Patent Description:
With the expansion of application environments of optical fibers and cables, ordinary optical fibers resistant only to a temperature of <NUM> degrees Celsius cannot be used in specific environments, such as aerospace, wind power, oil and gas exploration, and high-temperature industrial steam pipeline inspection. An optical fiber needs to maintain its transmission characteristics in these harsh environments, and higher requirements for optical performance, mechanical performance, and reliability of the optical fiber in these environments are thus demanded. An operating temperature of an optical fiber is directly determined by its coating material. At present, there are mainly four types of coating materials for the temperature-resistant optical fiber, that is, polyacrylate with high temperature resistance, organic silicone, polyimide, and metal. The optical fiber with the metallic coating can resist temperatures greater than <NUM> degrees Celsius, but there are few manufacturers and commercial applications. The optical fiber with the polyimide coating has the best temperature resistance among organic coatings, but its production process is relatively complicated, in that its drawing speed (<NUM> to <NUM>/min) and production efficiency are very low. Since a modulus of polyimide is large, there is much attenuation of the optical fiber coated by the polyimide.

Optical fiber that can resist a temperature of <NUM> degrees Celsius is almost unknown. The problem is that the coating layer of the optical fiber resisting <NUM> degrees Celsius is solidified thermally and by ultraviolet (UV), however, the thermal solidification has a slow speed and is difficult to realize mass production. UV solidification has a higher efficiency, but the subsequent heating and wrapping steps make the process complicated. A conventional method for forming an optical fiber is known from D3 (<CIT>).

In view of the above shortcomings, a method for forming an optical fiber is needed.

The present disclosure provides a method for forming optical fiber, including melting a fiber preform at <NUM> degrees Celsius and above, and drawing the fiber preform into a filament. The filament is cooled to <NUM> to <NUM> degrees Celsius. An acrylic resin or an organic silicone resin is coated on the cooled filament, which is solidified by ultraviolet to obtain a primary coated filament. An organic silicone resin is coated on the primary coated filament, which is solidified by ultraviolet to obtain the optical fiber.

Furthermore, the acrylic resin has a viscosity of <NUM> to 5000cps.

Furthermore, the organic silicone resin has a viscosity of <NUM> to 8000cps.

Furthermore, a drawing speed during drawing the fiber preform is <NUM> to <NUM>/min.

Furthermore, the solidifying by ultraviolet includes polymerizing ultraviolet-initiated resin onto the fiber preform to form a solid coating film that is insoluble and infusible, a time period for solidifying is <NUM> to <NUM>, and an outer diameter of the fiber preform is <NUM> to <NUM>.

Furthermore, after drawing the fiber preform and before cooling, a diameter of the filament is checking for a preset diameter.

Furthermore, the optical fiber is coiled on an optical fiber tray through an automatic take-up device.

Furthermore, the optical fiber is formed by the method. The optical fiber formed by the method is example not encompassed by the wording of the claims. The optical fiber comprises, from inside to outside, a core layer, a cladding layer, an inner coating layer, and an organic silicon outer coating layer, the inner coating layer is an acrylic inner coating layer or an organic silicone inner coating layer.

Furthermore, the optical fiber is a single-mode or a multi-mode fiber.

Furthermore, the optical fiber is capable of long term use at <NUM> degrees Celsius, and being used for more than <NUM> days at <NUM> degrees Celsius.

Compared to existing technology, the optical fiber of the present disclosure is formed by two coating processes with the acrylic (or the organic silicon) and the organic silicon. The diameter of the optical fiber reaches <NUM>. At <NUM> degrees Celsius, long term performance is stable. The optical fiber can also be used at <NUM> degrees Celsius for at least <NUM> days. The temperature-resistant optical fiber of the present disclosure has the screening strength of 100kpsi or 200kpsi. The coating layers are uniform. The segment length can be more than <NUM>, allowing long distance applications. The fatigue value Nd of the optical fiber is greater than <NUM>.

Implementations of the disclosure will now be described, with reference to the drawings.

Implementations of the disclosure will now be described, with reference to the drawing.

Implementations of the disclosure will be described by way of embodiments. It should be noted that non-conflicting details and features in a plurality of embodiments of the present disclosure may be combined with each other.

The disclosure is illustrative only, and changes may be made in the detail within the principles of the present disclosure. It will, therefore, be appreciated that the embodiments may be modified within the scope of the claims.

The term "segment length" in the disclosure means a one-piece length of the entire optical fiber.

