JPH01196004A - Method and device for removing intermediate covering of optical fiber - Google Patents

Abstract

PURPOSE:To expose optical fibers without breaking and damaging the fibers by dropping or injecting a heated sulfuric acid to a covering material to melt the covering material and rinsing the molten part. CONSTITUTION:The chemically ion-bonded and covalent-bonded covering material (high-polymer material) 3 of the optical fibers 2 is decomposed, bonded and melted by the hot sulfuric acid. Water is then injected to the molten part by which the molten covering material 3 is forcibly washed away. The optical fibers 2 on which the covering material 3 does not remain and stick are thereby exposed without being broken and damaged. The sulfuric acid of only the amt. required to be injected or dropped is heated just prior to the injection or dropping to assure the safety of the device. A sulfuric acid tank 9 and waste covering material liquid discharge tank are made into an attachable/detachable cassette type to prevent the chance of an operator to come into direct contact with the sulfuric acid.

Description

[Detailed Description of the Invention] [Objective of the Invention] (Industrial Field of Application) This invention is applicable to cases where, for example, a failure occurs in an optical fiber during signal transmission and it is necessary to switch and connect to another optical fiber. The present invention relates to a method and apparatus for removing an intermediate coating of an optical fiber, which removes the coating member of a coated optical fiber at an intermediate portion thereof when a failure or the like occurs.

(Prior Art) An optical fiber communication line can realize a transmission line with a large amount of information. When operating and maintaining such a large-capacity transmission line, if a failure or problem occurs in the optical fiber core containing multiple optical fibers that are transmitting signals as a working line,
A technology is needed to quickly switch and connect to another optical fiber that is not transmitting signals.

In order to perform such switching and connection of optical fibers, first, remove part of the coating material in the middle of the optical fiber that has experienced a problem during signal transmission to expose the optical fiber. What is done is done. Next, this exposed optical fiber is cut and connected to another optical fiber that is not transmitting a signal to perform a switching connection. The cut optical fiber is connected to another optical fiber that is not transmitting signals by butt splicing or fusion splicing. In this case, as described above, the coating material in the middle part of the optical fiber core is removed to expose the optical fiber, but if even a small amount of coating material III remains and adheres to the exposed optical fiber, it may cause fusion. This can cause connection failures due to errors in connection, etc., and increase connection loss. For this reason, technology to completely remove the coating material has become important and essential.

Generally, nylon, silicone, epoxy-based UV (ultraviolet curing) resin, urethane-based UV material, etc. are used as coating materials for optical fiber core wires, and in the above cases, it is necessary to completely remove these various coating materials. It is necessary.

As a first conventional technique for removing the intermediate coating of such an optical fiber core, there is a technique using a coating removal device as shown in FIG. 5, for example (Japanese Patent Laid-Open No. 60-55303). In this first conventional technique, an optical fiber coated wire 35 is held by an optical fiber coated wire clamp 38, and a high-temperature inert gas (nitrogen gas, etc.) 39 is blown onto the coating material in the middle portion using a nozzle 40. The optical fiber 36 is exposed by melting and scattering the fibers.

However, in this first conventional technique, there was a problem in that a portion of the coating material remained on the exposed surface of the optical fiber 36 due to the adhesive force of the coating material.

In addition, in this conventional technology, five optical fibers are included in one optical fiber.
~ When removing the intermediate coating of a tape core wire in which 10 optical fibers are arranged side by side, some of the coating material filled between adjacent optical fibers will remain, so the coating It was difficult to completely remove the material.

Further, as a second conventional technique for removing the intermediate coating of an optical fiber core, there is a technique using a coating removal device as shown in FIG. 6 (Japanese Patent Application Laid-Open No. 166304/1982). In this second conventional technique, an optical fiber core 35 is placed along a heated semicircular thermal force 41, and an optical fiber 36 and a coating material 3
In this method, a coating separation plate 42 is inserted between the optical fibers 7 and 7 to separate the melted coating material and expose the optical fiber 36.

