KR20230066912A - Cable shielding method using graphite sheet and graphite attached fiber - Google Patents

Abstract

A cable shielding method using a graphite sheet according to the present invention comprises: a first step of preparing a graphite sheet; and a second step of shielding with a shielding material made by rolling the graphite sheet around the signal line of the shielded cable, or cutting the graphite sheet and wrapping it diagonally around the signal line of the shielded cable, or shielding with a shielding material made by slitting the graphite sheet and braiding it to the signal line of the shielding cable. Using the present invention, the weight of the shielded cable can be reduced by using light graphite sheet or graphite-attached fiber as the shielding material instead of copper, steel, or aluminum. In addition, due to the excellent conductivity of graphite, it is possible to make a shielded cable with an excellent shielding effect of more than 60dB. In addition, due to the thin thickness of the graphite sheet or graphite-attached fiber of less than 25 ㎛, it is possible to make a shielding material that does not reduce the flexibility of the shielded cable.

Description

Cable shielding method using graphite sheet and graphite attached fiber

The present invention relates to a cable shielding method using a graphite sheet and graphite-adhered fiber.

Shielding is a method for quickly and reliably exporting data by wrapping the signal line of a shielded cable with aluminum (copper) to suppress external noise and internally generated noise.

Shielding is mainly done in three ways: braided shield, spiral shield, and aluminum wrap (tape) shield.

Braided shield is a method of shielding by tightly weaving copper or steel wire in the form of a net.

Spiral shield is similar to braided shielding, but it is shielded by winding a large number of thin copper wires in one direction rather than a grid.

Aluminum wrap (tape) shielding is a method of shielding by wrapping aluminum tape around the signal line.

Shielding using such a metal material has an excellent shielding effect, but increases the weight of the shielded cable and acts as a factor in reducing the flexibility of the shielded cable.

Korea Patent Publication (10-2015-0091461)

An object of the present invention is to provide a cable shielding method using a graphite sheet and a graphite-adhered fiber that can solve the above problems.

A cable shielding method using a graphite sheet for achieving the above object,

A first step of preparing a graphite sheet; and

The graphite sheet is shielded with a shielding material manufactured by wrapping the graphite sheet around the signal line of the shielded cable, or the graphite sheet is cut and shielded with a shielding material made by winding the graphite sheet diagonally around the signal line of the shielded cable, or the graphite sheet is slit to cover the signal line of the shielded cable It is characterized in that it comprises a second step of shielding with a shielding material made by braiding.

In addition, the above purpose,

A first step of preparing core fibers;

A second step of putting the core fiber into an impregnation tank containing a binder and graphite powder, covering the outer circumferential surface of the core fiber with the binder and graphite powder, and then taking it out of the impregnation tank;

a third step of drying and evaporating the binder deposited on the core fibers taken out of the impregnation tank and leaving only the graphite powder on the outer circumferential surface of the core fibers to form graphite-adhered fibers; and

It is achieved by a cable shielding method using graphite-adhered fibers comprising a fourth step of shielding the graphite-adhered fibers with a shielding material made by braiding the signal lines of the shielding cable.

In addition, the above purpose,

A first step of preparing core fibers;

A second step of putting the core fiber into an impregnation tank containing a binder, covering the outer circumferential surface of the core fiber with the binder, and then taking the core fiber out of the impregnation tank;

a third step of discharging graphite powder to the outer circumferential surface of the core fiber with the binder coming out of the impregnation tank to attach the graphite powder to the outer circumferential surface of the core fiber, and recovering the remaining graphite powder;

a fourth step of drying and evaporating the binder deposited on the core fiber and leaving only the graphite powder on the outer circumferential surface of the core fiber to form a graphite-adhered fiber; and

It is achieved by a cable shielding method using graphite-adhered fibers comprising a fifth step of shielding the graphite-adhered fibers with a shielding material made by braiding the signal lines of the shielding cable.

According to the present invention, the weight of a shielded cable can be reduced by using a lightweight graphite sheet or graphite-adhered fiber as a shielding material instead of copper, steel, or aluminum.

In addition, due to the excellent conductivity of the graphite sheet or the graphite-adhered fiber, a shielded cable having an excellent shielding effect of 60 dB or more can be made.

