KR101285689B1 - Impedance matching and one electromagnetic shielding type flexible flat cable and the manufacturing method - Google Patents

Abstract

PURPOSE: A flexible multicore cable with an integrated impedance matching and electromagnetic shielding function and a manufacturing method thereof are provided to reduce the number of processes by using one related process. CONSTITUTION: A conductor (230) is drawn out from each bobbin. An upper insulating film (210) and a lower insulating film (220) are drawn out. The upper film and the lower film are wound around each winding roll. A window is processed on the upper insulating film and the lower insulating film at a constant interval. The upper insulating film and the lower insulating film are attached with the conductor.

Description

Impedance matching and one electromagnetic shielding type flexible flat cable and the manufacturing method

The present invention relates to an impedance matching and electromagnetic shielding integrated flexible multi-core cable and a method of manufacturing the same, and more specifically, to impedance impedance and The present invention relates to an impedance matching and electromagnetic shielding-integrated flexible multi-core cable and a method of manufacturing the same, which can reduce electromagnetic wave shielding and reduce manufacturing costs due to reduction of manufacturing processes.

In general, all data is transmitted as an electrical signal in a digital home appliance, and in particular, a high-performance digital home appliance requires a system capable of effectively transferring a large amount of data between various components or between various devices without losing information.

As such, since signal transmission performance is directly related to the performance of the product, efforts to improve the performance of the data transmission system have been focused on the digital home appliances, and in order to improve the performance of the digital home appliances, A new interface technology is required along with the high frequency of the use frequency to realize the high speed of the signal transmission.

In this context, the use of low voltages can reduce power consumption, enable high-speed transmission, and have long transmission distances. Low Voltage Differential Signaling (LVDS) solutions are widely used.

The low voltage differential signal (LVDS) refers to a general interface standard for high speed data transmission, and is applied to various fields including a data transmission system of a digital device.

In particular, such a low voltage differential signal solution is mainly used for high-speed transmission of a large amount of data in a system of a digital device, and in a digital device such as a display device, a flexible print circuit (FPC) is used as a transmission medium for data transmission. Flexible Flat Cables (FFCs), which are equal in ductility and transmission characteristics, and have low manufacturing costs, are used to achieve low-voltage differential signaling solutions.

Conventional flat EMI cables for EMI-reducing LVDS include a composite magnetic layer coated with magnetic powder therein, and a metal shield material connected to the conductor and the upper and lower insulators clamped on the upper and lower portions of the conductor and the ground terminal. It can be configured to include, and is configured to form a composite magnetic material layer is applied to the magnetic powder inside the metal shielding material.

However, the above-described conventional flat cable for low voltage differential signal, because it is reflected by the electromagnetic wave does not absorb the signal transmission, due to degradation of insertion loss, cross talk, and return loss. Due to poor signal transmission, there was a problem that can not be used at high speeds over 3Gbps.

In view of this point, the patent application No. 10-2011-0015674 has been filed a flexible flat cable for low voltage differential signal.

Looking at the conventional low-voltage differential signal flexible flat cable, a low-voltage differential signal flexible flat cable, the upper and lower insulating film and the upper and lower insulating film between the upper and lower insulating film one at a regular interval from each other to be exposed to the outside. A plurality of conductors including ground lines and signal lines are arranged to be thermally fused and fixed through a heat welding apparatus, and a dielectric adhesive bonding member is formed on both sides of the upper insulating film or the lower insulating film or the upper and lower insulating films. A dielectric layer comprising pore type silica or a pore type silica organic polymer coated with calcium carbonate or an organic polymer so as to achieve low loss characteristic impedance during signal transmission, and absorbing electromagnetic waves generated when the signal is applied to the dielectric layer. Electromagnetic wave absorption layer provided to the, and the tram Comprises an electrically conductive metal member provided is adhered to the insulating member and the insulating member for the adhesive binding material which is provided on an upper surface of the insulating member is provided with heat-sealed to the top surface of the absorbent layer to be isolated as a medium.

However, in the conventional general low voltage differential signal flexible flat cable made as described above, after manufacturing the low voltage differential signal flexible flat cable as described above, one or both sides of the manufactured low voltage differential signal flexible flat cable, that is, the upper insulating film or the lower insulating film Alternatively, the bar is manufactured by attaching an electromagnetic wave absorbing layer to the upper and lower insulating films, and thus, a manufacturing cost increases due to a complicated process for manufacturing a flexible flat cable for low voltage differential signal.

