A housing 110 having a second terminal inserting portion 113 formed at a rear end thereof; An actuator 120 installed rotatably in the housing 110 and having a rotation shaft 121 at a lower end thereof; The tension arm part 131 is inserted into and coupled to the first terminal insertion part 112 and has a contact protrusion 131a at an upper portion thereof so as to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1. A plurality of first terminals 130; The first arm part 141 is inserted into and coupled to the second terminal insertion part 113 and has a contact protrusion 141a at a lower portion thereof to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1. And a second arm portion 142 elastically contacting the rotating shaft 121 at an upper portion thereof, and the first arm at an intermediate position between the first arm portion 141 and the second arm portion 142. A plurality of second terminals 140 extending from the portion 141 and having a third arm portion 143 elastically contacting the rotating shaft 121 to provide an elastic force to the first arm portion 141; And a metal shell 150 surrounding the housing 110.

Description

Connector for double-sided flexible circuit cable {CONNECTOR FOR DUAL FLEXIBLE CIRCUIT CABLE}

The present invention relates to a connector for a flexible circuit cable, and more specifically, the first terminal group (First Terminal Group) and the second terminal group (Second Terminal Group) are completely separated from each other in front and rear of the housing of the actuator The present invention relates to a connector for a double-sided flexible circuit cable in which the double-sided flexible circuit cable of the double-sided flexible circuit cable in the closed position is reliably contacted with the lower and upper circuit patterns respectively.

In general, Low Voltage Differential Signals (LVDS) refers to a general interface standard for high-speed data transmission, and more specifically, a transmission method for transmitting digital information to a flat panel display at high speed through copper wire.

LVDS is used for economical and efficient transmission because a small number of wires can be used between the panels of the motherboard, and flexible circuit cables (FPC / FFC) for LVDS are used for devices such as LCD panels and printed circuit boards. (Or Main Board) is connected. In order to connect the flexible circuit cable with the printed circuit board, a wire-to-board connector is required, and the wire-to-board connector is called an LVDS connector.

The LVDS connector has terminals arranged in both longitudinal directions in a housing extending in both sides, and the LVDS connector is formed in a structure in which the housing is wrapped in a metal shell and connected to the printed circuit board. The metal shell blocks the foreign matter through the coupling with the housing, and also serves as a mechanical connection to the circuit board while shielding the electromagnetic waves.

Conventional flexible circuit cable connectors are shown in FIGS. 1 and 2.

As shown in Figure 1 and 2, the conventional flexible circuit cable connector is fixed to a printed circuit board (not shown) and formed of a synthetic resin material, and the housing 10 in the rear of the housing 10 A plurality of terminals 20 inserted into and fixed to the housing 10 and an actuator 30 fixing the flexible circuit cable FPC / FFC (not shown) inserted into the front of the housing 10 to the housing 10. .

The front end of the housing 10 is formed with a seating slot 11 for fixing the flexible circuit cable is seated, the rear end of the housing 10 is formed with a terminal insertion portion 12 is inserted into the terminal 20 is fixed. .

Fixing arms 13 are formed at both sides of the housing 10, and fixing grooves 13a are formed at both ends of the actuator 30 at the inside of the fixing arm 13.

In addition, fixing protrusions 31 rotatably fixed to the fixing grooves 13a protrude from both sides of the rear end of the actuator 30, and the actuator 30 is positioned at both ends of the front end of the actuator 30. At this time, the locking protrusion 32 is formed to protrude from both sides of the front portion of the housing 10 to lock the actuator 30 so as not to rotate.

Therefore, when the actuator 30 is inserted between the fixing arms 13 in the open position (upright position), the fixing projections 31 of the actuators 30 are fixed grooves 13a of the housing 10. By inserting in, the actuator 30 is coupled to the housing 10.

As described above, in order to connect the flexible circuit cable, the actuator 30 is first placed in the open position, and the end of the flexible circuit cable is seated in the seating slot 11 of the housing 10, and then the actuator 30 is mounted. By rotating and positioning in the closed position, the flexible circuit cable is electrically connected to the terminal 20 in a fixed state by the actuator 30.

However, the conventional flexible circuit cable connector configured as described above has a limitation that can not be applied to the double-sided flexible circuit cable, the contact pressure of the terminal is not uniform, the actuator is flowed or opened in the closed position by the external pressure and the connectivity is Falling, there is a problem that the flexible circuit cable is incorrectly inserted.

In addition, since the conventional flexible circuit cable connector has only one type of pitch in one connector, there is a functional limitation that only a single level (Voltage & Current) signal can be transmitted.

The present invention is to solve the above-mentioned problems, the two terminal group (群), that is, the first terminal group and the second terminal group is coupled to each of the front and rear of the housing in a completely separated state, in the close position of the actuator It is an object of the present invention to provide a connector for a double-sided flexible circuit cable in which the first terminal group is in contact with the bottom circuit pattern of the double-sided flexible circuit cable, and the second terminal group is in reliable contact with the upper circuit pattern of the double-sided flexible circuit cable. have.

It is also an object of the present invention to provide a connector for a double-sided flexible circuit cable in which the actuator is not opened arbitrarily by an external impact at the close position of the actuator.

In addition, the present invention is to ensure the contact reliability of the terminal by applying the same pressure to the upper and lower contacts of the double-sided flexible circuit cable, and provides a connector for the double-sided flexible circuit cable that can match the maximum contact pressure point at the actuator close position. Has its purpose.

In addition, an object of the present invention is to provide a connector for a double-sided flexible circuit cable that can transmit a double level (Double Voltage & Current) signal because two types of pitch is formed in one connector.

In addition, in the present invention, since the ground terminal portion is integrally formed in the metal shell, the direction of the force applied by the ground terminal portion acts from the top to the bottom, so that the ground terminal of the metal shell is connected to the bottom surface of the flexible circuit cable at the close position of the actuator. It is an object of the present invention to provide a connector for a double-sided flexible circuit cable that can prevent the phenomenon that the actuator is opened arbitrarily by an external impact by being pressed further.

