KR20120010028A - Braided electro-conductive cable, manufacturing method thererof and manufacturing apparatus thererof - Google Patents

Abstract

PURPOSE: A braided conductive cable, a manufacturing method thereof, and a manufacturing apparatus thereof are provided to remarkably improve workability and productivity by making use of a braided conductive cable. CONSTITUTION: A braided conductive cable includes a conductive line(11) and an accompanying line(12). The conductive line has a conductive line exposure section(a) integrally bound in the accompanying line and the conductive line exposure section(b) exposed to the outside. The conductive line exposure section is formed between weaving sections of conductive lines in the braided conductive cable at a fixed interval. The conductive line and the accompanying line are formed to be tied together in the conductive line exposure section.

Description

BRAIDED ELECTRO-CONDUCTIVE CABLE, MANUFACTURING METHOD THEREROF AND MANUFACTURING APPARATUS THEREROF}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a braided conductive cable, a method for manufacturing the same, and an apparatus for manufacturing the same, and more particularly, a part of the conductive wire is selectively exposed to the outside to quickly connect the conductive wire, connect various elements or modules, and the like. The present invention relates to a braided conductive cable, a method of manufacturing the same, and a device for manufacturing the same, which are easily performed to improve workability and productivity.

In general, a conductive wire is a linear member called an electric wire, an electric cable, or the like, and is used as a power supply line for energizing current or transmitting an electric signal, or a heating wire used as a heat source of a heater.

In addition, the conductive wire is manufactured by forming an insulating layer by overlaying a resin on a metal wire such as a copper wire, and since the metal wire and the insulating layer do not have elasticity, they are not stretched when an external force such as a tensile force is applied. Does not have the disadvantage.

Accordingly, these conventional conductive wires have limitations that cannot be applied to articles or devices that require mobility, mobility, and elasticity. For example, clothing (heating clothes, smart clothes, wearable computers, power wires or heating wires required for comfort), a bed (heating heating wire for heating), a machine that is moved in a vertical direction There are limitations that cannot be applied to articles and devices such as (power line or heating line).

Accordingly, the present applicant has proposed a flexible heating wire as shown in Korean Patent Registration No. 10-0663328 to solve the above problems.

The flexible heating wire is a heating wire 20 in which a thermally conductive outer layer is overlaid on the outside of the conductive wire formed by a plurality of carbon fiber yarns, as shown in FIG. 1, so that the conductive wire 22 is wound around the inner center of the heating wire. An inner line 26 is formed separately, and the outer layer 24 overlying the outer line 26 and the conductive line 22 is formed of a stretchable insulating material and expands and contracts according to the tensile force acting in the longitudinal direction of the heating wire. It is supposed to shrink.

According to the stretchable heating wire, elasticity is provided in the longitudinal direction, and thus, the elastic heating wire may be used as a material for manufacturing active clothing, equipment, or the like, or may be variously used as a conductive wire of a cable or a product requiring elasticity.

However, since the flexible conductive wire 20 pre- filed by the applicant will form the outer skin layer 24 by winding the fiber yarn together, find the conductive wire twisted together with the fiber yarn to form a circuit or a connection with the power supply. The work of wiring, the work of connecting various elements or modules, etc. were very troublesome. That is, since the conductive wires 22 included in the fiber yarns constituting the flexible conductive wires 20 must be found and connected to each other, it is difficult to find the conductive wires and takes a lot of time, resulting in reduced workability and productivity. In the process of finding the fiber yarns around were damaged.

The present invention has been made in view of the above-described conventional problems, to improve the workability and productivity by performing a quick and simple connection of the conductive wire, connection of various elements or modules by selectively exposing a portion of the conductive wire to the outside. It is an object of the present invention to provide a braided conductive cable, a method of manufacturing the same, and an apparatus for manufacturing the same.

A braided conductive cable for achieving the object of the present invention as described above, the braided conductive wire and the companion wire supplied with the conductive wire are braided together in a wound or woven manner to form a long linear member In the conductive cable, a conductive wire weaving section (a) in which the conductive wire is tied to the companion line and restrained integrally, and a conductive line exposed section (b) in which the conductive wire is exposed to the outside without being tied to the companion line Characterized in that configured to have.

The braided conductive cable has a central yarn disposed at one or more strands along a longitudinal direction such that the conductive line and the companion line are wound at an inner center thereof, and the conductive line and the companion line are sequentially formed in the central yarn. They can be woven together to form different layers, or they can be woven together on the central yarn and placed in one layer.

The central yarn may be arranged in a plurality of strands parallel to each other along the longitudinal direction, and the conductive line and the companion line may be interlaced while crossing each other in an approximately "8" shape to be alternated between the central yarns.

The braided conductive cable may be formed such that a plurality of the conductive lines and the companion line are woven together to form a strip, and the surfaces of the strips may have three or more surfaces having an angle with respect to each other.

The cross-sectional shape of the braided conductive cable may be formed to have a cross-sectional shape of any one of "a" shape, "c" shape, "ㅁ" shape, "Δ" shape "I" shape, and "H" shape, or " ㅇ "Shape, semi-circle," ㅡ "shape," ㄱ "shape," ㄷ "shape," ㅁ "shape," △ "shape" I "shape," H "shape. Can be formed.

In addition, it may be provided with a central yarn disposed in one or more strands along the longitudinal direction so as to be located between the conductive line and the companion line.

On the other hand, the conductive wire is composed of a plurality of conductive yarns are formed in a bundle, the conductive yarn is composed of a metal yarn, carbon fiber yarn, at least one of the conductive yarns containing or coated with a conductive material in the fiber yarn is selected The conductive yarn may be composed of only insulated or uninsulated ones, or may be mixed and constituted together with insulated and uninsulated ones.

In this case, the companion line may be made of a wire material having a conductive line, or may be made of a fiber yarn having no conductivity.

In addition, the central yarn may be formed of an elastic wire rod formed to have elasticity with respect to an external force applied thereto.

In this case, the stretchable wire rod may be made of a stretchable polymer yarn formed of a stretchable polymer resin or may be formed in a coil structure.

In addition, the core yarn is a high-strength fiber yarn having a heat resistance and tensile strength, a fiber yarn having a hollow portion, a foam yarn formed by foaming polymer resin, a conductive yarn containing or coated with a conductive material in the fiber yarn, ceramic fiber yarn, glass fiber One of the yarns, and carbon fiber yarns may be selected and configured.

