KR20150015566A - Harness cable manufacturing apparatus - Google Patents

Abstract

The present invention relates to a harness cable manufacturing apparatus. A cable receiving part and a pin receiving part vertical to the cable receiving part are respectively formed in the side of a working table. A cable transfer part of transferring a cable is installed to the upper side of the working table. A cable forming part is installed to the front part of the cable transfer part. A pressing part is installed to the side opposite to the cable forming part. A stripped cable in the cable forming part and a pin connector received in the pin receiving part are moved and crossed. The cable and the pin connecter are pressed by a pressing part so that a harness cable of connecting the power source of an electric device and the electric signal is manufactured. According to the present invention, a cable transfer, a cutting, a striping and pressing process are automatized, thereby improving productivity, lowering defects by producing uniform products with automation, improving the reliability of products, minimizing the volume of a device by integrating each device having a cutting, striping, and a pressing process, facilitating maintenance with an integrated device, reducing the number of workers by disposing a few managers of managing the processes, saving labor costs, and allowing a worker to perform other processes at the same time.

Description

[0001] DESCRIPTION [0002] Harness cable manufacturing apparatus [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a harness cable manufacturing apparatus, and more particularly, to a harness cable manufacturing apparatus that improves the harness cable production yield by automating the process of cutting off, cutting, and connecting a pin connector to a cable.

Generally, a harness cable is a cable that connects a power source or an electrical signal between a vehicle or an electric device provided in various electric or electronic devices.

At this time, the harness cable is classified into small, medium and large according to the use purpose.

For example, medium- and large-size harness cables are mainly used for automobiles, ships, aircraft, military equipment or large ships, and small harness cables are used for small electronic devices such as mobile phones, notebooks and digital cameras.

The harness cable is connected at one end with a connector pin, which is connected to another terminal inside the electronic device, and an electric wire exposed to the outside at the other end is soldered to a board or a board to connect an electrical signal and a signal between the electric devices do.

Patent Document 1 is related to a cable cutting device, and Patent Document 2 is related to a cable breaking device, and FIG. 1 is a view showing a pin connector compression device.

Here, the cable cutting device and the cable breaking device refer to Patent Documents 1 and 2, and the pin connector press device will be described with reference to Fig.

First, with reference to Patent Document 1, when the cable is extended to the workpiece guide and the workpiece supply unit, the up-down cylinder and the LM unit of the workpiece supply unit are operated, and when the cable is moved by a predetermined pitch, The block advances in the Y-axis direction and pushes the cable toward the fixed clamping block, so that the cable is clamped between the clamping blocks.

At this time, two cylinders are operated simultaneously to interlock the press blocks, and the cutter blade in each press block enters from both sides of the cable to cut the cable.

A plurality of materials (cables) thus obtained are respectively subjected to a peeling operation through an optical fiber stripping stripper of Patent Document 2.

With reference to Patent Document 2, by placing the slider close to the fixed end, the cutout portion is opened with a distance by the elasticity of the movable member.

Then, when the operator presses the movable portion, the cable sheath is cut while the cut-out portion is in contact with the cable sheath in a state in which the cable sheath is raised on the first cutout groove and the position to be deviated from the end portion of the cable is measured and fitted using a ruler. Pulling the cable will cause the cable to peel off.

By repeating the above process by the operator repeatedly, the cable sheath is removed, thereby obtaining a plurality of cables from which a single sheath has been stripped.

Thereafter, the connector pin is pressed onto the cable through the compression device shown in Fig.

1, a work table 10, a receiving portion 20 installed on the upper surface of the work table 10 to support a cable C and a connector pin P so as to support the receiving portion 20, A pushing portion 30 provided on the upper surface of the work table 10 for lifting and lowering the connector pin P to press the connector pin P on the peeled portion of the cable C, And a guide 40 for guiding the light.

The receiving portion 20 is a structure having a recessed structure formed by an upper light blocking structure.

The pressing portion 30 is configured to engage with the receiving portion 20.

Here, the peeled portion of the cable C is placed on the receiving portion 20, and the pin connector P is stacked on the peeled portion of the cable C in this state.

Then, the pressing portion 30 is operated to move up and down so that the pressing portion 30 is engaged with the receiving portion 20.

