KR200397389Y1 - Connecting structure of coaxial cable to printed circuit board of sliding terminal - Google Patents

Abstract

The present invention relates to a printed circuit board connection structure of a slide type terminal in which the display unit slides on the main body and moves up and down. More specifically, the printed circuit board of the elevating unit provided with the display means and the printed circuit board of the main body part have excellent flexibility. A coaxial cable connected by a cable and both ends of the coaxial cable are directly soldered and fixed to the pattern portion formed on each printed circuit board, thereby connecting data to each printed circuit board and the coaxial cable without the need for a special connector. It relates to a printed circuit board connection structure of a slide-type terminal using.

Description

CONNECTING STRUCTURE OF COAXIAL CABLE TO PRINTED CIRCUIT BOARD OF SLIDING TERMINAL}

The present invention relates to a printed circuit board connection structure of a slide type terminal in which the display unit slides on and lifts up the main body. A coaxial cable connected by a cable and both ends of the coaxial cable are directly soldered and fixed to the pattern portion formed on each printed circuit board, thereby connecting data to each printed circuit board and the coaxial cable without the need for a special connector. It relates to a printed circuit board connection structure of a slide-type terminal using.

In general, the slide type mobile communication terminal is configured to include a lifting guide plate that is slide coupled to the lifting plate provided with the display means and the main body of the mobile communication terminal is connected, the lifting plate is configured to slide up and down on the lifting guide plate.

The slide type mobile communication terminal is connected to a flexible printed circuit board (FPCB) between a printed circuit board of a lift unit provided with a display means and a printed circuit board of a main body so that data is displayed on the display means. Many conductor wires were provided.

However, the conventional slide type mobile communication terminal connected by the flexible printed circuit board is folded when the display means is lowered and positioned on the upper surface of the main body, and thus the flexible printed circuit board is folded at an excessive angle and continuously folded. Excessive stimulus was transmitted to a specific site repeating and unfolding, there was a problem that is easily damaged.

In addition, the flexible circuit board has a problem in that the bending direction is limited to a unidirectional direction so that the printed circuit boards of the elevating part and the main body part may be stacked up and down facing each other, thereby contributing to the slimming of the mobile communication terminal.

In addition, recently, micro coaxial cables (Coaxial Cables), etc., which connect the printed circuit boards and transmit data with each other have been introduced, but such coaxial cables require separate special connectors at both ends of the coaxial cables to be connected to the printed circuit boards. There is a problem in that the existing manufacturing process is completely revised, and a special connector manufacturing process is newly added, thereby increasing the cost, and there is a problem in that the application of micro coaxial cable is poorly applied to the mobile communication terminal.

The present invention has been made to solve the above-described problems, and directly form a pattern portion made of a conductor to transmit and receive data on the printed circuit board and the printed circuit board of the main body sliding and vertically moving the display means, each of the printed circuits By soldering and fixing the coaxial cable signal line and shield wire directly to the pattern formed on the board, the flexible coaxial cable is bonded to the printed circuit board without using a special connector to simplify the manufacturing process, reduce the production cost, and bulk To provide a printed circuit board connection structure of a slide type terminal using a coaxial cable suitable for production.

Another object of the present invention, the coaxial cable is bent to one side at the same time when the lifting unit is sliding so that it is not overlapped up and down, the printed circuit board of the slide type terminal using a coaxial cable that can make the sliding mobile communication terminal more slim To provide a connection structure.

A printed circuit board connection structure of a slide type terminal using a coaxial cable according to the present invention for achieving the above object, the signal line for transmitting data, the inner insulator surrounding the signal line, and the shield wire surrounding the inner insulator; A coaxial cable part configured to repeat folding and unfolding when the sliding wire is formed of an outer insulator surrounding the shield wire; A first pattern portion directly patterned on a printed circuit board comprising a first signal pattern and a first ground pattern that are in contact with a shielded wire and a signal line laser-processed at one end of the coaxial cable portion, and a direct signal line on the first pattern portion A main body part including a first soldering part for soldering and fixing the shield wire; And a second pattern part which is slid on the main body part, and comprises a second signal pattern and a second ground pattern which are in contact with the signal line processed by the laser at the other end of the coaxial cable part and the shield wire and the second ground pattern. And a lifting part including a second soldering part for soldering and fixing the signal line and the shield wire directly on the second pattern part.

According to another feature of the present invention, the first signal pattern and the second signal pattern are patterned independently from each other by a plurality of small patterns spaced apart from each other by a predetermined distance, and the first ground pattern and the second ground pattern are the first signal pattern. Each of the and second signal patterns is patterned into a long rectangular shape spaced apart by a predetermined distance.

Another feature of the present invention is that both ends of the coaxial cable are laser processed so that the shield wire, the internal insulator, and the signal line are stepped by a predetermined length to the outside.