The method for manufacturing a braided conductive cable for achieving the object of the present invention as described above, the conductive wire, and the companion wire supplied with the conductive wire is woven in a coiling or weaving method to form a long linear member A method of manufacturing a braided conductive cable, the method comprising: forming a conductive wire weave section for forming a conductive wire weave section in which the conductive line and the companion line are woven together and restrained integrally; And a conductive line exposed section forming step of selectively forming a conductive line exposed section in which the conductive line is exposed to the outside without being tied to the companion line in the conducting step of forming the conductive line tied section. In the forming step, a supply process of supplying the conductive line and the companion line, a weaving process of weaving the conductive line and the companion line supplied through the supply process to form a long linear member, and the weaving process are formed through the weaving process. Simultaneously forming a drawing process to pull out the braided conductive cable to be drawn out, the conductive wire exposed section forming step is performed by performing only the supply process and the drawing process without performing the weaving process in a predetermined section The wire is exposed to the outside without being intertwined with the companion line to form a conductive line exposed section. The features.

The method may further include a central yarn supplying process for supplying a central yarn disposed in the longitudinal direction through the inner center of the braided conductive cable or between the serving portions of the conductive wires.

The apparatus for manufacturing a braided conductive cable for achieving the object of the present invention as described above is braided is made of a linear member having a long length by weaving a conductive wire, the companion wire supplied with the conductive wire in a coiling or weaving method An apparatus for manufacturing a conductive cable, comprising: a guide plate having a plurality of carriers around which the conductive line and the companion line are wound, and a track into which the carrier is inserted, and weaving the conductive line and the companion line together to form the braided conductive A cable forming unit forming a cable; Carrier drive means for moving the carrier along the trajectory by power transmitted from a main drive; A cable lead-out unit which is operated simultaneously with the operation of the cable forming unit and pulls out the braided conductive cable formed by the cable forming unit to the outside; Lead-out drive means for operating the cable lead-out by power transmitted from the main drive; And a clutching unit for intermittent power transmitted to the cable forming unit and the cable lead-out unit, wherein the clutching unit transmits power simultaneously to the carrier driving unit and the lead-out unit driving unit to bundle the braided conductive cable. And a first clutching position for forming a conductive line weaving section in which the conductive line and the companion line are intertwined with each other to be integrally restrained while the process and the drawing process are simultaneously performed, and power transmission to the carrier driving means is blocked and the A second clutter that transmits power only to the lead-out driving means so that the conductive line and the companion line are supplied and withdrawn only while the conductive line is not connected to the companion line and is exposed to the outside to form an exposed portion of the conductive line. A clutch member having a latching position; And an operation unit for operating the clutch member so that the clutching steps to the first and second clutching positions are selectively performed.

In this case, the clutch member is engaged to transfer power to the carrier driving means and the lead-out driving means in a state where the clutch member is moved to the first clutching position, and the carrier driving in the state where the clutch member is moved to the second clutching position. And a power transmission gear that is engaged to disengage the engagement with the means and to transmit power only to the outlet drive means, wherein the operation portion selectively switches the flow of power to the first and second clutching positions. It can be composed of a control lever that can be.

On the other hand, the actuator for operating the clutch member in the first clutching position or the second clutching position in accordance with a control signal; An input unit configured to input an input signal for operating the actuator; And a controller for controlling driving of the actuator according to the input signal of the input unit.

In addition, the main drive device may include a drive motor and a power transmission device for transmitting the power generated from the drive motor to the input side of the clutching portion.

The apparatus for manufacturing a braided conductive cable for achieving the object of the present invention as described above, the braid is made of a linear member having a long length by weaving a conductive wire and a companion wire supplied with the conductive wire in a winding or a looping method. A device for manufacturing a conductive cable, comprising: a guide plate having a plurality of carriers around which the conductive line and the companion line are wound, and a track into which the carrier is inserted, and braiding the conductive line and the companion line together A cable forming unit forming a conductive cable; Carrier driving means for moving the carrier along the track; A carrier driving motor applying a driving force to the carrier driving means; A cable lead-out unit for pulling out the braided conductive cable formed by the cable forming unit; Lead-out drive means for operating the cable lead-out by power transmitted from a main drive; A drawer driving motor for applying a driving force to the drawer driving means; An input unit configured to input an input signal for operating the carrier driving motor and the extractor driving motor; And a control unit controlling driving of the carrier driving motor and the extractor driving motor according to an input signal of the input unit, wherein the control unit is braided by simultaneously transmitting power to the carrier driving unit and the drawing unit driving unit. A first control step of forming a conductive line binding section in which the conductive line and the companion line are intertwined with each other and the constrained wire is formed while the braiding process and the drawing process of the conductive cable are simultaneously performed, the transmission of power to the carrier driving means is blocked. And the power is transmitted only to the lead-out driving means so that only the supplying and drawing process of the conductive line and the companion line is performed, and the conductive line is not connected to the companion line and is exposed to the outside to form an exposed portion of the conductive line. 2 control step, and transfer of power to the carrier drive means and the drawer drive means It is cut off to is characterized in that is configured to perform a third control step in which the conductive line and the accompanying line feeds, the yeokeum procedure, and drawn at the same time the process stops.

In addition, the cable forming unit may be formed in multiple stages so as to supply or weave the conductive line and the companion line, so that the braided conductive cable may be formed in a multilayer structure.

According to the braided conductive cable according to the present invention, a method for manufacturing the same, and a manufacturing apparatus thereof, a portion of the conductive line exposed portion that is selectively exposed to the outside at a predetermined interval between the conductive line weaving sections (a) ( Since the braided conductive cable formed with b) is realized, the conductive wires can be connected, and various devices or modules can be connected quickly and easily. Accordingly, the convenience of using the braided conductive cable is improved, and in using the braided conductive cable, the workability and productivity are remarkably improved.

1 is a view for explaining a conventional conductive cable,
2A and 2B are perspective views showing a braided conductive cable according to a first embodiment of the present invention;
3A is a perspective view showing a first modification of the braided conductive cable according to the first embodiment of the present invention;
3B is a perspective view showing a second modification of the braided conductive cable according to the first embodiment of the present invention;
3C is a perspective view showing a third modification of the braided conductive cable according to the first embodiment of the present invention;
3D is a perspective view showing a fourth modification of the braided conductive cable according to the first embodiment of the present invention;
4 is a perspective view showing a braided conductive cable according to a second embodiment of the present invention;
5A is a perspective view showing a braided conductive cable according to a third embodiment of the present invention;
5B is a view showing a modification of the braided conductive cable according to the third embodiment of the present invention;
6A and 6B are views for explaining a braided conductive cable according to a fourth embodiment of the present invention;
7 is a flowchart illustrating a method of manufacturing a braided conductive cable according to an exemplary embodiment of the present invention.
FIG. 8A is a schematic diagram illustrating the technical concept of an apparatus for manufacturing a braided conductive cable according to a first exemplary embodiment of the present invention; FIG.
FIG. 8B is a perspective view showing the carrier forming portion in more detail to help understand FIG. 8A;
9 is a schematic configuration diagram showing a first modification of the apparatus for manufacturing a braided conductive cable according to the first embodiment of the present invention;
10 is a configuration diagram for explaining an apparatus for manufacturing a braided conductive cable according to a second embodiment of the present invention;
FIG. 11 is a schematic diagram illustrating the technical concept of an apparatus for manufacturing a braided conductive cable according to a third exemplary embodiment of the present invention; FIG.
12A to 12G are schematic views for explaining a track applicable to the apparatus for manufacturing a braided conductive cable according to the present invention.