Unless otherwise defined, all technical terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. The technical terms used herein are not to be considered as limiting the scope of the embodiments.

<FIG> illustrates a method for forming an optical fiber, including following steps.

Step S1, a fiber preform is melted at high temperatures of <NUM> to <NUM> degrees Celsius and drawn into a filament.

In an embodiment, a drawing speed for drawing the fiber preform is <NUM> to <NUM>/min. When the drawing speed is lower than <NUM>/min, the forming speed is slow, and a diameter of the cladding layer is difficult to control, which affects the optical performance. When the drawing speed is higher than <NUM>/min, a time period for solidifying can be reduced. However, the solidifying effect may be poor, the uniformity of the coating layer of the optical fiber is difficult to control, and the appearance of the optical fiber is poor. The performance of the optical fiber is also affected. An outer diameter of the fiber preform is <NUM> to <NUM>.

Step S2, the filament is cooled to <NUM> to <NUM> degrees Celsius.

Step S3, the cooled filament is coated with acrylic resin or silicone resin, which is then solidified by ultraviolet to obtain a primary coated filament.

In an embodiment, a viscosity of the acrylic resin is <NUM> to 5000cps, and a viscosity of the silicone resin is <NUM> to 8000cps. The solidifying by ultraviolet includes polymerizing ultraviolet-initiated resin onto the fiber to form a solid coating film that is insoluble and infusible. A time period for solidifying is <NUM> to <NUM>. When the time period for solidifying is too short, insufficient solidification causes the fiber to be sticky and break during drawing. When the time period for solidifying is too long, over-solidification causes the optical fiber to be rigid and have a high attenuation.

Step S4, the primary coated filament is coated with a silicone resin, which is then solidified by ultraviolet to obtain the optical fiber.

In an embodiment, a viscosity of the silicone resin is <NUM> to 8000cps. The solidifying by ultraviolet includes polymerizing ultraviolet-initiated resin onto the fiber to form a solid coating film that is insoluble and infusible. A time period for solidifying is <NUM> to <NUM>. When the time period for solidifying is too short, an insufficient solidification causes the fiber to be sticky and break during drawing. When the time period for solidifying is too long, an excessive solidification causes the optical fiber to be rigid and have a high attenuation.

The viscosity of the acrylic resin or the silicone resin cannot be too small, otherwise, the coating material may sag and the solidifying effect is not good. The viscosity cannot be too large. When the viscosity is too large, the fluidity will be poor and a heat treatment is needed. The heating temperature should not be too high. So when coated with resin of high viscosity, the adhesion is not good, and a long time period is required for solidification. Internal stress is likely to occur after the solidification, which is not conducive to the performance of the optical fiber, for example, signal attenuation may increase.

In an embodiment, the method can further include followings steps.

Step S12, after drawing the fiber preform at step S1 and before cooling the filament at step S2, a diameter of the filament is checked for being a preset diameter.

Step S5: after the optical fiber is formed, the optical fiber is coiled on an optical fiber tray through an automatic coiling device.

The optical fiber obtained by the above method includes, from inside to outside, a core layer <NUM>, a cladding layer <NUM>, an inner coating layer <NUM>, and an organic silicon outer coating layer <NUM>. The inner coating layer <NUM> includes an acrylic inner coating layer or an organic silicon inner coating layer. The optical fiber is a single-mode or a multi-mode optical fiber as shown in <FIG>. The optical fiber can be used for a long time at <NUM> degrees Celsius, or for more than <NUM> days at <NUM> degrees Celsius. The existing method for forming the optical fiber with organic silicon coating has a high production cost, a low efficiency, and which needs a subsequent heat treatment. For the fiber of the present disclosure, the viscosity of the coating material is controlled, and the resulting optical fiber can resist temperatures of <NUM> to <NUM> degrees Celsius by two coatings and then the ultraviolet solidification. The forming process is simple and efficient. The optical fiber has low attenuation and good mechanical properties.

The following examples illustrate the method for forming the optical fiber of the present disclosure and the performance of the finished product.