Then, the pushing portion 30 enters the recessed portion 20, and presses the pin connector P and the cable C at the same time.

At this time, both ends of the pin connector P are pressed by inclined surfaces formed by the depression of the receiving portion 20, and are folded in directions opposite to each other, thereby wrapping the peeled portion of the cable C.

Thus, the harness cable to which the pin connector is connected at one end is manufactured through the process described above.

However, when the harness cable is manufactured using the above-described devices and mechanisms

First, it is troublesome for the operator to collect the cable cut by the cell unit, and the collected cable must be moved to the place where the apparatus and the device corresponding to the next process are located. There is a problem that the number of unnecessary working personnel is increased due to mobilization of personnel.

Secondly, since a large number of bulky equipments are provided, the number of personnel is increased by attaching personnel to each of the equipments, and the number of working people is increased, There is a problem.

Third, the process of removing and compressing the outer skin is manually performed by the operator, resulting in an increase in the defective product rate, a difficulty in producing a uniform product, a reduction in the production yield due to a change in product manufacturing time according to the efficiency of the worker, There is a problem that the reliability is lowered.

KR 10-0834882 B1 KR 10-0958773 B1

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a cable carrying unit, which has a cable receiving portion and a pin receiving portion orthogonal to the cable receiving portion, A cable forming portion is provided in front of the cable conveying portion and a crimping portion is provided on a side opposite to the cable forming portion so that the cable having the outer sheath removed from the cable forming portion and the pin connector accommodated in the pin receiving portion are cross- And to provide a harness cable manufacturing apparatus which manufactures a harness cable for connecting a power source or an electric signal between electric devices by pressing the cable and the pin connector with a crimping section.

In order to achieve the above object, according to the present invention, there is provided an apparatus for manufacturing a harness cable, comprising: a work table; A cable receiving part installed on one side of the work table to receive the cable; A cable feeder installed on the top surface of the workbench to move a cable accommodated in the cable receiver; A cable forming part installed in front of the cable conveying part and lifted and lowered in a vertical direction of the cable moving direction to break the cable sheath cut and cut to a predetermined length; A pin receiving portion provided on the other side of the work table perpendicular to the cable receiving portion and receiving the pin connector; A pin transfer unit installed on a side surface of the work table opposite to the pin receiving unit, the pin transfer unit moving the pin connector accommodated in the pin accommodating unit to cross the cable; And a crimping portion provided at the rear of the cable forming portion and vertically moved up and down to press the pin connector to a portion where the outer surface of the cable is peeled off.

In the apparatus for manufacturing a harness cable according to the present invention, the cable conveying portion is provided with a plurality of rotating rollers which are opposed to each other and spaced apart from each other in the longitudinal direction so as to push the outer surface of the cable forward, And a guide member for guiding the movement of the cable is formed at a central portion between the guide members.

In the apparatus for manufacturing a harness cable according to the present invention, a press-in roller portion is formed between the cable receiving portion and the cable conveying portion to form a plurality of press-in rollers for pressing the outer surface of the cable to be conveyed to the cable conveying portion, .

In the apparatus for manufacturing a harness cable according to the present invention, a guide tube for guiding the cable, which has passed through the cable conveying portion, to the cable forming portion is further formed between the cable conveying portion and the cable forming portion.

In the harness cable manufacturing apparatus according to the present invention, the cable forming unit may include: a vertical support plate fixed to the upper surface of the work surface and having a guide groove formed on one surface thereof; A lifting block slidably coupled to the guide grooves and being lifted and lowered in directions opposite to each other; A cable cut-off surface fixed to each of the elevating blocks and formed with an outer cutter blade that is connected to each other by lifting and lowering operation of the elevating block to break the cable sheath; And a cable cutter blade fixedly installed on the lifting block facing the mutually opposing surfaces of the sheathing support and for cutting the cable, wherein the sheathing support portion is fixed to one of the elevating blocks and supports the outer surface of the cable, And a second electrode.

