ITMI20001225A1 - METHOD FOR THE MANUFACTURE OF PASSIVE COMPONENTS IN OPTICAL FIBER AND EQUIPMENT TO IMPLEMENT THIS METHOD. - Google Patents

Description

Description of the industrial invention entitled:

"Method for fabricating passive fiber optic components and equipment to implement such a method."

Field of the invention.

The invention consists of a method for manufacturing passive optical fiber components (couplers, WDMs, attenuators, etc.) in which the optical fibers to be treated are suitably allocated inside an induction-fed heating element, which indirectly heats them bringing them to the softening point and preserving them from any risk of contamination from the surrounding environment.

The invention also relates to an apparatus for implementing this method.

Prior art.

Optical fiber transmission systems are assuming an increasing importance and diffusion: this has led and still involves the need to create and use an ever increasing number of passive fiber optic components (couplers, attenuators, etc.) and to improve the quality and performance of these passive components.

The most used technology to make these passive components (in particular the couplers) is the "fusion" one in which two or more optical fibers, deprived of their respective sheaths and placed side by side, are heated up to the softening temperature of the material (usually silica ) of which they are made and at the same time subjected to traction to be elongated: in this way the optical fibers become thinner and interpenetrate each other, generating the desired passive component, in which the optical power introduced at the input of the component itself is distributed in a fixed on two or more outputs.

Control apparatuses essentially constituted are also known

by a plurality of optical sensors, each of which is connected to an output of the passive component, which detect how the signal emitted

from an optical source connected to the input of the passive component, it is divided between the outputs and controls the element that heats the optical fibers to obtain input / output coupling ratios having the desired values.

The means suitable for subjecting the optical fibers and the control equipment to traction will not be further described because they are known per se.

Normally the optical fibers that form the component are brought to the softening temperature of the material that constitutes them by means of one or more gas torches.

Due to the instability of the flame and the impossibility of carrying out a correct temperature measurement, this method presents considerable problems of stability, control and reproducibility of the main melting parameters (such as, for example, the length of the heating zone and the temperature ) during the phases (softening, interpenetration and cooling of the optical fibers) of the production process of the passive component.

Qf The flame of the at least one torch, coming into direct contact with the optical fibers, can pollute the fibers themselves due to combustion residues which, by incorporating into the silica, modify (or can modify) its refractive indices, degrading the optical characteristics and the performance of the passive component.

In addition, the gas flow that feeds the at least one torch exerts a non-negligible pressure on the softened fibers, which can cause unwanted non-uniformity and bending, degrading the optical characteristics and performance of the passive component.

Finally, the use of gas-powered torches, in particular hydrogen, requires the adoption of complex and onerous safety equipment and procedures to protect operators.

The present invention relates to a method for manufacturing passive optical fiber components (couplers, WDMs, attenuators, etc.) which is immune from the limitations and / or drawbacks presented by known production methods, since the optical fibers to be treated are suitably located inside a heating element fed by induction, which indirectly heats them by radiation and brings them to the softening point, protecting them from any risk of contamination from the surrounding environment.

The present invention also relates to an apparatus for implementing this method.

Summary of the invention.

The present invention relates to a method for manufacturing passive optical fiber components in which each passive component is enclosed in a support, which comprises at least the steps of:

- insert the support into an induction-powered heating element; - insert in the support the optical fibers constituting the passive component, deprived of the external sheath, and fix them to means suitable for subjecting them to traction; .

- induction feed the heating element and bring the optical fibers to the softening point by heating them indirectly;

- subject the optical fibers to traction;

- having made the passive component, fix the optical fibers to the support and separate the passive component from the means suitable for subjecting the optical fibers to traction.

This method is implemented by means of an apparatus comprising at least, in combination with each other, a heating element, means suitable for subjecting the optical fibers forming the passive component to traction and means for controlling and regulating the heating element, where the heating element is powered by induction and indirectly heats the optical fibers that make up the passive component.

List of figures.