Best Mode for Carrying Out the Invention Preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, FIGS. 2A to 12G, and like reference numerals designate like elements in FIGS. 2A to 12G. Meanwhile, the drawings and detailed descriptions of configurations, operations, and effects that can be easily understood by those skilled in the art from general technology in each drawing are briefly or omitted, and are illustrated based on parts related to the present invention.

2A and 2B are perspective views showing a braided conductive cable according to a first embodiment of the present invention.

As shown in FIGS. 2A and 2B, the braided conductive cable according to the present invention may include a conductive line 11 and a companion line 12 supplied with the conductive line 11 in a wound or bundled manner. It is woven and formed of a long linear member, the conductive line 11 is woven to the companion line 12, the conductive line tied section (a) and the conductive line is exposed to the outside without being woven with the companion line It is comprised so that a conductive line exposure section b may be provided.

Such a braided conductive cable according to the present invention can be manufactured for a loom called a braiding device or a weaving machine, etc. A concrete manufacturing method and a manufacturing apparatus thereof will be described below in detail.

As described above, when the conductive line exposed section b is formed at a predetermined interval between the conductive line weaving sections a of the braided conductive cable, the conductive line exposed section b is accompanied by the conductive line 11. Since the lines 12 are not intertwined with each other, the conductive lines 11 can be easily found. Accordingly, the conductive wires 11 may be drawn out to be electrically connected to each other, or various electrical and electronic elements or devices such as LED lamps, small cameras, wireless communication modules, GPS modules, and the like may be electrically connected conveniently.

In particular, the braided conductive cable according to the present embodiment can conveniently manufacture an electric cable having terminals formed at both ends thereof. That is, when the conductive wire weaving section (a) is formed to a length corresponding to the length of the desired electric cable, the conductive wire exposing section (b) is subsequently formed, and the conductive wire exposing section (b) is cut, Terminals can be easily formed by joining or soldering the terminal pieces to the conductive wire exposed to the site.

The conductive wire 11 may include at least one selected from a conductive yarn in which a conductive material is included or coated in the metal yarn, the carbon fiber yarn, and the fiber yarn, but in this embodiment, a plurality of conductive yarns formed of the metal yarn may be used. What is formed in one bundle is applied as a conductive line. At this time, the conductive wire may further include a fiber having high heat resistance and strength in addition to the conductive yarn.

And, the conductive yarn may be composed of only insulated or not insulated, or insulated and not insulated together.

In more detail, the conductive yarn 11a provided in the above-described conductive line 11 will be described in more detail. According to the applied voltage or the magnitude of the current, the conductive yarn 11 may be electrically conductive or generate heat by resistance heat. Metal yarn, a fiber yarn including a conductive material in the form of nanoparticles, a plated yarn coated with a conductive metal on the fiber yarn, a carbon fiber yarn, etc.) may be selected and applied. In the present embodiment, a metal yarn having a diameter of about tens to hundreds of micrometers (μm) is formed, and preferably an insulating coating layer is formed on stainless steel wire, titanium wire, copper wire, etc. having a diameter of about 10 to 50 micrometers (μm). It is selected from metal yarns (usually called enameled wires). At this time, the number of strands of the conductive yarn (11a) can be changed in various ways depending on the rated voltage of the power supply, the heating temperature, etc., it is configured by arranging 5 to 30 strands.

In addition, the companion line 12 may be made of a wire material having conductivity similarly to the conductive wire 11 to be woven together, or may be made of a fiber yarn having no conductivity. In this case, if the companion line 12 is a fiber yarn having no conductivity, a prehistoric line used in the textile field and other fields may be selected and applied without limitation.

Meanwhile, each of the braided conductive cables shown in FIG. 2A is formed by winding one conductor wire 11 and a companion wire 12 by a winding method, that is, a winding method, and a plurality of braided conductive cables shown in FIG. 2B. The conductive lines 11 and the companion lines 12 of the strands are exemplified by a weaving method, that is, a braiding method.

3A is a perspective view showing a first modification of the braided conductive cable according to the first embodiment of the present invention.

Referring to FIG. 3A, the braided conductive cable may include a conductive line weaving section a in which the conductive line 11 and the companion line 12 are tied together and restrained integrally, and the conductive line 11 may be the companion line 12. It is configured to have a conductive line exposed section (b) exposed to the outside without being intertwined with, having a central yarn 13 is disposed along the longitudinal direction in the inner center of the conductive line and the companion line is wound around its outer peripheral surface.

The central yarn 13 is disposed and formed in at least one strand, and is composed of a flexible wire rod when it is configured to have elasticity with respect to an external force applied to the braided conductive cable.

For example, the flexible wire rod may be composed of a stretchable polymer yarn formed by spinning a stretchable polymer resin. In this case, the stretchable polymer resin may be a silicone resin, polyester, polyethylene terephthalate or a copolymer thereof.

In addition, the center yarn 13 may be configured to be formed to be stretched against external force by forming a coil structure having a coil structure in addition to the stretchable wire rod.

On the other hand, when the core yarn 13 does not require elasticity, various lines may be applied according to its purpose of use. For example, high-strength fibers having high heat resistance and high tensile strength, such as Kevlar and aramid yarns well known in the textile field, fiber yarns having hollow portions, foam yarns formed by foaming polymer resins, and conductive materials contained or coated in the fiber yarns It can be applied by selecting from conductive yarn, ceramic fiber yarn, glass fiber yarn, and carbon fiber yarn.

3B is a perspective view showing a second modified example of the braided conductive cable according to the first embodiment of the present invention, and FIG. 3C is a third modified example of the braided conductive cable according to the first embodiment of the present invention. 3D is a perspective view illustrating a fourth modified example of the braided conductive cable according to the first exemplary embodiment of the present invention. Shown.

Referring to FIG. 3B, the braided conductive cable is formed on the outer circumferential surface of the central yarn 13 in a manner in which the conductive line 11 and the companion line 12 are wound or entwined, and the conductive line and the companion line are woven together and restrained integrally. The conductive line binding section (a) and the conductive line is configured to have a conductive line exposed section (b) exposed to the outside without being tied to the companion line, the conductive line 11 and the companion line 12 is the center yarn (13) ) Are arranged and formed to be sequentially woven in different layers to form different layers.