In addition, in the double-sided flexible circuit cable, the metal shell and the ground terminal portion integrally formed in the metal shell absorb EMI and noise as well as EMI / EMS protection effect, so that the devices (devices) can cooperate with each other in harmony. It is an object of the present invention to provide a connector for a double-sided flexible circuit cable.

In order to achieve the above object, the connector for a double-sided flexible circuit cable according to the present invention is provided with a slot into which the end of the double-sided flexible circuit cable (FPC / FFC) is inserted in a front end portion, and a first terminal insertion portion is formed under the slot. A housing having a second terminal insertion portion formed at a rear end thereof; An actuator rotatably installed in the housing and having an axis of rotation at a lower end thereof; A plurality of first terminals inserted into and coupled to the first terminal insertion part, and having a tension arm having a contact protrusion formed at an upper portion thereof to contact a lower surface circuit pattern of the double-sided flexible circuit cable; A first arm portion is inserted into and coupled to the second terminal insertion portion, and has a first arm portion having a contact protrusion at a lower portion thereof so as to contact the upper circuit pattern of the double-sided flexible circuit cable, and a second arm portion is formed at the upper portion to elastically contact the rotating shaft. And a third arm portion formed at an intermediate position between the first arm portion and the second arm portion and extending from the first arm portion and elastically contacting the rotating shaft to provide an elastic force to the first arm portion. Second Terminals; And a metal shell surrounding the housing.

In the open position of the actuator, the rotational axis located between the second arm portion and the third arm portion does not contact the second arm portion and the third arm portion, and the first arm portion sags downward. Thus, when the end of the double-sided flexible circuit cable is inserted into the slot, the tension arm portion of the first terminal is in contact with the bottom circuit pattern of the double-sided flexible circuit cable, but the first arm portion is the top circuit of the double-sided flexible circuit cable It is configured not to contact the pattern.

At the close position of the actuator, the second arm portion and the third arm portion are elastically deformed by the rotation of the rotary shaft, and the elastic force of the third arm portion is transmitted to the first arm portion such that the contact protrusion is formed on both sides of the flexible portion. The upper surface of the circuit cable is in contact with the circuit pattern, and the contact protrusion of the tension arm portion is configured to be in contact with the lower circuit pattern of the double-sided flexible circuit cable.

In the close position of the actuator, a space portion is formed between the second arm portion and the housing such that the second arm portion is elastically deformed by the rotation of the rotary shaft.

In the close position of the actuator, the contact of the third arm portion, the contact of the first arm portion and the contact of the tension arm portion form a triangle structure and have the same contact pressure.

The actuator has a forward flip structure that rotates approximately 90 ° toward the front of the housing, and both sides of the metal shell may be provided with a reverse rotation preventing piece that prevents reverse rotation of the actuator.

A locking protrusion may be formed at a lower portion of the actuator, and a tension piece may be formed at both sides of the metal shell to correspond to the locking protrusion.

The first arm portion is configured to be in contact with the upper circuit pattern of the double-sided flexible circuit cable indirectly by the elastic deformation of the third arm portion without being directly affected by the rotation of the actuator.

In the open position of the actuator, the first arm portion is maintained in a raised state, and in the closed position of the actuator, the first arm portion is configured to remain in a downward state.

As described above, the present invention is coupled to the front and rear of the housing in a state in which two terminal groups, i.e., the first terminals and the second terminals, are completely separated, thereby providing a double-sided flexible circuit cable at the close position of the actuator. The first terminal is in contact with the bottom circuit pattern, and the second terminal is reliably in contact with the top circuit pattern of the double-sided flexible circuit cable.

That is, in the present invention, the second terminal group (upper contact terminals) and the first terminal group (lower contact terminals) are separated and assembled in front and rear of the housing, respectively, and the actuator is constrained and rotated in the structure of the upper contact. The upper contact point and the lower contact point are contacted with uniform force by one rotation operation, which greatly improves the contact reliability of the terminal.

In addition, the present invention is provided with a metal shell for shielding the EMI in the outer periphery of the housing, by the anti-rotation piece, the tension piece formed on both ends of the metal shell can be restrained stable during the close (closing) of the actuator Has the function.

Moreover, in the case of a connector, a heterogeneous pitch structure is possible for one connector in the pitch of a 1st terminal group and a 2nd terminal group. Therefore, there is an advantage that the signal transmission of different voltage or current can be made in one connector.

In addition, in the present invention, since the ground terminal portion is integrally formed in the metal shell, the direction of the force applied by the ground terminal portion acts from the top to the bottom, thereby additionally pressing the bottom surface of the flexible circuit cable at the close position of the actuator. The phenomenon in which the actuator is opened arbitrarily can be effectively prevented.

In addition, the present invention can improve the ability of the devices to work in harmony with each other by absorbing EMI and noise as well as the EMI / EMS protection effect by the metal shell and the ground terminal unit integrally formed in the metal shell.

