DE2630978A1 - Optical light guide fibre bundles - produced in concentric nozzles of concentric crucibles by centring cone forming bundles for coiling - Google Patents

Abstract

Optical light guide fibres are drawn from an inner crucible for the core material and an outer crucible for the sheath material, both with a pattern of coaxial concentric nozzles in their bottom plates. A system of stoppers can be used to close the nozzles from below. Lopping knives sever the fibres from the stoppers before a protective coating is applied and the fibres are grouped to a bundle in a centring cone ready for winding into coils. Sheathed optical light guide fibres can thus be produced in bundles, ready for installation.

Description

Device for the manufacture of optical fiber bundles.

The invention relates to a device for drawing optical fibers, as indicated in the preamble of claim 1.

It is already known, optical fibers, which ehen high refractive index core and have a low refractive index jacket to draw from double crucibles, such as atis of the publication C.R. Day, I.E. Midwinter, G.R. Newns, M.H. Reeve, K.J. Expanse, M.C. Brierley, Topical Meeting on Optical Fiber Transmission, January 7-9 (1975) Williamsburg, V.A. USA 'is going on. Such double crucibles have an inner crucible and an outer crucible, each with a drawing nozzle, and these nozzles have one in common Central axis. The nozzle of the outer pan has one opposite the nozzle of the inner pan larger diameter. The glass mass for the fiber optic core is located in the inner crucible, in the outer pan the glass mass for the fiber optic jacket.

An optical fiber can be provided from such a device pull the coated core.

As a rule, only optical fiber bundles can make sense in practice are used, therefore it is the object of the invention to provide a device with which fiber bundles can be produced from coated optical fibers.

This object is achieved by a device which, according to the invention has the features of the characterizing part of claim 1.

By making minor modifications to the device according to the invention it is advantageously possible to also produce stranded fiber bundles.

It is advantageous that easily possible by means of an additional device is to provide the individual fibers with a protective cover.

It is also advantageous that it is possible by means of additional devices is to surround the fiber bundles produced with an additional protective tube.

In the following the invention is based on an exemplary embodiment, which is shown in the figures, explained.

1 shows an overall view of the device according to the invention, Fig. 2 shows a section of the bottoms of the inner crucible and the outer crucible each with a nozzle, FIG. 3 shows a coating tank.

Corresponding positions have the same in the figures Reference number. The following reference symbols are for the individual positions in the Associated figures: 1 inner crucible 2 outer crucibles 3 nozzles of the inner crucible 30 nozzles of the outer crucible 4 bottom of the inner crucible 40 bottom of the outer crucible 5 protective chamber 6 Crucible suspension 7 Induction heating 8 Molten glass for the light jacket 9 Glass melt for the optical fiber cores 10 lower closure of the protective chamber 11 System of locking pins. 12 Sliding device for the lower locking device the protective chamber 13 glass rods for the melt of the fiber core material 130 Glass rods for the melt of the fiber cladding material 15 melting level in the inner crucible 150 Melt level in the outer crucible 16 Feed roller system 17 Trimming knife 18, 181 Protective bath 19, 191 coating basin 20 centering cone 21 cross spray head 22 extruder 23 protective hose 24 Cooling bath 25 Winding drum 26 Rotation platform 27 Counterweight 28 Refill hopper for extruder 230, 231 optical fibers.

According to FIG. 1, the device according to the invention has a double crucible, in which the inner pan 1 and the outer pan 2 are one of the number of optical fibers the number of nozzles 3 in the crucible bottom corresponding to the fiber bundle to be produced 4 of the inner crucible and a corresponding number of nozzles 30 in the crucible bottom 40 of the outer crucible. 1 The crucible bottoms are a few mm apart.

The center axes of the nozzles should coincide exactly. The relationship the diameter of the nozzles in the inner pan and the nozzles in the outer pan are aligned according to the ratio of the fiber core diameter to the total diameter of the optical fibers. It is known that the absolute value of the cross section changes when optical fibers are drawn of the fiber, However, the ratio of partial cross-sections of the fiber remains here Ratio of the cross-section of the optical fiber core to the cross-section of the entire fiber, same.

The double crucible is in the illustrated embodiment in a protective chamber 5 with walls made of quartz glass, this protective chamber can be evacuated or be filled with a protective gas. If necessary, in the protective chamber also be air under atmospheric pressure. These Schutzkammer has the Purpose to protect the melts in the crucibles from contamination, in particular from contamination with the elements Fe, Cu, Cr, Co, Mn and Ni.