However, in this prior art, the molten coating material 37 remains hardened and becomes a small lump at the part where the molten coating material 37 and the optical fiber 36 are separated. and,
Since this locally damages the optical fiber 36, there is a problem in that the optical fiber 36 may be broken when the coating material 37 is separated. In addition, in this second conventional technique, when removing the intermediate coating of the tape core wire, a part of the coating material filled between adjacent optical fibers remains. I had a similar problem.

Furthermore, as a third conventional technique for removing the intermediate coating of a coated optical fiber, there is a pure mechanical method in which the coating material of the intermediate portion is mechanically stripped off using a cutter. However, in this method using a cutter, the outer diameter of the optical fiber is usually 0.
4-0.9mm, the outer diameter of the optical fiber is 0.125mm
The problem is that the optical fiber is easily damaged due to its small diameter and thin layer of coating material. In addition, in this third conventional technique, unstripped coating material tends to remain on the exposed optical fibers, and furthermore, when removing the intermediate coating of the tape core, it is difficult to remove the coating material between adjacent optical fibers. The first and second cases where the covering material remains
There was a problem similar to that of the prior art.

On the other hand, a commonly used method is to immerse polymeric materials such as plastics in sulfuric acid or hot sulfuric acid, decompose them, combine them, and melt them. In this case, a method is adopted in which a heater is provided in a sulfuric acid storage tank, a large amount of hot sulfuric acid is produced, and the hot sulfuric acid is injected onto a polymeric material such as plastic to melt it.

However, removing the intermediate coating of an optical fiber by melting and removing a minute coating material does not require the above-mentioned large equipment and human sulfuric acid. Handling large amounts of sulfuric acid may pose a danger to workers and others due to contact with the sulfuric acid.

(Problems to be Solved by the Invention) In the first and third conventional techniques, there is a problem that a part of the coating material remains on the exposed surface of the optical fiber. In this case, a part of the coating material filled between adjacent optical fibers remains and it is difficult to completely remove the coating material, which is common to the first to third conventional techniques. There was a problem. Further, in the second and third conventional techniques, there is a problem in that the exposed optical fiber is easily broken or scratched.

On the other hand, a method is known in which polymeric materials such as plastics are immersed in hot sulfuric acid to decompose, combine, and melt, but this method uses large amounts of hot sulfuric acid in large equipment.
It is difficult to apply this method directly to the removal of the intermediate coating of an optical fiber, which is a limited area of coating material, and there is a problem in that it poses a danger to workers and the like.

- This invention was made based on the above circumstances, and it is possible to expose an optical fiber without any residual coating material adhering to it without breaking or damaging it, and also to avoid danger to workers etc. An object of the present invention is to provide a method and apparatus for removing intermediate coating of an optical fiber.

[Structure of the Invention (Means for Solving the Problems) In order to solve the above problems, the first invention provides a method for sulfuric acid that is dripped or injected from a sulfuric acid nozzle in the process immediately before being fed to the sulfuric acid nozzle. heating, dropping or spraying the heated sulfuric acid from the sulfuric acid nozzle onto the coating material in the intermediate portion of the coated optical fiber to melt the coating material, and then spraying water onto the melted portion of the coating material. The main point is to wash the molten coating material and sulfuric acid with water.

A second invention includes a processing chamber, and a coated optical fiber holder that is provided in the processing chamber and holds a coated optical fiber to be processed and positions an intermediate portion of the coated optical fiber to be processed in the processing chamber. a sulfuric acid nozzle provided in the processing chamber and configured to drop or inject sulfuric acid onto the coating material in the intermediate portion of the coated optical fiber to be processed; a sulfuric acid tank configured to supply sulfuric acid to the sulfuric acid nozzle; A sulfuric acid heating section is provided immediately before the sulfuric acid nozzle in the sulfuric acid supply path and heats the sulfuric acid fed from the sulfuric acid tank, and a sulfuric acid heating section is provided in the processing chamber and is used to wash the molten part of the coating material melted with the heated sulfuric acid. The present invention is characterized in that it has a water nozzle that injects water for use, and a sulfuric acid drain tank connected to a drain port provided in the processing chamber and into which the sulfuric acid drain used for melting the coating material is poured.