1 is an exploded perspective view showing a connector for a conventional flexible circuit cable
Figure 2 is a perspective view showing a connector for a conventional flexible circuit cable
3 is a plan view showing a circuit pattern of 0.5 pitch formed on the upper surface of the double-sided flexible circuit cable
4 is a plan view showing a circuit pattern of 0.75 pitch formed on the lower surface of the double-sided flexible circuit cable
5 is a perspective view of a flexible circuit cable connector according to a first embodiment of the present invention
6 is a front view showing a flexible circuit cable connector according to a first embodiment of the present invention
7 is a plan view showing a flexible circuit cable connector according to a first embodiment of the present invention
8 is a longitudinal sectional view showing the open position of the actuator in the flexible circuit cable connector according to the first embodiment of the present invention;
9 is a longitudinal cross-sectional view illustrating insertion of a double-sided flexible circuit cable in the flexible circuit cable connector according to the first embodiment of the present invention;
10 is a longitudinal cross-sectional view showing a close position of an actuator in the flexible circuit cable connector according to the first embodiment of the present invention;
11 is a view showing the arrangement of the top and bottom contact with the rotating shaft in the flexible circuit cable connector according to the first embodiment of the present invention
12 is a perspective view of an essential part of a flexible circuit cable connector according to a first embodiment of the present invention;
13 is a longitudinal cross-sectional view illustrating a state in which a flexible circuit cable ground terminal is in contact with a ground circuit pattern in a flexible circuit cable connector according to a first embodiment of the present invention;
14 is an exploded perspective view of a flexible circuit cable connector according to a second embodiment of the present invention;
15 is a perspective view illustrating a flexible circuit cable connector according to a second embodiment of the present invention;
FIG. 16 is a front view of FIG. 15
17 is a top view of FIG. 15.
18 is a right side view of FIG. 15
19 is a perspective view of an essential part of a flexible circuit cable connector according to a second embodiment of the present invention;
20 is a cross-sectional view taken along the line XX of FIG. 16 showing the open position of the actuator.
FIG. 21 is a sectional view taken along the line XX of FIG. 16 showing the close position of the actuator;
FIG. 22 is a cross-sectional view taken along line YY of FIG. 16 and illustrates a state in which a ground terminal is in contact with a bottom ground circuit pattern of a flexible circuit cable;

Hereinafter, a connector for a double-sided flexible circuit cable according to a preferred embodiment of the present invention with reference to the accompanying drawings.

3 is a plan view showing a circuit pattern of 0.5 pitch formed on the upper surface of the double-sided flexible circuit cable, Figure 4 is a plan view showing a circuit pattern of 0.75 pitch formed on the lower surface of the double-sided flexible circuit cable, Figure 5 is a first embodiment of the present invention 6 is a perspective view of a flexible circuit cable connector according to the present invention, FIG. 6 is a front view showing a flexible circuit cable connector according to a first embodiment of the present invention, FIG. 7 is a plan view showing a flexible circuit cable connector according to a first embodiment of the present invention; 8 is a longitudinal cross-sectional view showing an open position of an actuator in a flexible circuit cable connector according to a first embodiment of the present invention, Figure 9 is a double-sided flexible circuit cable of a flexible circuit cable connector according to a first embodiment of the present invention Figure 10 is a longitudinal cross-sectional view showing the insertion, Figure 10 is a longitudinal cross-sectional view showing the close position of the actuator in the flexible circuit cable connector according to the first embodiment of the present invention, Figure 11 FIG. 12 is a view showing the arrangement of the rotary shaft and the top contact and the bottom contact in the flexible circuit cable connector according to the first embodiment of the present invention. FIG. 12 is a perspective view of an essential part of the flexible circuit cable connector according to the first embodiment of the present invention. 10 is a longitudinal cross-sectional view illustrating a state in which a flexible circuit cable ground terminal is in contact with a ground circuit pattern in the flexible circuit cable connector according to the first exemplary embodiment of the present invention.

As shown in the drawing, the connector 100 for a double-sided flexible circuit cable according to the first embodiment of the present invention connects the double-sided flexible circuit cable 1 having different circuit patterns 1a and 1b formed on both sides thereof. It plays a role.

In the description of the present invention, a 0.75 pitch circuit pattern 1a and a bottom ground circuit pattern 1c are formed on the bottom surface of the double-sided flexible circuit cable 1, and 0.5 pitch is formed on the top surface of the double-sided flexible circuit cable 1. An example in which the circuit pattern 1b is formed will be described as an example (see FIGS. 3 and 4).

In addition, the connector 100 for a double-sided flexible circuit cable according to the first embodiment of the present invention is applied to the positive flip type in which the actuator 120 rotates only toward the front side of the housing 110.

In the connector 100 for a double-sided flexible circuit cable 100 according to the first embodiment of the present invention, a slot 111 into which an end of a double-sided flexible circuit cable (FPC / FFC) 1 is inserted is formed at a front end thereof, and the slot ( 111, a lower portion of the first terminal insertion portion 112 is formed, the rear end of the housing 110 is formed with a second terminal insertion portion 113; An actuator (120) installed in the housing (110) so as to be rotatable approximately 0 ° -90 ° and having a rotating shaft (121) at a lower end thereof; The tension arm part 131 is inserted into and coupled to the first terminal insertion part 112 and has a contact protrusion 131a at an upper portion thereof so as to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1. A plurality of first terminals 130; The first arm part 141 is inserted into and coupled to the second terminal insertion part 113 and has a contact protrusion 141a at a lower portion thereof to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1. And a second arm portion 142 elastically contacting the rotating shaft 121 at an upper portion thereof, and the first arm at an intermediate position between the first arm portion 141 and the second arm portion 142. A plurality of second terminals 140 extending from the portion 141 and having a third arm portion 143 elastically contacting the rotating shaft 121 to provide an elastic force to the first arm portion 141; And a metal shell 150 surrounding the housing 110.

In detail, the housing 110 is formed of an insulator, and a slot 111 into which an end of the double-sided flexible circuit cable 1 is inserted is formed at the front end portion.

A first terminal insertion part 112 is formed below the housing 110, and a second terminal insertion part 113 is formed at a rear end thereof.

The first terminal 130 is inserted into and coupled to the first terminal insertion portion 112, and the second terminal 140 is inserted into and coupled to the second terminal insertion portion 113.

The actuator 120 is installed to be rotatable about 0 ° -90 ° to the housing 110, has a rotation shaft 121 on one side of the lower end, and a locking protrusion 123 is formed on the other side of the lower end.

The first terminal 130 has a tension arm portion 131 having a contact protrusion 131a formed thereon. The first terminal 130 is inserted into and coupled to the first terminal insertion portion 112 to form the double-sided flexible circuit cable 1. The lower surface is in contact with the circuit pattern 1a.

A first arm portion 141 having a contact protrusion 141a is formed at a lower portion of the second terminal 140 to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1.

The second terminal 140 has a second arm portion 142 is formed on the upper portion of the second terminal 140 in elastic contact with the rotating shaft 121.