In addition, due to the thin thickness of the graphite sheet or the graphite-adhered fiber of 25 μm or less, a shielded cable that does not deteriorate in flexibility can be made.

1 is a flowchart illustrating a cable shielding method using a graphite sheet according to an embodiment of the present invention.
FIG. 2 is a view showing a state in which the shielded cable is shielded with the graphite sheet shown in FIG. 1. FIG. 2(a) is a state in which the graphite sheet is shielded with a shielding material manufactured by rolling the signal line of the shielded cable, FIG. 2(b) 2(c) is a diagram showing a state of shielding with a shielding material made by cutting a graphite sheet and winding it diagonally around the signal line of a shielded cable, and FIG. .
3 is a flowchart illustrating a cable shielding method using graphite-adhered fibers according to an embodiment of the present invention.
FIG. 4 is a view showing an apparatus for producing the graphite-adhered fiber shown in FIG. 3;
Fig. 5 is a longitudinal sectional view of graphite-adhered fibers.
6 is a flowchart illustrating a cable shielding method using graphite-adhered fibers according to another embodiment of the present invention.
FIG. 7 is a view showing an apparatus for producing the graphite-adhered fibers shown in FIG. 6;

Hereinafter, a cable shielding method using a graphite sheet according to an embodiment of the present invention will be described in detail.

As shown in FIG. 1, a cable shielding method using a graphite sheet according to an embodiment of the present invention,

A first step (S11) of preparing a graphite sheet; and

The graphite sheet is shielded with a shielding material manufactured by wrapping the graphite sheet around the signal line of the shielded cable, or the graphite sheet is cut and shielded with a shielding material made by winding the graphite sheet diagonally around the signal line of the shielded cable, or the graphite sheet is slit to cover the signal line of the shielded cable It consists of a second step (S12) of shielding with a shielding material made by braiding.

Hereinafter, the first step (S11) will be described.

A graphite sheet GS prepared as follows is prepared. The graphite sheet GS is manufactured in various ways.

[Graphite sheet manufacturing method 1]

Weave fibers with a carbon fraction of 90% or more. The woven fiber is carbonized, graphitized, and rolled to make a graphite sheet (GS).

[Graphite sheet manufacturing method 2]

The polyamic acid film is imidized at high temperature and stretched to form a polyimide film. A graphite sheet is made by carbonizing and graphitizing a polyimide film.

[Graphite sheet manufacturing method 3]

The polyamic acid film is chemically imidated and stretched to form a polyimide film. A graphite sheet (GS) is made by carbonizing and graphitizing a polyimide film.

division unit graphite sheet 1 graphite sheet 2 sheet thickness μm 17㎛ 25㎛ resistivity Ω 1.19x10 0.86x10 surface resistance Ω/cm2 ^{5.32x10-2 3.86x10-2} volume resistance Ωcm ^{9.05x10-5 9.64x10-5} conductivity S/cm 1.11x10 ⁴ 1.04x10 ⁴ tensile strength MPa 17.3 25.2 Electromagnetic shielding performance
(1.5 to 10 GHz range) dB Average 60.4 Average 61.1

[Physical properties of graphite sheet]

In general, the electromagnetic wave shielding performance required for industrial shielded cables is 20 to 40dB, and the electromagnetic wave shielding performance required for automotive shielded cables is 50dB. The graphite sheet (GS) has a high electromagnetic wave shielding level of 60.4~61.1 dB on average, so it can be used as an industrial shielded cable as well as a shielded cable for automobiles.

Hereinafter, the second step (S12) will be described.

As shown in FIG. 2, a shielded cable is composed of a conductor (1), an insulator (2), a shielding material (3), and a sheath (4). For convenience of explanation, the conductor 1 and the insulator 2 insulating the conductor 1 are collectively referred to as a “signal line”.

The shielding material 3 is made in three ways using the graphite sheet GS prepared in the first step S11.

[Shielding material manufacturing method 1]

As shown in FIG. 2(a), the shielding material 3 is manufactured by rolling the graphite sheet GS around the signal line of the shielded cable.