In the apparatus for manufacturing a harness cable according to the present invention, the crimping portion includes: a vertical support plate fixed to the upper surface of the work table and having guide rails formed on one surface thereof; An elevating member provided in a pair so as to face each other and being slidably engaged with the guide rails and moving up and down in opposite directions; A pushing member fixedly installed on one of the elevating members and pressing the pin connector and the cable; And a supporting member fixed to the elevating member opposed to the pressing member and supporting the pin connector and the cable by supporting the pin.

According to the present invention, it is possible to improve productivity of a product by automatically carrying out a cable feeding, cutting, peeling, and pressing process operations, producing a uniform product by automation to reduce a defect rate, .

In addition, each of the devices having the functions of cutting, peeling, and pressing is integrated into one device to minimize volume, and an integrated device can be maintained and easily managed.

In addition, a small number of workers who manage and supervise the process are disposed, which reduces labor costs and saves labor costs, and allows the worker to perform other tasks simultaneously by automating the processes.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic view showing a conventional compactor. Fig.
2 is a schematic view showing a harness cable manufacturing apparatus according to the present invention.
3 is a view showing a cable receiving portion and a press-fitting roller portion of a harness cable manufacturing apparatus according to the present invention.
4 is a perspective view showing a cable feeder of the harness cable manufacturing apparatus according to the present invention.
5 is a perspective view showing a cable forming unit of a harness cable manufacturing apparatus according to the present invention;
FIG. 6A is a view showing a state in which a cable sheath is unscrewed from a cable breaking portion of a harness cable manufacturing apparatus according to the present invention. FIG.
6B is a view showing a state where a cable is cut by a cable cutting portion of a harness cable manufacturing apparatus according to the present invention.
7 is a view showing a crimping portion of a harness cable manufacturing apparatus according to the present invention.
8A to 8B are views showing a state in which a cable and a connector pin are crossed and compressed in a crimping portion of a harness cable manufacturing apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The work table 100 is protruded to a predetermined height on the ground.

The work table 100 supports the cable receiving portion 200, the cable feed portion 300, the cable forming portion 400, the pin receiving portion 500, the pin feed portion 600, and the pressing portion 700 .

The work table 100 is preferably formed in a frame structure.

A tension roller 101 for holding the tension of the cable C sandwiched between the cable receiving portion 200 and the press roller portion 310 is installed on one side of the work table 100.

The tension rollers 101 are provided in a plurality of staggered structures so as to be staggered so that the tension of the cable C is maintained.

An operation button 102 for operating the cable receiving part 200, the cable feed part 300, the pin receiving part 500 and the pressing part 700 is formed on one side of the work table 100.

The cable receiving portion 200 is installed on one side of the work table 100 to receive the cable C.

The cable receiving portion 200 preferably has a roller structure in which a cable C is wound around the outer surface.

The cable receiving portion 200 is rotated by a motor (not shown) to transfer the cable C to the cable transfer portion 300.

The cable transfer unit 300 is installed on the upper surface of the work table 100 and moves the cable C accommodated in the cable receiving unit 200.

The cable feeder 300 is rotated by the servo motor 303 to move the cable C.

The cable conveying unit 300 is provided with a plurality of rotating rollers 301 which are opposed to each other and spaced apart from each other in the longitudinal direction to push the outer surface of the cable C forward, A guide member 302 for guiding the movement of the cable C is formed at the center portion between the guide members.

The outer surface of the rotating roller 301 is preferably formed in a hemispherical shape so as to surround the outer surface of the cable C and move the cable C forward.

The rotating rollers 301 are provided so as to face each other, and allow the cable C to pass therethrough and move forward.

The guide member 302 is formed to surround the outer surface of the cable C and is installed between the rotation rollers 301 to move the cable C in parallel.

It is preferable that a plurality of the guide members 302 are installed between the rotation rollers 301.

A plurality of indentation rollers 311 for flattening the outer surface of the cable C are formed between the cable receiving portion 200 and the cable feeder 300 by pressing the outer surface of the cable C fed to the cable feeder 300 The press roller unit 310 is further provided.

The press-in rollers 311 are provided so as to face each other and spaced at predetermined intervals along the longitudinal direction.

The press-in rollers 311 are provided so as to be opposed to each other, and the cable C is passed therethrough so as to spread the cable C flat.

The outer surface of the press roller 311 is formed in a hemispherical shape corresponding to the outer shape of the cable C.

