KR100913505B1 - Flaxible flat cable for optical disk drive - Google Patents

Abstract

A flexible multicore cable for an optical drive is provided to perform an accurate soldering by arranging a plurality of flat conductor wires through a reinforcing film or an arranging film. A flexible multicore cable comprises a top film, a bottom film, and a plurality of flat conductor wires(100c). A plurality of flat conductor wires is interposed between the top film and the bottom film. The flexible multicore cable includes a fixing part(110) and a moving part(130). The fixing part is directly connected to a PCB of a main body of an optical drive. The moving part is connected to an interface part of a tray. An arranging film(150) is attached to an end part of a bottom surface of the flat conductor wire of the fixing part. A reinforcing film(170) is attached to an end part of a top surface of the top film of the moving part.

Description

Flexible Multi-Cable Cable for Optical Drives {Flaxible Flat Cable For Optical Disk Drive}

The present invention relates to a flexible multi-core cable for an optical drive, and more particularly, by enabling the accurate soldering through the alignment of a plurality of flat conductor wires by excluding the connector used for the connection installation of the flexible multi-core cable, The present invention relates to a flexible multi-core cable for an optical drive that can reduce the defect rate caused by connecting and installing a flexible multi-core cable.

As is well known, the flexible flat cable (FFC) forms a heat-resistant plastic film such as polyester (PET) or polyamide (PI), which is a flexible material, on the upper and lower sides, that is, on both sides. It is manufactured through a thermal fusion apparatus through a plurality of flat conductor wires (copper) arranged to have a constant distance between the films.

Accordingly, the flexible multi-core cable has excellent flexibility in bending, overlapping, folding, curling, twisting, etc., by a heat-resistant plastic film, which requires effective use of space and three-dimensional wiring. Widely used in narrow spaces such as the head portion of the.

Such flexible multi-core cables are produced by thermal bonding or heat fusion of a plurality of flat conductor wires arranged at regular intervals between two films through a manufacturing apparatus.

The flexible multi-core cable manufactured as described above is provided with a connector at both ends to connect to the interface of the optical drive.

That is, the flexible multi-core cable manufactured through the manufacturing apparatus is slit through the slitting means provided in the manufacturing apparatus and is provided in a wound state on a winding roll, and then the flexible multi-core cable completed as a product through several post-processes. The sheet is cut into pieces through a cutter while being taken out of the winding roll.

After forming the engaging portions for fixedly connecting the connector at both ends of the flexible multi-core cable cut into a sheet as described above, it is possible to be connected to the interface of the optical drive by fixing the connector to the engaging portion.

1 is a view showing a state in which the conventional general flexible multi-core cable described above is installed in an optical drive of a data storage device (for example, a CD-ROM of a notebook computer).

As shown in the drawing, the flexible multi-core cable 11 installed in the optical drive main body 10 has a middle so that electrical and control signals can be connected in a narrow space such as a CD-ROM without contact with other components. After folding the part, one end slides in and out of the interface portion 13 of the fixed plate 12 fixed to the main body (not shown) of the computer, and the other end of the fixed plate 12 corresponds to the user's operation. It is largely divided into a fixing part 15 and a moving part 16 which are connected to the interface part (not shown) of the tray 14 which is possibly provided through the connectors 15a and 16a, respectively.

However, in the case of the flexible multi-core cable used for the optical drive as described above, since the connector is applied to both ends of the flexible multi-core cable in order to interconnect the interface portion of the fixing plate and the interface portion of the tray, Multi-core cables can be fastened correctly, but the cost of the product is increased due to the use of the connector, and each interface must be provided to correspond to the connector.

In addition, since the hook portion must be formed to fix the connector at both ends of the flexible multi-core cable, the work is very cumbersome and there is a high possibility that the defective rate of the product is increased due to the bias of the hook portion in the process of forming the hook portion. This will cause delays in the continuous production of flexible multicore cables.