A third invention is characterized in that, in the second invention, the sulfuric acid tank and the sulfuric acid drainage tank are each of a detachable cassette type.

In a fourth aspect of the invention, in the second aspect, the optical fiber holding section is a pair! ii! An inner layer made of a soft material that is resistant to acidic corrosion and is in close contact with the coated optical fiber to be processed, and an outer layer that is made of a hard material that is resistant to sulfuric acid and is provided outside the inner layer to support the inner layer. The gist is that the

(effect) In the above configuration, chemically ionic bonding and covalent bonding.

Coating material (polymer material) for coupled optical fibers
are decomposed, combined and melted by hot sulfuric acid. Then,
Water is injected onto the molten portion, forcing the melted coating material to wash away, exposing the optical fiber free of residual coating material without breaking or scratching. Sulfuric acid is
Only the necessary amount to be sprayed or dripped is heated immediately before spraying or dripping to ensure the safety of the device, and
The sulfuric acid tank and the sulfuric acid waste tank are removable cassette types to prevent workers from coming into direct contact with sulfuric acid.

(Example) Hereinafter, an example of the present invention will be described based on FIGS. 1 and 2.

First, to explain the optical fiber intermediate coating removal apparatus, in FIG. 1, 4 is a processing chamber;
includes an optical fiber holder 10 that holds the optical fiber core 1i11 to be processed and positions the intermediate portion thereof in the processing chamber 4, and a coating material 3 for the intermediate portion of the optical fiber core 1. A sulfuric acid nozzle 5 as an injection nozzle for dripping or spraying sulfuric acid and a water nozzle 6 for spraying water onto the melted portion of the coating material N3 are provided, and a drain lower is provided at the bottom. .

8 is a sulfuric acid supply section, and this sulfuric acid supply section 8 is equipped with a Ta acid tank 9, a sulfuric acid feed pump 13, and! A heater 15 is provided immediately before the sulfuric acid nozzle 5 in the sulfuric acid feed path 14 from the lIl acid pump 13.

A heated sulfuric acid heating section 16 is provided.

On the other hand, 17 is a water supply section, and this water supply section 17 includes:
A water tank 18 and a water supply pump 19 are provided.

Further, a sulfuric acid drain tank 24 and a drain tank 25 are connected to the drain lower via a switching valve 23. Switching valve 2
By switching 3, when sulfuric acid is being dripped into the processing chamber 4, the sulfuric acid wastewater is poured into the sulfuric acid wastewater tank 24, and when water is being injected into the processing chamber 4, the wastewater is poured into the sulfuric acid wastewater tank 24. It is designed to be poured into a tank 25.

Among the above-mentioned constituent members or parts, those that come into contact with sulfuric acid are made of materials such as tetrafluoroethylene resin or glass that have corrosion resistance against sulfuric acid.

Further, the sulfuric acid tank 9 and the sulfuric acid drainage tank 24 are of a removable cassette type, so that sulfuric acid, which is dangerous to the human body, can be disposed of without touching it.

FIG. 2 shows the configuration of the optical fiber holder 10 in more detail. The optical fiber holder 10 is made of a soft material that has corrosion resistance against sulfuric acid and is tightly attached to the optical fiber 1. and a holding part outer layer 12 which is made of a hard material having corrosion resistance against sulfuric acid and is provided on the outside of the holding part inner layer 11 so as to support the holding part inside B11.
It is made up of.

Inside the holding part L! As the soft material for i11, fluororubber or tetrafluoroethylene resin is used.

Further, as the hard material for the outer layer 12 of the holding part, quartz glass, hard glass, ceramics, tetrafluoroethylene resin,
ABS resin, polyphenylene sulfide, polypropylene, etc. are used.

Next, a method for removing the intermediate coating of a coated optical fiber using the apparatus configured as described above will be described.