The invention will now be better described with reference to non-limiting embodiments illustrated in the attached figures, where:

- Figure 1 schematically shows a block diagram of an equipment to implement the method object of the present invention;

Figure 2 schematically shows an embodiment of the heating element;

Figure 3 schematically shows a longitudinal section and a side view of an embodiment of a support.

In the attached figures, the corresponding elements will be identified by means of the same numerical references.

Detailed description.

Figure 1 schematically shows a block diagram of an apparatus for implementing the method according to the present invention, which comprises at least, in combination with each other, a heating element 3 (an embodiment of which is illustrated in Figure 2), means 1 adapted to subject to traction the optical fibers 2 which constitute the passive component and means for controlling and regulating the heating element 3, where the heating element 3 is fed by induction and indirectly heats the optical fibers 2.

In the non-limiting embodiment illustrated in Figure 1, the control and regulation means comprise a generator 6 which supplies the heating element 3, means 7 suitable for detecting the temperature of the heating element 3, the optical source 8 connected to the input of the passive component, the optical sensors 9 (connected to the outputs of the passive component) which detect the optical signals present at said outputs and a microprocessor 4 which receives (through the interface circuits 5) the temperature detected by the means 7 and the intensity (detected by the optical sensors 9) of the optical signals present at the outputs of the passive component and which, in response to the information received, drives (through the interface circuits 5, 5 ') the means 1 adapted to subject the optical fibers 2 to traction and the generator 6 which powers the heating element 3.

Without departing from the scope of the invention, it is possible to replace the control and regulation means indicated in figure 1 (not further described because they are known per se) with other functionally equivalent control and regulation means, also not described here because in themselves known.

Preferably but not necessarily, the generator 6 generates a radiofrequency signal which induction heats the heating element 3, while the means 7 (which detect the temperature of the heating element 3) consist of an optical pyrometer, a thermocouple or other functionally equivalent means.

The method according to the invention for making passive optical fiber components in which each passive component is enclosed in a support 13 (Figure 3), comprises at least the steps of:

- insert the support 13 in the heating element 3 powered by induction from the generator 6;

- inserting in the support 13 the optical fibers 2 which constitute the passive component, deprived of the external sheath, and fixing them to the means 1 suitable for subjecting them to traction;

- induction feed the heating element 3 and bring the optical fibers to the softening point by indirectly heating them through the support 13;

- subjecting the optical fibers 2 to traction;

- having made the passive component, fix the optical fibers 2 to the support 13 and separate the passive component from the means 1 adapted to subject the optical fibers 2 to traction.

Preferably but not necessarily, the optical fibers 2 are intertwined with each other before or after being inserted into the support 13.

This method has, compared to methods based on the use of at least one torch, at least the following advantages:

- the heating element 3, fed by induction, is physically stable and allows to obtain an easily controllable and reproducible heating profile of the optical fibers 2 and, consequently, a greater uniformity of the characteristics of the passive components produced by this method;

- it allows to carry out a precise temperature measurement in order to exercise an excellent process control;

- it allows to obtain a uniform temperature distribution on the section of the optical fibers 2 to be softened, improving the characteristics of the passive components thus produced;

- it has excellent flexibility that allows you to easily vary the size of the softening area of the optical fibers 2 to adapt to the specific needs of each type of passive component to be made;

- allows adequate cleaning of the softening zone of the optical fibers 2 and therefore eliminates (or, at least, minimizes) the presence of contaminating agents on the optical fibers 2 which constitute the passive component.

- it is inherently safer as it does not use flammable gases.

Figure 2 schematically shows an embodiment of the heating element 3, which comprises an external cylindrical body

12 inside which there is an internal cylindrical body 11 inside which an axial hole is made in which the support 13 is placed (figure 3) inside which the optical fibers 2 are aligned: in this way the optical fibers 2 are subjected to the irradiation of a surface that surrounds them in a uniform manner.