Accordingly, the present invention has been made to solve the above-described problems, a plurality of flat angles by attaching the alignment film or reinforcement film to align a plurality of flat conductor wires at both ends of the flexible multi-core cable It is an object of the present invention to provide a flexible multi-core cable for an optical drive that enables accurate soldering through alignment of the conductor wires, thereby reducing the manufacturing cost of the flexible multi-core cable.

In addition, another object of the present invention devised to solve the above-described problems, by attaching a film or reinforcing film for alignment to align a plurality of flat conductor wires at both ends of the flexible multi-core cable The present invention provides a flexible multi-core cable for an optical drive that enables accurate soldering by aligning the flat conductor wires of the wire to reduce the defect rate caused by the connection of the flexible multi-core cable.

The present invention for achieving the above object, the connection is directly connected by soldering with the PCB (PCB) provided in the optical drive body on the basis of the overlapping center portion between a plurality of flat conductor wires between the upper film and the lower fill A flexible multi-core cable for an optical drive, wherein each end is divided into a movable part that can be connected and connected to an interface part of a tray that is slide-in and retractably provided corresponding to a user's operation. The bottom of the exposed flat conductor wire is simultaneously held and aligned by holding the plurality of flat conductor wires at the bottom end of the exposed flat conductor wire by removing the ends of the top and bottom films to secure the contact. The alignment film for attaching directly to the pattern by soldering is attached, the One end of the eastern part exposes one side of a plurality of flat conductor wires by removing an end of the lower film to secure a contact, and a reinforcement film is attached to the top end of the top film to reinforce the strength of the end and to support the flat conductor wire. Characterized in that the attachment is made.

Here, the plurality of flat conductor wires are easily separated from the alignment film on the bottom surface of the plurality of flat conductor wires whose one surface is exposed by the alignment film attached to one end of the fixing part of the flexible multi-core cable, or more firmly without changing the gap. It is characterized in that the reinforcing alignment film is further attached to be arranged.

According to the flexible multi-core cable for an optical drive according to the present invention as described above, in the case of a moving part that repeats repeatedly bending (bending motion) in accordance with the opening and closing of the tray is slide-in, retractable to correspond to the user's operation Even if a connector is inevitably provided for the connection of the flexible multi-core cable, the fixing part can be soldered and connected as it is to the PCB pattern of the main body, thereby reducing the number of connectors. Accurate soldering is possible as the flat conductor wire exposed by the film is bent and kept unchanged, and the alignment film allows the number of flat conductor wires and the number of flat conductor wires as compared with conventional flexible multicore cables. The size of the flexible multicore cable without being restricted by the width It can be minimized, and there is an effect that the installation of the connector to form a short length of the flexible multicore cable connecting portion according to baejedoem.

Furthermore, according to the flexible multi-core cable for an optical drive according to the present invention, even in the moving portion connected to the tray, the reinforcement film is applied to the end to easily form a catch for connector coupling, the reinforcement film is coupled to the connector Since the opposite side of the conductor can be stably supported, the connector can be installed more tightly and stably.

Hereinafter, an embodiment of a flexible multi-core cable for an optical drive according to the present invention will be described in detail.

First, it should be noted that in the drawings, the same components or parts denote the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

2 is a plan view showing a state in which a flexible multi-core cable for an optical drive is installed in an optical drive, and FIG. 3 is a state in which a flexible multi-core cable for an optical drive is installed in an optical drive. 4 is a plan view showing a flexible multi-core cable for an optical drive according to the present invention.

As shown in the flexible multi-core cable 100 for an optical drive according to the present invention, a plurality of flat conductor wires (100c) is interposed between the upper film (100a) and the lower film (100b) on the basis of the overlapping portion PCB (B) provided in the optical drive main body (A) and the connectable fixing part 110 which is directly connected by soldering, and the tray (C) provided to slide in, out and out corresponding to the user's operation Each end is largely divided into a movable unit 130 which can be connected to the interface unit D of FIG. 5 (see FIG. 5).