Patent Application No. 10-2011-0015674, filed date; February 22, 2011 Title of the Invention: Flexible flat cable for low voltage differential signal, FIG.

Accordingly, the present invention has been made to solve the above-described problems, by being able to manufacture an integrated flexible multi-core cable capable of impedance matching and electromagnetic shielding through a series of processes, it is possible to manufacture impedance matching and electromagnetic shielding as well as to manufacture It is an object of the present invention to provide an impedance matching and electromagnetic shielding-integrated flexible multi-core cable and a method of manufacturing the same, so that the manufacturing cost can be reduced by reducing the process.

Other objects of the present invention will become apparent as the description proceeds.

The present invention for achieving the above object, in the method of manufacturing a flexible multi-core cable integrated impedance matching and electromagnetic shielding, each bobbin corresponding to driving by the control unit of the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus Impedance produced through the step of withdrawing the conductor wound on the upper insulation film wound on each winding roll to cover the upper and lower surfaces of the conductor drawn by the step and the impedance matching and electromagnetic shielding integral insulation film manufacturing apparatus The step of drawing the matching and electromagnetic shielding integral insulating film, respectively, and processing the window at regular intervals through the molding die for the conductor exposure to the upper insulating film and the impedance matching and electromagnetic shielding integral insulating film drawn by the step; By the above steps, windows are formed at regular intervals. It was passed through a pair of heating roller with a transmission upper insulating film and an impedance matching and electromagnetic wave-shielding integral conductor and insulating film characterized by comprising an attaching with the application of heat.

In addition, it is characterized in that it is further provided with a step of rolling with a pair of rolling roller press which one is movable up and down so as to form a thin thickness of a portion of the conductor being drawn out by the above-mentioned step.

In addition, another object of the present invention for achieving the above object is, in the impedance matching and electromagnetic shielding-integrated flexible multi-core cable, each of the upper and lower adhesives are applied to each surface, either one or both of the impedance matching and electromagnetic shielding The upper and lower insulating film is manufactured and provided as a single body and the upper and lower insulating films are arranged at regular intervals between the upper and lower insulating films, and fixed by heating and pressing by a heating roller, and both ends of the plurality of conductors are provided to be exposed. Characterized in that the made up.

In addition, the bottom surface of the exposed conductor is characterized in that the short prevention film is further provided so as to prevent the occurrence of a short of the exposed conductor by being partially covered and fixed to the lower insulating film.

As described above, according to the impedance matching and electromagnetic shielding-integrated flexible multi-core cable according to the present invention and a method for manufacturing the same, impedance matching and electromagnetic shielding are possible, and the manufacturing cost can be reduced by reducing the manufacturing process. Since the impedance matching and electromagnetic shielding integrated flexible multicore cable is manufactured by a series of processes, the defect rate may be reduced when the impedance matching and the electromagnetic shielding integrated flexible multicore cable are manufactured.

1 is a flowchart illustrating a method of manufacturing impedance matching and electromagnetic shielding integrated flexible multi-core cable according to the present invention.
2 is a process chart for explaining a method for manufacturing impedance matching and electromagnetic shielding integrated flexible multi-core cable according to the present invention.
3 is a view showing another impedance matching and electromagnetic shielding integrated flexible multi-core cable according to the present invention.

Hereinafter, an embodiment of the impedance matching and electromagnetic shielding-integrated flexible multi-core cable according to the present invention and a manufacturing method thereof will be described in detail.

First, it should be noted that, in the drawings, the same components or parts have the same reference numerals as much as possible. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the gist of the invention.

As shown in the drawing, the method of manufacturing the impedance matching and electromagnetic shielding integrated flexible multi-core cable includes the respective bobbins corresponding to driving by the control unit (not shown) of the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10. Winding the conductors 230 wound on the (11) (S110) and the respective winding rolls (14, 15) to cover the upper and lower surfaces of the conductor 230, which is drawn out by the step (S110) Drawing the upper insulating film 210 and the lower insulating film 220 (hereinafter, collectively referred to as lower film) capable of impedance matching and electromagnetic shielding manufactured through an impedance matching and electromagnetic shielding integrated insulating film manufacturing apparatus ( S120 and the upper insulating film 210 and the lower insulating film 220 drawn out by the step S120, respectively, through the molding dies 18 and 18 'for exposing the conductor to the window at regular intervals ( Omit reference numerals) The step S130, and the upper insulating film 210 and the lower insulating film 220 to be transported while the window is formed at a predetermined interval by the step (S130) together with a pair of heating rollers (23) (23) Passing through and attaching while applying heat (S140) is made.

