KR101968564B1 - Separating system for outer cladding of waste optical cable - Google Patents

Abstract

The present invention relates to an outer cladding separation system of a waste optical cable in which an outer cladding formed on a surface of a metal shield is continuously peeled and removed while continuously moving waste optical cables requiring recycling. The outer cladding separation system of a waste optical cable comprises: a waste optical cable transfer unit transferring one or more waste optical cables in a longitudinal direction; a cut groove forming unit inserting a blade into the waste optical cable, which is transferred in the longitudinal direction, in the longitudinal direction to continuously form a cut groove which is cut in the longitudinal direction to an outer cladding of the waste optical cable; and a cutting and peeling unit discharging compressed air through a jet nozzle to the cut groove formed in the outer cladding to cut the outer cladding along the cut groove by the compressed air discharged in the cut groove so as to peel and separate the outer cladding from a surface of a metal shield.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an outer cladding of waste optical cable,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an outer coating separating system for a waste optical cable, and more particularly, to an outer coating separating system for a waste optical cable in which an outer covering formed on the surface of a metal shield is continuously peeled and removed while continuously moving waste optical cables requiring recycling .

As is known, an optical cable is a kind of signal transmission means for transmitting an optical signal in which a plurality of thin optical fibers are bundled and electrical signals are converted through optical fibers.

The optical cable 100 includes a plurality of optical fibers 140 as shown in FIG. 5; An inner cladding 130 for fixing the optical fibers; A metal shield 120 formed on a surface of the inner cover to shield electromagnetic waves and protect the optical fibers 140; And an outer sheath 110 formed to be laminated on the surface of the metal shield 120 to mitigate external impact.

The optical fiber of this optical cable is lighter and thinner than the coaxial cable and occupies a space of 10 billion times wider than the copper wire which is used in the past.

The optical cable is used in a data transmission field requiring high speed data transmission and high reliability because the transmission speed of the optical signal is very fast and the transmission error is only one tenth of a billionth. There is a great advantage in network security because it is not subject to electrical interference in relation, and its use is increasing widely.

In recent years, attempts have been made to reuse such optical cables to minimize the generation of hazardous wastes and reuse of resources.

However, unlike the coaxial cable, the optical cable has a metal shield formed therein. In order to recycle the optical cable, an outer cover formed on the surface of the metal shield is peeled off from the metal shield.

Accordingly, various devices for removing the outer covering from the waste optical cable have also been proposed in the art.

Korean Patent Laid-Open Publication No. 10-2012-0067587 discloses a method and an apparatus for peeling off a cover of a cable. The cable includes an entrance roller guided and guided by a guide roller, a cable passing through the entry roller, A thermal expansion region for guiding the flaring of the cover in a state where a curved line is formed on the cover by the blade of the blade holder portion and a thermal expansion region for guiding the flaring of the cover, And a guide tube for guiding to be automatically separated into a cover body is formed to peel off the covering member of the recovered recovered electric wire, and a method and an apparatus for peeling off the cable cover body are disclosed.

However, since the conventional technique described above requires a process of sufficiently heating the outer coating of the waste optical cable in the thermal expansion region to thermally expand, a long time and power are consumed due to the heating of the waste optical cable.

In particular, there is a problem in that a large amount of electric power is consumed due to the heating of the waste optical cable, odor and environmental pollution occur, and the coating is heated for a long time, so that it takes a long time and productivity is deteriorated.

In addition, since it is difficult to completely remove the thermally expanded outer coating on the surface of the metal shield, it is pointed out that it is difficult to secure the reliability due to the separation of the outer coating.

No. 10-2012-0067587 Issue A 10-2017-0009197 Issue A 10-1329096 B1

An object of the present invention to solve the above problems is to continuously remove and remove an outer cover formed on a surface of a metal shield while continuously moving waste optical cables requiring recycling, The outer cover is forcedly peeled off along the cut grooves by the air pressure by the compressed air to remove the outer cover in a short time to stably peel off the outer cover in a short time, And to provide an outer jacket separation system for a waste optical cable.