A quartz fiber is a single-mode fiber having a structure of <NUM>/<NUM>. The inner coating layer is an acrylic resin coating layer (the viscosity of the coating material is <NUM>-5000cps) resistant to high temperatures. The outer coating layer is silicone resin coating layer (the viscosity of the coating material is <NUM>- 8000cps). Both the inner and the outer coating layers are solidified by ultraviolet. The diameter of the inner coating of the optical fiber is <NUM>, and the diameter of the outer coating is <NUM>. At room temperature, the attenuation of the optical fiber is <NUM>. 34dB/km at <NUM>, and is <NUM>. 23dB/km at <NUM>. The screening strength of the optical fiber is 200kpsi. The segment length is greater than <NUM>, Nd= <NUM>. In an environment of <NUM> degrees Celsius, the additional attenuation of the optical fiber is less than <NUM>. After being in an environment of <NUM> degrees Celsius for <NUM> days, the additional attenuation of the optical fiber is less than <NUM>.

A quartz fiber is a multi-mode fiber having a structure of <NUM>/<NUM> or <NUM>/<NUM>. The inner coating layer is an acrylic resin coating layer resisting to high temperatures, and the outer coating is a silicone resin coating layer. Both the inner and the outer coating layers are solidified by ultraviolet. The diameter of the inner coating layer of the optical fiber is <NUM>, and the diameter of the outer coating layer is <NUM>. At room temperature, the attenuation of the optical fiber is <NUM>. 41dB/km at <NUM>, and is <NUM>. 62dB/km at <NUM>. The screening strength of the optical fiber is 100kpsi. The segment length is greater than <NUM>.

A quartz fiber is a single-mode fiber having a structure of <NUM>/<NUM>. The inner coating layer is a silicone resin coating layer, and the outer coating layer is a silicone resin coating layer. The coating layer can be solidified by ultraviolet. The diameter of the inner coating layer of the fiber is <NUM>, and the diameter of the outer coating layer is <NUM>. At room temperature, the attenuation of the optical fiber is <NUM>. 35dB/km at <NUM>, and is <NUM>. 24dB/km at <NUM>. The screening strength of the optical fiber is 100kpsi. The segment length is greater than <NUM>. In an environment of <NUM> degrees Celsius, the additional attenuation of the optical fiber is less than <NUM>. The optical fiber can be used in an environment of <NUM> degrees Celsius for more than <NUM> days.

Comparative example <NUM> is different from Example <NUM> in that the outer coating layer is an acrylic resin coating layer (the viscosity of the coating material is <NUM>-5000cps) resistant to high temperature. Other steps are the same as those of Example <NUM>. The diameter of the coating layer of the optical fiber is <NUM>. At room temperature, the attenuation of the optical fiber is <NUM>. 32dB/km at <NUM>, and is <NUM>. 21dB/km at <NUM>. The screening strength of the optical fiber is 200kpsi. The segment length is greater than <NUM>. In an environment of <NUM> degrees Celsius, the additional attenuation of the optical fiber is less than <NUM>. But in an environment of <NUM> degrees Celsius, the additional attenuation value of the optical fiber is greater than <NUM>.

Comparing Example <NUM> with Comparative Example <NUM>, at high temperatures, the attenuation characteristics of the optical fiber which have two acrylic coating layers are inferior to the attenuation characteristics of the optical fiber which have acrylic and organic silicone coating layers according to the present disclosure. At <NUM> degrees Celsius, additional attenuation greater than <NUM>. 05dB/km is found in comparative Example <NUM>. In the present disclosure, whether the optical fiber has coating layers of acrylic and organic silicon, or has coating layers of organic silicon and organic silicon, when the optical fiber is used at <NUM> degrees Celsius for a long time, the performance is stable, and the attenuation is low.

In summary, the temperature-resistant optical fiber suitable for high temperature and harsh environment according to the present disclosure has two resin coating layers. The diameter of the finished optical fiber reaches <NUM>. The optical fiber can be used at <NUM> degrees Celsius for a long time, and the performance is stable. The optical fiber can also be used at <NUM> degrees Celsius for at least <NUM> days. The temperature-resistant optical fiber of the present disclosure has the screening strength of 100kpsi or 200kpsi. The coating layers are uniform. The segment length can be more than <NUM>, which allows use of the optical fiber for long distances. The fatigue value Nd of the optical fiber is greater than <NUM>.

Claim 1:
A method for forming optical fiber, characterized in that, the method comprises:
melting a fiber preform at <NUM> degrees Celsius and above, and drawing the fiber preform into a filament;
cooling the filament to <NUM> to <NUM> degrees Celsius;
coating an acrylic resin having a viscosity of <NUM> to 5000cps on the cooled filament, which is solidified by ultraviolet to obtain a primary coated filament;
coating an organic silicone resin having a viscosity of <NUM> to 8000cps on the primary coated filament, which is solidified by ultraviolet to obtain the optical fiber.