An intermediate position between the first arm portion 141 and the second arm portion 142 extends from the first arm portion 141 and elastically contacts the rotation shaft 121 to allow the first arm portion ( A third arm portion 143 is provided that provides elastic force to 141.

On one end of the third arm portion 143, a separation preventing protrusion 143a is formed, and on the other side, an actuator reverse rotation preventing protrusion 143b is formed.

The metal shell 150 is composed of a metal body and positioned to surround the housing 110. On both sides of the metal shell 150, a fitting nail 155 fixed to the printed circuit board (main board) P is formed.

In the open position of the actuator 120, the rotation shaft 121 positioned between the second arm portion 142 and the third arm portion 143 is the second arm portion 142 and the third arm. When the end of the double-sided flexible circuit cable 1 is inserted into the slot 111 because the first arm portion 141 does not sag downward, the first terminal 130 does not contact the portion 143. The tension arm portion 131 is in contact with the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1.

However, the first arm portion 141 is configured not to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1. Therefore, when the operator inserts the end of the double-sided flexible circuit cable 1 into the slot 111, the insertion is very easy.

In the close position of the actuator 120, the second arm portion 142 and the third arm portion 143 are elastically deformed by the rotation of the rotary shaft 121, and the third arm portion 143 The elastic force is transmitted to the first arm portion 141 so that the contact protrusion 141a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable 1, and the contact protrusion of the tension arm portion 131 131a is configured to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1.

At the close position of the actuator 120, the second arm part 142 and the housing 110 are elastically deformed by the rotation of the rotation shaft 121. The space portion S is formed therebetween.

In the close position of the actuator 120, the contact c of the third arm part 143, the contact a of the first arm part 141, and the contact b of the tension arm part 131. Has a triangular structure and has the same contact pressure (see FIG. 11).

In the open position of the actuator 120, the first arm portion 141 is maintained upward, and in the closed position of the actuator 120, the first arm portion 141 is closed. Configured to remain drooping downwards.

The actuator 120 has a forward flip structure that rotates about 90 ° toward the front of the housing 110, and both ends of the metal shell 150 prevent reverse rotation of the actuator 120 at both ends of the metal shell 150. 151 is formed (see Fig. 12).

A locking protrusion 123 is formed at a lower portion of the actuator 120, and a tension piece 153 is formed at both ends of the metal shell 150 to correspond to the locking protrusion 123 (see FIG. 12). .

The first arm portion 141 is not directly affected by the rotation of the actuator 120, but indirectly by the elastic deformation of the third arm portion 143, the upper circuit pattern of the double-sided flexible circuit cable 1. It is configured to contact (1b).

In addition, a double-sided flexible circuit cable grounding terminal 135 is inserted into and coupled to both sides of the first terminal insertion part 112, and the double-sided flexible circuit cable grounding terminal 135 has a bottom ground circuit of the double-sided flexible circuit cable 1. It has a tension arm portion 136 so as to contact the pattern 1c, and a contact protrusion 136a is formed in the tension arm portion 136 (see FIGS. 5 and 13).

The operation of the double-sided flexible circuit cable connector 100 according to the first embodiment of the present invention configured as described above is as follows.

As shown in FIG. 8, in the open position of the actuator 120, the rotation shaft 121 positioned between the second arm portion 142 and the third arm portion 143 may be configured as the second arm portion ( 142 and the third arm portion 143 are not in contact with each other, and are in contact with each other so that elastic force does not occur even if they are contacted due to diarrhea assembly tolerances.

In this state, since the elastic force does not occur in the third arm portion 143, the first arm portion 141 does not sag downward.

At this time, the separation preventing protrusion 143a formed at one end of the third arm part 143 serves to prevent the actuator 120 from being randomly separated.

Therefore, as shown in FIG. 9, when the end of the double-sided flexible circuit cable 1 is inserted into the slot 111, the tension arm portion 131 of the first terminal 130 is connected to the double-sided flexible circuit cable. The lower surface of (1) is hardly in contact with the circuit pattern 1a, and the first arm portion 141 is not in contact with the upper circuit pattern 1b of the double-sided flexible circuit cable 1.

As shown in FIG. 10, in the close position of the actuator 120, the second arm portion 142 and the third arm portion 143 are elastically deformed by the rotation of the rotation shaft 121. 3, the elastic force of the arm portion 143 is transmitted to the first arm portion 141 so that the contact protrusion 141a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable 1, and the tension arm portion The contact protrusion 131a of 131 is in contact with the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1.

In this case, the third arm part 143 is elastically deformed by the rotation shaft 121 as well as the second arm part by the space part S formed between the second arm part 142 and the housing 110. 142 is also elastically deformed upwards.

That is, a structure capable of canceling the force transmitted to the upper side is also formed by the space S, so that the rotational force to be transmitted only to the lower side can be dispersed, and such an elastic structure in the vertical direction is formed in duplicate. When the actuator 120 is opened or closed, a light “click feeling” is produced.

In addition, the actuator 120 prevents the actuator 120 from rotating in the reverse direction by effectively preventing the projection 143b (see FIG. 10).

10 and 11, the contact point c of the third arm part 143, the contact point a of the first arm part 141, and the contact point b of the tension arm part 131 are provided. It is triangular and has the same contact pressure.

That is, the centers of the upper and lower contacts (c) (a) and the upper and lower surfaces of the rotary shaft 121 may be transmitted to the upper contact c or the lower contact a with the same level of force. By being arranged in a triangular composition, the position of the rotary shaft 121 is located in the center of the triangular structure to maximize the pressing force to the lower left and right.

At this time, the force of the upper surface contact (c) can be seen that the force acts in the upward direction rather than the downward direction, and if the repulsive force passes through the rotation axis 121 again, the force is transmitted in the direction of the contact (a), When the force is transmitted to the process in which the actuator 120 is closed while the upper surface of the double-sided flexible circuit cable 1 is rotated, the maximum force is achieved when the actuator 120 is completely closed, leading to an effect of pressing the contact point a.