In the braided conductive cable according to the present modification, a conductive wire layer in which the conductive wires 11 are woven is first formed on the outer circumferential surface of the central yarn 13 as shown in FIG. 3B, and the insulating fiber is formed outside the conductive wire layer. Complementary line layer is formed of a structure in which the companion line 12 is woven, such as yarn, the companion line layer is to perform the function of the outer skin layer for the insulation and protection of the conductive line layer.

However, the stacked form of the conductive line layer and the companion line layer is not limited thereto, and the companion line layer may be formed first and then the conductive line layer may be formed later according to the use of the braided conductive cable.

In addition, in the braided conductive cable, a conductive line layer and a companion line layer may be formed in a multilayer structure as shown in FIG. 3C. For example, the conductive line layer, the companion line layer, and the conductive line layer may be repeatedly formed on the outer circumferential surface of the central yarn 13.

Referring to FIG. 3D, the braided conductive cable is formed on the outer circumferential surface of the central yarn 13 in a manner in which the conductive line 11 and the companion line 12 are wound or entwined, and the conductive line 11 and the companion line 12 are formed. The conductive lines are intertwined and restrained integrally with each other, and the conductive lines are configured to have a conductive line exposed section (b) exposed to the outside without being tied with the companion line, wherein the conductive line 11 and the companion line ( It is configured to form a layer by weaving 12) at the same time in the center yarn.

In this case, the conductive line 11 and the companion line 12 are simultaneously woven to the central yarn in the conductive line weaving section a, and are exposed to the outside without being woven together at the same time in the conductive line exposing section b.

4 is a perspective view showing a braided conductive cable according to a second embodiment of the present invention. In the following embodiments, the same reference numerals are used to designate the same or similar components as those in the first embodiment.

Referring to FIG. 4, the braided conductive cable according to the second exemplary embodiment includes a conductive line weaving section a in which the conductive line 11 and the companion line are intertwined with each other, and the conductive line 11 is connected to the companion line. It is configured to have a conductive line exposed section (b) exposed to the outside without being woven, the center yarn is arranged in a plurality of strands in parallel along the longitudinal direction, the companion line 12 is alternately approximately "8" between the center yarn 13 "They are intertwined and intertwined.

5A is a perspective view showing a braided conductive cable according to a third embodiment of the present invention, and FIG. 5B is a view showing a modification of the braided conductive cable according to the third embodiment of the present invention.

Referring to FIG. 5A, the braided conductive cable according to the third exemplary embodiment includes a conductive line weaving section a and a conductive line 11 in which the conductive line 11 and the companion line 12 are tied together and restrained integrally. It is configured to have a conductive line exposed section (b) exposed to the outside without being woven with the companion line 12, the cross-sectional structure is formed in a strip shape of approximately "-" shape.

That is, the conductive line 11 and the companion line 12 are entangled with each other in a zigzag form to form a band, but the conductive line 11 and the companion line 12 are simultaneously woven together in the conductive line weave section (a). In the conductive line exposed section (b), they are not connected to each other and are exposed to the outside.

In addition, the braided conductive cable according to the third exemplary embodiment has a center yarn 13 disposed along the longitudinal direction such that the braided conductive cable is positioned between the conductive line 11 and the companion line 12 at the bonding portion, as shown in FIG. 5B. It may be arranged and formed.

Since the center yarn 13 is disposed between the conductive wire 11 and the companion wire 12, the center yarn 13 may function as a reinforcing yarn to increase the overall rigidity of the braided conductive wire cable. In addition, when the center yarn 13 is composed of a stretchable polymer yarn or a coil yarn having the same elasticity as the span yarn, the center yarn 13 may be made to have a structure having elasticity as a whole.

6A and 6B are views for explaining a braided conductive cable according to a fourth exemplary embodiment of the present invention. As an example, a perspective view of a braided conductive cable having a cross-sectional structure having an “H” shape is shown. will be.

Referring to FIG. 6A, the braided conductive cable according to the fourth exemplary embodiment includes a conductive line weaving section a and a conductive line 11 in which the conductive line 11 and the companion line 12 are tied together and restrained integrally. It is formed in a band shape having a conductive line exposed section (b) exposed to the outside without being woven with the companion line 12, characterized in that the number of surfaces of the conductive line cable is formed of three or more. At this time, the surface quantity of the conductive cable is the surface quantity when it is assumed that the surfaces are different if each surface has an angle with respect to each other.

As an example of the braided conductive cable according to the fourth embodiment, the cross-sectional structure appearing on the lateral cross section as illustrated in FIG. 6A is merely illustrated as having an "H" shape, but is not limited thereto. It can be configured to have various cross-sectional shapes, such as a "c" shape, a "wh" shape, a "Δ" shape and an "I" shape.

And the manufacturing form of a braided conductive cable can be implement | achieved by adjusting suitably the track | orbit of a cable formation part, as can be understood from description of the manufacturing apparatus mentioned later. The braided conductive cable having three or more surfaces can be manufactured for a loom called a braiding machine or a weaving machine, and the "H" shaped braided conductive cable for the specific manufacturing method and the manufacturing apparatus. For example, the manufacturing process will be described in detail below.

6B is a view for explaining a modified example of the braided conductive cable according to the fourth embodiment of the present invention. As shown therein, the braided conductive cable according to the modified example of the fourth embodiment may be implemented in the first to fourth embodiments. The braided conductive cable was constructed by selectively combining the cross-sectional structure shown in the example.

That is, the conductive cables having the " o " and "-" shaped cross-sectional shapes shown in the first to third embodiments are combined with each other, or " H " having three or more surfaces as shown in Figs. 6A and 6B. A conductive cable having a cross-sectional shape such as "-", "a" -shape, "c" -shape, "wh" -shape, "△" -shape, "I" -shape, and "o" shape shown in the first to third embodiments. It can be formed in the shape which combined two or more of the conductive cables which have a "-" shaped cross-sectional shape.

6B exemplified in this embodiment is a form in which conductive cables having a "-" shaped cross-sectional shape are combined with each other on both sides of the "-" shaped conductive cable body, and the manufacturing method thereof is described in detail in the description of the manufacturing apparatus described below. It is.

In addition, the braided conductive wire cable further includes a central yarn (not shown) disposed along the longitudinal direction so as to be positioned between the conductive wire 11 and the companion line 12, and as a reinforcement yarn to increase the overall rigidity. It can be configured to perform a function.

7 is a flowchart illustrating a method of manufacturing a braided conductive cable according to a preferred embodiment of the present invention.

In the method for manufacturing a braided conductive cable according to the present invention, the conductive wire weaving section forming step of forming the conductive wire weaving section (a) in which the conductive line 11 and the companion line 12 are woven together and restrained integrally (S1) ) And a conductive line exposed section forming step (S2) forming a conductive line exposed section (b) in which the conductive line 11 is exposed to the outside without being tied to the companion line 12.