The above object is achieved by the following constitutions provided in the present invention.

According to the present invention, there is provided an external coating / separating system for a waste optical cable,

A waste optical cable transfer part for transferring one or more waste optical cables in the longitudinal direction;

A cut-out groove forming unit for continuously cutting the longitudinally incised cut-out groove in the outer cover of the optical fiber cable by inserting the cut-out portion in the lengthwise direction into the waste optical cable to be transported in the longitudinal direction; And

And a cut-off separator for separating the outer cover from the surface of the metal shield and separating the outer cover from the surface of the metal shield by compressed air discharged through the injection nozzle into the cut-out groove formed in the outer cover by compressed air discharged in the cut- Respectively,

The outer sheath is cut by the compressed air discharged in the cutout groove and then separated and separated from the surface of the metal shield by compressed air penetrating between the inner wall of the outer sheath and the surface of the metal shield along the cutout cutout groove ,
The cut-
A support roller unit for supporting a lower half of a waste optical cable moved in the longitudinal direction by the waste optical cable transfer unit;
And a cutting blade unit that cuts a blade part on an upper part of a waste optical cable supported by the support roller unit to form a cutting groove in the longitudinal direction on the upper part of the waste optical cable,
The cut-
A blade member having a blade at a lower end thereof;
A hinge shaft for fixing the blade member in a vertically rotating structure; And
And a traction spring for elastically pulling the upper end of the blade member in one direction and elastically cutting the blade portion formed at the lower end of the blade member into an upper end portion of the optical fiber cable,
Further comprising a fixed scraping portion and a rotating scraping portion for scraping the surface of the metal shield of the waste optical cable whose outer cover is peeled off while passing through the cut-off peeling portion to remove the outer coating sludge remaining on the surface of the metal shield,
Wherein the fixed scraping portion comprises a fixed scraper having a plurality of semicircular grooves formed at the tip thereof and fixed by a support spring,
The half-moon blade is resiliently cut into the metal shield surface of the waste optical cable whose outer covering is primarily removed by the elastic function of the support spring to scrape the surface of the metal shield to remove the outer covering sludge remaining on the surface of the metal shield and,
Wherein the rotating type scraping portion comprises a rotary drum and at least one scraping blade disposed upright on the rotary drum,
Wherein a semicircular groove is formed at an outer end of each of the scraping blades, the scraping blade is made of an elastic steel sheet elastically deformed by external interference,
The metal shield of the waste optical cable is scraped by the semicircular grooves so that the outer coating sludge remaining on the surface is removed while the metal shield of the waste optical cable is moved into the semicircular groove of the scraping blade rotated by the rotary drum,
Wherein the fixed scraping portion and the rotating scraping portion are configured such that a vacuum suction unit is disposed and the outer covering sludge removed from the waste optical cable while passing through the scraping portion is collected by the vacuum suction unit.

Preferably, the cut groove forming unit comprises: a support roller unit having at least one support groove for supporting a lower half of the waste optical cable; And a cutting blade unit that cuts the blade part on the upper part of the waste optical cable supported by the support groove of the support roller unit to form a cutout groove cut in the longitudinal direction on the outer cover of the waste optical cable.

In addition, a tunnel type preheating portion for preheating the waste optical cable through the waste optical cable supplied in the longitudinal direction is provided to the waste optical cable transfer portion. The waste optical cable is preheated while passing through the tunnel type preheating portion, and sequentially passes through the cut groove forming portion and the cut- .

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The outer cover may be peeled off from the metal shield while passing through the cut-off peeling unit. The outer coat may be removed from the metal shield, To be peeled off from the metal shield while being pulled tight.

As described above, according to the present invention, a cutting groove forming step of forming cut grooves in the longitudinal direction in the outer covering while moving the waste optical cable in the longitudinal direction; A cutoff peeling step of peeling off the outer coat from the metal shield of the optical fiber cable along the cutout groove by discharging compressed air to the cutout groove is sequentially performed so that the outer coat is cut off by the compressed air discharged in the cutoff groove at high pressure, .