Since the direction of the force applied to the bottom contact a acts from the top to the bottom, the actuator 120 presses the double-sided flexible circuit cable 1 to the entire flat bottom surface at the close position of the actuator 120. The effect of suppressing the opening of the reverse side 120 also occurs at the same time.

5 and 12, a locking protrusion 123 is formed at a lower portion of the actuator 120, and a tension piece 153 is formed at both sides of the metal shell 150 to correspond to the locking protrusion 123. This formation, as well as acting as a locking role when opening or closing the actuator 120, as well as to feel a light "click feeling (Click feeling)".

In addition, the reverse rotation prevention piece 151 formed on both sides of the metal shell 150 serves to prevent the reverse rotation of the actuator 120.

On the other hand, Figure 14 is an exploded perspective view of a flexible circuit cable connector according to a second embodiment of the present invention, Figure 15 is a perspective view of a combined flexible circuit cable connector according to a second embodiment of the present invention, Figure 16 is a front view of Figure 15 FIG. 17 is a plan view of FIG. 15, FIG. 18 is a right side view of FIG. 15, FIG. 19 is an excerpt perspective view of a flexible circuit cable connector according to a second exemplary embodiment of the present invention, and FIG. 20 is a sectional view taken along line XX of FIG. 16. The open position of the actuator is shown, FIG. 21 is a sectional view taken along the line XX of FIG. 16, the close view of the actuator is shown, and FIG. 22 is a sectional view taken along the line YY of FIG. It is a figure which shows the state which contacted.

Referring to the drawings, the connector 200 for a double-sided flexible circuit cable according to the second embodiment of the present invention is formed with a first terminal insertion portion 212 at the front end, the second terminal insertion portion 213 at the rear end Is formed in the housing 210; An actuator (220) installed in the housing (210); A plurality of first terminals 230 inserted into and coupled to the first terminal insertion part 212 and contacting a lower surface circuit pattern 1a of the double-sided flexible circuit cable 1; A plurality of second terminals 240 inserted into and coupled to the second terminal insertion part 213 and contacting the upper circuit pattern 1b of the double-sided flexible circuit cable 1; And a metal shell 250 surrounding the housing 210 and provided with ground terminal portions 255 at both ends thereof so as to contact the lower surface circuit pattern 1c of the double-sided flexible circuit cable 1. .

In more detail, the housing 210 has a slot 211 into which an end of a double-sided flexible circuit cable (FPC / FFC) 1 is inserted at a front end thereof, and a first terminal is formed below the slot 211. An insertion unit 212 is formed, and a second terminal insertion unit 213 is formed at a rear end thereof.

The actuator 220 is rotatably installed in the housing 210 and has a rotating shaft 221 at a lower end thereof.

The first terminals 230 are inserted into and coupled to the first terminal insertion unit 212, and have contact protrusions 231a thereon to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1. Tension arm portion 231 is formed.

The second terminals 240 are inserted into and coupled to the second terminal inserting portion 213 and have contact protrusions 241a at lower portions thereof to contact the upper circuit patterns 1b of the double-sided flexible circuit cable 1. A first arm portion 241 is formed, and a second arm portion 242 is formed on the upper portion of the second arm portion 242 to be in elastic contact with the rotating shaft 221. The first arm portion 241 and the second arm portion 242 are formed. ) Is formed in the intermediate position of the third arm portion 243 extending from the first arm portion 241 and elastically contacting the rotating shaft 221 to provide elastic force to the first arm portion 241. .

The metal shell 250 is positioned to surround the housing 210, and ground terminal portions 257 are formed at both ends of the metal shell 250 so as to contact the bottom circuit pattern 1c of the double-sided flexible circuit cable 1. (See FIG. 22). The ground terminal portion 257 may be formed as a separate member in the metal shell 250, but is formed integrally is advantageous in terms of work, manufacturing cost, rigidity, elastic force, and the like.

Here, a gap between the bottom surface 217b and the ground terminal portion 257 when inserting an end portion of the double-sided flexible circuit cable 1 into the bottom surface 217b of the housing 210. The ground terminal portion 257 is positioned relatively lower than the bottom surface 217b to prevent the end of the double-sided flexible circuit cable 1 from being inserted into the gap. An inclined surface 257a for guiding the end of the double-sided flexible circuit cable 1 is preferably formed at an end portion of the portion 257.

As described above, since the ground terminal portion 257 is positioned lower than the lower surface 217b, the gap is not blocked between the lower surface 217b and the ground terminal portion 257. When the end of 1) is advanced toward the lower surface 217b of the housing 210, the end of the double-sided flexible circuit cable 1 is not misinserted (see FIG. 16).

In addition, an inclined surface 257a for guiding the end of the double-sided flexible circuit cable 1 is formed at the end of the ground terminal portion 257, thereby connecting the end of the double-sided flexible circuit cable 1 to the housing 210. When advancing toward the bottom surface 217b, the ends of the double-sided flexible circuit cable 1 may be smoothly guided to improve the connection performance of the ground terminal 257 (see FIG. 16).

On both sides of the metal shell 250, a fitting nail 255 fixed to the printed circuit board (main board) P is formed.

Step jaws 217 are formed at both ends of the front end of the housing 210, and the step jaws 217 are formed with an insertion groove 217a into which the ground terminal part 257 is inserted (see FIG. 14).

In the open position of the actuator 220, the rotating shaft 221 located between the second arm portion 242 and the third arm portion 243 is the second arm portion 242 and the third arm. When the end of the double-sided flexible circuit cable 1 is inserted into the slot 211 because the first arm portion 241 does not sag downward because the first arm portion 241 is not in contact with the portion 243. The tension arm portion 231 of () is in contact with the lower circuit pattern (1a) of the double-sided flexible circuit cable (1), the first arm portion 241 is the upper surface of the double-sided flexible circuit cable ( 1b).