[Shielding material manufacturing method 2]

As shown in FIG. 2(b), the shielding material 3' is manufactured by cutting the graphite sheet GS and winding it obliquely around the signal line of the shielded cable.

[Shielding material manufacturing method 3]

As shown in FIG. 2(c), or by slitting the graphite sheet GS and braiding it to the signal line of the shielded cable, the shielding material 3" is manufactured.

Hereinafter, a cable shielding method using graphite-attached fibers according to an embodiment of the present invention will be described in detail. Figure 4 is basically referenced.

As shown in FIG. 3, the cable shielding method using graphite-attached fibers according to an embodiment of the present invention,

A first step of preparing core fibers (S21);

A second step (S22) of putting the core fiber into an impregnation tank containing a binder and graphite powder, covering the outer circumferential surface of the core fiber with the binder and graphite powder, and then taking it out of the impregnation tank;

A third step (S23) of drying and evaporating the binder on the core fibers taken out of the impregnation tank and leaving only the graphite powder on the outer circumferential surface of the core fibers to form graphite-adhered fibers; and

It consists of a fourth step (S24) of shielding with a shielding material made by braiding the graphite-attached fiber to the signal line of the shielding cable.

Hereinafter, the first step (S21) will be described.

A core fiber (OF), which will be the center of the graphite-attached fiber, is prepared.

As the core fiber (OF), various types of fibers such as carbon fiber, glass fiber, basalt fiber, aramid fiber, and nylon fiber may be used.

In addition, since the core fiber (OF) itself also has an electromagnetic wave shielding function, metal-coated carbon fiber may be used as the core fiber (OF). In metal-coated carbon fibers, the electromagnetic wave shielding performance can be easily adjusted by changing the type of metal (copper, silver, gold, etc.) coated on the carbon fibers.

Hereinafter, the second step (S22) will be described.

The core fiber (OF) is put into the impregnation tank 10 containing the binder (B) and the graphite powder (G), the outer peripheral surface of the core fiber (OF) is coated with the binder (B) and the graphite powder (G), and then the impregnation tank (10) Take it out.

Binder (B)

The binder (B) may be water, methyl ethyl ketone or the like.

Graphite powder (G)

The graphite powder (G) may be composed of natural graphite or expanded graphite.

In order to improve the dispersibility of the graphite powder (G) in the binder (B), the graphite powder (G) is preferably composed of expanded graphite having a larger interlayer distance than natural graphite.

dispersant

In order to prevent the graphite powder (G) from aggregating in the binder (B), a dispersant may be further added into the impregnation bath (10). Polyvinyl pyrrolidone may be used as a dispersing agent.

Impregnation Tank(10)

The impregnation bath 10 has a box shape with an open upper surface and an internal space.

The upper left and right surfaces of the impregnation tank 10 are provided with an entry port 11 through which the core fibers (OF) enter and an exit port 12 through which the core fibers (OF) exit.

A cover 13 for opening and closing the open upper surface is installed on the upper surface of the impregnation tank 10.

A guide roller 14 is provided inside the impregnation bath 10 . The guide roller 14 guides the core fibers OF.

A compression roller 15 is provided inside the impregnation bath 10 . The compression roller 15 compresses the core fiber (OF) coated with the binder (B) and the graphite powder (G). Due to this, while the core fibers (OF) pass through the impregnation bath 10, the graphite powder (G) can be firmly adhered to the outer circumferential surface of the core fibers (OF).

Hereinafter, the third step (S23) will be described.

The core fibers (OF) coming out of the impregnation bath 10 pass through the dryer 20. The dryer 20 dries and evaporates the binder (B) on the core fiber (OF). Then, as shown in FIG. 5, graphite-adhered fibers GF in which the graphite powder G is attached to the outer circumferential surface of the core fiber OF are formed. The graphite-adhered fiber GF is wound around the recovery roller R. To this end, the recovery roller R is rotated clockwise at constant speed by a motor (not shown).

dryer(20)

The dryer 20 may be variously configured with known technologies such as a body 21, a heating wire built into the body 21, and a surface heating element, so detailed descriptions thereof will be omitted.