With this configuration, since the reduction of productivity and the excessive consumption of current due to the heating of the waste optical cable requiring recycling for a long time are prevented, the outer covering of the waste optical cable can be peeled and removed in a short time at low cost.

Since the outer cover can be stably peeled and discharged from the surface of the metal shield, the reliability of the operation due to the peeling and discharging of the outer cover is secured, and in particular, the harmful gas caused by heating the waste optical cable at high temperature is not generated Therefore, a pleasant work environment can be created.

1 and 2 show a waste optical cable in which an outer coating is peeled and removed by a coating and separating system for a waste optical cable proposed in a preferred embodiment of the present invention,
FIG. 3 is a schematic view showing the details of the cutting groove forming portion, the cut-off peeling portion, and the scraping portion, which are 'A' portions, in the coating and separating system of the waste optical cable shown in FIG.
FIG. 4 is an enlarged view showing detailed states of the 'B' portion, the 'C' portion, the 'D' portion and the 'E' portion in FIG. 2,
5 is a cross-sectional view of a waste optical cable in which an outer coating is removed by a coating and separating system for a waste optical cable proposed in a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a coating and separating system for a waste optical cable proposed in a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 show a waste optical cable in which an outer coating is peeled and removed by a coating and separating system for a waste optical cable proposed in the preferred embodiment of the present invention, and FIG. 3 is a view showing a waste optical cable of the waste optical cable shown in FIG. FIG. 4 is a view showing a detailed configuration of a cutout groove forming part, a cut-off peeling part, and a scraping part in the separation system, FIG. 5 is a view showing an enlarged detail state of the 'D' portion and the 'E' portion of the waste optical cable, Sectional view of the structure of FIG.

 The outer coating separating system 1 of the waste optical cable proposed in the preferred embodiment of the present invention is an outer covering separating system 1 for separating waste optical cables which are required to be recycled and which are formed on the surface of the metal shield 120 of the waste optical cable 100, (110) is peeled and removed.

As shown in FIG. 5, the waste optical cable 100 includes a plurality of optical fibers 140; An inner cladding 130 for fixing the optical fibers; A metal shield 120 formed on a surface of the inner cover to shield electromagnetic waves and protect the optical fibers 140; And an outer covering 110 formed to be laminated on the surface of the metal shield 120 to relieve an external impact, and the outer covering 110 is generally made of a thermoplastic resin such as PE.

As shown in FIGS. 1 and 2, the present invention for removing the outer cover 110 of the waste optical cable 100 includes a waste optical cable transferring unit (not shown) for transferring one or more waste optical cables 100 in the longitudinal direction 10); A cutout groove forming process for continuously forming a cutout groove 111 cut in the longitudinal direction is formed in the outer cover 110 of the waste optical cable 100 by cutting the blade portion in the longitudinal direction of the waste optical cable 100 transported in the longitudinal direction, (20); And the outer cover 110 is cut off by the high temperature compressed air discharged into the cutout groove 111 by discharging the high temperature compressed air through the injection nozzle 31 to the cutout groove 111 formed in the outer cover 110, And a cut-off peeling portion 30 that is cut along the groove 111 to be peeled and separated from the surface of the metal shield 120.

In this embodiment, as shown in FIGS. 1 and 2, a tunnel type preheating unit (not shown) for preheating the waste optical cable 100 by passing the waste optical cable 100 supplied in the longitudinal direction to the waste optical cable transfer unit 10 is provided in front of the waste optical cable transfer unit 10, (Not shown) while passing through the tunnel-type preheating section 50 in the longitudinal direction, and the outer cover is preheated by the heat emitted from the electrothermal heater (20) and the cut-off peeling unit (30).