The conductive line exposed section forming step S2 is a step of forming the conductive line exposed section b at every desired interval in the conducting process of the conductive line weaving section forming step S1. As shown in the drawing, the conductive line weaving section forming step S1 and the conductive line exposing section forming step S2 are repeated.

The conductive line weaving section forming step (S1) is a supply process of supplying the conductive line 11 and the companion line 12, the weaving process of weaving the conductive line 11 and the companion line 12 supplied through the supply process, And drawing out the braided conductive cable so that the braided conductive cable can be carried out by pulling out the woven portion through the weaving process, so that the conductive line 11 and the companion line 12 are wound or entwined. The braided conductive cable of the form of a long linear member is woven into the wire.

In addition, the conductive line weaving section (a) is a section that can be formed only when the supply process, the weaving process, and the drawing process are performed at the same time, that is, the conductive line 11 and the companion line 12 which can be woven through the weaving process. The supply process must be carried out so that) can be supplied, and the withdrawal process must be carried out at the same time to draw out the woven parts through the weaving process and to withdraw the continuous weaving process from the weaving site.

In the conductive line exposed section forming step (S2), the conductive line exposed section (b) is repeatedly formed in a predetermined section of the braided conductive cable, and the conductive line exposed section (b) is supplied without a weaving process. Only withdrawal process can be implemented. That is, since the conductive wire should not be woven, the braided wire of the braided conductive cable formed as described above is provided with the supply process for supplying the conductive wire 11 exposed to the outside in the conductive wire exposed section b. The withdrawal process for pulling out the exposure section (b) should be carried out simultaneously.

On the other hand, the manufacturing method of the braided conductive cable according to the present invention further provides a center yarn supply process for supplying the center yarn disposed in the longitudinal direction through the inner center of the braided conductive cable or between the serving portions of the conductive line 11 It may include.

The core yarn supplying process is carried out simultaneously with the supply process, the weaving process, and the drawing process. The core yarn is supplied in the same direction as the movement direction of the braided conductive cable, and the conductive line 11 and The companion line 12 is woven, and in the step of forming the conductive line exposed section b, the conductive line 11 and the companion line 12 are moved together in parallel without being woven.

Hereinafter, a braided conductive cable manufacturing apparatus capable of substantially manufacturing the braided conductive cable according to the present invention as described above and specifically implementing the manufacturing method will be described.

FIG. 8A is a schematic configuration diagram for describing a technical concept of an apparatus for manufacturing a braided conductive cable according to a first exemplary embodiment of the present invention. FIG. 8B is a perspective view illustrating the carrier forming unit side in more detail to help understand FIG. 8A. to be.

Referring to FIG. 8A, the apparatus for manufacturing a braided conductive cable includes a cable forming part 110, a carrier driving means 120, a cable drawing part 130, a drawing part driving means 140, and a clutching part 150. And a storage roller 160 for winding and storing the braided conductive cable discharged from the cable lead-out unit 130, and a main driving device for providing a driving force to the carrier driving unit 120 and the lead-out driving unit 140. 170 is provided.

The cable forming unit 110 is a portion in which the conductive line 11 and the companion line 12 are woven together to form a braided conductive cable, and the plurality of carriers 111 in which the conductive line 11 and the companion line 12 are wound. And a guide plate 112 having a track c formed to cross each other so that the carrier 111 moves.

Carrier drive means 120 is configured to move the carrier 111 along the track (c) by the power transmitted from the main drive device, a plurality of transfer gear 121 disposed inside the guide plate 112 It consists of).

As shown in Fig. 8B, the carrier 111 is rotatably positioned on the guide plate 112, as is widely employed in the braiding device, and is provided with a support mechanism 111a and a conductive wire 11 formed thereunder. And a knitting mechanism 111b in which the companion line 12 is wound. The support mechanism 111a moves along the track c by the rotational force transmitted from the transfer gear 121 installed in the frame 115 to transfer the entire carrier 111.

As shown in FIG. 8A, the cable lead-out unit 130 is operated simultaneously with the operation of the cable forming unit 110 to pull out the braided conductive cable woven from the cable forming unit to the outside. If the structure can be easily withdrawn, it can be configured in various ways without limitation. In this embodiment, it consists of two upper and lower winding wheels (131, 132) provided to face each other, and the braided conductive cable is wound and discharged along with the rotation operation.

The lead-out drive unit 140 is configured to operate the cable lead-out unit 130 by the power transmitted from the main drive unit 170. If the structure can rotate the cable lead-out unit 130, belt or chain power It can be configured by various mechanical power transmission methods such as transmission method and gear power transmission method. In the present embodiment, the worm 142 and the wheel 143 for converting the rotational force transmitted from the vertical input shaft 141 in the perpendicular direction as the lead-out driving unit 140 and the first transmission connected to the wheel shaft 144 and rotated. The lower winding wheel 132 provided on the shaft 147 of the second transmission gear 146 is provided with a gear 145 and a second transmission gear 146 connected to the first transmission gear 145. It is supposed to be. The third transmission gear 148 is installed on the shaft of the second transmission gear 146, and the fourth transmission gear 149 meshing with the third transmission gear 148 is provided on the shaft of the upper winding wheel 131. As the upper and lower winding wheels 131 and 132 are rotated, the braided conductive cable is pulled out.

The clutching unit 150 is configured to control the power transmitted to the cable forming unit 110 and the cable lead-out unit 130, and controls the power transmission to the carrier driving unit 120 and the drawing unit driving unit 140. The clutch member 151 and the operation part 152 which operates this clutch member 151 are comprised.

The clutch member 151 simultaneously transmits power to the carrier driving means 120 and the lead driving means 140, and the braided conductive cable is intertwined with the conductive wire 11 and the lead wire (when the drawing process is simultaneously performed). The first clutching position where 12) is woven together to form a conductive wire binding section (a), which is integrally constrained, and power transmission to the carrier driving means 120 is blocked, and only to the outlet driving means 140. As the power is transmitted, only the supply process and the drawing process of the conductive line 11 and the companion line 12 are performed, and the conductive line 11 is exposed to the outside without being intertwined with the companion line 12, thereby exposing the conductive line exposed section (b). And to a second clutching position to form.

In the present embodiment, the clutch member 151 is engaged to transfer power to the carrier driving means 120 and the lead-out driving means 140 in a state where the clutch member 151 is moved to the first clutching position, and moves to the second clutching position. In this state, the engagement with the carrier driving means 120 is released and is configured to be a power transmission gear that is operated to transmit power only to the lead-out drive means.

The operation unit 152 is configured to operate the clutch member 151 to selectively perform the clutching steps to the first and second clutching positions, and selectively switch the flow of power to the first and second clutching positions. It is composed of control lever that can be used.

In addition, the clutching unit 150 may be implemented by various mechanical mechanisms if the same function is performed in addition to the structure or shape illustrated in FIG. 8A.