The internal cylindrical body 11, controlled in temperature by the detection means 7, is heated by induction by a radiofrequency signal emitted by the generator 6.

The support 13 on which the optical fibers 2 are fixed, the generator 6, and the control and interface means have been omitted in Figure 2 for simplicity of graphic representation.

Preferably but not necessarily, the internal cylindrical body 11 is made of platinum or its alloys or graphite and its compounds with alumina and zirconia, the external cylindrical body 12 is made of a material transparent to radiofrequency (such as, for example, quartz or a ceramic material) and the support 13 consists of a quartz capillary tube.

Preferably but not necessarily, the external cylindrical body 12 has an opening 14 which allows the means 7, facing the opening 14, to more easily and more accurately detect the external temperature of the internal cylindrical body 11.

The process of formation of the passive component therefore takes place inside the tube 13 (and is therefore protected from contamination both

* during the realization of the passive component and subsequently) due to the heat radiated uniformly by! internal cylindrical body 11; once the formation process is finished, the optical fibers 2 are fixed to! quartz support 13 with a resin.

The capillary tube which constitutes the support 13 therefore has the function of protecting the softening region of the optical fibers 2 from contamination and of acting as a support on which to fix, by means of a resin, the semi-finished passive component so as to be able to handle it easily.

The type of resin used to fix the optical fibers 2 to the support 13 is related to the characteristics of the passive component to be made and to its intended use: for standard passive components a polymeric resin is normally used, while if the passive component must have strong hermetic characteristics (for example because it is intended to be mounted in equipment for special applications) one of the hermetically sealed resins available on the market is used, for example a glass-based resin, which seals the passive component inside the support 13 .

Long theoretical studies and experimental tests have allowed the Applicant to identify which fundamental elements to optimize the production process of passive fiber optic components:

- the particular structure of the heating element 3 described in figure 2; - the dimensions of the internal cylindrical body 11 and the temperature to which the optical fibers 2 are subjected, which are decisive for the optical performance of the passive component: preferably, the length of the internal cylindrical body 11 is between 4 and 30 mm, its internal diameter is between 1 and 5 mm and its external diameter is between 6 and 12 mm, while the effective range of the operating temperature, measured on the external wall of the internal cylindrical body 11, is correlated to the softening temperature of the fibers optics 2 being processed and is between 1300 and 1900 ° C;

- The material with which the heating element 3 is made, important for obtaining the necessary temperatures and for avoiding contamination of the softening zone of the optical fibers 2; advantageously, the internal cylindrical body 11 is made of platinum with purity greater than 99%, of graphite (and / or its compounds with alumina and zirconia) or of platinum alloys: in the last two cases it is necessary to keep inside the internal cylindrical body 11 an atmosphere saturated with inert gas (such as, for example, Nitrogen or Argon) to avoid combustion residues that could dirty the support 13 inside which the optical fibers 2 are heated, shielding the radiation produced by the internal cylindrical body 11 and consequently modifying the temperature to which the optical fibers 2 are subjected.

Figure 3 schematically shows a longitudinal section and a side view of an embodiment of the support 13, which consists of a quartz capillary tube which has, towards each end, a window 20 suitable for exposing the optical fibers 2 and to ensure optimal anchoring of the resin to the support 13: once the passive component has been made, the optical fibers are fixed to the support 13 by means of two drops of resin 21, which occlude the windows 20 and the quartz tube, isolating the passive component inside the tube and eliminating any risk of contamination from the external environment.

The side view of figure 3 shows the quartz tube occluded by a drop of resin 21 from which two optical fibers 2 emerge.

In the embodiment illustrated in Figure 3, the quartz tube which constitutes the support 13 has a length between 10 and 150 millimeters, an external diameter not greater than the internal diameter of the internal cylindrical body 11 and in any case between 0.8 and 4 , 8 millimeters and an internal diameter between 0.5 and 4.5 millimeters; the windows 20 have a length between 1 and 30 millimeters,

Without departing from the scope of the invention, it is possible for a technician to make all the modifications and improvements suggested by normal experience and natural evolution to the method for manufacturing passive optical fiber components and to the apparatus for implementing this method, object of the present description. of the technique.