Here, the preheating temperature by the tunnel preheating part 50 and the temperature of the compressed air discharged to the outer cover through the cut-off peeling part 30 to be described later are increased or decreased according to the thickness and the material of the outer cover of the optical fiber cable .

The waste optical cable transfer unit 10 includes a feeding unit 11 for feeding waste optical cables 100 in the longitudinal direction; And a pulling unit 12 for pulling and moving the waste optical cable 100 fed by the feeding unit 11 in the longitudinal direction.

In this embodiment, the cut groove forming portion 20, the cut-off peeling portion 30 and the scraping portion 40, which will be described later, are sequentially disposed between the feeding unit 11 and the pulling unit 12, A cutting groove forming step of forming cut grooves 111 in the longitudinal direction; A cutting and peeling step of discharging high temperature compressed air to the cutout groove 111 and peeling off the outer cover 110 along the cutout groove 111 from the metal shield 120 of the waste optical cable 100 is sequentially performed do.

3 and 4A, the cut groove forming unit 20 includes a support roller unit 21 for supporting the lower half of the waste optical cable 100 moved in the longitudinal direction by the waste optical cable conveyance unit 10; A cut-off blade unit 22 for cutting the blade part on the upper part of the waste optical cable 100 supporting the lower half by the support roller unit 21 to form a cut-out groove 111 in the longitudinal direction on the upper part of the waste optical cable 100, .

In this embodiment, as shown in FIGS. 3 and 4A, the support roller unit 21 is formed with the V-shaped support grooves 21a, which linearly support both sides of the lower half of the waste optical cable 100, at regular intervals.

3B, 3C and 4A, the supporting roller unit 21 linearly supports the lower half of the plurality of the waste optical cables 100, which are transported in the longitudinal direction through the waste optical cable transporting unit 10, Thereby preventing a phenomenon that the optical cable 100 rotates or flows from side to side.

The cutting blade unit 22, which is cut into the outer cover 110 of the waste optical cable 100 with the lower half supported by the support roller unit 21 to form the cutout groove 111, A blade member 22a having a blade portion 22a-a formed at the lower end thereof as shown in FIG. 3b; A hinge shaft 22b for fixing the blade member 22a in a vertically rotating structure; And a traction spring 22c that elastically pulls the upper end of the blade member 22a in one direction and elastically drains the blade 22a-a formed at the lower end of the blade 22a to the upper end of the closed optical cable 100. [

The waste optical cable 100 transported in the longitudinal direction by the waste optical cable transporting unit 10 is transported to the outer covering 110 while being supported by the supporting roller unit 21 while passing through the cut- A cut-out groove 111 cut in the longitudinal direction is formed at the upper portion by the blade portion 22a-a of the blade member 22a which is resiliently inserted into the cut-out portion.

At this time, the cut-out groove 111 formed in the longitudinal direction of the outer cover 110 has a shape gradually becoming narrower from the upper part to the lower part, and the cut-out part of each injection nozzle 31 of the cut- The high-pressure compressed air discharged at high pressure is cut off to the left and right.

The waste optical cable 100 to be transported in the longitudinal direction by the waste optical cable transporting unit 10 is cut by the blade portion 22a-a of the blade member 22a, which is inserted in the longitudinal direction while passing through the cut groove forming portion 20, A cut-out groove 111 cut in the longitudinal direction is formed on the outer covering 110 by the cut-

The high-temperature compressed air discharged from the jetting nozzle 31 of the cut-off peeling unit 30 is supplied to the cut groove 111 formed in the longitudinal direction of each of the closed optical fibers 100 while passing through the cut groove forming unit 20 The outer cover 110 is cut off right and left along the cutout groove 111 to be peeled off from the surface of the metal shield 120 of the scrapped optical cable 100 and removed therefrom, as shown in FIGS. 3B, 3C and 4B, do.

That is, the outer cover 110 formed with the 'V' type cut-out groove 111 is cut along the cut-out groove 111 by the high-temperature compressed air, and then the inner wall of the outer cover 110 and the metal shield The outer sheath 110 is peeled off from the surface of the metal shield 120 by the hot compressed air that penetrates between the surfaces of the metal shield 120.