On the other hand, the main drive unit 170 includes a drive motor 171 and a power transmission device 174 for transmitting the power generated from the drive motor 171 to the input side of the clutching unit 150. The power transmission device 174 includes an electric pulley 174a installed on the motor shaft of the drive motor 171, a driven pulley 174c connected to the other side of the belt 174b connected to the electric pulley 174a, and a driven pulley. An input side bevel gear 174d provided on the shaft, and an output side bevel gear 174e connected to the input side bevel gear 174d.

FIG. 9 is a schematic configuration diagram showing a first modification of the apparatus for manufacturing a braided conductive cable according to the first embodiment of the present invention, and as shown therein, a means for operating the clutch member 151 instead of the operation unit. The actuator 153 is configured to operate in the first clutching position or the second clutching position in accordance with the control signal.

In addition, an input unit 154 capable of inputting an input signal for operating the actuator 153 and a control unit 155 controlling the driving of the actuator 153 according to the input signal of the input unit 154 are provided. . The input unit 154 sets the time for which the clutch member 151 stays in the first clutching position and the second clutching position, thereby controlling the conductive line weaving section (a) of the braided conductive cable under the control of the controller 155. The distance between the conductive line exposed section b and the length of the conductive line exposed section b may be controlled.

In addition, the actuator 153 may include a solenoid, a pneumatic cylinder, or the like.

FIG. 10 is a block diagram illustrating an apparatus for manufacturing a braided conductive cable according to a second exemplary embodiment of the present invention. FIG. 10 is a block diagram of the components, not specifically illustrated.

Referring to FIG. 10, the apparatus for manufacturing a braided conductive cable may supply or thread the conductive line 11 and the companion line 12 to manufacture the braided conductive cable of the type shown in FIGS. 3A to 4. The cable forming portion is formed of a multi-stage layer so that the braided conductive cable can be formed in a multilayer structure.

Referring to FIG. 10 in more detail, the apparatus for manufacturing a braided conductive cable includes a frame 220 and a structure formed on the frame 220 to primarily weave the conductive line 11 and the companion line 12. Basic cable forming unit 230 for forming a first cable layer, and at least one additional cable forming unit 240 is formed on the frame 220 to form a second cable layer outside or inside the first cable layer. It is provided.

In addition, the power transmission and the clutch for transmitting and interrupting the rotational force supplied from the cable lead-out unit 250 and the main drive unit 260 to wind the braided conductive cable which is woven and moved upward in the apparatus for manufacturing the braided conductive cable. There is a title portion 280.

As shown in FIG. 10, the basic cable forming unit 230 includes a plurality of carriers 111 on which the conductive line 11 and the companion line 12 are wound, and a guide plate having a track formed to intersect with each other. The additional cable forming unit 240 is configured above or below the basic cable forming unit 230 according to the formation position of the second cable layer. That is, when the additional cable forming unit 240 is configured above the basic cable forming unit 230, a second cable layer may be formed outside the first cable layer in the weaving process, and the basic cable forming unit 230 may be formed. If configured to the lower side of the weaving process can form a second cable layer inside the first cable layer. In FIG. 10, the additional cable forming unit 240 is formed below the basic cable forming unit 230.

In addition, the basic cable forming unit 230 and the additional cable forming unit 240 include moving holes 231 and 241 for moving the center line 13, the conductive line 11, and the companion line 12. In addition, when the center line 13 is to be placed inside the first cable layer, a center line supply part 270 configured to supply the center line at the bottom thereof is provided.

FIG. 11 is a schematic diagram illustrating a technical concept of an apparatus for manufacturing a braided conductive cable according to a third exemplary embodiment of the present invention.

Referring to FIG. 11, an apparatus for manufacturing a braided conductive cable includes a conductive line 11 and a plurality of carriers 111 on which the companion line 12 is wound, and a guide plate having a track formed to cross each other. Cable forming part 310 to form a braided conductive cable by weaving (11) and the companion line 12 to each other, carrier driving means 320 to move the carrier 111 along the track, cable forming unit ( It is operated simultaneously with the operation of the 310, the cable lead-out portion 330 for pulling out and pulling out the braided conductive cable formed by the cable forming portion 310, the lead-out drive means 340 for operating the cable lead-out portion 330 Is provided, the carrier driving motor 360 for applying a driving force to the carrier driving means 320, and the lead-out drive motor 370 for applying a driving force to the drive unit driving means 340 is configured separately.

In addition, an input unit 380 capable of inputting an input signal for operating the carrier driving motor 360 and the extractor driving motor 370, and the carrier driving motor 360 and the input signal of the input unit 380. A control unit 390 for controlling the driving of the drawing unit driving motor 370 is provided.

The controller 390 may include a first control step of forming a conductive line weaving section a, a second control step of forming a conductive line exposing section b, and a third control step of stopping all operations. It is meant to be performed.

In the first control step, power is simultaneously transmitted to the carrier driving unit 320 and the lead-out driving unit 340 to simultaneously perform the braiding and braiding of the braided conductive cable, and the drawing process. ) Is a step of operating both the carrier driving motor 360 and the lead-out drive motor 370 so that the conductive wire weave section (a) is formed while being constrained integrally with each other.

In the second control step, transmission of power to the carrier driving means 320 is cut off, and power is transmitted only to the drawing part driving means 340 so that only the supply process and the drawing process of the conductive line 11 and the companion line 12 are performed. The conductive line 11 is exposed to the outside without being woven with the companion line 12 while the conductive line 11 is exposed to form the conductive line exposed section b so as to operate only the lead driving motor 370.

In the third control step, power transmission to the carrier driving unit 320 and the drawing unit driving unit 340 is cut off at the same time, so that the supply process, the weaving process, and the drawing process of the conductive line 11 and the companion line 12 are simultaneously stopped. The carrier driving motor 360 and the lead-out driving motor 370 are stopped so as to stop all of them.

In FIG. 11, detailed configurations of the carrier driving unit 320 and the drawing unit driving unit 340 are similar to those of the first embodiment described above, and thus detailed description thereof will be omitted. Reference numeral 350 in FIG. 11 denotes a storage roller for winding a braided conductive cable.

12A to 12G are schematic views for explaining a track applicable to the apparatus for manufacturing a braided conductive cable according to the present invention, and schematically show only the shape of the track appearing on a plane.

12A to 12G, the cable forming parts 110, 230, 240, and 310 of the apparatus for manufacturing the braided conductive cable described above are provided with various types of tracks c according to the shape of the braided conductive cable to be manufactured as described above. Guide plate is provided.

First, FIG. 12A is configured to manufacture a braided conductive cable of the type shown in FIG. 2B. The track c formed on the guide plate is composed of two tracks crossing each other.