First, both ends of a coated optical fiber 1 to be processed from which the covering material 3 of the intermediate portion is to be removed are held by the coated optical fiber holder 10, and the intermediate portion is positioned in the processing chamber 4. Next, the sulfuric acid feed pump 13 is started to suck a required flow rate of about 10-odd cc/min from the sulfuric acid tank 9, and the heated sulfuric acid is heated by the sulfuric acid heating section 16 just before the sulfuric acid nozzle 5 to convert the hot sulfuric acid into sulfuric acid. It is dripped or sprayed from the nozzle 5 onto the coating material 3 in the middle portion of the optical fiber core 1 .

l1iI! When the acid is heated, the reaction rate of decomposing, bonding and melting the coating material 3 increases. The coating material 3 is melted in a short time and the optical fiber 2 is exposed. During this time, by switching the switching valve 23, the drain lower is connected to the sulfuric acid drain tank 24, and the sulfuric acid drain is poured into the sulfuric acid drain tank 24. Once the optical fiber 2 is exposed, the sulfuric acid feed pump 13 is stopped to stop the supply of sulfuric acid.

Next, the switching valve 23 is switched to the drain tank 25 side, and the water supply pump 19 is started to suck water from the water tank 18 and spray the water from the water nozzle 6 onto the melted portion of the coating material 3. By this injection, the exposed optical fiber 2
The molten coating material and sulfuric acid adhering to the water are forcibly washed away, and the water is poured into the drainage tank 25. In this way, the coating material 3 in the middle portion of the optical fiber core 1 is removed, so that the optical fiber 2 is completely free of any coating material.
can be exposed without breaking or damaging it. Furthermore, in the optical fiber holder 10, the optical fiber 1 is held with good adhesion by the inner layer 11 of the holder, so that sulfuric acid is prevented from entering into the optical fiber holder 10. , only the required intermediate portion of the coating material is melted and removed.

When removing the coating material, it is dangerous to heat and feed a large amount of sulfuric acid, but as described above, the sulfuric acid feed pump 13 sucks only the small amount necessary to melt the coating material in the middle part. The sulfuric acid is heated immediately before the sulfuric acid nozzle 5, and the sulfuric acid is dripped or sprayed from the sulfuric acid nozzle 5 immediately after heating, so it is safe. Also, sulfuric acid tank 9 and!
Since the ilIm drain tank 24 is of a removable cassette type, sulfuric acid can be supplied and drained without touching the dangerous sulfuric acid, ensuring safety.

Next, FIG. 3 shows a modification of the optical fiber holder. The optical fiber coated wire holding section 2o of this modification has a structure in which the holding section inner layer 21 is wound around the optical fiber coated wire 1, and has a slit in the longitudinal direction.

By providing the slits, the elastic deformability is improved and the closeness with the optical fiber coating 3 is improved. 2
2 is the outer layer of the holding portion.

FIG. 4 shows another modification of the optical fiber holder. In the optical fiber holder 30 of this modification, a protruding strip 32 is provided at the end of the inner layer 31 of the holder, which is inside the processing chamber 4, in a direction perpendicular to the longitudinal direction of the optical fiber 1. There is. Since the protrusions 32 are in close contact with the coating material 3 of the optical fiber core 1, intrusion of sulfuric acid into the optical fiber core holding portion 30 can be more effectively prevented. ing. 33 is an outer layer of the holding portion.

[Effects of the Invention] As explained above, according to the present invention, the coating material of the intermediate portion of the optical fiber core is melted by utilizing the decomposition and bonding action of the polymer material by hot sulfuric acid, and then the Since water is sprayed onto the molten part and the molten coating material is forcibly washed away, the optical fiber, which has no coating material attached, can be exposed without breaking or damaging it.