At this time, the outer covering 110 continuously removed from the metal shield 120 is discharged in a state of being pulled tightly by the pull-out portion 60 disposed at the lower portion of the peel-off portion 30, (60) includes two or more discharge drums (61) that rotate circumscribedly each other.

Therefore, the outer cover 110 of the waste optical cable 100 passing through the cut-off peeling unit 30 is pulled by the pull-out portion 60 tightly and is compressed by the hot compressed air discharged into the cut- And is stably removed from the surface of the metal shield 120 and removed.

In this embodiment, the surface of the metal shield 120 of the waste optical cable 100, in which the outer cover 110 is primarily peeled off from the surface of the metal shield 120 while passing through the cut-off peeling unit 30, By adding scraping parts 40 and 70 which are scraped physically, a stable removal of the outer coating sludge S remaining on the surface of the metal shield 120 is achieved.

The fixed scraping portion 40 and the rotating scraping portion 70 are disposed in the present embodiment so that the outer coating sludge S remaining on the surface of the metal shield 120 is stably removed.

The stationary scraper 40 includes a stationary scraper 41 having a plurality of radial grooves 41a formed at the tip thereof. In this embodiment, the stationary scraper 41 is fixed to the support spring 42, The groove 41a is resiliently inserted into the surface of the metal shield 120 of the waste optical cable 100 whose outer covering is primarily removed by the action of the elasticity of the support spring 42 so that the surface of the metal shield 120 is scraped So that the outer coating sludge S remaining on the surface of the metal shield 120 is removed.

In this case, the fixed scraper 41 is provided with the support springs 42 so that the semicircular flute 41a is resiliently inserted into the surface of the metal shield 120. The semicircular flute 41a formed on the fixed scraper 41, Can be prevented.

4D and 4E, the rotating type scraping unit 70 includes at least one scraping blade 72 disposed upright on the rotary drum 71 and the rotary drum 71, A pair of scraping blades are arranged on the rotary drum 71 at an equal angle.

A semicircular groove 72a is formed at an outer end of each of the scraping blades 72, and the scraping blade 72 is made of an elastic steel sheet elastically deformed by external interference.

The metal shield 120 of the waste optical cable 100 in which the outer cover 110 is primarily removed while passing through the severing and peeling unit 30 is sandwiched between the scraping wings 72 rotated by the rotary drum 71, The outer coating sludge S scraped off by the semicircular flute 72a and left on the surface is removed while moving in the semi-circular groove 72a.

Particularly, in this embodiment, the vacuum suction unit 80 is disposed in the scraping parts 40 and 70, and the outer covering sludge removed from the waste optical cable while passing through the scraping parts 40 and 70 is discharged through the vacuum suction unit 80, .

The vacuum suction unit 80 includes a collecting chamber 81 and a vacuum suction pipe 82 for collecting the outer coating sludge by reducing the pressure in the collecting chamber 81.

4D, the rotating type scraping unit 70 is disposed in the collecting chamber 81, and the outer covering sludge S removed from the waste optical cable 100 by the rotating type scraping unit 70, To collect the vacuum.

Therefore, in the system 1 for separating the outer cover of the optical fiber cable according to the present embodiment, the cut-out groove forming portion 20 and the outer cover 110 formed on the surface of the metal shield 120 by the cut- And then the scrapping action by the scraping portions 40 and 70 and the vacuum suction action by the vacuum suction unit 80 are carried out in a stable manner on the outer coating sludge S remaining on the surface of the metal shield 120 As a result, the outer covering 110 formed on the surface of the metal shield 120 of the optical fiber cable 100 can be stably removed in a short time.