When the cable forming unit having a track of this type is operated, the carrier is moved along each track c in the conductive wire weaving section a, so that the conductive wire 11 and the companion line 12 wound around the carrier 111 are moved. 2) forms the conductive wire weaving section (a) shown in FIG. 2b, and in the conductive wire exposed section (b), the operation of the cable forming part is stopped and only the cable lead-out part is operated so that the conductive line 11 and the companion line 12 ), So that the conductive line exposed section b shown in FIG. 2B is formed.

Then, when the moving hole is formed in the center of the guide plate having a track as shown in FIG. 12A and the center yarn 13 is supplied from the lower side to be pulled together by the cable lead-out unit as shown in FIGS. 3A to 4. As will be appreciated a braided conductive cable with a central thread 13 may be manufactured.

FIG. 12B is configured to manufacture a braided conductive cable of the type shown in FIG. 5A, and is composed of one track c in which tracks crossing each other are pivoted at both ends and connected to opposite tracks. Accordingly, since the carrier 111 moves on one track, the braided conductive cable manufactured is not formed in a circular structure but is formed in a band shape having a cross-sectional structure of approximately "-" shape.

When the cable forming part having the track c of this type is operated, the conductive line 11 and the companion line 12 wound around the carrier 111 in the conductive line weaving section a are connected to the conductive shown in FIG. 5A. The line weaving section (a) is formed, and in the conductive line exposed section (b), the operation of the cable forming unit is stopped and only the cable lead-out unit is operated to pull the conductive line 11 and the companion line 12, as shown in FIG. 5A. The exposed conductive line exposed section b is formed.

Then, to form a moving hole (d) on the guide plate corresponding between the opposite track (c) as shown in Figure 12c and to feed the central yarn 13 from the lower portion to be pulled together by the cable lead-out portion As shown in FIG. 5B, a braided conductive cable having a central thread 13 may be manufactured at a binding portion of the conductive line 11 and the companion line 12.

On the other hand, Figure 12d is a track configured to be manufactured in a form similar to a braided conductive cable having a H-shaped cross-sectional structure shown in Figure 6a, the track is formed in a substantially H shape on the guide plate, the track When a plurality of carriers disposed in (c) is moved, a braided conductive cable having a H-shaped cross-sectional structure is formed and discharged upward.

That is, when the cable forming unit is operated, in the conductive line weaving section a, the conductive line 11 and the companion line 12 wound around the carrier 111 form a conductive line weaving section a. In the exposed section (b), the cable forming unit is stopped and only the cable lead-out unit is operated to pull the conductive line 11 and the companion line 12, thereby forming the conductive line exposing section b (not shown).

As shown in FIG. 12E, a plurality of moving holes may be formed on the guide plate so that the overall shape has an H shape, and the central yarn 13 may be moved between the tracks c. d) forming and feeding the central yarn 13 from the lower portion thereof to be pulled together by the cable lead-out portion, as shown in Figure 6a in the binding portion of the conductive line 11 and the companion line 12 A braided conductive cable having a center yarn 13 of can be manufactured. At this time, if a plurality of carriers in which the conductive line 11 and the companion line 12 are wound are arranged, and the weaving process is performed, the lady's conductive cable having high durability and tensile strength can be manufactured while being woven with the central yarn 13. have.

On the other hand, Figure 12f is configured to manufacture a braided conductive cable according to a modification of the fourth embodiment as shown in Figure 6b described above, the cable forming portion having a track (c) of the form shown in Figure 12f When configured, a braided conductive cable having a shape of a "-" shaped cross-section connected to both sides of the "-" shaped conductive cable body can be manufactured.

More specifically with reference to FIG. 12F, the cable forming portion according to the present embodiment is formed so that two tracks intersect in a circular structure on a guide plate, and on both sides ("e" portion of FIG. 12F) of the circular track, Two orbits are formed. When the track is formed in this form, the circular track forms a "-" shaped conductive cable body, and the two straight tracks form a conductive cable body having a "-" shaped cross-sectional shape.

Figure 12g shows a carrier driving means provided for transporting the carrier to the lower portion of the guide plate configured as shown in Figure 12f, a plurality of transfer gears 121 are arranged in a circular shape in the lower portion of the circular track, a straight track (Fig. The lower portion of the "e" of 12g) the transfer gear 121 is arranged in a straight shape and braided in a form similar to that shown in Figure 6b by transferring the carrier while being rotated together by the rotational force transmitted from the electric gear 123 The conductive cable will be manufactured.

As described above, the braided conductive cable according to a preferred embodiment of the present invention, a method of manufacturing the same, and a manufacturing apparatus thereof are shown in accordance with the above description and drawings, but this is merely described by way of example and the technical spirit of the present invention. Those skilled in the art will appreciate that various changes and modifications can be made without departing from the scope of the invention.

a: conductive line weave section b: conductive line exposed section
c: orbit S1: step of forming the conductive line binding section
S2: conductive line exposed section forming step 11: conductive line
12: Companion 13: Core History
110, 310: cable forming unit 120, 240, 320: carrier driving means
130, 250, 330: cable lead-out 140, 340: lead-out drive means
150: clutching part 151: clutch member
152: operation unit 153: actuator
154,380 input unit 155,390 control unit
160,350: Storage roller 170,260: Main drive
220: frame 230: basic cable forming portion
240: additional cable forming unit 360: carrier drive motor
370: drive part motor

Claims (19)