These impurities lead to high absorption losses in the LichNeitfibres. Therefore, the material of the protective chamber must also be very pure so that the atmosphere in the protective chamber cannot be contaminated.

The crucibles must be made of a heat-resistant material, which does not enter into any undesirable reactions with the melts in the crucibles that would lead to Absorption losses in the finished optical fibers could result. Are suitable e.g. platinum, iridium or platinum-rhodium alloys.

Less heat-loaded parts that come into contact with the melt, can consist of aluminum or aluminum alloys, which are free of Fe, Should be Cu, Cr, Co, Xri and Ni.

The holder of the double crucible in the protective chamber can, for example, as shown, by crucible suspensions 6 on the upper closure 14 of the protective chamber take place, the upper closure can be cooled with water (not shown).

An induction heater 7 is used here to heat the double crucible provided, which heats the outer crucible 2. The melt 8 in the outer crucible, the inner crucible and the melt 9 in the inner crucible are then heated by convection. In the illustrated For example, the induction heating is arranged outside the protective chamber. That's why the protective chamber wall between the induction heater and the outer pan must be made a dielectric material such as quartz glass as described above the outer pan must be made of a metal.

Other heating systems are also possible, e.g. radiant heaters, then must the wall of the protective chamber consist of a material permeable to heat radiation, for that is again Suitable for quartz glass. The illustrated induction heating However, it is characterized by its structural simplicity.

Before the double crucible is charged with melting material, the nozzles in the bottoms of the inner and outer crucibles through a system of pins 11 locked, this system of pins is on the lower lock 10 of the protective chamber arranged.

Fig. 2 shows as a detail a pin 11, which is so formed is that he has at the same time a nozzle 30 in the bottom 40 of the Autentiegel and an overlying one Can close nozzle 3 in the bottom 4 of the inner crucible.

The lower shutter 10 of the protective chamber can vertically by means of a Shifting device 12 are shifted so that the pins 11, the nozzles in the Release crucibles. As long as the pins 11 cover the nozzles in the crucible bottoms, the protective chamber is closed by the lower lock 10.

The crucibles can be loaded with glasses or plastics, accordingly, optical fibers can be made of glass or plastic. Since the production of glass or plastic fibers takes place in the same way, and since up to now glass fibers have the better optical properties, the following only the production of optical fibers from glass is described.

The loading of the inner crucible can through thin glass rods 13, the of the outer crucible also take place through thin glass rods 130. These glass rods can be approx. 1 m long and several mm thick, they consist of the one for the optical fiber core, Glass rods 13, or the material provided for the optical fiber jacket, glass rods 130. These glass rods are continuous from above through the upper protective chamber closure 14 introduced and melted in the crucibles. The level 15 of the glass melt in the inner crucible and the level 150 of the molten glass in the outer crucible are determined by the speed the feed of the respective glass rods adjusted so that the pressure of the melt of the inner crucible and the pressure of the melt of the Outer crucible the lower edge of the nozzles of the inner crucible must be approximately the same size.

If the lower shutter 10 of the protective chamber is lowered, give the pins 11 free the nozzles in crucible bottoms and the glass ohms for the fiber cores and the fiber sheaths can be pulled off downwards in the form of core-sheathed optical fibers will. As soon as the closure has passed the feed roller system 16, the fresh glass fibers 230 adhering to the pins 11 by means of a trimming knife 17 from these Pins separated. The shutter 10 is turned sideways into a rest position, this rest position is shown in dashed lines. The further advance of the glass fibers The roller system 16 now takes over.

The fresh optical fibers 230 are placed in a centering cone 20 merged into a bundle.

The centering cone can be connected to a cross-head 21, which is fed from an extruder 22 with a liquid plastic material, so that the fiber bundle is surrounded by a protective tube 23. This protective hose can either sit loosely or firmly on the fiber bundle.

The resulting fiber bundle, uneven with a protective tube is now pulled through a cooling belt 24 for cooling and then onto a winding drum 25 wound.

Now the feed roller system 16 can be removed because the Take-up drum 25 takes over the pulling of the fiber.

In the direction of movement of the fresh fibers in front of the centering cone a coating basin 19 can be arranged with a protective bath 18 through which the Optical fibers 230 can be drawn. As a protective bath, for example, Kynar (dies is a trade name for polyvinylidene chloride) serve wibhes in a light volatile Solvent is dissolved, e.g. in acetone. The protective bath serves to protect the optical fibers to be coated with a protective coating which improves the mechanical properties and to prevent the fibers from rubbing against each other. This coating is particular then necessary when the fibers are loose in the protective tube 23.