1. External coating separation system of waste optical cable
10. Waste optical cable transfer part
11. Feeding unit 12. Towing unit
20. Cutting groove forming part
21. Support Roller Unit 21a. Support groove
22. Cutting blade unit 22a. Blade member
22a-a. Blade 22b. Hinge axis
22c. Traction spring
30. Cutting off part 31. Injection nozzle
40. Fixed scraping part 41. Fixed scraper
41a. Half-moon groove 42. Support spring
50. Tunnel type preheating part 60. Traction exhaust part
70. Rotating type scraping unit 71. Rotating drum
72. Scraping wing 72a. Semi-circle home
80. Vacuum suction unit 81. Collection chamber
82. Vacuum suction pipe

Claims (5)

A waste optical cable transfer part for transferring one or more waste optical cables in the longitudinal direction;
A cut-out groove forming unit for continuously cutting the longitudinally incised cut-out groove in the outer cover of the optical fiber cable by inserting the cut-out portion in the lengthwise direction into the waste optical cable to be transported in the longitudinal direction; And
And a cut-off separator for separating the outer cover from the surface of the metal shield and separating the outer cover from the surface of the metal shield by compressed air discharged through the injection nozzle into the cut-out groove formed in the outer cover by compressed air discharged in the cut- Respectively,
The outer sheath is cut by the compressed air discharged in the cutout groove and then separated and separated from the surface of the metal shield by compressed air penetrating between the inner wall of the outer sheath and the surface of the metal shield along the cutout cutout groove ,
The cut-
A support roller unit for supporting a lower half of a waste optical cable moved in the longitudinal direction by the waste optical cable transfer unit;
And a cutting blade unit that cuts a blade part on an upper part of a waste optical cable supported by the support roller unit to form a cutting groove in the longitudinal direction on the upper part of the waste optical cable,
The cut-
A blade member having a blade at a lower end thereof;
A hinge shaft for fixing the blade member in a vertically rotating structure; And
And a traction spring for elastically pulling the upper end of the blade member in one direction and elastically cutting the blade portion formed at the lower end of the blade member into an upper end portion of the optical fiber cable,
Further comprising a fixed scraping portion and a rotating scraping portion for scraping the surface of the metal shield of the waste optical cable whose outer cover is peeled off while passing through the cut-off peeling portion to remove the outer coating sludge remaining on the surface of the metal shield,
Wherein the fixed scraping portion comprises a fixed scraper having a plurality of semicircular grooves formed at the tip thereof and fixed by a support spring,
The half-moon blade is resiliently cut into the metal shield surface of the waste optical cable whose outer covering is primarily removed by the elastic function of the support spring to scrape the surface of the metal shield to remove the outer covering sludge remaining on the surface of the metal shield and,
Wherein the rotating type scraping portion comprises a rotary drum and at least one scraping blade disposed upright on the rotary drum,
Wherein a semicircular groove is formed at an outer end of each of the scraping blades, the scraping blade is made of an elastic steel sheet elastically deformed by external interference,
The metal shield of the waste optical cable is scraped by the semicircular grooves so that the outer coating sludge remaining on the surface is removed while the metal shield of the waste optical cable is moved into the semicircular groove of the scraping blade rotated by the rotary drum,
Wherein a vacuum suction unit is disposed in the fixed scraping portion and the rotating scraping portion so that the outer coating sludge removed from the waste optical cable while passing through the scraping portion is captured by the vacuum suction unit. system. delete delete 2. The apparatus according to claim 1, further comprising a tunnel preheating unit for preheating the waste optical cable through a waste optical cable supplied in a longitudinal direction to the waste optical cable transfer unit,
Wherein the waste optical cable is sequentially supplied to the cut groove forming part and the cut-off peeling part in a preheated state while passing through the tunnel type preheating part. [3] The apparatus of claim 1, further comprising a traction discharging portion for traction and discharging the outer cover peeled off from the metal shield in the cut-off peeling portion,
Wherein the outer cover which is peeled off from the metal shield while passing through the cut-off peeling portion is pulled tightly by the pull-out portion and is peeled off from the metal shield.

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