In the braided conductive cable formed of a linear member having a long length of the conductive wire and the companion wire supplied with the conductive wire are wound together or wound together,
The conductive wire is connected to the companion line is constrained integrally with the conductive wire binding section (a), and the conductive line is characterized in that it is configured to have a conductive line exposed section (b) exposed to the outside without being tied to the companion line Braided conductive cable. The method of claim 1,
The braided conductive cable has a central yarn disposed at one or more strands along a longitudinal direction such that the conductive line and the companion line are wound at an inner center thereof.
The conductive line and the companion line are sequentially braided to the center yarn to form different layers, or are braided conductive cables, characterized in that they are simultaneously woven to the center yarn and arranged in one layer. The method of claim 2,
The center yarn is arranged in a plurality of strands in parallel along the longitudinal direction, the conductive wire and the companion line is interwoven between the intersecting in a substantially "8" shape alternately between the center yarn braided conductive cable. The method of claim 1,
The braided conductive cable has a plurality of conductive wires and the companion wires are woven together to form a band shape, wherein the surface of the band is formed to have three or more surfaces having an angle with respect to each other Conductive cable. The method of claim 4, wherein
The cross-sectional shape of the braided conductive cable may be formed to have a cross-sectional shape of any one of "a" shape, "c" shape, "ㅁ" shape, "Δ" shape "I" shape, and "H" shape, or " ㅇ "Shape, semi-circle," ㅡ "shape," ㄱ "shape," ㄷ "shape," ㅁ "shape," △ "shape" I "shape," H "shape. A braided conductive cable, characterized in that formed. The method of claim 5,
A braided conductive cable comprising a central yarn disposed in at least one strand along a longitudinal direction so as to be positioned between the conductive line and the companion line. The method according to any one of claims 1 to 6,
The conductive line is composed of a plurality of conductive yarns formed in a bundle,
The conductive yarn is composed of one or more selected from the conductive yarns containing or coated with a conductive material in the metal yarn, carbon fiber yarn, fiber yarn,
The electrically conductive yarn is composed of only insulated or not insulated, or braided conductive cable, characterized in that the mixed and insulated and not insulated together. The method of claim 7, wherein
The companion wire is a braided conductive cable comprising a wire rod having a conductive wire in the same way as the conductive wire, or a fiber yarn having no conductivity. The method according to any one of claims 2, 3 and 6,
The core thread is a braided conductive cable, characterized in that the flexible wire rod formed to have elasticity against the applied external force. The method according to claim 9,
The stretched wire is braided conductive cable, characterized in that composed of a stretchable polymer yarn formed of a stretchable polymer resin, or formed in a coil structure. The method according to any one of claims 2, 3 and 6,
The core yarn is a high-strength fiber yarn having a heat resistance and tensile strength, a fiber yarn having a hollow portion, a foam yarn formed by foaming a polymer resin, a conductive yarn containing or coated with a conductive material in the fiber yarn, ceramic fiber yarn, glass fiber yarn, And any one selected from carbon fiber yarns. In the manufacturing method of the braided conductive cable formed of a linear member having a long length of the conductive wire, and the accompanying wire supplied with the conductive wire is wound in a winding method or weaving method,
A conductive line weaving section forming step of forming a conductive line weaving section in which the conductive line and the companion line are woven together to be integrally constrained; And
And a conductive line exposed section forming step of selectively forming a conductive line exposed section in which the conductive line is exposed to the outside without being tied to the companion line during the conducting of the conductive line binding section forming step.
In the forming of the conductive line weaving section, a supply process of supplying the conductive line and the companion line, a weaving process of weaving the conductive line and the companion line supplied through the supply process into a long linear member, and the weaving process Formed by simultaneously carrying out the drawing process to pull out the braided conductive cable formed by weaving through,
In the forming of the conductive line exposed section, the conductive line is exposed to the outside without being tied to the companion line by forming only the supply process and the withdrawal process without performing the weaving process in a predetermined section to form the conductive line exposed section. A method for producing a braided conductive cable, characterized in that the. The method of claim 12,
And a center yarn supplying process for supplying a center yarn disposed in the longitudinal direction through the inner center of the braided conductive cable or between the serving portions of the conductive wires. In the manufacturing apparatus of the braided conductive cable which is made of a linear member having a long length by weaving the conductive wire and the accompanying wire supplied with the conductive wire in a coiling or weaving method,
A cable forming part including a plurality of carriers around which the conductive line and the companion line are wound, and a guide plate having a track into which the carrier is inserted to form the braided conductive cable by weaving the conductive line and the companion line together;
Carrier drive means for moving the carrier along the trajectory by power transmitted from a main drive;
A cable lead-out unit which is operated simultaneously with the operation of the cable forming unit and pulls out the braided conductive cable formed by the cable forming unit to the outside;
Lead-out drive means for operating the cable lead-out by power transmitted from the main drive; And
It includes a clutching portion for intermittent the power transmitted to the cable forming portion and the cable lead-out,
The clutching portion,
Power is simultaneously transmitted to the carrier driving means and the lead-out driving means to simultaneously conduct the braided conductive cable weaving process, and the drawing process. The first clutching position to be formed and the transmission of power to the carrier driving means is cut off and the power is transmitted only to the lead-out driving means so that only the supplying and drawing process of the conductive line and the companion line is performed and the conductive line is carried out. A clutch member having a second clutching position which is not entwined with the companion line and is exposed to the outside to form a conductive line exposed section; And
And an operation portion for operating the clutch member to selectively perform the clutching steps to the first and second clutching positions. The method of claim 14,
The clutch member is engaged to transfer power to the carrier driving means and the lead-out driving means in a state where the clutch member is moved to the first clutching position, and the carrier driving means and the carrier driving means in the state where the clutch member is moved to the second clutching position. It is composed of a power transmission gear is engaged so that the engaged state of the release is released and the power can be transmitted only to the drive unit driving means,
And said operating part is an operating lever capable of selectively switching the flow of power to said first and second clutching positions. The method of claim 14,
An actuator for operating the clutch member to the first clutching position or the second clutching position according to a control signal;
An input unit configured to input an input signal for operating the actuator; And
And a control unit for controlling driving of the actuator according to the input signal of the input unit. The method according to any one of claims 14 to 16,
The main drive device includes a drive motor and a power transmission device for transmitting the power generated from the drive motor to the input side of the clutching portion manufacturing apparatus of the braided conductive cable. In the manufacturing apparatus of the braided conductive cable which is made of a linear member having a long length by weaving the conductive wire and the accompanying wire supplied with the conductive wire in a coiling or weaving method,
A cable forming part including a plurality of carriers around which the conductive line and the companion line are wound, and a guide plate having a track into which the carrier is inserted to form the braided conductive cable by weaving the conductive line and the companion line together;
Carrier driving means for moving the carrier along the track;
A carrier driving motor applying a driving force to the carrier driving means;
A cable lead-out unit for pulling out the braided conductive cable formed by the cable forming unit;
Lead-out drive means for operating the cable lead-out by power transmitted from a main drive;
A drawer driving motor for applying a driving force to the drawer driving means;
An input unit configured to input an input signal for operating the carrier driving motor and the extractor driving motor; And
A control unit controlling driving of the carrier driving motor and the drawing unit driving motor according to an input signal of the input unit;
The control unit,
Power is simultaneously transmitted to the carrier driving means and the lead-out driving means to connect the braided conductive cable, and the drawing process is carried out at the same time. A first control step of forming the
Power transmission to the carrier driving means is cut off and power is transmitted only to the lead-out driving means so that only the supplying and drawing process of the conductive line and the companion line is performed, and the conductive line is not connected to the companion line and is exposed to the outside. A second control step of forming a conductive line exposed section, and
Bray, characterized in that the power transmission to the carrier driving means and the lead-out drive means is blocked at the same time to perform a third control step of the supply process, the weaving process, and the drawing process of the conductive line and the companion line is stopped at the same time Apparatus for manufacturing deed conductive cable. The method according to any one of claims 14 to 16 and 18,
Apparatus for manufacturing a braided conductive cable, characterized in that the cable forming portion is formed in multiple stages so as to supply or weave the conductive line and the companion line to form the braided conductive cable in a multi-layered structure.

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