On each of the left and right side surfaces of the body 21, an inlet 21a into which the core fiber (OF) to which graphite powder (G) is attached enters, and an outlet 22b through which the graphite-adhered fiber (GF) produced by drying the binder (B) comes out. is provided

Hereinafter, the fourth step (S24) will be described.

Unwind the graphite-adhered fiber (GF) wound around the recovery roller (R) and cut it to an appropriate length. Shield the signal line with a shielding material made by braiding graphite-attached fiber (GF) cut to an appropriate length on the signal line of the shielded cable.

Hereinafter, a cable shielding method using graphite-attached fibers according to another embodiment of the present invention will be described in detail. Figure 7 is basically referred to.

In this embodiment, the process of applying the binder (B) to the core fibers (OF) and the process of attaching the graphite powder (G) to the core fibers (OF) with the binder (B) are separated.

As shown in FIG. 6, a cable shielding method using graphite-attached fibers according to another embodiment of the present invention,

A first step of preparing core fibers (S31);

A second step (S32) of putting the core fiber into an impregnation tank containing a binder, covering the outer circumferential surface of the core fiber with the binder, and then taking the core fiber out of the impregnation tank;

A third step (S33) of discharging graphite powder to the outer circumferential surface of the core fiber coated with the binder coming out of the impregnation tank to attach the graphite powder to the outer circumferential surface of the core fiber, and recovering the remaining graphite powder;

A fourth step (S34) of drying and evaporating the binder and leaving only the graphite powder on the outer circumferential surface of the core fiber to form graphite-adhered fibers;

It is achieved by a cable shielding method using graphite-adhered fibers comprising a fifth step (S35) of shielding the graphite-adhered fibers with a shielding material made by braiding the signal lines of the shielding cable.

Hereinafter, the first step (S31) will be described.

A core fiber (OF), which will be the center of the graphite-attached fiber, is prepared.

Hereinafter, the second step (S32) will be described.

The core fiber (OF) is put into the impregnation tank 10 containing the binder (B), the outer circumferential surface of the core fiber (OF) is coated with the binder (B), and then taken out of the impregnation tank 10.

Since there is a separate graphite powder attachment process in this embodiment, the compression roller 15 for attaching the graphite powder (G) to the core fiber (OF) in the impregnation bath 10 is not required.

In addition, since only the binder (B) is contained in the impregnation tank 10, there is no need to put a dispersant into the impregnation tank 10 to prevent the graphite powder (G) from aggregating in the binder (B).

Hereinafter, the third step (S33) will be described.

The attaching machine 30 discharges graphite powder (G) to the outer circumferential surface of the core fiber (CF) to adhere the graphite powder (G) to the outer circumferential surface of the core fiber (OF), and recovers the remaining graphite powder (G).

Applicator (30)

Attacher 30 is composed of a body 31, an ejector 32, and a collector 33.

Each of the left and right side surfaces of the body 31 is provided with an inlet 31a into which the core fiber (OF) coated with the binder (B) enters, and an outlet 31b through which the core fiber (OF) to which the graphite powder (G) is attached comes out. .

The ejector 32 and the collector 33 are installed inside the body 31 and face each other with the core fibers OF interposed therebetween at regular intervals.

The ejector 32 ejects a set amount of graphite powder G at a set discharge pressure for a set time. Due to this, it is possible to easily control the amount of graphite powder (G) to be attached to the core fiber (OF). In addition, by increasing the pressure for discharging the graphite powder (G) from the attachment machine 30, the graphite powder (G) can penetrate deep into the core fiber (OF), and the adhesion of the graphite powder (G) can be increased. Since the ejector 32 may be configured in various ways using known technologies such as a discharge pump and a nozzle, a detailed description thereof will be omitted.

The collector 33 is located on the opposite side of the ejector 32, sucks in and collects the remaining graphite powder G attached to the outer circumferential surface of the core fiber OF. Due to this, the graphite powder (G) can be recovered and recycled. Since the collector 33 may be configured in various ways using known technologies such as a suction pump and a nozzle, a detailed description thereof will be omitted.