That is, the flexible multi-core cable 100 for the optical drive according to the present invention, one end of the fixing portion 110 is exposed by removing the end of the upper and lower films (100a, 100b) to secure the contact. Simultaneously holding and aligning the plurality of flat conductor wires 100c at the bottom end of the flat conductor wire 100c to connect the bottom of the exposed flat conductor wire 100c to the PCB (B) pattern of the main body A. An alignment film 150 for attaching directly by soldering is attached, and one end of the moving part 130 is removed by a plurality of flat conductor wires 100c by removing an end of the lower film 100b to secure a contact point. One surface is exposed, the reinforcement film 170 is attached to the upper end of the upper film 100a to support the strength of the end and the flat conductor wire 100c.

Hereinafter, the flexible multi-core cable for an optical drive according to the present invention will be described in detail.

In the flexible multi-core cable 100 for an optical drive according to the present invention, a plurality of flat conductor wires 100c are longitudinally arranged at regular intervals between the upper film 100a and the lower film 100b to be continuously heat-sealed. A plurality of flat conductor wires 100c exposed to the PCB B of the optical drive body A after being cut to a length usable for the body A of the optical dred, as shown in FIGS. 4 and 5. Moving part 130 having a connector (not shown) installed at an end thereof so that the fixing part 110 directly connected by soldering and the interface part D provided in the tray C of the optical drive body A are installed. Is divided based on the overlapping portion (omitted reference numeral) overlapping the center portion.

In addition, the bottom surface of the lower film 100b of the fixing unit 110 is provided with a double-sided tape 190 is attached to fix the fixing unit 110 to the optical drive body (A).

In addition, one end of the moving part 130 of the flexible multi-core cable 100 connected to the tray (C) side is exposed flat conductor wire (100c) by removing the end of the lower film (100b) to secure contact The reinforcement film 170 is attached to the upper end of the upper film 100a for strength reinforcement and support.

In addition, one end of the fixing part 110 of the flexible multi-core cable 100 is connected to the optical drive body (A) side to remove the ends of the upper film (100a) and the lower film (100b) to secure contact. The bottom surface of the exposed flat conductor wire 100c is simultaneously held by soldering the PCB (B) pattern of the optical drive body A by simultaneously holding the flat conductor wire 100c on the bottom of the end of the flat conductor wire 100c exposed by the same. The alignment film 150 is attached to be connected directly.

Meanwhile, at one end of the fixing part 110 of the flexible multi-core cable 100 for an optical drive according to the present invention, a plurality of exposed flat conductor wires 100c are simultaneously held as shown in FIGS. 4 and 5. The alignment film 150 is attached to connect the upper surface of the exposed flat conductor wire 100c to the PCB (B) pattern of the optical drive body A by soldering, but is not limited thereto. As shown in FIG. 6, a plurality of flat conductor wires 100c 'having one surface exposed by an alignment film 150' attached to one end of the fixing part 110 'of the flexible multi-core cable 100' are illustrated. The reinforcing alignment film 1500 may be further attached to the upper surface so that the plurality of flat conductor wires 100c 'may be easily detached from the alignment film 150' or may be more firmly aligned without changing a gap.

Here, the alignment film 150 and the reinforcement alignment film 1500 attached to one end of the fixing parts 110 and 110 ′, that is, the bottom surface or the upper surface of the exposed plurality of flat conductor wires 100c and 100c ′ are respectively provided. In addition, the moving part 130 may be provided by attaching the same reinforcement film as the reinforcement film 170 attached to the upper surface end of the upper film 100a.

The installation of the flexible multi-core cable for an optical drive according to the present invention made as described above is a flat conductor wire having an upper surface exposed by attaching the alignment film 150 to the bottom end, as shown in FIGS. 2 to 5. The exposed flat conductor wire 100c portion of the fixing portion 110 having the (100c) is matched to correspond to the PCB (B) pattern of the optical drive body A, and then quickly soldered in the usual manner to obtain the high The government 110 is connected and connected.