In addition, the step (S115) of rolling out a pair of rolling roller press 13 which is movable up and down so as to form a thin thickness of a portion of the conductor 230 being drawn out and transported by the step (S110) (S115) Is further provided.

In addition, the shot preventing film 240 from the shot preventing film winding unit 19 to prevent the short of the exposed conductor 230 is attached to the window of the lower insulating film 220 formed by the step (S130). The drawing and attaching step (S150) is further provided.

The reinforcing film from the reinforcing film winding part 20 to reinforce the exposed portion of the conductor 230 attached to the other surface of the anti-short film attached to prevent the window of the lower insulating film 220 moving by the step (S150) ( 250 is drawn out and attached (S160) is further provided.

After the step of processing the window on the upper insulating film (16) (S130), one surface is attached to the upper surface of the exposed conductor 230 from the lifting prevention film winding unit 21 to prevent the conductor 230 is lifted up The lifting prevention film is taken out and attached (S170) is further provided.

One side is attached to the other surface of the lifting prevention film attached to the upper surface of the conductor 230 exposed by the step (S170) and the alignment film from the alignment film winding 22 to align the exposed conductor 230 ( 260 is drawn out and attached (S180) is further provided.

Here, in the step S120 of the upper insulating film and the impedance matching and electromagnetic shielding integrated lower insulating film, the impedance matching and electromagnetic shielding integral lower insulating film 220 of the impedance matching and electromagnetic shielding integral insulating film Manufacturing an insulating film by applying an insulating adhesive on one surface of the insulating film wound on the take-up roll by driving the take-out driving motor driven by the controller of the manufacturing apparatus (S121); The shielding insulating film and the metal of the thin film wound on the shielding insulating film winding roll and the metal film conductive material winding roll, respectively, to be able to shield the impedance matching and the electromagnetic waves by being attached to the other surface of the insulating film manufactured in step S121. While the film conductive material is drawn out by driving each driving motor, it is adhered through an adhesive to impede impedance matching and electromagnetic shielding. To prepare a step (S122), and in the aging room for 24 hours to 48 hours in the temperature range of 50 ℃ to 70 ℃ for stabilizing the adhesive included in the impedance matching and electromagnetic shielding film prepared by the step (S122) Pressurized rollers are interposed between the insulating film prepared by the step (S123) and the impedance matching and electromagnetic shielding film stabilized by the step (S123) and the insulating film prepared by the step (S121). It is produced by the step (S124) of manufacturing a film for impedance matching and electromagnetic shielding by passing.

In addition, after the impedance matching and electromagnetic shielding integral insulating film is prepared by the above step (S124) for 24 hours to 48 hours in the aging room having an internal temperature of 50 ℃ ~ 70 ℃ for the stabilization of the adhesive After the second stabilization of the adhesive (S125) is configured to ship the product.

In addition, in the step (S121) of manufacturing the insulating film, the insulating film wound on the take-up roll to correspond to the driving of the draw-out driving motor by the control unit of the manufacturing apparatus of the impedance matching and electromagnetic wave shield integrated insulating film. When the insulating film is drawn out from the take-up roll by the step S1211 and the step S1211, and transferred, the insulating film supplied from the insulating adhesive storage unit corresponds to the opening / closing valve being opened under the control of the controller. The adhesive is composed of a step (S1212) is applied to one surface of the insulating film.

In addition, the impedance matching and electromagnetic shielding film manufacturing step (S122) is wound on the insulating film winding roll for shielding and driving the driving motor by the control unit, the impedance matching and shielding insulating film is withdrawn (S1221) And, when the impedance matching and shielding insulating film is drawn out from the shielding insulating film winding roll by the step (S1221) and conveyed, the adhesive supplied from the adhesive storage unit to correspond to the opening and closing valve under the control of the control unit When the adhesive is applied to one surface of the impedance matching and shielding insulating film being transported by the step (S1222) and the transfer step by the step (S1222), wound on the metal film conductive material winding roll The thin film metal conductive material is drawn out and attached to the other side of the adhesive by the driving motor of the metal film conductive material withdrawing drive. Is composed of step S1223.