In the close position of the actuator 220, the second arm portion 242 and the third arm portion 243 are elastically deformed by the rotation of the rotation shaft 221, and the third arm portion 243 The elastic force is transmitted to the first arm portion 241 so that the contact protrusion 241a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable 1, and the contact protrusion of the tension arm portion 231 231a is configured to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1.

In the close position of the actuator 220, a space portion between the second arm portion 242 and the housing 210 so that the second arm portion 242 is elastically deformed by the rotation of the rotary shaft 221. S) is formed.

The actuator 220 has a positive flip structure that rotates about 90 ° toward the front of the housing 210, and a reverse rotation prevention piece 251 that prevents reverse rotation of the actuator 220 on both sides of the metal shell 250. ) Is formed.

In the shape of the reverse rotation prevention piece 251, when the end of the double-sided flexible circuit cable 1 is inserted into the lower surface 217b of the housing 210, the housing 210 and the actuator 220 The reverse rotation preventing piece 251 extends and bends downwardly to prevent the gap from being inserted into the gap between the ends of the double-sided flexible circuit cable 1. Preferably, the end portion of the reverse rotation preventing piece 251 has a shape inserted into the groove 214 (see FIG. 19).

A locking protrusion 223 is formed below the actuator 220, and a tension piece 253 is formed on both sides of the metal shell 250 to correspond to the locking protrusion 223.

The first arm part 241 is not directly affected by the rotation of the actuator 220, but indirectly by the elastic deformation of the third arm part 243, the upper circuit pattern of the double-sided flexible circuit cable 1. It is configured to contact (1b).

In the open position of the actuator 220, the first arm portion 241 is maintained upward, and in the closed position of the actuator 220, the first arm portion 241 sags downward. It is configured to maintain.

On one side of the end of the third arm portion 243, a separation preventing protrusion 243a is formed, and on the other side, an actuator reverse rotation preventing protrusion 243b is formed.

The operation of the double-sided flexible circuit cable connector 200 according to the second embodiment of the present invention configured as described above is as follows.

As shown in FIG. 20, in the open position of the actuator 220, the rotation shaft 221 positioned between the second arm portion 242 and the third arm portion 243 may be configured as the second arm portion ( 242 and the third arm portion 243 are not in contact with each other, and are contacted to such an extent that elastic force does not occur even if they are contacted due to diarrhea assembly tolerances.

In this state, since the elastic force does not occur in the third arm portion 243, the first arm portion 241 does not sag downward.

At this time, the separation preventing protrusion 243a formed at one end of the third arm portion 243 serves to prevent the actuator 220 from being randomly separated.

Therefore, when the end of the double-sided flexible circuit cable 1 is inserted into the slot 211, the tension arm portion 231 of the first terminal 230 is the bottom circuit pattern (1) of the double-sided flexible circuit cable (1) It is hardly in contact with 1a), and the first arm portion 241 is not in contact with the upper circuit pattern 1b of the double-sided flexible circuit cable 1.

As shown in FIG. 21, in the close position of the actuator 220, the second arm portion 242 and the third arm portion 243 are elastically deformed by the rotation of the rotation shaft 221. The elastic force of the three arm portion 243 is transmitted to the first arm portion 241 so that the contact protrusion 241a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable 1, and the tension arm portion The contact protrusion 231a of 231 contacts the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1.

In this case, the third arm portion 243 is elastically deformed by the rotation shaft 221 as well as the second arm portion by the space portion S formed between the second arm portion 242 and the housing 210. 242 is also elastically deformed upwards.

That is, a structure capable of canceling the force transmitted to the upper side is also formed by the space S, so that the rotational force to be transmitted only to the lower side can be dispersed, and such an elastic structure in the vertical direction is formed in duplicate. It is configured to feel a light "click feeling" when opening or closing the actuator 220.

In addition, the actuator 220 prevents the actuator 220 from rotating in the reverse direction by effectively preventing the projection 243b (see FIG. 21).

In addition, the ability of devices to work in concert with each other is called EMC (Electro Magnetic Compatibility). EMC consists of EMI and EMS, and there are two ways to solve the noise problem. One is to suppress the radiation of unwanted electromagnetic waves (EMI: Electro Magnetic Interference), and the other is to strengthen the EMI (Electro Magnetic Susceptibility) to withstand the obstacles and operate normally within a certain electromagnetic environment. Way.

The ground inside the electronic device can be divided into the signal ground (SG) and the frame ground (FG). The trouble caused by noise is often caused by the level variation of the SG system and the FG system. Since SG is a ground for returning circuit current, it is a ground through which current flows, and FG is a ground where no current flows, which can cause noise radiation to the outside when FG flows, and also increases sensitivity to external electromagnetic fields. Therefore, make the impedance of earth circuit as small as possible. It is important to ensure that no current flows through the earth circuit and that no ground loop is formed.

Since the EMI / EMS generated in the IC or power circuit is transferred to the flexible circuit cable (1), the ground (GND) processing is required as close as possible, and the metal shell of the connector affected by external noise is a flexible circuit cable. Separate grounding (GND) processing is required.

In consideration of such a series of matters, in the connector 200 for a double-sided flexible circuit cable according to the present invention, an EMI / EMS protection effect is provided by a metal shell 250 and a ground terminal part 257 formed integrally with the metal shell 250. It also absorbs EMI and noise, improving the ability of devices to work in concert.

In addition, since the direction of the force applied by the ground terminal portion 257 acts from top to bottom, the ground terminal portion 257 further presses the bottom surface of the flexible circuit cable 1 at the close position of the actuator 220. As a result, the phenomenon in which the actuator 220 is arbitrarily opened by an external impact can be effectively prevented.

As described above, the present invention is the two terminal group, that is, the first terminal group and the second terminal group are respectively coupled in front and rear of the housing in a completely separated state of the double-sided flexible circuit cable at the close position of the actuator The first terminal group may contact the lower surface circuit pattern, and the second terminal group may reliably contact the upper circuit pattern of the double-sided flexible circuit cable.