Meanwhile, when the body 31 rotates 360°, the ejector 32 and the collector 33 can discharge and collect the graphite powder G while rotating 360° around the core fiber OF. Due to this, the graphite powder (G) can be evenly attached to the entire outer circumferential surface of the core fiber (OF) in a uniform thickness, so that electromagnetic wave shielding performance can be obtained uniformly from either side of the graphite-adhering fiber (GF). Since the configuration for rotating the body 31 by 360° may be variously configured using known technologies such as a motor and a ball bearing, a detailed description thereof will be omitted.

Hereinafter, the fourth step (S34) will be described.

After passing through the attachment machine 30, the core fiber OF to which the graphite powder G has adhered to the outer peripheral surface passes through the dryer 20. The dryer 20 dries and evaporates the binder (B) on the core fiber (OF). Graphite-adhered fibers (GF) are made. The graphite-adhered fiber GF is wound around the recovery roller R. To this end, the recovery roller R is rotated clockwise at constant speed by a motor (not shown).

Hereinafter, the fifth step (S35) will be described.

Unwind the graphite-adhered fiber (GF) wound around the recovery roller (R) and cut it to an appropriate length. Shield the signal line with a shielding material made by braiding graphite-attached fiber (GF) cut to an appropriate length on the signal line of the shielded cable.

10: impregnation tank 13: cover
14: guide roller 15: compression roller
20: dryer 30: attachment machine
31: ejector 32: recovery machine
GS: Graphite sheet B: Binder
G: graphite powder OF: core fiber
GF: graphite adhering fiber

Claims (8)

A first step of preparing a graphite sheet; and
The graphite sheet is shielded with a shielding material manufactured by wrapping the graphite sheet around the signal line of the shielded cable, or the graphite sheet is cut and shielded with a shielding material made by winding the graphite sheet diagonally around the signal line of the shielded cable, or the graphite sheet is slit to cover the signal line of the shielded cable A cable shielding method using a graphite sheet, characterized in that it comprises a second step of shielding with a shielding material made by braiding. The method of claim 1, wherein the graphite sheet,
A cable shielding method using a graphite sheet, characterized in that it is produced by weaving fibers having a carbon fraction of 90% or more, and carbonizing, graphitizing, and rolling the woven fibers. The method of claim 1, wherein the graphite sheet,
A cable shielding method using a graphite sheet, characterized in that it is prepared by imidizing a polyamic acid film at high temperature, stretching it to form a polyimide film, and then carbonizing and graphitizing the polyimide film. The method of claim 1, wherein the graphite sheet,
A cable shielding method using a graphite sheet, characterized in that it is manufactured by chemically imidating a polyamic acid film, stretching it to form a polyimide film, and then carbonizing and graphitizing the polyimide film. A first step of preparing core fibers;
A second step of putting the core fiber into an impregnation tank containing a binder and graphite powder, covering the outer circumferential surface of the core fiber with the binder and graphite powder, and then taking it out of the impregnation tank;
a third step of drying and evaporating the binder deposited on the core fibers taken out of the impregnation tank and leaving only the graphite powder on the outer circumferential surface of the core fibers to form graphite-adhered fibers; and
A cable shielding method using graphite-attached fibers comprising a fourth step of shielding the graphite-attached fibers with a shielding material made by braiding the signal lines of the shielding cable. A first step of preparing core fibers;
A second step of putting the core fiber into an impregnation tank containing a binder, covering the outer circumferential surface of the core fiber with the binder, and then taking the core fiber out of the impregnation tank;
a third step of discharging graphite powder to the outer circumferential surface of the core fiber with the binder coming out of the impregnation tank to attach the graphite powder to the outer circumferential surface of the core fiber, and recovering the remaining graphite powder;
a fourth step of drying and evaporating the binder deposited on the core fiber and leaving only the graphite powder on the outer circumferential surface of the core fiber to form a graphite-adhered fiber; and
A cable shielding method using graphite-attached fibers comprising a fifth step of shielding the graphite-attached fibers with a shielding material made by braiding the signal lines of the shielding cable. The method of claim 5 or 6, wherein the core fiber,
A cable shielding method using graphite-adhered fiber, characterized in that it is any one of carbon fiber, glass fiber, basalt fiber, aramid fiber, and nylon fiber. The method of claim 5 or 6, wherein the core fiber,
A cable shielding method using graphite-adhered fibers, characterized in that they are metal-coated carbon fibers.

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