The cable forming part 400 is installed in front of the cable conveying part 300 and is lifted and lowered in the vertical direction of the moving direction of the cable C so that the cable C is cut and cut into a predetermined length, do.

The cable forming unit 400 includes a vertical support plate 410, an elevating block 420, a cable removing unit 430, and a cable cutting unit 440.

The cable removing skin 430 and the cable cutting portion 440 are simultaneously lifted and lowered by the lifting block 420.

The vertical support plate 410 is fixed on the upper surface of the work table 100 and has a guide groove 411 formed on one surface thereof.

The elevating blocks 420 are provided so as to be opposed to each other and are slidably engaged with the guide grooves 411 and moved up and down in opposite directions.

The elevating block 420 is elevated and lowered by a driving motor (not shown).

The cable removing skin 430 is fixed to each of the elevating blocks 420 and connected to the elevating block 420 by the elevating and lowering operation of the elevating block 420 to cut off the outer surface of the cable C, .

The outer cutter blade 431 is formed in a hemispherical shape so as to cut the outer surface of the cable C.

It is preferable that the hemispherical diameter formed by recessing the outer cutter blade 431 is equal to the inner circumferential surface diameter of the outer circumference of the cable C. [

The cable cutting portion 440 is fixed to any one of the elevating blocks 420 and is formed with a sheath support portion 441 for supporting the outer surface of the cable C. The sheath support portion 441, A cable cutter blade 442 fixed to the lift block 420 for cutting the cable is formed.

The sheath support portion 441 and the cable cutter blade 442 of the cable cutting portion 440 are passed to be offset from each other by the lifting and lowering operation of the lifting block 420 to cut the cable C. [

Preferably, the cable cutting portion 440 is positioned in front of the cable removing skin 430.

The pin receiving portion 500 is provided on the other side of the work table 100 that is orthogonal to the cable receiving portion 200 and accommodates the pin connector P. [

The pin receiving portion 500 preferably has a roller structure in which a pin connector P is wound around the outer surface.

The pin receiving portion 500 is rotationally operated by the pin transferring portion 600 that moves the pin connector P.

The pin connectors P are attached to the connecting strips (not shown) at predetermined intervals along the longitudinal direction.

The pin transfer part 600 is installed on the side of the work table 100 facing the pin receiving part 500 and moves the pin connector P accommodated in the pin receiving part 500 so as to cross the cable C .

The pin transfer unit 600 is rotated by a driving motor (not shown) to pull the pin connector P. [

The crimping portion 700 is installed at the rear of the cable forming portion 400 and is lifted and lowered in the vertical direction to press the pin connector P onto the portion where the outer skin of the cable C is peeled off.

The pressing unit 700 includes a vertical supporting plate 710, an elevating member 720, a pressing member 730, and a supporting member 740.

The vertical support plate 710 is fixed to the upper surface of the work table 100 and has guide rails 711 formed on one surface thereof.

The elevating members 720 are provided in pairs so as to face each other and are slidably engaged with the guide rails 711 so as to move up and down in opposite directions.

It is preferable that the elevating member 720 is moved up and down by a driving motor (not shown).

The pressing member 730 is fixed to any one of the elevating members 720 to press the pin connector P and the cable C. [

The pushing member 730 forms a protruding portion 731 of the upper light blocking structure and simultaneously presses the pin connector P and the cable C with the protruding portion 731.

The protruding portion 731 enters the inclined groove 741 of the receiving member 740 and presses the pin connector P to the cable C. [

The supporting member 740 is fixed to the elevating member 720 opposed to the pressing member 730 and supports the pin connector P and the cable C by supporting the supporting member 740.

An inclined groove 741 for seating the cable C and the pin connector P is formed on the upper surface of the receiving member 740.

The inclined grooves 741 enter the protrusions 731 of the pressing member 730 to support the cable C and the pin connector P. [

The harness cable manufacturing apparatus according to the present invention constructed as above operates as follows.

The terminal end of the cable C accommodated in the cable receiving portion 200 is positioned in the cable forming portion 400 and the terminal accommodated in the pin receiving portion 500 is inserted into the pin connector P (Not shown) to the pin transfer unit 600 is directly performed by the operator, and a description thereof will be omitted.