In addition, the present invention has an effect that the actuator is not opened arbitrarily by external impact at the close position of the actuator on both ends of the metal shell.

In addition, the present invention can be ensured contact reliability by applying the same pressure to the upper and lower contacts of the double-sided flexible circuit cable, it can be matched with the highest contact pressure point at the close position of the actuator.

In addition, in the conventional connector, only one level (Voltage & Current) signal was transmitted because the same pitch was formed in one connector, but in the case of the connector of the present invention, in the pitch of the first terminal group and the second terminal group, Since different pitch configurations are possible in one connector, signal transmission of different voltages or currents can be performed in one connector.

In addition, in the present invention, since the ground terminal portion is integrally formed in the metal shell, the direction of the force applied by the ground terminal portion acts from the top to the bottom, thereby additionally pressing the bottom surface of the flexible circuit cable at the close position of the actuator, thereby making the actuator external. It is possible to prevent the phenomenon of opening arbitrarily due to the impact and to obtain an EMI / EMS protection effect.

As described above, the rights of the present invention are not limited to the above-described embodiments, and are defined by the claims, and various modifications can be made within the scope of the claims by those skilled in the art. As can be seen, the present invention is not limited to LVDS, and is applicable to all devices using double-sided flexible circuit cables.

1: double-sided flexible circuit cable
1a: bottom circuit pattern
1b: upper circuit pattern
1c: bottom ground circuit pattern
110: housing
111: slot
112: first terminal insertion portion
113: second terminal insertion section
120: actuator
121: axis of rotation
123: jamming
130: terminal 1
131: tension arm part
131a: Contact projection
135: double-sided flexible circuit cable grounding terminal
140: second terminal
141: first arm part
141a: contact projection
142: second arm part
143: third arm part
143a: release prevention protrusion
150: metal shell
151: reverse rotation prevention
153: tension
S: space department
210: housing
211: slot
212: first terminal insert
213: second terminal insert
214: home
220: actuator
221: axis of rotation
230: terminal 1
231 tension arm part
240: second terminal
241: first arm part
241a: contact projection
242: second arm part
243: third arm part
250: metal shell
251: reverse rotation prevention piece
255: fitting rail
257 ground terminal
257a: slope

Claims (27)