Claims (18)

CLAIMS 1) Method for manufacturing passive optical fiber components in which each passive component is enclosed in a support (13), characterized by the fact that it comprises at least the steps of: - insert the support (13) in a heating element (3) fed by induction; - inserting in the support (13) the optical fibers (2) constituting the passive component, deprived of the outer sheath, and fixing them to means (1) suitable for subjecting them to traction; - powering the heating element (3) by induction and bringing the optical fibers (2) to the softening point by indirectly heating them through the support (13); - subjecting the optical fibers (2) to traction; - having made the passive component, fix the optical fibers (2) to the support (13) and separate the passive component from the means (1) suitable for subjecting the optical fibers (2) to traction. 2) Method as in claim 1 implemented by means of an apparatus comprising at least, in combination with each other, a heating element (3), means (1) suitable for subjecting the optical fibers (2) forming the passive component to traction and control means and adjustment of the heating element (3), characterized in that the heating element (3) is fed by induction and indirectly heats the optical fibers (2) constituting the passive component. 3) Method as in claim 2, characterized by the fact that the heating element (3) comprises an external cylindrical body (12) inside which there is an internal cylindrical body (11) inside which an axial hole is made in which is placed the support (13) inside which the optical fibers (2) are placed. 4) Method as in claim 3, characterized in that the internal cylindrical body (11) is heated by induction by a radiofrequency signal emitted by a generator belonging to the control and regulation means. 5) Method as in claim 3, characterized in that the external cylindrical body (12) is made of a material transparent to radiofrequency. 6) Method as in claim 5, characterized in that the external cylindrical body (12) is made of quartz or a ceramic material. 7) Method as in claim 3, characterized by the fact that the external cylindrical body (12) has an opening (14) which faces the control and adjustment means of the heating element (3). 8) Method as in claim 3, characterized in that the internal cylindrical body (11) is made of platinum or its alloys or graphite and its compounds with alumina and zirconia. 9) Method as in claim 8, characterized in that the internal cylindrical body (11) is made of platinum with a purity greater than 99%. 10) Method as in claim 8, in which the internal cylindrical body (11) is made of platinum alloys or graphite and its compounds with alumina and zirconia, characterized by the fact that inside the internal cylindrical body (11) it is maintained an atmosphere saturated with inert gas. 11) Method as in claim 2, characterized in that the length of the internal cylindrical body (11) is between 4 and 30 mm, its internal diameter is between 1 and 5 mm and its external diameter is between 6 and 12 mm. 12) Method as in claim 2, characterized in that the operating temperature, measured on the external wall of the internal cylindrical body (11), is comprised between 1300 and 1900 ° C. 13) Method as in claim 3, characterized in that the support (13) consists of a quartz capillary tube. 14) Method as in claim 1 for making standard passive components, characterized in that the optical fibers (2) are fixed to the support (13) by means of a polymeric resin. 15) Method as in claim 1 for making hermetic passive components, characterized in that the optical fibers (2) are fixed to the support (13) by means of a hermetically sealed resin which seals the passive component inside the support (13). 16) Method as in claim 13, characterized by the fact that the quartz capillary tube which constitutes the support (13) has, towards each end, a window (20) suitable for exposing the optical fibers (2) and guaranteeing a optimal anchoring of the resin to the support (13) and by the fact that, once the passive component has been made, the optical fibers (2) are fixed to the support (13) by means of two drops of resin (21) which occlude the windows (20) and the quartz tube. 17) Method as in claim 13, characterized by the fact that the quartz tube which constitutes the support (13) has a length between 10 and 150 mm, an external diameter between 0.8 and 4.8 mm and an internal diameter between 0.5 and 4.5mm. 18) Method as in claim 16, characterized in that the windows (20) have a length of between 1 and 30 millimeters.