As described above, when the exposed flat conductor wire 100c of the fixing part 110 is soldered to the PCB (B) pattern, the optical film is formed using the double-sided tape 190 bonded to the lower film 100b of the fixing part 110. Attaches and fixes to the drive body (A).

After fixing the fixing unit 110 to the optical drive main body (A), the moving unit that performs repeated bending (bending motion) to open and close the tray (C), which is in and out corresponding to the user's operation ( 130 is connected to the interface (D) of the tray (C).

That is, by fixing the connector to the reinforcement film 170 attached to the upper end of the upper film 100a of the moving part 130, and then connecting it to the interface portion (D) of the tray (C) Installation of the flexible multi-core cable 100 for an optical drive according to the present invention is completed.

When the flexible multi-core cable 100 for an optical drive according to the present invention made as described above is applied to an optical drive, in the case of the moving part 130 which repeatedly performs bending according to opening and closing of the tray C, for connection. Even if the connector is inevitably applied, the fixing part 110 can reduce the number of connectors due to being soldered and connected to the PCB (B) pattern of the optical drive body A as it is.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a view showing a state in which a conventional general flexible multi-core cable is installed in the optical drive of the data storage device

2 is a plan view showing a state in which a flexible multi-core cable for an optical drive according to the present invention is installed in an optical drive

Figure 3 is a side view showing a state in which the flexible multi-core cable for the optical drive installed in the optical drive according to the present invention

4 is a plan view showing a flexible multi-core cable for an optical drive according to the present invention.

5 is a side view showing a flexible multi-core cable for an optical drive according to the present invention.

6 is a side view showing another embodiment of a flexible multi-core cable for an optical drive according to the present invention;

* Description of the symbols for the main parts of the drawings *

100; Flexible multi-core cable for optical drive

110; Fixture

130; Moving parts

150; Alignment Film

170; Reinforcement film

190; Double-sided tape

Claims (3)

A plurality of flat conductor wires 100c are interposed between the upper film 100a and the lower film 100b and soldered to the PCB (B) provided in the optical drive body A based on the overlapping center portion. Directly connected to the movable connection unit 130 is connected to the fixed connection unit 110, each end is connected to the interface unit (D) of the tray (C) that is provided slide-in, retractable corresponding to the user's operation In most flexible multi-core cables for optical drives, One end of the fixing part 110 is a plurality of flat conductor wires 100c at the bottom end of the flat conductor wires 100c exposed by removing the ends of the upper and lower films 100a and 100b to secure the contact. The alignment film 150 for directly connecting the bottom surface of the exposed flat conductor wire 100c by soldering to the PCB (B) pattern of the main body (A) by soldering is attached, One end of the moving part 130 is exposed to one surface of the plurality of flat conductor wires 100c by removing the ends of the lower film 100b to secure the contact point, but the strength of the end and the flat conductor wires 100c are exposed. The flexible multi-core cable for an optical drive, characterized in that the reinforcement film 170 is attached to the upper end of the upper film (100a) to support the. The method of claim 1, The alignment film 150 is disposed on an upper surface of the plurality of flat conductor wires 100c 'exposed on one surface by an alignment film 150' attached to one end of the fixing portion 110 'of the flexible multi-core cable 100'. A plurality of flat conductor wires (100c ') from the') flexible multi-core cable for optical drive, characterized in that the reinforcement alignment film (1500) is further attached to be able to be more firmly aligned without changing the gap. The method according to claim 1 or 2, The alignment film 150 and the reinforcement alignment film 1500 attached to the bottom surface or the top surface of the plurality of flat conductor wires 100c and 100c 'exposed at one end of the fixing portions 110 and 110' are moved. The flexible multi-core cable for an optical drive, characterized in that attached to the reinforcement film and the same as the reinforcement film 170 attached to the upper end of the upper film (100a) of the unit 130.

Images