Another feature of the present invention is that the coaxial cable portion is bent at the same time when the lifting unit is sliding, so that the coaxial cable is configured to further comprise a taping portion for binding and fixing a plurality of coaxial cables.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

Printed circuit board connection structure of the slide-type terminal using a coaxial cable according to the present invention, as shown in Figure 1, the printed circuit board is connected to each other coaxial cable unit 100 for transmitting data, and the coaxial cable unit A main body 200 having a printed circuit board 240 coupled to one end thereof, and a printed circuit board 340 coupled to the other end of the coaxial cable unit are provided, and are moved upwards and downwards by sliding on the main body 200. The unit 300 is configured to be included.

The coaxial cable unit 100 is composed of a micro coaxial cable, as shown in Figure 3, the signal line 110, which is a conductor for transmitting and receiving data, the inner insulator 120 surrounding the signal line and insulated, and the inside The shield wire 130 surrounds the insulator and shields electromagnetic interference generated during signal transmission, and an outer insulator 140 surrounding the shield wire to form an outer appearance of the coaxial cable.

The main body 200 is provided with a keypad (not shown) and processes wirelessly received data, and as shown in FIG. 2, the signal line 110 and shield wire of the coaxial cable part exposed to the outside by laser processing. The first pattern portion directly formed on the printed circuit board 240 to be in contact with the 130, the signal line 110 and the shield wire 130 placed on the first pattern portion is coupled on the printed circuit board 240 It is configured to include a first soldering unit 230 for fixing.

As shown in FIG. 4, the first pattern part is formed of a conductor to contact the signal line to receive and transmit data, and the first signal pattern 210 patterned on one surface of the printed circuit board 240 and the shield. It consists of a first ground pattern 220 formed on the printed circuit board 240 at a position spaced apart from the signal pattern by a conductor to contact the wire to form a ground.

In this case, the first signal pattern 210 is the signal line 110 by removing the external insulator 140, the shield wire 130 and the internal insulator 120 by laser processing at one end of the coaxial cable unit 100. As the contact point, small patterns of a number corresponding to the number of signal lines are formed on the printed circuit board 240 independently of each other by a predetermined distance. In addition, the first ground pattern 220 is a place where the shield wire 130 exposed to the outside after a predetermined distance from the signal line in contact with the first signal pattern is exposed to the outside, the coaxial cable portion It consists of a substantially rectangular shape which extends by the width | variety which it comprises.

As shown in FIGS. 5A and 5B, the first soldering unit 230 fixes the plurality of signal lines 110 to the first signal pattern 210, respectively, and the shield wire 130 is first grounded. In order to fix the pattern 220, the signal line and the shield wire may be soldered by a soldering apparatus such as a pulse heater to be fixed to the first signal pattern and the first ground pattern.

The lifting unit 300 is provided with a display means (not shown) to display the data transmitted from the main body portion, and slides up and down on the main body portion 200, printing to receive the data transmitted from the main body portion The second pattern part directly formed on the circuit board 340 and the second soldering part 330 to which the signal line and the shield wire of the coaxial cable part are coupled are fixed.

The second pattern part is made of a conductor to receive data in contact with a signal line provided at the other end of the coaxial cable, similarly to the first pattern part, and has a second signal patterned on one surface of the printed circuit board 340 of the lifting part. The pattern 310 and the second ground pattern 320 are patterned on the printed circuit board 340 at a position spaced apart from the signal pattern by a conductor to be grounded in contact with the shield wire.

The second signal pattern 310 is configured to be in contact with the signal line 110 exposed by laser processing and a plurality of small patterns are patterned on the printed circuit board 340 independently of each other by a predetermined distance, the second The ground pattern 320 is formed by patterning a long rectangular conductor formed on the printed circuit board 340 in contact with a shield wire exposed by laser processing and extending by a width formed by the coaxial cable unit 100.

The second soldering unit 330 is a soldering device such as a pulse heater to prevent the signal line and the shield wire from being separated from the second signal pattern and the second ground pattern by a small external force, similarly to the first soldering unit. In this case, the signal line and the shield wire are soldered to the second signal pattern 310 and the second ground pattern 320.

In addition, as shown in FIGS. 7A and 7B according to another embodiment of the present invention, the printed circuit board of the lifting unit and the main body unit when the lifting unit 300 is lowered so that the slide type mobile communication terminal is configured to be slimmer. The 240 and 340 may not be in contact with each other, and the coaxial cable unit 100 may be configured to be bent to the side.

In this case, the coaxial cable unit 100 is installed on the printed circuit boards 240 and 340 to be biased toward one side of the lifting unit 300 and the main body unit 200, and the lifting unit is in the middle of the coaxial cable unit 100. It is preferable that a taping unit 150 is formed to bundle the coaxial cable so that a plurality of coaxial cables can be bent simultaneously in a predetermined direction by an external force applied when the part is lowered.

Next, the operation of the printed circuit board connection structure of the slide type terminal using the coaxial cable according to the present invention configured as described above will be described.

First, the outer insulator, the shield wire, and the inner insulator are removed by a certain length by laser processing at both ends of the coaxial cable part to expose the shield wire, the inner insulator, and the signal line step by step. In addition, the exposed signal line 110 is positioned on the first signal pattern 210 and the second signal pattern 310 patterned on each of the printed circuit boards 240 and 340 of the main body and the lifting unit, and the exposed shield wire The 130 is positioned on the first ground pattern 220 and the second ground pattern 320 patterned on each of the printed circuit boards 240 and 340, and then shields the signal line 110 and the shield using a pulse heater. Each of the wires 130 is fixed by soldering.