On the other hand, the impedance matching and electromagnetic shielding integrated flexible multi-core cable according to another embodiment of the present invention manufactured by the method of manufacturing a flexible shielding integrated electromagnetic wave shield, as shown in FIG. The lower adhesive is applied, respectively, one or both of the upper and lower insulating films (210,220) is made of a single body provided to enable impedance matching and electromagnetic shielding, and the constant between the upper and lower insulating films (210,220) Arranged at intervals and fixed by heating compression by a heating roller, the both ends include a plurality of conductors 230 provided to be exposed.

Here, the short prevention film 240 is further formed on the bottom surface of the exposed conductor 230 so as to prevent occurrence of a short of the exposed conductor 230 by being partially covered and fixed to the lower insulating film 220. It is provided.

In addition, one surface is fixed to include a part of the lower insulating film 220 on the other surface of the anti-short film 240 fixed to one surface of the conductor 230 exposed by being partially covered by the lower insulating film 220. The reinforcement film 250 is further provided to reinforce the conductor 230.

In addition, an alignment film 260 is further provided so that one surface is attached to one end of the upper surface of the exposed conductor 230 to align the exposed conductor 230.

In addition, between the upper surface of the exposed conductor 230 and the alignment film 260 may be configured to further attach the anti-lift film to prevent the lifting of the conductor 230.

In addition, the exposed conductor 230 is manufactured by the impedance matching and electromagnetic shielding integrated flexible multicore cable by the rolling roller press 13 of the apparatus 10 (see FIG. 2). Rolled to provide a thin thickness of the exposed conductor 230 at the time is provided.

The lower insulating film 220 is attached to the insulating film part 221 and one surface of the insulating film part 221 through an integrated adhesive 222 to form an impedance matching and electromagnetic shielding insulating film part ( 233, wherein the insulating film part 221 is an insulating film layer 221b and an adhesive 221a which is drawn to one surface of the insulating film layer 221b and is attached to the upper insulating film 210. The impedance matching and electromagnetic wave shielding insulating film part 223 is configured to be attached to the other surface of the insulating film part 221 through the integral adhesive agent 222, the insulating film layer for impedance matching and electromagnetic shielding. 2423a and a thin film metal conductive material layer 223c attached to the other surface of the insulating film layer 223a for impedance matching and electromagnetic shielding via an adhesive 223b to shield electromagnetic waves.

In order to manufacture the impedance matching and electromagnetic shielding integrated flexible multicore cable according to the present invention, the impedance matching and the electromagnetic shielding integrated flexible multicore cable according to the present invention are made as shown in FIGS. 1 and 2. First, by operating the control unit, the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10 is driven.

As described above, the conductor 230 wound around each bobbin 11 is drawn out by driving the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10, and the drawn conductor 230 is bobbin 11. Rolled at a predetermined interval by a pair of rolling roller press 13 installed in the front and driven by the control unit is moved.

As described above, the conductors 230 are rolled at regular intervals by the pair of rolling roller presses 13, and at the same time, the respective winding rolls 14 cover the upper and lower surfaces of the conductors 230 by the control of the control unit. The insulating film for impedance matching and electromagnetic shielding is attached to the upper insulating film 210, the insulating film portion 221, and one surface of the insulating film portion 221 by an integral adhesive 222 wound by Lower insulating films 220 composed of portions 233 are each drawn out.

When the upper insulating film 210 and the lower insulating film 220 are drawn out as described above, the upper mold insulating part 18 and 18 'for conductor exposure installed in front of each of the winding rolls 14 and 15 is driven. The window is processed at regular intervals on the 210 and the lower insulating film 220.

As described above, when the upper insulating film 210 and the lower insulating film 220 are transferred while the windows are processed at regular intervals, the conductor 230 exposed by being attached to the bottom surface of the window to form the lower insulating film 220 is blocked. The short prevention film 240 is pulled out from the short prevention film winding unit 19 so as to prevent the occurrence of a short.