A slot 111 into which an end of a double-sided flexible circuit cable (FPC / FFC) 1 is inserted is formed at a front end thereof, and a first terminal insertion part 112 is formed at a lower end of the slot 111. A housing 110 in which a second terminal insertion portion 113 is formed;
An actuator 120 installed rotatably in the housing 110 and having a rotation shaft 121 at a lower end thereof;
The tension arm part 131 is inserted into and coupled to the first terminal insertion part 112 and has a contact protrusion 131a at an upper portion thereof so as to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1. A plurality of first terminals 130;
The first arm part 141 is inserted into and coupled to the second terminal insertion part 113 and has a contact protrusion 141a at a lower portion thereof to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1. And a second arm portion 142 elastically contacting the rotating shaft 121 at an upper portion thereof, and the first arm at an intermediate position between the first arm portion 141 and the second arm portion 142. A plurality of second terminals 140 extending from the portion 141 and having a third arm portion 143 elastically contacting the rotating shaft 121 to provide an elastic force to the first arm portion 141; And
And a metal shell (150) surrounding the housing (110). The method of claim 1,
In the open position of the actuator 120, the rotation shaft 121 positioned between the second arm portion 142 and the third arm portion 143 is the second arm portion 142 and the third arm. When the end of the double-sided flexible circuit cable 1 is inserted into the slot 111 because the first arm portion 141 does not sag downward, the first terminal 130 does not contact the portion 143. The tension arm portion 131 of () is in contact with the lower circuit pattern (1a) of the double-sided flexible circuit cable (1), the first arm portion 141 is the upper circuit pattern of the double-sided flexible circuit cable (1) A connector for a double-sided flexible circuit cable, characterized in that not to be in contact with 1b). The method of claim 1,
In the close position of the actuator 120, the second arm portion 142 and the third arm portion 143 are elastically deformed by the rotation of the rotary shaft 121, and the third arm portion 143 The elastic force is transmitted to the first arm portion 141 so that the contact protrusion 141a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable 1, and the contact protrusion of the tension arm portion 131 A connector for a double-sided flexible circuit cable, characterized in that 131a is configured to contact the lower surface circuit pattern (1a) of the double-sided flexible circuit cable (1). The method of claim 1,
In the close position of the actuator 120, a space portion between the second arm portion 142 and the housing 110 is elastically deformed by the rotation of the rotary shaft 121. S) is a connector for a double-sided flexible circuit cable, characterized in that formed. The method of claim 1,
In the close position of the actuator 120, the contact c of the third arm part 143, the contact a of the first arm part 141, and the contact b of the tension arm part 131. Is a triangle structure, the connector for the double-sided flexible circuit cable, characterized in that configured to have the same contact pressure. The method of claim 1,
The actuator 120 has a positive flip structure that rotates 90 ° toward the front of the housing 110, and a reverse rotation preventing piece 151 that prevents reverse rotation of the actuator 120 on both sides of the metal shell 150. Double-sided flexible circuit cable connector characterized in that it is formed. The method according to claim 1 or 6,
A locking protrusion 123 is formed below the actuator 120, and a tension piece 153 is formed on both sides of the metal shell 150 to correspond to the locking protrusion 123. Connector for cable. The method according to claim 1 or 6,
The first arm portion 141 is not directly affected by the rotation of the actuator 120, but indirectly by the elastic deformation of the third arm portion 143, the upper circuit pattern of the double-sided flexible circuit cable 1. A connector for a double-sided flexible circuit cable, characterized in that it is configured to contact (1b). The method according to claim 1 or 6,
In the open position of the actuator 120, the first arm portion 141 maintains an upward state, and in a closed position of the actuator 120, the first arm portion 141 sags downward. Connector for double-sided flexible circuit cable, characterized in that configured to hold. The method according to claim 1 or 6,
One end portion of the third arm portion 143, the separation preventing projection (143a) is formed on the other side, the actuator reverse rotation preventing projection (143b) is formed, characterized in that the connector for the double-sided flexible cable. The method according to claim 1 or 6,
A double-sided flexible circuit cable ground terminal 135 inserted into and coupled to both sides of the first terminal inserting portion 112 and to be in contact with the bottom ground circuit pattern 1b of the double-sided flexible circuit cable 1; Connector for circuit cable. The front end is formed with a slot 211 into which the end of the double-sided flexible circuit cable (FPC / FFC) (1) is inserted, the first terminal insertion portion 212 is formed in the lower portion of the slot 211, the rear end A housing 210 in which a second terminal insertion part 213 is formed;
An actuator 220 rotatably installed in the housing 210 and having a rotation shaft 221 at a lower end thereof;
The tension arm part 231 is inserted into and coupled to the first terminal insertion part 212 and has a contact protrusion 231a at an upper portion thereof so as to contact the lower surface circuit pattern 1a of the double-sided flexible circuit cable 1. A plurality of first terminals 230;
The first arm portion 241 is inserted into and coupled to the second terminal insertion portion 213 and has a contact protrusion 241a at a lower portion thereof to contact the upper circuit pattern 1b of the double-sided flexible circuit cable 1. And a second arm portion 242 which is elastically in contact with the rotating shaft 221, and is formed at an intermediate position between the first arm portion 241 and the second arm portion 242. A plurality of second terminals 240 extending from the portion 241 and having a third arm portion 243 elastically contacting the rotating shaft 221 to provide an elastic force to the first arm portion 241; And
A metal shell 250 surrounding the housing 210 and provided with ground terminal portions 257 at both ends thereof so as to be in contact with the bottom ground circuit pattern 1c of the double-sided flexible circuit cable 1. Flexible circuit cable connector. The method of claim 12,
In the open position of the actuator 220, the rotating shaft 221 located between the second arm portion 242 and the third arm portion 243 is the second arm portion 242 and the third arm. When the end of the double-sided flexible circuit cable 1 is inserted into the slot 211 because the first arm portion 241 does not sag downward because the first arm portion 241 is not in contact with the portion 243. The tension arm portion 231 of () is in contact with the lower circuit pattern (1a) of the double-sided flexible circuit cable (1), the first arm portion 241 is the upper surface of the double-sided flexible circuit cable ( A connector for a double-sided flexible circuit cable, characterized in that not to be in contact with 1b). The method of claim 12,
In the close position of the actuator 220, the second arm portion 242 and the third arm portion 243 are elastically deformed by the rotation of the rotation shaft 221, and the third arm portion 243 An elastic force is transmitted to the first arm portion 241 so that the contact protrusion 241a contacts the upper circuit pattern 1b of the double-sided flexible circuit cable (FPC / FFC) 1 and the tension arm portion 231 Connector of the double-sided flexible circuit cable, characterized in that the contact projection (231a) of the two-sided flexible circuit cable (1) is in contact with the lower surface of the circuit pattern (1a). The method of claim 12,
In the close position of the actuator 220, a space portion between the second arm portion 242 and the housing 210 so that the second arm portion 242 is elastically deformed by the rotation of the rotary shaft 221. S) is a connector for a double-sided flexible circuit cable, characterized in that formed. The method of claim 12,
The actuator 220 has a positive flip structure that rotates 90 ° toward the front of the housing 210, and a reverse rotation preventing piece 251 that prevents reverse rotation of the actuator 220 on both sides of the metal shell 250. Double-sided flexible circuit cable connector characterized in that it is formed. The method of claim 16,
When inserting an end portion of the double-sided flexible circuit cable 1 into the lower surface 217b of the housing 210, the double-sided flexible circuit cable 1 into the gap between the housing 210 and the actuator 220. 1) The reverse rotation prevention piece (251) is a connector for a double-sided flexible circuit cable, characterized in that the bending to prevent the gap is inserted into the end of the gap. The method of claim 12,
A locking protrusion 223 is formed below the actuator 220, and a tension piece 253 is formed on both sides of the metal shell 250 to correspond to the locking protrusion 223. Connector for cable. The method according to claim 12 or 18, wherein
The first arm part 241 is not directly affected by the rotation of the actuator 220, but indirectly by the elastic deformation of the third arm part 243, the upper circuit pattern of the double-sided flexible circuit cable 1. A connector for a double-sided flexible circuit cable, characterized in that it is configured to contact (1b). The method of claim 12,
In the open position of the actuator 220, the first arm portion 241 is maintained upward, and in the closed position of the actuator 220, the first arm portion 241 sags downward. Connector for double-sided flexible circuit cable, characterized in that configured to hold. The method of claim 12,
One end portion of the third arm portion (243) is a separation preventing projection (243a) is formed on the other side, the actuator for reverse rotation prevention projections (243b) is formed on the other side is a double-sided flexible circuit cable connector. The method of claim 12,
On both sides of the metal shell 250, a fitting nail 255 is fixed to a printed circuit board (main board) P, and the ground terminal portion 257 is formed integrally with the metal shell 250. Double-sided flexible circuit cable connector characterized in that the. The method of claim 12 or 22,
When inserting the end of the double-sided flexible circuit cable 1 into the lower surface (217b) of the housing 210, the double-sided flexible into the gap (gap) between the bottom surface 217b and the ground terminal portion 257 And the ground terminal portion 257 is positioned relatively lower than the bottom surface 217b so as to prevent the end of the circuit cable from being inserted incorrectly. The method of claim 23, wherein
A connector for a double-sided flexible circuit cable, characterized in that the inclined surface (257a) for guiding the end of the double-sided flexible circuit cable (1) is formed at the end of the ground terminal portion (257). The method of claim 12,
Stepped 217 is formed at both ends of the front end of the housing 210, and the stepped 217 is formed with an insertion groove 217a into which the ground terminal part 257 is inserted. Connector. delete delete

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