The cable transferring unit 200, the cable forming unit 400, and the crimping unit 700 are operated simultaneously and simultaneously. In the present invention, the respective parts will be sequentially described along the movement path of the cable C. FIG.

First, the operation button 102 of the work table 100 is operated to operate the apparatus with the cable (C) and the connection pin (not shown) of the pin connector P positioned in the above-described position.

Then, the rotation roller 301 of the cable feeder 300 is rotated in the forward direction to push the cable C forward and to pass through the guide member 302.

At this time, the cable C received in the cable receiving portion 300 is conveyed to the cable conveying portion 300 through the tension roller 101 and the press roller portion 310.

Here, the tension roller 101 keeps the cable C between the cable receiving portion 200 and the press-fit roller portion 310 in a state of being tight.

The press roller 311 spreads the cable C fed to the cable feeder 300 in a flat manner.

At this time, the press-in rollers 311 are formed as a pair, press-fit the outer surface of the cable C while allowing the cable C to pass therethrough so that the cable C is flattened.

The cable C that has passed through the cable conveyance unit 300 is guided by the guide tube 320 and is positioned at the cable descender 430 of the cable forming unit 400.

Here, the cable C is sandwiched between the rotating rollers 301 of the cable feeder 300, which is inactivated, and is located at the cable descaling 430.

The elevation block 420 of the cable forming part 400 is moved up and down along the guide grooves 411 of the vertical support plate 410 so that the outer surface of the cable descaling skin 430 The cutter blades 431 are connected to each other to cut the outer surface of the cable C.

The rotation of the rotating roller 301 of the cable feeder 300 is reversed so that the cable C located on the cable removing skin 430 is moved backward so that the outer surface of the cable C is removed, The cable C is moved to the crimping portion.

At this time, the cable feeding part 300 places the cable C in the crimping part 700 and stops.

At the same time, the pin conveying unit 600 is rotated to move the connecting strip (not shown) attaching the plurality of pin connectors P in the direction orthogonal to the cable C, And moved to the crimping portion 700.

Thus, the portion where the outer skin of the cable C is peeled off and the pin connector P are positioned on the same vertical line between the pushing member 730 and the receiving member 740.

The elevating member 720 of the pressing portion 700 is moved up and down along the guide rail 711 of the vertical supporting plate 710 and the pressing members 730 and 730 of the elevating member 720 And the pin member P is connected to the cable C while the support members 740 are connected to each other.

That is, the protrusion 731 of the pressing member 730 enters the inclined groove 741 of the receiving member 740 and presses the pin connector P and the cable C, And both ends are folded in the direction in which they are opposed to each other so as to cover the portion where the outer surface of the cable C is peeled off.

The pressing member 730 and the receiving member 740 of the crimping portion 700 are returned to their original positions and the rotating roller 301 of the cable feeding portion 300 is rotated forward to rotate the cable connecting the pin connector P (C) is moved forward.

The cable C to which the pin connector P is connected is positioned in front of the cable cutting portion 440 of the cable forming portion 400 by the cable feeding portion 300 and the cable forming portion 400 The lifting block 420 is lifted and lowered.

At this time, the sheath support portion 441 of the cable cutting portion 440 supports the outer surface of the cable C, and the cable cutter blade 442 is passed so as to be staggered with the sheath support portion 441 to cut the cable C , A cell-based harness cable is obtained.

Here, the cable removing skin 430 is lifted and lowered at the same time as the cable cutting portion 440, and the sheath of the rear portion of the cable C spaced a predetermined distance from the cut portion of the cable C is peeled off.

Thereafter, the cell-unit harness cable is pushed by the cable (C) to which the pin connector (P) positioned in front of the cable cutting portion (440) is connected and is discharged to the outside.

Accordingly, the present invention can produce a large amount of harness cable by the repetitive operation as described above.

As a result of automating the process of conveying, removing, cutting and cutting the cable (C) and pressing the pin connector (P) to the cable (C), the operation of the cable transfer, cutting, Improvement of production efficiency, production of uniform product by automation, decrease of defective rate, which improves the reliability of product, and minimizes volume by integrating each device having cutting, dissolving and pressing functions into one device And it is easy to manage by maintaining a single integrated device, and the labor cost is saved at the same time as the number of the working personnel is reduced.