When the short insulating film 240 is attached as described above and the lower insulating film 220 is transferred, the reinforcing film 250 is drawn out from the reinforcing film winding 20 to reinforce the exposed conductor 230. It is attached to the other surface of the film 240.

As such, when the conductor 210 is inserted and transported between the lower insulating film 220 to which the short prevention film 240 and the reinforcement film 250 are sequentially attached and the upper insulating film 210 to be transported while the window is processed, the upper A portion of the conductor 230 is exposed by the window formed on the insulating film 210 and the lower insulating film 220, and at this time, the alignment film from the alignment film winding 22 to align the exposed conductor 230. 260 is withdrawn and attached.

When the alignment film 260 is attached to the exposed upper surface of the conductor as described above, the upper insulating film 210 and the lower insulating film 220 together with the conductor 230, a pair of heating roller 23 By attaching while passing through heat, the manufacture of the impedance matching and electromagnetic shielding integrated flexible multicore cable is completed.

As such, the manufacturing process of the integrated flexible multi-core cable capable of impedance matching and electromagnetic shielding is completed through a series of processes, thereby shortening the manufacturing process.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be clear to those who have knowledge of.

200; Impedance Matching and Electromagnetic Shielding Integrated Flexible Multi-core Cable
210; Upper insulation film
220; Lower insulation film
230; Conductor

Claims (10)