The basin 19 for the protective bath consists of two halves that are attached to the Fibers are brought in and enclose them as soon as the drawing process is initiated is.

If the optical fibers are not stranded in the protective tube, so this can lead to the individual optical fibers being mechanically uneven are claimed.

This is avoided if the optical fibers are stranded. With stranding of the device according to the invention is advantageously easy possible, for this it is only necessary to place the winding drum 25 on a rotatable rotation platform 26 to be arranged. A is used to compensate for the centrifugal force of the winding drum Counterweight 27 on the rotating plate. As can be seen from the figure, it is true the axis of rotation of the rotation platform with the longitudinal axis of the fiber bundle in the Protective hose 23.

Notwithstanding the arrangement shown, the double crucible can also be used be arranged in a rotating manner, However, it is then not possible in the same way for a continuous coating of the optical fibers, as described above in the description of the coating basin 19 has been shown to provide. In this case, for the Coating an arrangement as shown in Figs. 3 and 4 can be used Fig. 3 shows a sectional view, Fig. 4 shows a plan view.

The optical fibers 231 (the double crucible rotates), are drawn through a modified coating tank 191. This The basin has an upper overflow basin, over the edge of which a protective bath 181 runs, e.g. Kynar again. The optical fibers are in this overflowing protective bath 231 coated, excess protective bath is in one under the overflow basin arranged.

The catch basin is collected and returned to the overflow basin with a pump pumped. Arrows indicate that the Double crucible rotates, while the optical fibers are pulled downwards.

With the embodiment shown, it is continuous Tracking of the glass rods for the glass melts in the inner and outer crucibles both with continuous feeding of the plastic material into the extruder 21, the refill funnel 28 is used for this, easily possible, any fiber optic cable Length.

In one embodiment of the invention, the fiber optic cores the F-7 glass from Schott and the LF-5 glass for the fiber-optic jackets Schott used. However, other glasses can also be used, however need the glass for the fiber optic core and the glass for the fiber optic cladding can be drawn at the same temperature. The cleaner the starting substances from which the glass material is made, the lower the attenuation of the finished optical fibers.

In one embodiment, the nozzles in the inner pot had one Diameter of 2 mm and the nozzles in the outer crucible a diameter of 3 mm. the The drawing speed was adjusted so that the optical fibers had a diameter of 120 / µm.

In one embodiment, the plastic material used to form of the protective tube for the fiber bundle polyethylene terephthalate is used.

6 claims 4 figures Blank page

Claims (6)

P a t e n t a n s P r ü c h e 1. Device for drawing core-clad optical fibers, in which the core is made from a first glass material and the cladding is made from another Consist of glass material, the device being a double crucible with an inner and an outer crucible, the inner crucible for receiving a melt for the core of the optical fiber and the outer crucible to hold a melt serve for the cladding of the optical fiber and wherein the inner crucible and the outer crucible Each have a nozzle, the central axes of which coincide, the purchmesser the nozzle in the outer pan is larger than the diameter of the nozzle in the inner pan, characterized in that the bottom (4) of the inner crucible (1) and the bottom (40) of the outer crucible (2) each has a plurality of nozzles (3, 30), the central axis of each nozzle (3) in the inner crucible being the central axis of each a nozzle (30) in the outer pan corresponds to a system of locking pins (11) is provided, with which the superimposed nozzles (3) in the inner pan and nozzles (30) in the outer pan are closable that this system the locking pin can be moved downwards so that trimming knives (17) are provided, with which freshly drawn optical fibers (230) are separated from the locking pins (11) can be that a feed roller system (16) is provided that a centering cone (20) is provided with which die.frischen optical fibers are brought together to form a bundle can be, and that a winding drum (25) for the finished optical fibers is provided. 2. Apparatus according to claim 1, characterized in that g e k e n n -z e i c h n e t that the winding drum is arranged on a rotation platform (26). 3. Apparatus according to claim 1, characterized in that g e k e n n -z e i c h n e t that the double crucible is arranged rotatably about its longitudinal axis. 4. Device according to one of claims 1 and 2, characterized g e k e n n z e i c h n e t that a basin (19, 191) for receiving a protective bath (18, 181) is provided, with which the individual optical fibers (230, 231) with a Protective coating can be provided. 5. Device according to one of claims 1 to 4, characterized g e k e n n z e i c h n e t that the centering cone is connected to a transverse injection head (21) is, via an extruder (22) with a plastic material to form a Protective tube for the bundle of optical fibers can be fed. 6. Device according to one of claims 1 to 5, characterized g e k e n n z e i c h n e t that a cooling bath (24) is provided for cooling the optical fibers is.