In addition, regarding the heating of sulfuric acid, instead of preheating a large amount of sulfuric acid, the sulfuric acid heating section heats only the necessary amount to be sprayed or dropped immediately before spraying or dropping from the sulfuric acid nozzle. Extremely safe,
Plus a sulfuric acid tank! Since the acid drain tank is a removable cassette type, there is no opportunity for workers to come into direct contact with sulfuric acid, and there is no danger to the human body. moreover,
The optical fiber core holding part has a two-layer structure of an inner layer and an outer layer, and the inner layer is made of a soft material that has corrosion resistance against sulfuric acid and has good adhesion to the optical fiber core, so it is easy to hold the optical fiber core. The optical fiber core portion held in the section is not melted by sulfuric acid, and only the necessary covering material of the intermediate portion can be melted.

Therefore, it is possible to prevent connection failures caused by impurities adhering to the optical fiber surface when connecting by fusion splicing or the like when switching and connecting optical fibers, and it is possible to prevent connection failures due to impurities adhering to the surface of the optical fiber, and to facilitate switching and connection work of optical fiber communication lines. This has an extremely excellent practical effect of being able to be carried out smoothly.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the optical fiber intermediate coating removal apparatus according to the present invention, FIG. 2 is an enlarged perspective view showing the structure of the optical fiber holding part in the same apparatus, and FIG. FIG. 4 is a perspective view showing a modification of the optical fiber holder; FIG. 5 is a perspective view showing another modification of the optical fiber holder;
This figure is a block diagram showing a first conventional example of an optical fiber intermediate coating removal device, and FIG. 6 is a block diagram showing a second conventional example. 1: Optical fiber core wire to be processed, 2: Optical fiber, 3: Coating material, 4: Processing chamber, 5: Sulfuric acid nozzle,
6: Water nozzle, 7: Drain port, 9: Sulfuric acid tank, 10.20.3
0: Optical fiber core holding section, 11.21.31: Holding section inner layer, 12.22.32: Holding section outer layer, 14: Sulfuric acid feed path, 16: 1i7i1 acid heating section,
24: Sulfuric acid drainage tank. Agent Patent Attorney Yasuo Miyoshi Figure 1 Figure 3 j Figure 8 Figure 5x Figure 6

Claims (4)

[Claims] (1) The sulfuric acid dripped or injected from the sulfuric acid nozzle is heated in the process immediately before being fed to the sulfuric acid nozzle, and the heated sulfuric acid is transferred from the sulfuric acid nozzle to the coating material for the intermediate portion of the coated optical fiber to be processed. 1. A method for removing an intermediate coating of an optical fiber core, comprising: melting the coating material by dropping or spraying the coating material, and then spraying water onto the melted portion of the coating material to wash away the molten coating material and sulfuric acid. (2) a processing chamber; an optical fiber holder provided in the processing chamber to hold a coated optical fiber to be processed and position an intermediate portion of the coated optical fiber to be processed in the processing chamber; A sulfuric acid nozzle provided in the processing chamber and configured to drop or spray sulfuric acid onto the coating material in the intermediate portion of the coated optical fiber to be processed; a sulfuric acid tank configured to supply sulfuric acid to the sulfuric acid nozzle; and a sulfuric acid tank configured to supply sulfuric acid from the sulfuric acid tank. A sulfuric acid heating section is provided immediately before the sulfuric acid nozzle in the sulfuric acid tank and heats the sulfuric acid fed from the sulfuric acid tank, and a sulfuric acid heating section is provided in the processing chamber and supplies water for washing to the melted part of the coating material melted with heated sulfuric acid. a water nozzle that sprays
An optical fiber core intermediate coating removal apparatus comprising: a sulfuric acid drain tank connected to a drain port provided in the processing chamber and into which a sulfuric acid drain used for melting the coating material is poured. (3) Claim 2, wherein the sulfuric acid tank and the sulfuric acid waste tank are each of a removable cassette type.
The optical fiber core intermediate coating removal device described above. (4) The optical fiber core holding section includes an inner layer made of a soft material that is resistant to corrosion by sulfuric acid and tightly adheres to the coated optical fiber to be processed, and an inner layer that is made of a hard material that is resistant to corrosion by sulfuric acid and is placed on the outside of the inner layer. 3. The optical fiber intermediate coating removal device according to claim 2, wherein the optical fiber intermediate coating removal device includes a supporting outer layer.