The above-described harness cable manufacturing apparatus according to the present invention is not limited to the above-described embodiments, and various modifications and changes may be made without departing from the scope of the present invention as defined in the following claims. There is a technical spirit to the extent that anyone can make various changes.

100: work table 101: tension roller
102: Operation button 200: Cable receiving portion
300: cable feeder 301: rotating roller
302: guide member 310: press-fit roller unit
311: press-in roller 320: guide tube
400: cable forming part 410: vertical supporting plate
411: guide groove 420: lift block
430: Cable removal skin 431: Sheath cutter blade
440: Cable cutting portion 441:
442: cable cutter blade 500: pin receiving portion
501: stationary roller 600: pin transfer part
700: Crimping portion 710: Vertical support plate
711: guide rail 720: elevating member
730: pressing member 731:
740: support member 741; Oblique groove
C: Cable P: Pin connector

Claims (6)

A work table 100;
A cable receiving portion 200 installed at one side of the work table 100 to receive the cable C;
A cable transferring part 300 installed on the upper surface of the work table 100 to move a cable C accommodated in the cable receiving part 200;
A cable forming part 400 installed in front of the cable conveying part 300 and lifted and lowered in the vertical direction of the moving direction of the cable C to break the cable C cut in the predetermined length and to break the sheath of the cut cable C, ;
A pin receiving portion 500 installed on the other side of the work table 100 orthogonal to the cable receiving portion 200 to receive the pin connector P;
A pin transfer unit 600 installed on the side of the work table 100 facing the pin receiving unit 500 and moving the pin connector P accommodated in the pin receiving unit 500 to cross the cable C; And
A crimping portion 700 installed at the rear of the cable forming portion 400 and lifted and lowered in a vertical direction to press the pin connector P onto a portion where the outer surface of the cable C is peeled off;
Wherein the harness cable is connected to the harness cable. The method according to claim 1,
The cable feeder 300 includes:
A plurality of rotating rollers 301 which are arranged to be spaced apart from each other in the longitudinal direction so as to move the outer surface of the cable C forward and to move the cable C forward, And a guide member (302) for guiding movement of the guide member (302). The method according to claim 1,
Between the cable receiving part 200 and the cable feed part 300,
And a pressing roller unit 310 forming a plurality of pressing rollers 311 for spreading the outer surface of the cable C by pressing the outer surface of the cable C fed to the cable feeding unit 300 Harness cable manufacturing apparatus. The method according to claim 1,
Between the cable feeder 300 and the cable forming part 400,
Further comprising a guide tube (320) for guiding the cable (C) passed through the cable feeder (300) to the cable forming part (400). The method according to claim 1,
The cable forming part (400)
A vertical support plate 410 fixed on the upper surface of the work table 100 and having a guide groove 411 formed on one surface thereof;
A lifting block 420 which is provided in a pair so as to face each other and which is slidably engaged with the guide grooves 411 and moved up and down in opposite directions;
A cable cut-off surface 430 (see FIG. 4) that is fixed to each of the elevating blocks 420 and forms a sheathing cutter 431 that is connected to the elevating block 420 by lifting and lowering operation of the elevating block 420 to break the sheath of the cable C, ); And
The outer casing 441 is fixed to one of the elevating blocks 420 and is fixed to the elevating block 420 facing the outer casing supporting portion 441. [ A cable cutting portion 440 formed with a cable cutter blade 442 for cutting the cable;
Wherein the harness cable is connected to the harness cable. The method according to claim 1,
The crimping portion (700)
A vertical support plate 710 fixed on the upper surface of the work table 100 and having guide rails 711 formed on one surface thereof;
An elevating member 720 which is provided in pairs so as to face each other and which is slidably engaged with the guide rails 711 and moved up and down in a direction opposite to each other;
A pressing member 730 fixed to any one of the elevating members 720 and pressing the pin connector P and the cable C;
A supporting member 740 fixed to the elevating member 720 opposed to the pressing member 730 and supporting the pin connector P and the cable C so as to support it;
Wherein the harness cable is connected to the harness cable.

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