As such, the signal lines and shield wires at both ends of the coaxial cable are directly soldered and fixed to the patterned first pattern portion and the second pattern portion on each of the printed circuit boards 240 and 340 of the main body and the lifting portion. It is possible to configure the coaxial cable as a data transmission means between the main body and the lifting unit without a special connector. 6A and 6B, when sliding the lifting unit 300 on the main body 200, the moving coaxial cable is excellent in flexibility and freely deformed, so that a continuous stimulus is applied to a specific site. It is firmly fixed to the printed circuit boards 240 and 340 of the main body and the lifting portion while preventing the falling.

In addition, according to another embodiment of the present invention, as shown in FIGS. 7A and 7B, when the lifting unit 300 descends, the coaxial cable, which is centrally bound by the taping unit 150, is simultaneously bent to one side and is elevated. When the lifting unit 300 is elevated, the bent portion is extended and connects the lifting unit and the printed circuit boards 240 and 340 of the main unit. As such, when the coaxial cable is bent to one side, the coaxial cable does not overlap vertically, and thus the mobile communication terminal can be configured more slim.

The present invention is not limited to the technical spirit of the specific embodiments or drawings described above, without having to leave the gist of the present invention claimed in the utility model registration claims without having ordinary knowledge in the technical field to which the present invention belongs. Anyone can make various modifications, as well as such changes are within the scope of the present invention.

The peculiar effect of the present invention is that the data transmission signal line of the coaxial cable and the shielding shield wire are directly soldered and fixed to the pattern portion formed directly on the printed circuit board of the display means sliding and vertically moving and the main body part. The coaxial cable is fixed to the elevating part and the main part of the printed circuit board without using a special connector, which simplifies the manufacturing process, reduces the production cost, and is suitable for mass production.

Another effect of the present invention is that it is not easily damaged by the folding and unfolding of the coaxial cable that is repeated when sliding and moving up and down by connecting the elevating unit and the main body with a coaxial cable having excellent flexibility and shape deformation.

1 is an overall plan view of a printed circuit board connection structure of a slide type terminal using a coaxial cable according to the present invention;

2 is an enlarged plan view of a printed circuit board connection structure of a slide type terminal using a coaxial cable according to the present invention;

3 is a perspective view of a coaxial cable according to the present invention;

4 is a plan view of the pattern portion according to the present invention;

5A is a cross-sectional view taken along line A-A of FIG. 1;

5B is a cross-sectional view taken along line B-B of FIG. 1;

6a and 6b is an embodiment showing a state before and after sliding in accordance with the present invention,

7a and 7b is an embodiment showing a state before and after sliding of another embodiment according to the present invention.

<Description of the symbols for the main parts of the drawings>

100-coaxial cable section 110-signal line

120-Internal Insulator 130-Shield Wire

140-External insulator 150-Taping part

200-main body 210-first signal pattern

220-First ground pattern 230-First soldering part

240-Main part printed circuit board 300-Lifting part

310-second signal pattern 320-second ground pattern

330-Second soldering section 340-Lifting section printed circuit board

Claims (4)

A coaxial cable part including a signal line for transmitting data, an inner insulator surrounding the signal line, a shield wire surrounding the inner insulator, and an outer insulator surrounding the shield wire, and repeating folding and unfolding when sliding; A first pattern portion directly patterned on a printed circuit board comprising a first signal pattern and a first ground pattern that are in contact with a shielded wire and a signal line laser-processed at one end of the coaxial cable portion, and a direct signal line on the first pattern portion A main body part including a first soldering part for soldering and fixing the shield wire; And A second pattern part which is slid on the main body part, and comprises a second signal pattern and a second ground pattern which are in contact with the laser-processed signal line and the shield wire at the other end of the coaxial cable part and patterned directly on the printed circuit board; 2. A printed circuit board connection structure of a slide type terminal using a coaxial cable, comprising: a lifting unit including a second soldering unit for soldering and fixing a signal line and a shield wire directly on two pattern units. The method of claim 1, The first signal pattern and the second signal pattern are patterned independently of each other by a plurality of small patterns spaced apart from each other by a predetermined distance, and the first ground pattern and the second ground pattern are respectively formed in the first signal pattern and the second signal pattern. A printed circuit board connection structure of a slide type terminal using a coaxial cable, characterized by being patterned into a long rectangular shape spaced apart from a certain distance. The method according to claim 1 or 2, And both ends of the coaxial cable are laser-processed so that the shield wire, the internal insulator, and the signal line are exposed to the outside stepwise by a predetermined length. The method according to claim 1 or 2, The coaxial cable unit is a printed circuit board connection structure of a slide type terminal using a coaxial cable, characterized in that further comprising a taping unit for binding and fixing a plurality of coaxial cables, so as to be bent simultaneously to the side when the lifting unit is sliding.