SE454302B - FIRE SAFETY OPTICAL FIBER CABLE - Google Patents

Description

30 35 40 454 302 but which can also maintain its operating characteristics in the event of a fire.

Ordinary fiber cable of the type mentioned above, for example the type made according to the loose cladding or "loose tube" principle to avoid microbending of the fiber and provide good mechanical protection, will not be able to provide sufficient protection during a fire. , in that the organic material enclosing the fiber cable will burn up, so that the mechanical protection of the fiber will disappear.

A main object of the present invention is thus to provide a cable which provides a tube-like protection of the optical fiber itself during a fire, ie to give instructions to a protective tube which arises during the fire itself.

This object is achieved by coating the protective jacket, preferably the tube of organic material, with an inorganic, fire-retardant material, which during a fire is transformed into a protective tube for replacement of the organic tube.

Conveniently, the protective sheath or tube may be coated with mica tape, preferably mica tape on a glass support, and preferably in the form of a band.

During a fire, these materials will be subjected to a sintering process and form a new tube that protects the fibers. It will then be possible to avoid the fiber taking on microbends due to mechanical and thermal influences, thereby preventing light from radiating out. Such microbends are critical to the bond to be maintained through the optical fiber, and it is therefore important that mechanical protection is maintained.

According to another feature of the present invention, the protective sheath coated with the fire retardant material is designed as a tube which between it and the optical fiber holds a substance which is as passive as possible in the event of a fire (minimal volume increase, gas evolution, flammability etc), eg modified silica grains.

In addition to helping the fiber cable to maintain its loose cladding, silicon grains will also help to supply the fiber with the least possible amount of oxygen during a fire, in order to thereby prevent oxidation of the optical fiber.

A bare optical fiber will be oxidized during a fire with one pass and the mechanical properties of the fiber will be degraded. The breaking strength of the fiber can then be reduced to less than 10% of the original.

The ash of silicon grains is quartz in fine powder form which will also provide mechanical support and thus mechanical protection of the fiber.

By using the materials specified above, the fireproof fiber cable can also be used to burn various primary coatings available on the market, such as silicone coatings, acrylates or some form of varnish, or aluminum coating.

In the case of the cable according to the present invention, a fire will transform the organic protection present under normal conditions into a temperature-resistant inorganic protection. When using mica strips in combination with a silicon grain-filled organic tube, in a fire situation on the one hand the mica strips will be sintered together into an inorganic tube to replace the organic, and on the other hand the ash of the silicon grains, which form a fine quartz powder, will be retained. in place of the now inorganic tube and protects the inner optical fiber. Keeping the quartz powder in place means that the fiber receives the necessary support to be kept in a really functional position.

It is known from GB patent specification 1,583,954 to use a mica strip which surrounds the combustible parts of an inner cable, but this is not a question of the use of mica strips in connection with a fiber cable which has a very special construction, and which in connection with moisture protection must be filled with grease.

This patent also does not provide any indication as to how the mica strip will create a supporting inorganic tube which holds the quartz powder from burnt out silicon grains in place when a fiber cable is exposed to fire.

Furthermore, GB patent application 2,050,041 discloses the use of mica tape which surrounds an electrical conductor, the mica tape being in turn enclosed by an elastomer, preferably an ethylene-propylene-based rubber. Admittedly, the patent states that the mica strip protects the conductor in the event of fire, even if the elastomer is destroyed, but the use of mica here is substantially different from the pipe-creating and quartz powder-supporting property used. according to the present invention.

It should be noted that the organic pipe does not necessarily have to be filled with silicon grains, but any other material that meets the properties for volume increase, gas evolution and flammability during a fire, and during normal use has a small coefficient of expansion and small viscosity change with temperature, can be used .

To further support the protective jacket or tube coated with mica tape, a layer of glass tape may be provided on top of one or more elements of the coated jacket.

To further secure the cable construction against fire, a filler jacket with good fire-retardant properties can be enclosed on the outside of the protective pipe with the fire-retardant coating and the glass strip.

Suitably, another glass strip may be arranged on top of such a filling jacket, possibly with a steel reinforcement over the strip. Such an additional measure will further strengthen the mechanical nature of the cable before, during and after a fire.

Finally, the cable may have an outer sheath of a preferably halogen-free material with suitable fire-retardant properties.

Cables in accordance with the present invention have been tested in a fire chamber where they were exposed to fire at 930 ° C for three hours. It turned out that the cables were functional during the entire fire test, ie transmitted the necessary light energy which was emitted at one cable end for a satisfactory effect of receiver elements arranged at the other end of the cable.

The cable construction has little or no corrosive effect on the environment during a fire and, with its material composition, will satisfy strict fire technical, mechanical and functional requirements both before, during and after a fire.

Various embodiments of the invention are described below with reference to the drawing, in which Fig. 1 shows a section through a first embodiment of a fire-fighting fiber cable in accordance with the present invention, and Figs. shows a section through another embodiment of a fireproof fiber cable in accordance with the invention.

In Fig. 1, the reference numeral 1 denotes a possible inner core of steel or fiber-reinforced plastic with high mechanical strength and low coefficient of temperature expansion.