In the method of manufacturing impedance matching and electromagnetic shielding integrated flexible multi-core cable,
A step (S110) of drawing out conductors 230 wound on the respective bobbins 11 so as to be driven by the controller control of the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10;
The upper insulating film 210 wound on each of the winding rolls 14 and 15 and the impedance matching and electromagnetic shielding integrated insulating film manufacturing apparatus to cover the upper and lower surfaces of the conductor 230 drawn out by the step (S110). A step of drawing out the impedance matching and electromagnetic shielding integral lower insulating film 220 manufactured through the step S120;
The windows are processed at regular intervals through the upper mold insulating portions 18 and 18 'for conductor exposure to the upper insulating film 210 and the impedance matching and electromagnetic shielding integrated lower insulating film 220 drawn by the step S120. Step (S130);
The upper insulating film 210 and the impedance matching and electromagnetic shielding integral lower insulating film 220 which are transferred while the windows are formed at predetermined intervals by the step S130 are connected to the pair of heating rollers 23 with the conductor 230. Including the step of applying heat while passing (S140),
The short-circuit prevention film winding unit 19 is prevented from being shorted to prevent the short-circuit of the exposed conductor 230 by being attached to the window of the impedance matching and the electromagnetic shielding integrated lower insulating film 220 formed by the step (S130). The method of manufacturing the impedance matching and electromagnetic shielding-integrated flexible multi-core cable, characterized in that the film 240 is further provided with a step (S150) attached to it.
The method of claim 1,
The step (S115) of rolling with a pair of rolling roller press 13, which is movable up and down, is further formed so as to form a thin thickness of a portion of the conductor 230 being transferred and transported by the step (S110). Impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing method characterized in that provided.
delete In the method of manufacturing impedance matching and electromagnetic shielding integrated flexible multi-core cable,
A step (S110) of drawing out conductors 230 wound on the respective bobbins 11 so as to be driven by the controller control of the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10;
The upper insulating film 210 wound on each of the winding rolls 14 and 15 and the impedance matching and electromagnetic shielding integrated insulating film manufacturing apparatus to cover the upper and lower surfaces of the conductor 230 drawn out by the step (S110). A step of drawing out the impedance matching and electromagnetic shielding integral lower insulating film 220 manufactured through the step S120;
The windows are processed at regular intervals through the upper mold insulating portions 18 and 18 'for conductor exposure to the upper insulating film 210 and the impedance matching and electromagnetic shielding integrated lower insulating film 220 drawn by the step S120. Step (S130);
The upper insulating film 210 and the impedance matching and electromagnetic shielding integral lower insulating film 220 which are transferred while the windows are formed at predetermined intervals by the step S130 are connected to the pair of heating rollers 23 with the conductor 230. Including the step of applying heat while passing (S140),
The short-circuit prevention film winding unit 19 is prevented from being shorted to prevent the short-circuit of the exposed conductor 230 by being attached to the window of the impedance matching and the electromagnetic shielding integrated lower insulating film 220 formed by the step (S130). The film 240 is taken out and attached (S150),
The reinforcing film is attached to the other surface of the short prevention film 240 attached to the window to prevent the impedance matching and the electromagnetic shielding integrated lower insulating film 220 moving by the step (S150). The method of manufacturing an impedance matching and electromagnetic shielding-integrated flexible multi-core cable, characterized in that the step (S160) is further provided to the reinforcement film 250 is drawn out from the winding unit (20).
In the method of manufacturing impedance matching and electromagnetic shielding integrated flexible multi-core cable,
A step (S110) of drawing out conductors 230 wound on the respective bobbins 11 so as to be driven by the controller control of the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufacturing apparatus 10;
The upper insulating film 210 wound on each of the winding rolls 14 and 15 and the impedance matching and electromagnetic shielding integrated insulating film manufacturing apparatus to cover the upper and lower surfaces of the conductor 230 drawn out by the step (S110). A step of drawing out the impedance matching and electromagnetic shielding integral lower insulating film 220 manufactured through the step S120;
The windows are processed at regular intervals through the upper mold insulating portions 18 and 18 'for conductor exposure to the upper insulating film 210 and the impedance matching and electromagnetic shielding integrated lower insulating film 220 drawn by the step S120. Step (S130);
The upper insulating film 210 and the impedance matching and electromagnetic shielding integral lower insulating film 220 which are transferred while the windows are formed at predetermined intervals by the step S130 are connected to the pair of heating rollers 23 with the conductor 230. Including the step of applying heat while passing (S140),
After the window processing step (S130), one surface is attached to the upper surface of the exposed conductor 230 to remove the lifting film from the lifting film winding unit 21 to prevent the lifting of the conductor 230 Step S170 and the alignment film winding part 22 to align the exposed conductor 230 by attaching one surface to the other surface of the lifting prevention film attached to the upper surface of the conductor 230 exposed by the step S170. The method of manufacturing an impedance matching and electromagnetic shielding-integrated flexible multi-core cable, characterized in that the step (S180) is further provided to take out and attach the alignment film (260).
In the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufactured by the manufacturing method of any one of claims 1, 2, 4 and 5,
Top and bottom adhesive is applied to each side, respectively, one or both of the upper and lower insulating films (210,220) are provided and manufactured as a single body to enable impedance matching and electromagnetic shielding;
The upper and lower insulating films 210 and 220 are arranged at regular intervals from each other and are fixed by heating and pressing by a heating roller, and include a plurality of conductors 230 provided at both ends thereof.
On the bottom surface of the exposed conductor 230, a short prevention film 240 is further provided to prevent the short circuit of the exposed conductor 230 by being partially covered and fixed to the lower insulating film 220. Flexible multi-core cable with integrated impedance matching and electromagnetic shielding.
delete In the impedance matching and electromagnetic shielding integrated flexible multi-core cable manufactured by the manufacturing method of any one of claims 1, 2, 4 and 5,
Top and bottom adhesive is applied to each side, respectively, one or both of the upper and lower insulating films (210,220) are provided and manufactured as a single body to enable impedance matching and electromagnetic shielding;
The upper and lower insulating films 210 and 220 are arranged at regular intervals from each other and are fixed by heating and pressing by a heating roller, and include a plurality of conductors 230 provided at both ends thereof.
The exposed part of the lower insulating film 220 is fixed to include a part of the lower insulating film 220 on the other surface of the anti-short film 240 fixed to one surface of the conductor 230 exposed by being partially covered by the lower insulating film 220. Impedance matching and electromagnetic shielding integrated flexible multi-core cable, characterized in that the reinforcement film 250 is further provided to reinforce (230).
9. The method of claim 8,
An impedance matching and electromagnetic shielding integrated flexible multi-core cable, characterized in that the alignment film 260 is further provided so that one surface is attached to one end of the upper surface of the exposed conductor 230 to align the exposed conductor 230.
The method according to claim 6,
The exposed conductor 230 is a conductor 230 exposed during the manufacture of the impedance matching and electromagnetic shielding integrated flexible multi-core cable by the rolling roller press 13 of the apparatus 10 for manufacturing flexible shielding integrated electromagnetic wave. Impedance matching and electromagnetic shielding integrated flexible multi-core cable, characterized in that the roll provided so as to implement a thin thickness.

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