Such a core can be used to advantage when the cable is to contain more than one fiber. ' Arranged around the core 1 in the exemplary embodiment shown are four optical fibers Za-Zd which can be coated with a layer of acrylate, acetate or silicone rubber, this layer protecting against moisture and mechanical damage to the optical fiber itself.

A tube 4 of organic material, for example acrylic, is arranged around each of the optical fibers Za-Zd, and in the cavity between the tube 4 and the individual fiber Za-Zd is filled with silicon grains 3, the combination of acrylic tubes 4 and silicon grains provide a so-called loose cladding or "loose tube" mounting of the optical fibers Za-Zd.

A layer of mica tape is wound around the tube 4 of organic material, whereby the mica material can suitably be arranged on a glass support.

During a fire, the material with which the tube 4 is coated, for example mica tape, will undergo a sintering process, so that a new tube is formed for replacement of the organic tube 4 itself, which contributes to the mechanical protection of the optical fibers themselves. Za-Zd is maintained during and after a fire. At the same time, the filling mass 3, for example the silicon grains in the space between the tube 4 and the individual optical fibers 2a-2d, will be of such a nature that the smallest possible residues are generated during a fire, in order to avoid oxidation, gas evolution, sooting and pressure increases between the tube. 4 and the fibers Za 2d. In addition to reducing the risk of pressure increase during fire, the silicon grains 4 will also have a small coefficient of expansion and a small change in viscosity with temperature. This condition also contributes to the migration of the fibers 2a-2d being as small as possible both under normal operating conditions and under fire conditions, which means that the fibers are exposed to the least possible stress and thus avoid micro-10 15 20 25 30 35 40 454 302 L bends which cause the light transmitted through the optical fibers to radiate and not reach the destination for maintaining the connection between the two cable ends. The probability of breakage in the fibers is reduced accordingly.

The ash of silicon grains is quartz in fine powder form which will provide additional mechanical support to the fibers. At the same time, the mica strip sintered tube that replaces the organic tube will form a support for the quartz powder, so that it does not run off, but constantly closes around the fibers.

Around a or a collection of organic pipes with the fire-retardant coating 5, a layer of glass strip 6 is arranged, the strip serving to support the construction both before and after a fire, at the same time as it provides an extra flame protection of the mica strip 5. A filling jacket 7 with good fire-retardant properties is arranged on the outside of the glass strip 6.

On the outside of the filling jacket 7, in the embodiment shown in Fig. 1, an additional glass strip 8 is arranged, possibly reinforced with steel over the strip. Such a compilation serves to keep the filling jacket 7 in place under fire conditions.

An outer jacket with good fire-retardant properties is arranged on the outside of the glass strip 8, the material being of such a nature that it provides a protective ash during fire.

Fig. 2 shows a section through another embodiment of a cable construction in accordance with the present invention, the basic components included in the cable construction here being the same as in connection with the embodiment shown in Fig. 1, but where the number fiber cores deviate É from the previously described embodiment. Thus, Fig. 2 shows a central element 1 of steel or fiber-reinforced plastic, possibly glass with high mechanical strength and low coefficient of temperature expansion, at the same time as six optical fibers 2a-2f are arranged around the core 1, which in turn are arranged in a ring around the core 1.

Incidentally, the construction of the cable variant in Fig. 2 corresponds to that described in Fig. 1.

Experiments have shown that a cable construction in accordance with 454 302 of the invention can withstand a fire at 930 ° C for three hours without losing its operability, i.e. without reducing the signal level of the light transmission necessary for reliable communication between the two ends of cable.

The cable construction according to the invention could thus satisfy the requirements of being able to function for half an hour in a hydrocarbon fire where temperatures above 900 ° C can often occur.

Claims (10)

10 15 20 25 30 35 454 302 P t v Fire-resistant optical fiber cable of a loose tube structure comprising a signal-bearing optical fiber (2a-2d) enclosed by a loose protective sheath (4) which in turn is surrounded by mica tape (5) on a glass bead, characterized in that the protective sheath (4) between it and the optical fiber (2a-2d) contains a filler material which prevents oxidation of the optical fiber cable (2a-2d) and which emits few residues during fire and forms ash which does not oxidize the fiber. and which supports the fiber, the mica strip (S) forming a sintered tube during a fire which forms the sheath (4) and holds the ash in place. Fiber cable according to claim 1, in that the filling material comprises silicon grains. k ä n n e t e c k n a d Fiber cable according to claim 1, characterized in that it comprises one or more sheathed fibers surrounded by a layer of glass ribbon (6). Fiber cable according to claim 3, in that it comprises a filling sheath 57) with fire-retardant characteristics around the glass strip (5). Fiber cable according to Claim 4, in that it has a reinforcement, braid, characteristic, spinning or banding (B) of glass, steel or other fire-resistant material outside the filling jacket (7). Fiber cable according to claim 1, in that it comprises an outer sheath (9) of halogen-free known material. Fiber cable according to claim 1, in that it has an outer sheath which forms protective ash in the event of a known fire. B. A fiber cable according to claim 1, characterized in that it has a reinforcing core. Fiber cable according to claim 8, characterized in that the core is made of steel, fiber-reinforced plastic or glass. Fiber cable according to claim 1, in that the protective sheath (4) is made of organic material. k ä n n e t e c k n a d